Affiliations
Harvard Medical School
Department of Medicine, Massachusetts General Hospital, Boston, Massachusetts
Given name(s)
Stephanie
Family name
Mueller
Degrees
MD, MPH

An On-Treatment Analysis of the MARQUIS Study: Interventions to Improve Inpatient Medication Reconciliation

Article Type
Changed
Sun, 10/13/2019 - 21:47

Unintentional medication discrepancies in the hospital setting are common and contribute to adverse drug events, resulting in patient harm.1 Discrepancies can be resolved by implementing high-quality medication reconciliation, but there are insufficient data to guide hospitals as to which interventions are most effective at improving medication reconciliation processes and reducing harm.2 We recently reported that implementation of a best practices toolkit reduced total medication discrepancies in the Multi-Center Medication Reconciliation Quality Improvement Study (MARQUIS).3 This report describes the effect of individual toolkit components on rates of medication discrepancies with the potential for patient harm.

METHODS

Detailed descriptions of the intervention toolkit and study design of MARQUIS are published.4,5 Briefly, MARQUIS was a pragmatic, mentored, quality improvement (QI) study in which five hospitals in the United States implemented interventions from a best practices toolkit to improve medication reconciliation on noncritical care medical and surgical units from September 2011 to July 2014. We used a mentored implementation approach, in which each site identified the leaders of their local quality improvement team (ie, mentees) who received mentorship from a trained physician with QI and medication safety experience.6 Mentors conducted monthly calls with their mentees and two site visits. Sites adapted and implemented one or more components from the MARQUIS toolkit, a compilation of evidence-based best practices in medication reconciliation.5,7

The primary outcome was unintentional medication discrepancies in admission and discharge orders with the potential for causing harm, as previously described.4 Trained study pharmacists at each site took “gold standard” medication histories on a random sample of up to 22 patients per month. These medications were then compared with admission and discharge medication orders, and all unintentional discrepancies were identified. The discrepancies were then adjudicated by physicians blinded to the treatment arm, who confirmed whether discrepancies were unintentional and carried the potential for patient harm.

We employed a modification of a stepped wedge methodology to measure the incremental effect of implementing nine different intervention components, introduced at different sites over the course of the study, on the number of potentially harmful discrepancies per patient. These analyses were restricted to the postimplementation period on hospital units that implemented at least one intervention. All interventions conducted at each site were categorized by component, including dates of implementation. Each intervention component could be applied more than once per site (eg, when involving a new group of providers) or implemented on a new hospital unit or service, in which case, all dates were included in the analysis. We conducted a multivariable Poisson regression (with time divided into months) adjusted for patient factors, season, and site, with the number of potentially harmful discrepancies as the dependent variable, and the total number of gold standard medications as a model offset. The model was designed to analyze changes in the y-intercept each time an intervention component was either implemented or spread and assumed the change in the y-intercept was the same for each of these events for any given component. The model also assumes that combinations of interventions had independent additive effects.

 

 

RESULTS

Across the five participating sites, 1,648 patients were enrolled from September 2011 to July 2014. This number included 613 patients during the preimplementation period and 1,035 patients during the postimplementation period, of which 791 were on intervention units and comprised the study population. Table 1 displays the intervention components implemented by site. Sites implemented between one and seven components. The most frequently implemented intervention component was training existing staff to take the best possible medication histories (BPMHs), implemented at four sites. The regression results are displayed in Table 2. Three interventions were associated with significant decreases in potentially harmful discrepancy rates: (1) clearly defining roles and responsibilities and communicating this with clinical staff (hazard ratio [HR] 0.53, 95% CI: 0.32–0.87); (2) training existing staff to perform discharge medication reconciliation and patient counseling (HR 0.64, 95% CI: 0.46–0.89); and (3) hiring additional staff to perform discharge medication reconciliation and patient counseling (HR 0.48, 95% CI: 0.31–0.77). Two interventions were associated with significant increases in potentially harmful discrepancy rates: training existing staff to take BPMHs (HR 1.38, 95% CI: 1.21–1.57) and implementing a new electronic health record (EHR; HR 2.21, 95% CI: 1.64–2.97).

DISCUSSION

We noted that three intervention components were associated with decreased rates of unintentional medication discrepancies with potential for harm, whereas two were associated with increased rates. The components with a beneficial effect were not surprising. A prior qualitative study demonstrated the confusion related to clinicians’ roles and responsibilities during medication reconciliation; therefore, clear delineations should reduce rework and improve the medication reconciliation process.8 Other studies have shown the benefits of pharmacist involvement in the inpatient setting, particularly in reducing errors at discharge.9 However, we did not anticipate that training staff to take BPMHs would be detrimental. Possible reasons for this finding that are based on direct observations by mentors at site visits or noted during monthly calls include (1) training personnel on this task without certification of competency may not sufficiently improve their skills, leading instead to diffusion of responsibility; (2) training personnel without sufficient time to perform the task well (eg, frontline nurses with many other responsibilities) may be counterproductive compared with training a few personnel with time dedicated to this task; and (3) training existing personnel in history-taking may have been used to delay the necessary hiring of more staff to take BPMHs. Future studies could address several of these shortcomings in both the design and implementation of medication history-training intervention components.

Several reasons may explain the association we found between implementing a new EHR and increased rates of discrepancies. Based on mentors’ experiences, we suspect it is because sitewide EHR implementation requires significant resources, time, and effort. Therefore, sitewide EHR implementation pulls attention away from a focus on medication safety. Most large vendor EHRs have design flaws in their medication reconciliation modules, with the overarching problem being that their systems are not designed for an interdisciplinary team approach to medication reconciliation (unpublished material). In addition, problems may also exist with the local implementation of these modules and the way they are used by clinicians (eg, bypassing critical steps in the medication reconciliation process that lead to new medication errors). We have updated the MARQUIS toolkit to include pros and cons of EHR software and ideal features and functions of medication reconciliation information technology. We should note that this finding contrasts with previous studies that showed beneficial effects of dedicated medication reconciliation applications, which used proprietary technology, often combined with process redesign, in a focused QI effort.10-13 These findings suggest the need for improvements in the design, local customization, and use of medication reconciliation modules in vendor EHRs.

Our study has several limitations. We conducted an on-treatment analysis, which may be confounded by characteristics of sites that chose to implement different intervention components; however, we adjusted for sites in the analysis. Some results are based on a limited number of sites implementing an intervention component (eg, defining roles and responsibilities). Although this was a longitudinal study, and we adjusted for seasonal effects, it is possible that temporal trends and cointerventions confounded our results. The adjudication of discrepancies for the potential for harm was somewhat subjective, although we used a rigorous process to ensure the reliability of adjudication, as in prior studies.3,14 As in the main analysis of the MARQUIS study, this analysis did not measure intervention fidelity.

Based on these analyses and the literature base, we recommend that hospitals focus first on hiring and training dedicated staff (usually pharmacists) to assist with medication reconciliation at discharge.7 Hospitals should also be aware of potential increases in medication discrepancies when implementing a large vendor EHR across their institution. Further work is needed on the best ways to mitigate these adverse effects, at both the design and local site levels. Finally, the effect of medication history training on discrepancies warrants further study.

 

 

Disclosures

SK has served as a consultant to Verustat, a remote health monitoring company. All other authors have no disclosures or conflicts of interests.

Funding

This study was supported by the Agency for Healthcare Research and Quality (grant number: R18 HS019598). JLS has received funding from (1) Mallinckrodt Pharmaceuticals for an investigator-initiated study of opioid-related adverse drug events in postsurgical patients; (2) Horizon Blue Cross Blue Shield for an honorarium and travel expenses for workshop on medication reconciliation; (3) Island Peer Review Organization for honorarium and travel expenses for workshop on medication reconciliation; and, (4) Portola Pharmaceuticals for investigator-initiated study of inpatients who decline subcutaneous medications for venous thromboembolism prophylaxis. ASM was funded by a VA HSR&D Career Development Award (12-168).

Trial Registration

ClinicalTrials.gov NCT01337063

References

1. Cornish PL, Knowles SR, Marchesano R, et al. Unintended medication discrepancies at the time of hospital admission. Arch Intern Med. 2005;165(4):424-429. https://doi.org/10.1001/archinte.165.4.424.
2. Kaboli PJ, Fernandes O. Medication reconciliation: moving forward. Arch Intern Med. 2012;172(14):1069-1070. https://doi.org/10.1001/archinternmed.2012.2667. PubMed
3. Schnipper JL, Mixon A, Stein J, et al. Effects of a multifaceted medication reconciliation quality improvement intervention on patient safety: final results of the MARQUIS study. BMJ Qual Saf. 2018;27(12):954-964. https://doi.org/10.1136/bmjqs-2018-008233.
4. Salanitro AH, Kripalani S, Resnic J, et al. Rational and design of the Multicenter Medication Reconciliation Quality Improvement Study (MARQUIS). BMC Health Serv Res. 2013;13:230. https://doi.org/10.1186/1472-6963-13-230.
5. Mueller SK, Kripalani S, Stein J, et al. Development of a toolkit to disseminate best practices in inpatient medication reconciliation. Jt Comm J Qual Patient Saf. 2013;39(8):371-382. https://10.1016/S1553-7250(13)39051-5.
6. Maynard GA, Budnitz TL, Nickel WK, et al. 2011 John M. Eisenberg patient safety and quality awards. Mentored implementation: building leaders and achieving results through a collaborative improvement model. Innovation in patient safety and quality at the national level. Jt Comm J Qual Patient Saf. 2012;38(7):301-310. https://doi.org/10.1016/S1553-7250(12)38040-9.
7. Mueller SK, Sponsler KC, Kripalani S, Schnipper JL. Hospital-based medication reconciliation practices: a systematic review. Arch Intern Med. 2012;172(14):1057-1069. https://doi.org/10.1001/archinternmed.2012.2246.
8. Vogelsmeier A, Pepper GA, Oderda L, Weir C. Medication reconciliation: a qualitative analysis of clinicians’ perceptions. Res Social Adm Pharm. 2013;9(4):419-430. https://doi.org/10.1016/j.sapharm.2012.08.002.
9. Kaboli PJ, Hoth AB, McClimon BJ, Schnipper JL. Clinical pharmacists and inpatient medical care: a systematic review. Arch Intern Med. 2006;166(9):955-964. https://doi.org/10.1001/archinte.166.9.955.
10. Plaisant C, Wu J, Hettinger AZ, Powsner S, Shneiderman B. Novel user interface design for medication reconciliation: an evaluation of Twinlist. J Am Med Inform Assoc. 2015;22(2):340-349. https://doi.org/10.1093/jamia/ocu021.
11. Bassi J, Lau F, Bardal S. Use of information technology in medication reconciliation: a scoping review. Ann Pharmacother. 2010;44(5):885-897. https://doi.org/10.1345/aph.1M699.
12. Marien S, Krug B, Spinewine A. Electronic tools to support medication reconciliation: a systematic review. J Am Med Inform Assoc. 2017;24(1):227-240. https://doi.org/10.1093/jamia/ocw068.
13. Agrawal A. Medication errors: prevention using information technology systems. Br J Clin Pharmacol. 2009;67(6):681-686. https://doi.org/10.1111/j.1365-2125.2009.03427.x.
14. Pippins JR, Gandhi TK, Hamann C, et al. Classifying and predicting errors of inpatient medication reconciliation. J Gen Intern Med. 2008;23(9):1414-1422. https://doi.org/10.1007/s11606-008-0687-9.

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Related Articles

Unintentional medication discrepancies in the hospital setting are common and contribute to adverse drug events, resulting in patient harm.1 Discrepancies can be resolved by implementing high-quality medication reconciliation, but there are insufficient data to guide hospitals as to which interventions are most effective at improving medication reconciliation processes and reducing harm.2 We recently reported that implementation of a best practices toolkit reduced total medication discrepancies in the Multi-Center Medication Reconciliation Quality Improvement Study (MARQUIS).3 This report describes the effect of individual toolkit components on rates of medication discrepancies with the potential for patient harm.

METHODS

Detailed descriptions of the intervention toolkit and study design of MARQUIS are published.4,5 Briefly, MARQUIS was a pragmatic, mentored, quality improvement (QI) study in which five hospitals in the United States implemented interventions from a best practices toolkit to improve medication reconciliation on noncritical care medical and surgical units from September 2011 to July 2014. We used a mentored implementation approach, in which each site identified the leaders of their local quality improvement team (ie, mentees) who received mentorship from a trained physician with QI and medication safety experience.6 Mentors conducted monthly calls with their mentees and two site visits. Sites adapted and implemented one or more components from the MARQUIS toolkit, a compilation of evidence-based best practices in medication reconciliation.5,7

The primary outcome was unintentional medication discrepancies in admission and discharge orders with the potential for causing harm, as previously described.4 Trained study pharmacists at each site took “gold standard” medication histories on a random sample of up to 22 patients per month. These medications were then compared with admission and discharge medication orders, and all unintentional discrepancies were identified. The discrepancies were then adjudicated by physicians blinded to the treatment arm, who confirmed whether discrepancies were unintentional and carried the potential for patient harm.

We employed a modification of a stepped wedge methodology to measure the incremental effect of implementing nine different intervention components, introduced at different sites over the course of the study, on the number of potentially harmful discrepancies per patient. These analyses were restricted to the postimplementation period on hospital units that implemented at least one intervention. All interventions conducted at each site were categorized by component, including dates of implementation. Each intervention component could be applied more than once per site (eg, when involving a new group of providers) or implemented on a new hospital unit or service, in which case, all dates were included in the analysis. We conducted a multivariable Poisson regression (with time divided into months) adjusted for patient factors, season, and site, with the number of potentially harmful discrepancies as the dependent variable, and the total number of gold standard medications as a model offset. The model was designed to analyze changes in the y-intercept each time an intervention component was either implemented or spread and assumed the change in the y-intercept was the same for each of these events for any given component. The model also assumes that combinations of interventions had independent additive effects.

 

 

RESULTS

Across the five participating sites, 1,648 patients were enrolled from September 2011 to July 2014. This number included 613 patients during the preimplementation period and 1,035 patients during the postimplementation period, of which 791 were on intervention units and comprised the study population. Table 1 displays the intervention components implemented by site. Sites implemented between one and seven components. The most frequently implemented intervention component was training existing staff to take the best possible medication histories (BPMHs), implemented at four sites. The regression results are displayed in Table 2. Three interventions were associated with significant decreases in potentially harmful discrepancy rates: (1) clearly defining roles and responsibilities and communicating this with clinical staff (hazard ratio [HR] 0.53, 95% CI: 0.32–0.87); (2) training existing staff to perform discharge medication reconciliation and patient counseling (HR 0.64, 95% CI: 0.46–0.89); and (3) hiring additional staff to perform discharge medication reconciliation and patient counseling (HR 0.48, 95% CI: 0.31–0.77). Two interventions were associated with significant increases in potentially harmful discrepancy rates: training existing staff to take BPMHs (HR 1.38, 95% CI: 1.21–1.57) and implementing a new electronic health record (EHR; HR 2.21, 95% CI: 1.64–2.97).

DISCUSSION

We noted that three intervention components were associated with decreased rates of unintentional medication discrepancies with potential for harm, whereas two were associated with increased rates. The components with a beneficial effect were not surprising. A prior qualitative study demonstrated the confusion related to clinicians’ roles and responsibilities during medication reconciliation; therefore, clear delineations should reduce rework and improve the medication reconciliation process.8 Other studies have shown the benefits of pharmacist involvement in the inpatient setting, particularly in reducing errors at discharge.9 However, we did not anticipate that training staff to take BPMHs would be detrimental. Possible reasons for this finding that are based on direct observations by mentors at site visits or noted during monthly calls include (1) training personnel on this task without certification of competency may not sufficiently improve their skills, leading instead to diffusion of responsibility; (2) training personnel without sufficient time to perform the task well (eg, frontline nurses with many other responsibilities) may be counterproductive compared with training a few personnel with time dedicated to this task; and (3) training existing personnel in history-taking may have been used to delay the necessary hiring of more staff to take BPMHs. Future studies could address several of these shortcomings in both the design and implementation of medication history-training intervention components.

Several reasons may explain the association we found between implementing a new EHR and increased rates of discrepancies. Based on mentors’ experiences, we suspect it is because sitewide EHR implementation requires significant resources, time, and effort. Therefore, sitewide EHR implementation pulls attention away from a focus on medication safety. Most large vendor EHRs have design flaws in their medication reconciliation modules, with the overarching problem being that their systems are not designed for an interdisciplinary team approach to medication reconciliation (unpublished material). In addition, problems may also exist with the local implementation of these modules and the way they are used by clinicians (eg, bypassing critical steps in the medication reconciliation process that lead to new medication errors). We have updated the MARQUIS toolkit to include pros and cons of EHR software and ideal features and functions of medication reconciliation information technology. We should note that this finding contrasts with previous studies that showed beneficial effects of dedicated medication reconciliation applications, which used proprietary technology, often combined with process redesign, in a focused QI effort.10-13 These findings suggest the need for improvements in the design, local customization, and use of medication reconciliation modules in vendor EHRs.

Our study has several limitations. We conducted an on-treatment analysis, which may be confounded by characteristics of sites that chose to implement different intervention components; however, we adjusted for sites in the analysis. Some results are based on a limited number of sites implementing an intervention component (eg, defining roles and responsibilities). Although this was a longitudinal study, and we adjusted for seasonal effects, it is possible that temporal trends and cointerventions confounded our results. The adjudication of discrepancies for the potential for harm was somewhat subjective, although we used a rigorous process to ensure the reliability of adjudication, as in prior studies.3,14 As in the main analysis of the MARQUIS study, this analysis did not measure intervention fidelity.

Based on these analyses and the literature base, we recommend that hospitals focus first on hiring and training dedicated staff (usually pharmacists) to assist with medication reconciliation at discharge.7 Hospitals should also be aware of potential increases in medication discrepancies when implementing a large vendor EHR across their institution. Further work is needed on the best ways to mitigate these adverse effects, at both the design and local site levels. Finally, the effect of medication history training on discrepancies warrants further study.

 

 

Disclosures

SK has served as a consultant to Verustat, a remote health monitoring company. All other authors have no disclosures or conflicts of interests.

Funding

This study was supported by the Agency for Healthcare Research and Quality (grant number: R18 HS019598). JLS has received funding from (1) Mallinckrodt Pharmaceuticals for an investigator-initiated study of opioid-related adverse drug events in postsurgical patients; (2) Horizon Blue Cross Blue Shield for an honorarium and travel expenses for workshop on medication reconciliation; (3) Island Peer Review Organization for honorarium and travel expenses for workshop on medication reconciliation; and, (4) Portola Pharmaceuticals for investigator-initiated study of inpatients who decline subcutaneous medications for venous thromboembolism prophylaxis. ASM was funded by a VA HSR&D Career Development Award (12-168).

Trial Registration

ClinicalTrials.gov NCT01337063

Unintentional medication discrepancies in the hospital setting are common and contribute to adverse drug events, resulting in patient harm.1 Discrepancies can be resolved by implementing high-quality medication reconciliation, but there are insufficient data to guide hospitals as to which interventions are most effective at improving medication reconciliation processes and reducing harm.2 We recently reported that implementation of a best practices toolkit reduced total medication discrepancies in the Multi-Center Medication Reconciliation Quality Improvement Study (MARQUIS).3 This report describes the effect of individual toolkit components on rates of medication discrepancies with the potential for patient harm.

METHODS

Detailed descriptions of the intervention toolkit and study design of MARQUIS are published.4,5 Briefly, MARQUIS was a pragmatic, mentored, quality improvement (QI) study in which five hospitals in the United States implemented interventions from a best practices toolkit to improve medication reconciliation on noncritical care medical and surgical units from September 2011 to July 2014. We used a mentored implementation approach, in which each site identified the leaders of their local quality improvement team (ie, mentees) who received mentorship from a trained physician with QI and medication safety experience.6 Mentors conducted monthly calls with their mentees and two site visits. Sites adapted and implemented one or more components from the MARQUIS toolkit, a compilation of evidence-based best practices in medication reconciliation.5,7

The primary outcome was unintentional medication discrepancies in admission and discharge orders with the potential for causing harm, as previously described.4 Trained study pharmacists at each site took “gold standard” medication histories on a random sample of up to 22 patients per month. These medications were then compared with admission and discharge medication orders, and all unintentional discrepancies were identified. The discrepancies were then adjudicated by physicians blinded to the treatment arm, who confirmed whether discrepancies were unintentional and carried the potential for patient harm.

We employed a modification of a stepped wedge methodology to measure the incremental effect of implementing nine different intervention components, introduced at different sites over the course of the study, on the number of potentially harmful discrepancies per patient. These analyses were restricted to the postimplementation period on hospital units that implemented at least one intervention. All interventions conducted at each site were categorized by component, including dates of implementation. Each intervention component could be applied more than once per site (eg, when involving a new group of providers) or implemented on a new hospital unit or service, in which case, all dates were included in the analysis. We conducted a multivariable Poisson regression (with time divided into months) adjusted for patient factors, season, and site, with the number of potentially harmful discrepancies as the dependent variable, and the total number of gold standard medications as a model offset. The model was designed to analyze changes in the y-intercept each time an intervention component was either implemented or spread and assumed the change in the y-intercept was the same for each of these events for any given component. The model also assumes that combinations of interventions had independent additive effects.

 

 

RESULTS

Across the five participating sites, 1,648 patients were enrolled from September 2011 to July 2014. This number included 613 patients during the preimplementation period and 1,035 patients during the postimplementation period, of which 791 were on intervention units and comprised the study population. Table 1 displays the intervention components implemented by site. Sites implemented between one and seven components. The most frequently implemented intervention component was training existing staff to take the best possible medication histories (BPMHs), implemented at four sites. The regression results are displayed in Table 2. Three interventions were associated with significant decreases in potentially harmful discrepancy rates: (1) clearly defining roles and responsibilities and communicating this with clinical staff (hazard ratio [HR] 0.53, 95% CI: 0.32–0.87); (2) training existing staff to perform discharge medication reconciliation and patient counseling (HR 0.64, 95% CI: 0.46–0.89); and (3) hiring additional staff to perform discharge medication reconciliation and patient counseling (HR 0.48, 95% CI: 0.31–0.77). Two interventions were associated with significant increases in potentially harmful discrepancy rates: training existing staff to take BPMHs (HR 1.38, 95% CI: 1.21–1.57) and implementing a new electronic health record (EHR; HR 2.21, 95% CI: 1.64–2.97).

DISCUSSION

We noted that three intervention components were associated with decreased rates of unintentional medication discrepancies with potential for harm, whereas two were associated with increased rates. The components with a beneficial effect were not surprising. A prior qualitative study demonstrated the confusion related to clinicians’ roles and responsibilities during medication reconciliation; therefore, clear delineations should reduce rework and improve the medication reconciliation process.8 Other studies have shown the benefits of pharmacist involvement in the inpatient setting, particularly in reducing errors at discharge.9 However, we did not anticipate that training staff to take BPMHs would be detrimental. Possible reasons for this finding that are based on direct observations by mentors at site visits or noted during monthly calls include (1) training personnel on this task without certification of competency may not sufficiently improve their skills, leading instead to diffusion of responsibility; (2) training personnel without sufficient time to perform the task well (eg, frontline nurses with many other responsibilities) may be counterproductive compared with training a few personnel with time dedicated to this task; and (3) training existing personnel in history-taking may have been used to delay the necessary hiring of more staff to take BPMHs. Future studies could address several of these shortcomings in both the design and implementation of medication history-training intervention components.

Several reasons may explain the association we found between implementing a new EHR and increased rates of discrepancies. Based on mentors’ experiences, we suspect it is because sitewide EHR implementation requires significant resources, time, and effort. Therefore, sitewide EHR implementation pulls attention away from a focus on medication safety. Most large vendor EHRs have design flaws in their medication reconciliation modules, with the overarching problem being that their systems are not designed for an interdisciplinary team approach to medication reconciliation (unpublished material). In addition, problems may also exist with the local implementation of these modules and the way they are used by clinicians (eg, bypassing critical steps in the medication reconciliation process that lead to new medication errors). We have updated the MARQUIS toolkit to include pros and cons of EHR software and ideal features and functions of medication reconciliation information technology. We should note that this finding contrasts with previous studies that showed beneficial effects of dedicated medication reconciliation applications, which used proprietary technology, often combined with process redesign, in a focused QI effort.10-13 These findings suggest the need for improvements in the design, local customization, and use of medication reconciliation modules in vendor EHRs.

Our study has several limitations. We conducted an on-treatment analysis, which may be confounded by characteristics of sites that chose to implement different intervention components; however, we adjusted for sites in the analysis. Some results are based on a limited number of sites implementing an intervention component (eg, defining roles and responsibilities). Although this was a longitudinal study, and we adjusted for seasonal effects, it is possible that temporal trends and cointerventions confounded our results. The adjudication of discrepancies for the potential for harm was somewhat subjective, although we used a rigorous process to ensure the reliability of adjudication, as in prior studies.3,14 As in the main analysis of the MARQUIS study, this analysis did not measure intervention fidelity.

Based on these analyses and the literature base, we recommend that hospitals focus first on hiring and training dedicated staff (usually pharmacists) to assist with medication reconciliation at discharge.7 Hospitals should also be aware of potential increases in medication discrepancies when implementing a large vendor EHR across their institution. Further work is needed on the best ways to mitigate these adverse effects, at both the design and local site levels. Finally, the effect of medication history training on discrepancies warrants further study.

 

 

Disclosures

SK has served as a consultant to Verustat, a remote health monitoring company. All other authors have no disclosures or conflicts of interests.

Funding

This study was supported by the Agency for Healthcare Research and Quality (grant number: R18 HS019598). JLS has received funding from (1) Mallinckrodt Pharmaceuticals for an investigator-initiated study of opioid-related adverse drug events in postsurgical patients; (2) Horizon Blue Cross Blue Shield for an honorarium and travel expenses for workshop on medication reconciliation; (3) Island Peer Review Organization for honorarium and travel expenses for workshop on medication reconciliation; and, (4) Portola Pharmaceuticals for investigator-initiated study of inpatients who decline subcutaneous medications for venous thromboembolism prophylaxis. ASM was funded by a VA HSR&D Career Development Award (12-168).

Trial Registration

ClinicalTrials.gov NCT01337063

References

1. Cornish PL, Knowles SR, Marchesano R, et al. Unintended medication discrepancies at the time of hospital admission. Arch Intern Med. 2005;165(4):424-429. https://doi.org/10.1001/archinte.165.4.424.
2. Kaboli PJ, Fernandes O. Medication reconciliation: moving forward. Arch Intern Med. 2012;172(14):1069-1070. https://doi.org/10.1001/archinternmed.2012.2667. PubMed
3. Schnipper JL, Mixon A, Stein J, et al. Effects of a multifaceted medication reconciliation quality improvement intervention on patient safety: final results of the MARQUIS study. BMJ Qual Saf. 2018;27(12):954-964. https://doi.org/10.1136/bmjqs-2018-008233.
4. Salanitro AH, Kripalani S, Resnic J, et al. Rational and design of the Multicenter Medication Reconciliation Quality Improvement Study (MARQUIS). BMC Health Serv Res. 2013;13:230. https://doi.org/10.1186/1472-6963-13-230.
5. Mueller SK, Kripalani S, Stein J, et al. Development of a toolkit to disseminate best practices in inpatient medication reconciliation. Jt Comm J Qual Patient Saf. 2013;39(8):371-382. https://10.1016/S1553-7250(13)39051-5.
6. Maynard GA, Budnitz TL, Nickel WK, et al. 2011 John M. Eisenberg patient safety and quality awards. Mentored implementation: building leaders and achieving results through a collaborative improvement model. Innovation in patient safety and quality at the national level. Jt Comm J Qual Patient Saf. 2012;38(7):301-310. https://doi.org/10.1016/S1553-7250(12)38040-9.
7. Mueller SK, Sponsler KC, Kripalani S, Schnipper JL. Hospital-based medication reconciliation practices: a systematic review. Arch Intern Med. 2012;172(14):1057-1069. https://doi.org/10.1001/archinternmed.2012.2246.
8. Vogelsmeier A, Pepper GA, Oderda L, Weir C. Medication reconciliation: a qualitative analysis of clinicians’ perceptions. Res Social Adm Pharm. 2013;9(4):419-430. https://doi.org/10.1016/j.sapharm.2012.08.002.
9. Kaboli PJ, Hoth AB, McClimon BJ, Schnipper JL. Clinical pharmacists and inpatient medical care: a systematic review. Arch Intern Med. 2006;166(9):955-964. https://doi.org/10.1001/archinte.166.9.955.
10. Plaisant C, Wu J, Hettinger AZ, Powsner S, Shneiderman B. Novel user interface design for medication reconciliation: an evaluation of Twinlist. J Am Med Inform Assoc. 2015;22(2):340-349. https://doi.org/10.1093/jamia/ocu021.
11. Bassi J, Lau F, Bardal S. Use of information technology in medication reconciliation: a scoping review. Ann Pharmacother. 2010;44(5):885-897. https://doi.org/10.1345/aph.1M699.
12. Marien S, Krug B, Spinewine A. Electronic tools to support medication reconciliation: a systematic review. J Am Med Inform Assoc. 2017;24(1):227-240. https://doi.org/10.1093/jamia/ocw068.
13. Agrawal A. Medication errors: prevention using information technology systems. Br J Clin Pharmacol. 2009;67(6):681-686. https://doi.org/10.1111/j.1365-2125.2009.03427.x.
14. Pippins JR, Gandhi TK, Hamann C, et al. Classifying and predicting errors of inpatient medication reconciliation. J Gen Intern Med. 2008;23(9):1414-1422. https://doi.org/10.1007/s11606-008-0687-9.

References

1. Cornish PL, Knowles SR, Marchesano R, et al. Unintended medication discrepancies at the time of hospital admission. Arch Intern Med. 2005;165(4):424-429. https://doi.org/10.1001/archinte.165.4.424.
2. Kaboli PJ, Fernandes O. Medication reconciliation: moving forward. Arch Intern Med. 2012;172(14):1069-1070. https://doi.org/10.1001/archinternmed.2012.2667. PubMed
3. Schnipper JL, Mixon A, Stein J, et al. Effects of a multifaceted medication reconciliation quality improvement intervention on patient safety: final results of the MARQUIS study. BMJ Qual Saf. 2018;27(12):954-964. https://doi.org/10.1136/bmjqs-2018-008233.
4. Salanitro AH, Kripalani S, Resnic J, et al. Rational and design of the Multicenter Medication Reconciliation Quality Improvement Study (MARQUIS). BMC Health Serv Res. 2013;13:230. https://doi.org/10.1186/1472-6963-13-230.
5. Mueller SK, Kripalani S, Stein J, et al. Development of a toolkit to disseminate best practices in inpatient medication reconciliation. Jt Comm J Qual Patient Saf. 2013;39(8):371-382. https://10.1016/S1553-7250(13)39051-5.
6. Maynard GA, Budnitz TL, Nickel WK, et al. 2011 John M. Eisenberg patient safety and quality awards. Mentored implementation: building leaders and achieving results through a collaborative improvement model. Innovation in patient safety and quality at the national level. Jt Comm J Qual Patient Saf. 2012;38(7):301-310. https://doi.org/10.1016/S1553-7250(12)38040-9.
7. Mueller SK, Sponsler KC, Kripalani S, Schnipper JL. Hospital-based medication reconciliation practices: a systematic review. Arch Intern Med. 2012;172(14):1057-1069. https://doi.org/10.1001/archinternmed.2012.2246.
8. Vogelsmeier A, Pepper GA, Oderda L, Weir C. Medication reconciliation: a qualitative analysis of clinicians’ perceptions. Res Social Adm Pharm. 2013;9(4):419-430. https://doi.org/10.1016/j.sapharm.2012.08.002.
9. Kaboli PJ, Hoth AB, McClimon BJ, Schnipper JL. Clinical pharmacists and inpatient medical care: a systematic review. Arch Intern Med. 2006;166(9):955-964. https://doi.org/10.1001/archinte.166.9.955.
10. Plaisant C, Wu J, Hettinger AZ, Powsner S, Shneiderman B. Novel user interface design for medication reconciliation: an evaluation of Twinlist. J Am Med Inform Assoc. 2015;22(2):340-349. https://doi.org/10.1093/jamia/ocu021.
11. Bassi J, Lau F, Bardal S. Use of information technology in medication reconciliation: a scoping review. Ann Pharmacother. 2010;44(5):885-897. https://doi.org/10.1345/aph.1M699.
12. Marien S, Krug B, Spinewine A. Electronic tools to support medication reconciliation: a systematic review. J Am Med Inform Assoc. 2017;24(1):227-240. https://doi.org/10.1093/jamia/ocw068.
13. Agrawal A. Medication errors: prevention using information technology systems. Br J Clin Pharmacol. 2009;67(6):681-686. https://doi.org/10.1111/j.1365-2125.2009.03427.x.
14. Pippins JR, Gandhi TK, Hamann C, et al. Classifying and predicting errors of inpatient medication reconciliation. J Gen Intern Med. 2008;23(9):1414-1422. https://doi.org/10.1007/s11606-008-0687-9.

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*Corresponding Author: Amanda S. Mixon, MD, MS, MSPH, FHM; E-mail: Amanda.S.Mixon@vumc.org; Telephone: 615-936-3710; Twitter: @mixovida.
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State of Research in Adult Hospital Medicine: Results of a National Survey

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Almost all specialties in internal medicine have a sound scientific research base through which clinical practice is informed.1 For the field of Hospital Medicine (HM), this evidence has largely comprised research generated from fields outside of the specialty. The need to develop, invest, and grow investigators in hospital-based medicine remains unmet as HM and its footprint in hospital systems continue to grow.2,3

Despite this fact, little is known about the current state of research in HM. A 2014 survey of the members of the Society of Hospital Medicine (SHM) found that research output across the field of HM, as measured on the basis of peer-reviewed publications, was growing.4 Since then, however, the numbers of individuals engaged in research activities, their background and training, publication output, or funding sources have not been quantified. Similarly, little is known about which institutions support the development of junior investigators (ie, HM research fellowships), how these programs are funded, and whether or not matriculants enter the field as investigators. These gaps must be measured, evaluated, and ideally addressed through strategic policy and funding initiatives to advance the state of science within HM.

Members of the SHM Research Committee developed, designed, and deployed a survey to improve the understanding of the state of research in HM. In this study, we aimed to establish the baseline of research in HM to enable the measurement of progress through periodic waves of data collection. Specifically, we sought to quantify and describe the characteristics of existing research programs, the sources and types of funding, the number and background of faculty, and the availability of resources for training researchers in HM.

 

 

METHODS

Study Setting and Participants

Given that no defined list, database, or external resource that identifies research programs and contacts in HM exists, we began by creating a strategy to identify and sample adult HM programs and their leaders engaged in research activity. We iteratively developed a two-step approach to maximize inclusivity. First, we partnered with SHM to identify programs and leaders actively engaging in research activities. SHM is the largest professional organization within HM and maintains an extensive membership database that includes the titles, e-mail addresses, and affiliations of hospitalists in the United States, including academic and nonacademic sites. This list was manually scanned, and the leaders of academic and research programs in adult HM were identified by examining their titles (eg, Division Chief, Research Lead, etc.) and academic affiliations. During this step, members of the committee noticed that certain key individuals were either missing, no longer occupying their role/title, or had been replaced by others. Therefore, we performed a second step and asked the members of the SHM Research Committee to identify academic and research leaders by using current personal contacts, publication history, and social networks. We asked members to identify individuals and programs that had received grant funding, were actively presenting research at SHM (or other major national venues), and/or were producing peer-reviewed publications related to HM. These programs were purposefully chosen (ie, over HM programs known for clinical activities) to create an enriched sample of those engaged in research in HM. The research committee performed the “second pass” to ensure that established investigators who may not be accurately captured within the SHM database were included to maximize yield for the survey. Finally, these two sources were merged to ensure the absence of duplicate contacts and the identification of a primary respondent for each affiliate. As a result, a convenience sample of 100 programs and corresponding individuals was compiled for the purposes of this survey.

Survey Development

A workgroup within the SHM Research Committee was tasked to create a survey that would achieve four distinct goals: (1) identify institutions currently engaging in hospital-based research; (2) define the characteristics, including sources of research funding, training opportunities, criteria for promotion, and grant support, of research programs within institutions; (3) understand the prevalence of research fellowship programs, including size, training curricula, and funding sources; and (4) evaluate the productivity and funding sources of HM investigators at each site.

Survey questions that target each of these domains were drafted by the workgroup. Questions were pretested with colleagues outside the workgroup focused on this project (ie, from the main research committee). The instrument was refined and edited to improve the readability and clarity of questions on the basis of the feedback obtained through the iterative process. The revised instrument was then programmed into an online survey administration tool (SurveyMonkey®) to facilitate electronic dissemination. Finally, the members of the workgroup tested the online survey to ensure functionality. No identifiable information was collected from respondents, and no monetary incentive was offered for the completion of the survey. An invitation to participate in the survey was sent via e-mail to each of the program contacts identified.

 

 

Statistical Analysis

Descriptive statistics, including proportions, means, and percentages, were used to tabulate results. All analyses were conducted using Stata 13 MP/SE (StataCorp, College Station, Texas).

Ethical and Regulatory Considerations

The study was reviewed and deemed exempt from regulation by the University of Michigan Institutional Review Board (HUM000138628).

RESULTS

General Characteristics of Research Programs and Faculty

Out of 100 program contacts, 28 (representing 1,586 faculty members) responded and were included in the survey (program response rate = 28%). When comparing programs that did respond with those that did not, a greater proportion of programs in university settings were noted among respondents (79% vs 21%). Respondents represented programs from all regions of the United States, with most representing university-based (79%), university-affiliated (14%) or Veterans Health Administration (VHA; 11%) programs. Most respondents were in leadership roles, including division chiefs (32%), research directors/leads (21%), section chiefs (18%), and related titles, such as program director. Respondents indicated that the total number of faculty members in their programs (including nonclinicians and advance practice providers) varied from eight to 152 (mean [SD] = 57 [36]) members, with physicians representing the majority of faculty members (Table 1).

Among the 1,586 faculty members within the 28 programs, respondents identified 192 faculty members (12%) as currently receiving extra- or intramural support for research activities. Of these faculty, over half (58%) received <25% of effort from intra or extramural sources, and 28 (15%) and 52 (27%) faculty members received 25%-50% or >50% of support for their effort, respectively. The number of investigators who received funding across programs ranged from 0 to 28 faculty members. Compared with the 192 funded investigators, respondents indicated that a larger number of faculty in their programs (n = 656 or 41%) were involved in local quality improvement (QI) efforts. Of the 656 faculty members involved in QI efforts, 241 individuals (37%) were internally funded and received protected time/effort for their work.

Key Attributes of Research Programs

In the evaluation of the amount of total grant funding, respondents from 17 programs indicated that they received $500,000 in annual extra and intramural funding, and those from three programs stated that they received $500,000 to $999,999 in funding. Five respondents indicated that their programs currently received $1 million to $5 million in grant funding, and three reported >$5 million in research support. The sources of research funding included several divisions within the National Institute of Health (NIH, 12 programs), Agency for Healthcare Research and Quality (AHRQ, four programs), foundations (four programs), and internal grants (six programs). Additionally, six programs indicated “other” sources of funding that included the VHA, Patient-Centered Outcomes Research Institute (PCORI), Centers for Medicare and Medicaid Services, Centers for Disease Control (CDC), and industry sources.

A range of grants, including career development awards (11 programs); small grants, such as R21 and R03s (eight programs); R-level grants, including VA merit awards (five programs); program series grants, such as P and U grants (five programs), and foundation grants (eight programs), were reported as types of awards. Respondents from 16 programs indicated that they provided internal pilot grants. Amounts for such grants ranged from <$50,000 (14 programs) to $50,000-$100,000 (two programs).

 

 

Research Fellowship Programs/Training Programs

Only five of the 28 surveyed programs indicated that they currently had a research training or fellowship program for developing hospitalist investigators. The age of these programs varied from <1 year to 10 years. Three of the five programs stated that they had two fellows per year, and two stated they had spots for one trainee annually. All respondents indicated that fellows received training on study design, research methods, quantitative (eg, large database and secondary analyses) and qualitative data analysis. In addition, two programs included training in systematic review and meta-analyses, and three included focused courses on healthcare policy. Four of the five programs included training in QI tools, such as LEAN and Six Sigma. Funding for four of the five fellowship programs came from internal sources (eg, department and CTSA). However, two programs added they received some support from extramural funding and philanthropy. Following training, respondents from programs indicated that the majority of their graduates (60%) went on to hybrid research/QI roles (50/50 research/clinical effort), whereas 40% obtained dedicated research investigator (80/20) positions (Table 2).

The 23 institutions without research training programs cited that the most important barrier for establishing such programs was lack of funding (12 programs) and the lack of a pipeline of hospitalists seeking such training (six programs). However, 15 programs indicated that opportunities for hospitalists to gain research training in the form of courses were available internally (eg, courses in the department or medical school) or externally (eg, School of Public Health). Seven programs indicated that they were planning to start a HM research fellowship within the next five years.

Research Faculty

Among the 28 respondents, 15 stated that they have faculty members who conduct research as their main professional activity (ie, >50% effort). The number of faculty members in each program in such roles varied from one to 10. Respondents indicated that faculty members in this category were most often midcareer assistant or associate professors with few full professors. All programs indicated that scholarship in the form of peer-reviewed publications was required for the promotion of faculty. Faculty members who performed research as their main activity had all received formal fellowship training and consequently had dual degrees (MD with MPH or MD, with MSc being the two most common combinations). With respect to clinical activities, most respondents indicated that research faculty spent 10% to 49% of their effort on clinical work. However, five respondents indicated that research faculty had <10% effort on clinical duties (Table 3).

Eleven respondents (39%) identified the main focus of faculty as health service research, where four (14%) identified their main focus as clinical trials. Regardless of funding status, all respondents stated that their faculty were interested in studying quality and process improvement efforts (eg, transitions or readmissions, n = 19), patient safety initiatives (eg, hospital-acquired complications, n = 17), and disease-specific areas (eg, thrombosis, n = 15).

In terms of research output, 12 respondents stated that their research/QI faculty collectively published 11-50 peer-reviewed papers during the academic year, and 10 programs indicated that their faculty published 0-10 papers per year. Only three programs reported that their faculty collectively published 50-99 peer-reviewed papers per year. With respect to abstract presentations at national conferences, 13 programs indicated that they presented 0-10 abstracts, and 12 indicated that they presented 11-50.

 

 

DISCUSSION

In this first survey quantifying research activities in HM, respondents from 28 programs shared important insights into research activities at their institutions. Although our sample size was small, substantial variation in the size, composition, and structure of research programs in HM among respondents was observed. For example, few respondents indicated the availability of training programs for research in HM at their institutions. Similarly, among faculty who focused mainly on research, variation in funding streams and effort protection was observed. A preponderance of midcareer faculty with a range of funding sources, including NIH, AHRQ, VHA, CMS, and CDC was reported. Collectively, these data not only provide a unique glimpse into the state of research in HM but also help establish a baseline of the status of the field at large.

Some findings of our study are intuitive given our sampling strategy and the types of programs that responded. For example, the fact that most respondents for research programs represented university-based or affiliated institutions is expected given the tripartite academic mission. However, even within our sample of highly motivated programs, some findings are surprising and merit further exploration. For example, the observation that some respondents identified HM investigators within their program with <25% in intra- or extramural funding was unexpected. On the other extreme, we were surprised to find that three programs reported >$5 million in research funding. Understanding whether specific factors, such as the availability of experienced mentors within and outside departments or assistance from support staff (eg, statisticians and project managers), are associated with success and funding within these programs are important questions to answer. By focusing on these issues, we will be well poised as a field to understand what works, what does not work, and why.

Likewise, the finding that few programs within our sample offer formal training in the form of fellowships to research investigators represents an improvement opportunity. A pipeline for growing investigators is critical for the specialty that is HM. Notably, this call is not new; rather, previous investigators have highlighted the importance of developing academically oriented hospitalists for the future of the field.5 The implementation of faculty scholarship development programs has improved the scholarly output, mentoring activities, and succession planning of academics within HM.6,7 Conversely, lack of adequate mentorship and support for academic activities remains a challenge and as a factor associated with the failure to produce academic work.8 Without a cadre of investigators asking critical questions related to care delivery, the legitimacy of our field may be threatened.

While extrapolating to the field is difficult given the small number of our respondents, highlighting the progress that has been made is important. For example, while misalignment between funding and clinical and research mission persists, our survey found that several programs have been successful in securing extramural funding for their investigators. Additionally, internal funding for QI work appears to be increasing, with hospitalists receiving dedicated effort for much of this work. Innovation in how best to support and develop these types of efforts have also emerged. For example, the University of Michigan Specialist Hospitalist Allied Research Program offers dedicated effort and funding for hospitalists tackling projects germane to HM (eg, ordering of blood cultures for febrile inpatients) that overlap with subspecialists (eg, infectious diseases).9 Thus, hospitalists are linked with other specialties in the development of research agendas and academic products. Similarly, the launch of the HOMERUN network, a coalition of investigators who bridge health systems to study problems central to HM, has helped usher in a new era of research opportunities in the specialty.10 Fundamentally, the culture of HM has begun to place an emphasis on academic and scholarly productivity in addition to clinical prowess.11-13 Increased support and funding for training programs geared toward innovation and research in HM is needed to continue this mission. The Society for General Internal Medicine, American College of Physicians, and SHM have important roles to play as the largest professional organizations for generalists in this respect. Support for research, QI, and investigators in HM remains an urgent and largely unmet need.

Our study has limitations. First, our response rate was low at 28% but is consistent with the response rates of other surveys of physician groups.14 Caution in making inferences to the field at large is necessary given the potential for selection and nonresponse bias. However, we expect that respondents are likely biased toward programs actively conducting research and engaged in QI, thus better reflecting the state of these activities in HM. Second, given that we did not ask for any identifying information, we have no way of establishing the accuracy of the data provided by respondents. However, we have no reason to believe that responses would be altered in a systematic fashion. Future studies that link our findings to publicly available data (eg, databases of active grants and funding) might be useful. Third, while our survey instrument was created and internally validated by hospitalist researchers, its lack of external validation could limit findings. Finally, our results vary on the basis of how respondents answered questions related to effort and time allocation given that these measures differ across programs.

In summary, the findings from this study highlight substantial variations in the number, training, and funding of research faculty across HM programs. Understanding the factors behind the success of some programs and the failures of others appears important in informing and growing the research in the field. Future studies that aim to expand survey participation, raise the awareness of the state of research in HM, and identify barriers and facilitators to academic success in HM are needed.

 

 

Disclosures

Dr. Chopra discloses grant funding from the Agency for Healthcare Research and Quality (AHRQ), VA Health Services and Research Department, and Centers for Disease Control. Dr. Jones discloses grant funding from AHRQ. All other authors disclose no conflicts of interest.

References

1. International Working Party to Promote and Revitalise Academic Medicine. Academic medicine: the evidence base. BMJ. 2004;329(7469):789-792. PubMed
2. Flanders SA, Saint S, McMahon LF, Howell JD. Where should hospitalists sit within the academic medical center? J Gen Intern Med. 2008;23(8):1269-1272. PubMed
3. Flanders SA, Centor B, Weber V, McGinn T, Desalvo K, Auerbach A. Challenges and opportunities in academic hospital medicine: report from the academic hospital medicine summit. J Gen Intern Med. 2009;24(5):636-641. PubMed
4. Dang Do AN, Munchhof AM, Terry C, Emmett T, Kara A. Research and publication trends in hospital medicine. J Hosp Med. 2014;9(3):148-154. PubMed
5. Harrison R, Hunter AJ, Sharpe B, Auerbach AD. Survey of US academic hospitalist leaders about mentorship and academic activities in hospitalist groups. J Hosp Med. 2011;6(1):5-9. PubMed
6. Sehgal NL, Sharpe BA, Auerbach AA, Wachter RM. Investing in the future: building an academic hospitalist faculty development program. J Hosp Med. 2011;6(3):161-166. PubMed
7. Nagarur A, O’Neill RM, Lawton D, Greenwald JL. Supporting faculty development in hospital medicine: design and implementation of a personalized structured mentoring program. J Hosp Med. 2018;13(2):96-99. PubMed
8. Reid MB, Misky GJ, Harrison RA, Sharpe B, Auerbach A, Glasheen JJ. Mentorship, productivity, and promotion among academic hospitalists. J Gen Intern Med. 2012;27(1):23-27. PubMed
9. Flanders SA, Kaufman SR, Nallamothu BK, Saint S. The University of Michigan Specialist-Hospitalist Allied Research Program: jumpstarting hospital medicine research. J Hosp Med. 2008;3(4):308-313. PubMed
10. Auerbach AD, Patel MS, Metlay JP, et al. The Hospital Medicine Reengineering Network (HOMERuN): a learning organization focused on improving hospital care. Acad Med. 2014;89(3):415-420. PubMed
11. Souba WW. Academic medicine’s core values: what do they mean? J Surg Res. 2003;115(2):171-173. PubMed
12. Bonsall J, Chopra V. Building an academic pipeline: a combined society of hospital medicine committee initiative. J Hosp Med. 2016;11(10):735-736. PubMed
13. Sweigart JR, Tad YD, Kneeland P, Williams MV, Glasheen JJ. Hospital medicine resident training tracks: developing the hospital medicine pipeline. J Hosp Med. 2017;12(3):173-176. PubMed
14. Cunningham CT, Quan H, Hemmelgarn B, et al. Exploring physician specialist response rates to web-based surveys. BMC Med Res Methodol. 2015;15(1):32. PubMed

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Almost all specialties in internal medicine have a sound scientific research base through which clinical practice is informed.1 For the field of Hospital Medicine (HM), this evidence has largely comprised research generated from fields outside of the specialty. The need to develop, invest, and grow investigators in hospital-based medicine remains unmet as HM and its footprint in hospital systems continue to grow.2,3

Despite this fact, little is known about the current state of research in HM. A 2014 survey of the members of the Society of Hospital Medicine (SHM) found that research output across the field of HM, as measured on the basis of peer-reviewed publications, was growing.4 Since then, however, the numbers of individuals engaged in research activities, their background and training, publication output, or funding sources have not been quantified. Similarly, little is known about which institutions support the development of junior investigators (ie, HM research fellowships), how these programs are funded, and whether or not matriculants enter the field as investigators. These gaps must be measured, evaluated, and ideally addressed through strategic policy and funding initiatives to advance the state of science within HM.

Members of the SHM Research Committee developed, designed, and deployed a survey to improve the understanding of the state of research in HM. In this study, we aimed to establish the baseline of research in HM to enable the measurement of progress through periodic waves of data collection. Specifically, we sought to quantify and describe the characteristics of existing research programs, the sources and types of funding, the number and background of faculty, and the availability of resources for training researchers in HM.

 

 

METHODS

Study Setting and Participants

Given that no defined list, database, or external resource that identifies research programs and contacts in HM exists, we began by creating a strategy to identify and sample adult HM programs and their leaders engaged in research activity. We iteratively developed a two-step approach to maximize inclusivity. First, we partnered with SHM to identify programs and leaders actively engaging in research activities. SHM is the largest professional organization within HM and maintains an extensive membership database that includes the titles, e-mail addresses, and affiliations of hospitalists in the United States, including academic and nonacademic sites. This list was manually scanned, and the leaders of academic and research programs in adult HM were identified by examining their titles (eg, Division Chief, Research Lead, etc.) and academic affiliations. During this step, members of the committee noticed that certain key individuals were either missing, no longer occupying their role/title, or had been replaced by others. Therefore, we performed a second step and asked the members of the SHM Research Committee to identify academic and research leaders by using current personal contacts, publication history, and social networks. We asked members to identify individuals and programs that had received grant funding, were actively presenting research at SHM (or other major national venues), and/or were producing peer-reviewed publications related to HM. These programs were purposefully chosen (ie, over HM programs known for clinical activities) to create an enriched sample of those engaged in research in HM. The research committee performed the “second pass” to ensure that established investigators who may not be accurately captured within the SHM database were included to maximize yield for the survey. Finally, these two sources were merged to ensure the absence of duplicate contacts and the identification of a primary respondent for each affiliate. As a result, a convenience sample of 100 programs and corresponding individuals was compiled for the purposes of this survey.

Survey Development

A workgroup within the SHM Research Committee was tasked to create a survey that would achieve four distinct goals: (1) identify institutions currently engaging in hospital-based research; (2) define the characteristics, including sources of research funding, training opportunities, criteria for promotion, and grant support, of research programs within institutions; (3) understand the prevalence of research fellowship programs, including size, training curricula, and funding sources; and (4) evaluate the productivity and funding sources of HM investigators at each site.

Survey questions that target each of these domains were drafted by the workgroup. Questions were pretested with colleagues outside the workgroup focused on this project (ie, from the main research committee). The instrument was refined and edited to improve the readability and clarity of questions on the basis of the feedback obtained through the iterative process. The revised instrument was then programmed into an online survey administration tool (SurveyMonkey®) to facilitate electronic dissemination. Finally, the members of the workgroup tested the online survey to ensure functionality. No identifiable information was collected from respondents, and no monetary incentive was offered for the completion of the survey. An invitation to participate in the survey was sent via e-mail to each of the program contacts identified.

 

 

Statistical Analysis

Descriptive statistics, including proportions, means, and percentages, were used to tabulate results. All analyses were conducted using Stata 13 MP/SE (StataCorp, College Station, Texas).

Ethical and Regulatory Considerations

The study was reviewed and deemed exempt from regulation by the University of Michigan Institutional Review Board (HUM000138628).

RESULTS

General Characteristics of Research Programs and Faculty

Out of 100 program contacts, 28 (representing 1,586 faculty members) responded and were included in the survey (program response rate = 28%). When comparing programs that did respond with those that did not, a greater proportion of programs in university settings were noted among respondents (79% vs 21%). Respondents represented programs from all regions of the United States, with most representing university-based (79%), university-affiliated (14%) or Veterans Health Administration (VHA; 11%) programs. Most respondents were in leadership roles, including division chiefs (32%), research directors/leads (21%), section chiefs (18%), and related titles, such as program director. Respondents indicated that the total number of faculty members in their programs (including nonclinicians and advance practice providers) varied from eight to 152 (mean [SD] = 57 [36]) members, with physicians representing the majority of faculty members (Table 1).

Among the 1,586 faculty members within the 28 programs, respondents identified 192 faculty members (12%) as currently receiving extra- or intramural support for research activities. Of these faculty, over half (58%) received <25% of effort from intra or extramural sources, and 28 (15%) and 52 (27%) faculty members received 25%-50% or >50% of support for their effort, respectively. The number of investigators who received funding across programs ranged from 0 to 28 faculty members. Compared with the 192 funded investigators, respondents indicated that a larger number of faculty in their programs (n = 656 or 41%) were involved in local quality improvement (QI) efforts. Of the 656 faculty members involved in QI efforts, 241 individuals (37%) were internally funded and received protected time/effort for their work.

Key Attributes of Research Programs

In the evaluation of the amount of total grant funding, respondents from 17 programs indicated that they received $500,000 in annual extra and intramural funding, and those from three programs stated that they received $500,000 to $999,999 in funding. Five respondents indicated that their programs currently received $1 million to $5 million in grant funding, and three reported >$5 million in research support. The sources of research funding included several divisions within the National Institute of Health (NIH, 12 programs), Agency for Healthcare Research and Quality (AHRQ, four programs), foundations (four programs), and internal grants (six programs). Additionally, six programs indicated “other” sources of funding that included the VHA, Patient-Centered Outcomes Research Institute (PCORI), Centers for Medicare and Medicaid Services, Centers for Disease Control (CDC), and industry sources.

A range of grants, including career development awards (11 programs); small grants, such as R21 and R03s (eight programs); R-level grants, including VA merit awards (five programs); program series grants, such as P and U grants (five programs), and foundation grants (eight programs), were reported as types of awards. Respondents from 16 programs indicated that they provided internal pilot grants. Amounts for such grants ranged from <$50,000 (14 programs) to $50,000-$100,000 (two programs).

 

 

Research Fellowship Programs/Training Programs

Only five of the 28 surveyed programs indicated that they currently had a research training or fellowship program for developing hospitalist investigators. The age of these programs varied from <1 year to 10 years. Three of the five programs stated that they had two fellows per year, and two stated they had spots for one trainee annually. All respondents indicated that fellows received training on study design, research methods, quantitative (eg, large database and secondary analyses) and qualitative data analysis. In addition, two programs included training in systematic review and meta-analyses, and three included focused courses on healthcare policy. Four of the five programs included training in QI tools, such as LEAN and Six Sigma. Funding for four of the five fellowship programs came from internal sources (eg, department and CTSA). However, two programs added they received some support from extramural funding and philanthropy. Following training, respondents from programs indicated that the majority of their graduates (60%) went on to hybrid research/QI roles (50/50 research/clinical effort), whereas 40% obtained dedicated research investigator (80/20) positions (Table 2).

The 23 institutions without research training programs cited that the most important barrier for establishing such programs was lack of funding (12 programs) and the lack of a pipeline of hospitalists seeking such training (six programs). However, 15 programs indicated that opportunities for hospitalists to gain research training in the form of courses were available internally (eg, courses in the department or medical school) or externally (eg, School of Public Health). Seven programs indicated that they were planning to start a HM research fellowship within the next five years.

Research Faculty

Among the 28 respondents, 15 stated that they have faculty members who conduct research as their main professional activity (ie, >50% effort). The number of faculty members in each program in such roles varied from one to 10. Respondents indicated that faculty members in this category were most often midcareer assistant or associate professors with few full professors. All programs indicated that scholarship in the form of peer-reviewed publications was required for the promotion of faculty. Faculty members who performed research as their main activity had all received formal fellowship training and consequently had dual degrees (MD with MPH or MD, with MSc being the two most common combinations). With respect to clinical activities, most respondents indicated that research faculty spent 10% to 49% of their effort on clinical work. However, five respondents indicated that research faculty had <10% effort on clinical duties (Table 3).

Eleven respondents (39%) identified the main focus of faculty as health service research, where four (14%) identified their main focus as clinical trials. Regardless of funding status, all respondents stated that their faculty were interested in studying quality and process improvement efforts (eg, transitions or readmissions, n = 19), patient safety initiatives (eg, hospital-acquired complications, n = 17), and disease-specific areas (eg, thrombosis, n = 15).

In terms of research output, 12 respondents stated that their research/QI faculty collectively published 11-50 peer-reviewed papers during the academic year, and 10 programs indicated that their faculty published 0-10 papers per year. Only three programs reported that their faculty collectively published 50-99 peer-reviewed papers per year. With respect to abstract presentations at national conferences, 13 programs indicated that they presented 0-10 abstracts, and 12 indicated that they presented 11-50.

 

 

DISCUSSION

In this first survey quantifying research activities in HM, respondents from 28 programs shared important insights into research activities at their institutions. Although our sample size was small, substantial variation in the size, composition, and structure of research programs in HM among respondents was observed. For example, few respondents indicated the availability of training programs for research in HM at their institutions. Similarly, among faculty who focused mainly on research, variation in funding streams and effort protection was observed. A preponderance of midcareer faculty with a range of funding sources, including NIH, AHRQ, VHA, CMS, and CDC was reported. Collectively, these data not only provide a unique glimpse into the state of research in HM but also help establish a baseline of the status of the field at large.

Some findings of our study are intuitive given our sampling strategy and the types of programs that responded. For example, the fact that most respondents for research programs represented university-based or affiliated institutions is expected given the tripartite academic mission. However, even within our sample of highly motivated programs, some findings are surprising and merit further exploration. For example, the observation that some respondents identified HM investigators within their program with <25% in intra- or extramural funding was unexpected. On the other extreme, we were surprised to find that three programs reported >$5 million in research funding. Understanding whether specific factors, such as the availability of experienced mentors within and outside departments or assistance from support staff (eg, statisticians and project managers), are associated with success and funding within these programs are important questions to answer. By focusing on these issues, we will be well poised as a field to understand what works, what does not work, and why.

Likewise, the finding that few programs within our sample offer formal training in the form of fellowships to research investigators represents an improvement opportunity. A pipeline for growing investigators is critical for the specialty that is HM. Notably, this call is not new; rather, previous investigators have highlighted the importance of developing academically oriented hospitalists for the future of the field.5 The implementation of faculty scholarship development programs has improved the scholarly output, mentoring activities, and succession planning of academics within HM.6,7 Conversely, lack of adequate mentorship and support for academic activities remains a challenge and as a factor associated with the failure to produce academic work.8 Without a cadre of investigators asking critical questions related to care delivery, the legitimacy of our field may be threatened.

While extrapolating to the field is difficult given the small number of our respondents, highlighting the progress that has been made is important. For example, while misalignment between funding and clinical and research mission persists, our survey found that several programs have been successful in securing extramural funding for their investigators. Additionally, internal funding for QI work appears to be increasing, with hospitalists receiving dedicated effort for much of this work. Innovation in how best to support and develop these types of efforts have also emerged. For example, the University of Michigan Specialist Hospitalist Allied Research Program offers dedicated effort and funding for hospitalists tackling projects germane to HM (eg, ordering of blood cultures for febrile inpatients) that overlap with subspecialists (eg, infectious diseases).9 Thus, hospitalists are linked with other specialties in the development of research agendas and academic products. Similarly, the launch of the HOMERUN network, a coalition of investigators who bridge health systems to study problems central to HM, has helped usher in a new era of research opportunities in the specialty.10 Fundamentally, the culture of HM has begun to place an emphasis on academic and scholarly productivity in addition to clinical prowess.11-13 Increased support and funding for training programs geared toward innovation and research in HM is needed to continue this mission. The Society for General Internal Medicine, American College of Physicians, and SHM have important roles to play as the largest professional organizations for generalists in this respect. Support for research, QI, and investigators in HM remains an urgent and largely unmet need.

Our study has limitations. First, our response rate was low at 28% but is consistent with the response rates of other surveys of physician groups.14 Caution in making inferences to the field at large is necessary given the potential for selection and nonresponse bias. However, we expect that respondents are likely biased toward programs actively conducting research and engaged in QI, thus better reflecting the state of these activities in HM. Second, given that we did not ask for any identifying information, we have no way of establishing the accuracy of the data provided by respondents. However, we have no reason to believe that responses would be altered in a systematic fashion. Future studies that link our findings to publicly available data (eg, databases of active grants and funding) might be useful. Third, while our survey instrument was created and internally validated by hospitalist researchers, its lack of external validation could limit findings. Finally, our results vary on the basis of how respondents answered questions related to effort and time allocation given that these measures differ across programs.

In summary, the findings from this study highlight substantial variations in the number, training, and funding of research faculty across HM programs. Understanding the factors behind the success of some programs and the failures of others appears important in informing and growing the research in the field. Future studies that aim to expand survey participation, raise the awareness of the state of research in HM, and identify barriers and facilitators to academic success in HM are needed.

 

 

Disclosures

Dr. Chopra discloses grant funding from the Agency for Healthcare Research and Quality (AHRQ), VA Health Services and Research Department, and Centers for Disease Control. Dr. Jones discloses grant funding from AHRQ. All other authors disclose no conflicts of interest.

Almost all specialties in internal medicine have a sound scientific research base through which clinical practice is informed.1 For the field of Hospital Medicine (HM), this evidence has largely comprised research generated from fields outside of the specialty. The need to develop, invest, and grow investigators in hospital-based medicine remains unmet as HM and its footprint in hospital systems continue to grow.2,3

Despite this fact, little is known about the current state of research in HM. A 2014 survey of the members of the Society of Hospital Medicine (SHM) found that research output across the field of HM, as measured on the basis of peer-reviewed publications, was growing.4 Since then, however, the numbers of individuals engaged in research activities, their background and training, publication output, or funding sources have not been quantified. Similarly, little is known about which institutions support the development of junior investigators (ie, HM research fellowships), how these programs are funded, and whether or not matriculants enter the field as investigators. These gaps must be measured, evaluated, and ideally addressed through strategic policy and funding initiatives to advance the state of science within HM.

Members of the SHM Research Committee developed, designed, and deployed a survey to improve the understanding of the state of research in HM. In this study, we aimed to establish the baseline of research in HM to enable the measurement of progress through periodic waves of data collection. Specifically, we sought to quantify and describe the characteristics of existing research programs, the sources and types of funding, the number and background of faculty, and the availability of resources for training researchers in HM.

 

 

METHODS

Study Setting and Participants

Given that no defined list, database, or external resource that identifies research programs and contacts in HM exists, we began by creating a strategy to identify and sample adult HM programs and their leaders engaged in research activity. We iteratively developed a two-step approach to maximize inclusivity. First, we partnered with SHM to identify programs and leaders actively engaging in research activities. SHM is the largest professional organization within HM and maintains an extensive membership database that includes the titles, e-mail addresses, and affiliations of hospitalists in the United States, including academic and nonacademic sites. This list was manually scanned, and the leaders of academic and research programs in adult HM were identified by examining their titles (eg, Division Chief, Research Lead, etc.) and academic affiliations. During this step, members of the committee noticed that certain key individuals were either missing, no longer occupying their role/title, or had been replaced by others. Therefore, we performed a second step and asked the members of the SHM Research Committee to identify academic and research leaders by using current personal contacts, publication history, and social networks. We asked members to identify individuals and programs that had received grant funding, were actively presenting research at SHM (or other major national venues), and/or were producing peer-reviewed publications related to HM. These programs were purposefully chosen (ie, over HM programs known for clinical activities) to create an enriched sample of those engaged in research in HM. The research committee performed the “second pass” to ensure that established investigators who may not be accurately captured within the SHM database were included to maximize yield for the survey. Finally, these two sources were merged to ensure the absence of duplicate contacts and the identification of a primary respondent for each affiliate. As a result, a convenience sample of 100 programs and corresponding individuals was compiled for the purposes of this survey.

Survey Development

A workgroup within the SHM Research Committee was tasked to create a survey that would achieve four distinct goals: (1) identify institutions currently engaging in hospital-based research; (2) define the characteristics, including sources of research funding, training opportunities, criteria for promotion, and grant support, of research programs within institutions; (3) understand the prevalence of research fellowship programs, including size, training curricula, and funding sources; and (4) evaluate the productivity and funding sources of HM investigators at each site.

Survey questions that target each of these domains were drafted by the workgroup. Questions were pretested with colleagues outside the workgroup focused on this project (ie, from the main research committee). The instrument was refined and edited to improve the readability and clarity of questions on the basis of the feedback obtained through the iterative process. The revised instrument was then programmed into an online survey administration tool (SurveyMonkey®) to facilitate electronic dissemination. Finally, the members of the workgroup tested the online survey to ensure functionality. No identifiable information was collected from respondents, and no monetary incentive was offered for the completion of the survey. An invitation to participate in the survey was sent via e-mail to each of the program contacts identified.

 

 

Statistical Analysis

Descriptive statistics, including proportions, means, and percentages, were used to tabulate results. All analyses were conducted using Stata 13 MP/SE (StataCorp, College Station, Texas).

Ethical and Regulatory Considerations

The study was reviewed and deemed exempt from regulation by the University of Michigan Institutional Review Board (HUM000138628).

RESULTS

General Characteristics of Research Programs and Faculty

Out of 100 program contacts, 28 (representing 1,586 faculty members) responded and were included in the survey (program response rate = 28%). When comparing programs that did respond with those that did not, a greater proportion of programs in university settings were noted among respondents (79% vs 21%). Respondents represented programs from all regions of the United States, with most representing university-based (79%), university-affiliated (14%) or Veterans Health Administration (VHA; 11%) programs. Most respondents were in leadership roles, including division chiefs (32%), research directors/leads (21%), section chiefs (18%), and related titles, such as program director. Respondents indicated that the total number of faculty members in their programs (including nonclinicians and advance practice providers) varied from eight to 152 (mean [SD] = 57 [36]) members, with physicians representing the majority of faculty members (Table 1).

Among the 1,586 faculty members within the 28 programs, respondents identified 192 faculty members (12%) as currently receiving extra- or intramural support for research activities. Of these faculty, over half (58%) received <25% of effort from intra or extramural sources, and 28 (15%) and 52 (27%) faculty members received 25%-50% or >50% of support for their effort, respectively. The number of investigators who received funding across programs ranged from 0 to 28 faculty members. Compared with the 192 funded investigators, respondents indicated that a larger number of faculty in their programs (n = 656 or 41%) were involved in local quality improvement (QI) efforts. Of the 656 faculty members involved in QI efforts, 241 individuals (37%) were internally funded and received protected time/effort for their work.

Key Attributes of Research Programs

In the evaluation of the amount of total grant funding, respondents from 17 programs indicated that they received $500,000 in annual extra and intramural funding, and those from three programs stated that they received $500,000 to $999,999 in funding. Five respondents indicated that their programs currently received $1 million to $5 million in grant funding, and three reported >$5 million in research support. The sources of research funding included several divisions within the National Institute of Health (NIH, 12 programs), Agency for Healthcare Research and Quality (AHRQ, four programs), foundations (four programs), and internal grants (six programs). Additionally, six programs indicated “other” sources of funding that included the VHA, Patient-Centered Outcomes Research Institute (PCORI), Centers for Medicare and Medicaid Services, Centers for Disease Control (CDC), and industry sources.

A range of grants, including career development awards (11 programs); small grants, such as R21 and R03s (eight programs); R-level grants, including VA merit awards (five programs); program series grants, such as P and U grants (five programs), and foundation grants (eight programs), were reported as types of awards. Respondents from 16 programs indicated that they provided internal pilot grants. Amounts for such grants ranged from <$50,000 (14 programs) to $50,000-$100,000 (two programs).

 

 

Research Fellowship Programs/Training Programs

Only five of the 28 surveyed programs indicated that they currently had a research training or fellowship program for developing hospitalist investigators. The age of these programs varied from <1 year to 10 years. Three of the five programs stated that they had two fellows per year, and two stated they had spots for one trainee annually. All respondents indicated that fellows received training on study design, research methods, quantitative (eg, large database and secondary analyses) and qualitative data analysis. In addition, two programs included training in systematic review and meta-analyses, and three included focused courses on healthcare policy. Four of the five programs included training in QI tools, such as LEAN and Six Sigma. Funding for four of the five fellowship programs came from internal sources (eg, department and CTSA). However, two programs added they received some support from extramural funding and philanthropy. Following training, respondents from programs indicated that the majority of their graduates (60%) went on to hybrid research/QI roles (50/50 research/clinical effort), whereas 40% obtained dedicated research investigator (80/20) positions (Table 2).

The 23 institutions without research training programs cited that the most important barrier for establishing such programs was lack of funding (12 programs) and the lack of a pipeline of hospitalists seeking such training (six programs). However, 15 programs indicated that opportunities for hospitalists to gain research training in the form of courses were available internally (eg, courses in the department or medical school) or externally (eg, School of Public Health). Seven programs indicated that they were planning to start a HM research fellowship within the next five years.

Research Faculty

Among the 28 respondents, 15 stated that they have faculty members who conduct research as their main professional activity (ie, >50% effort). The number of faculty members in each program in such roles varied from one to 10. Respondents indicated that faculty members in this category were most often midcareer assistant or associate professors with few full professors. All programs indicated that scholarship in the form of peer-reviewed publications was required for the promotion of faculty. Faculty members who performed research as their main activity had all received formal fellowship training and consequently had dual degrees (MD with MPH or MD, with MSc being the two most common combinations). With respect to clinical activities, most respondents indicated that research faculty spent 10% to 49% of their effort on clinical work. However, five respondents indicated that research faculty had <10% effort on clinical duties (Table 3).

Eleven respondents (39%) identified the main focus of faculty as health service research, where four (14%) identified their main focus as clinical trials. Regardless of funding status, all respondents stated that their faculty were interested in studying quality and process improvement efforts (eg, transitions or readmissions, n = 19), patient safety initiatives (eg, hospital-acquired complications, n = 17), and disease-specific areas (eg, thrombosis, n = 15).

In terms of research output, 12 respondents stated that their research/QI faculty collectively published 11-50 peer-reviewed papers during the academic year, and 10 programs indicated that their faculty published 0-10 papers per year. Only three programs reported that their faculty collectively published 50-99 peer-reviewed papers per year. With respect to abstract presentations at national conferences, 13 programs indicated that they presented 0-10 abstracts, and 12 indicated that they presented 11-50.

 

 

DISCUSSION

In this first survey quantifying research activities in HM, respondents from 28 programs shared important insights into research activities at their institutions. Although our sample size was small, substantial variation in the size, composition, and structure of research programs in HM among respondents was observed. For example, few respondents indicated the availability of training programs for research in HM at their institutions. Similarly, among faculty who focused mainly on research, variation in funding streams and effort protection was observed. A preponderance of midcareer faculty with a range of funding sources, including NIH, AHRQ, VHA, CMS, and CDC was reported. Collectively, these data not only provide a unique glimpse into the state of research in HM but also help establish a baseline of the status of the field at large.

Some findings of our study are intuitive given our sampling strategy and the types of programs that responded. For example, the fact that most respondents for research programs represented university-based or affiliated institutions is expected given the tripartite academic mission. However, even within our sample of highly motivated programs, some findings are surprising and merit further exploration. For example, the observation that some respondents identified HM investigators within their program with <25% in intra- or extramural funding was unexpected. On the other extreme, we were surprised to find that three programs reported >$5 million in research funding. Understanding whether specific factors, such as the availability of experienced mentors within and outside departments or assistance from support staff (eg, statisticians and project managers), are associated with success and funding within these programs are important questions to answer. By focusing on these issues, we will be well poised as a field to understand what works, what does not work, and why.

Likewise, the finding that few programs within our sample offer formal training in the form of fellowships to research investigators represents an improvement opportunity. A pipeline for growing investigators is critical for the specialty that is HM. Notably, this call is not new; rather, previous investigators have highlighted the importance of developing academically oriented hospitalists for the future of the field.5 The implementation of faculty scholarship development programs has improved the scholarly output, mentoring activities, and succession planning of academics within HM.6,7 Conversely, lack of adequate mentorship and support for academic activities remains a challenge and as a factor associated with the failure to produce academic work.8 Without a cadre of investigators asking critical questions related to care delivery, the legitimacy of our field may be threatened.

While extrapolating to the field is difficult given the small number of our respondents, highlighting the progress that has been made is important. For example, while misalignment between funding and clinical and research mission persists, our survey found that several programs have been successful in securing extramural funding for their investigators. Additionally, internal funding for QI work appears to be increasing, with hospitalists receiving dedicated effort for much of this work. Innovation in how best to support and develop these types of efforts have also emerged. For example, the University of Michigan Specialist Hospitalist Allied Research Program offers dedicated effort and funding for hospitalists tackling projects germane to HM (eg, ordering of blood cultures for febrile inpatients) that overlap with subspecialists (eg, infectious diseases).9 Thus, hospitalists are linked with other specialties in the development of research agendas and academic products. Similarly, the launch of the HOMERUN network, a coalition of investigators who bridge health systems to study problems central to HM, has helped usher in a new era of research opportunities in the specialty.10 Fundamentally, the culture of HM has begun to place an emphasis on academic and scholarly productivity in addition to clinical prowess.11-13 Increased support and funding for training programs geared toward innovation and research in HM is needed to continue this mission. The Society for General Internal Medicine, American College of Physicians, and SHM have important roles to play as the largest professional organizations for generalists in this respect. Support for research, QI, and investigators in HM remains an urgent and largely unmet need.

Our study has limitations. First, our response rate was low at 28% but is consistent with the response rates of other surveys of physician groups.14 Caution in making inferences to the field at large is necessary given the potential for selection and nonresponse bias. However, we expect that respondents are likely biased toward programs actively conducting research and engaged in QI, thus better reflecting the state of these activities in HM. Second, given that we did not ask for any identifying information, we have no way of establishing the accuracy of the data provided by respondents. However, we have no reason to believe that responses would be altered in a systematic fashion. Future studies that link our findings to publicly available data (eg, databases of active grants and funding) might be useful. Third, while our survey instrument was created and internally validated by hospitalist researchers, its lack of external validation could limit findings. Finally, our results vary on the basis of how respondents answered questions related to effort and time allocation given that these measures differ across programs.

In summary, the findings from this study highlight substantial variations in the number, training, and funding of research faculty across HM programs. Understanding the factors behind the success of some programs and the failures of others appears important in informing and growing the research in the field. Future studies that aim to expand survey participation, raise the awareness of the state of research in HM, and identify barriers and facilitators to academic success in HM are needed.

 

 

Disclosures

Dr. Chopra discloses grant funding from the Agency for Healthcare Research and Quality (AHRQ), VA Health Services and Research Department, and Centers for Disease Control. Dr. Jones discloses grant funding from AHRQ. All other authors disclose no conflicts of interest.

References

1. International Working Party to Promote and Revitalise Academic Medicine. Academic medicine: the evidence base. BMJ. 2004;329(7469):789-792. PubMed
2. Flanders SA, Saint S, McMahon LF, Howell JD. Where should hospitalists sit within the academic medical center? J Gen Intern Med. 2008;23(8):1269-1272. PubMed
3. Flanders SA, Centor B, Weber V, McGinn T, Desalvo K, Auerbach A. Challenges and opportunities in academic hospital medicine: report from the academic hospital medicine summit. J Gen Intern Med. 2009;24(5):636-641. PubMed
4. Dang Do AN, Munchhof AM, Terry C, Emmett T, Kara A. Research and publication trends in hospital medicine. J Hosp Med. 2014;9(3):148-154. PubMed
5. Harrison R, Hunter AJ, Sharpe B, Auerbach AD. Survey of US academic hospitalist leaders about mentorship and academic activities in hospitalist groups. J Hosp Med. 2011;6(1):5-9. PubMed
6. Sehgal NL, Sharpe BA, Auerbach AA, Wachter RM. Investing in the future: building an academic hospitalist faculty development program. J Hosp Med. 2011;6(3):161-166. PubMed
7. Nagarur A, O’Neill RM, Lawton D, Greenwald JL. Supporting faculty development in hospital medicine: design and implementation of a personalized structured mentoring program. J Hosp Med. 2018;13(2):96-99. PubMed
8. Reid MB, Misky GJ, Harrison RA, Sharpe B, Auerbach A, Glasheen JJ. Mentorship, productivity, and promotion among academic hospitalists. J Gen Intern Med. 2012;27(1):23-27. PubMed
9. Flanders SA, Kaufman SR, Nallamothu BK, Saint S. The University of Michigan Specialist-Hospitalist Allied Research Program: jumpstarting hospital medicine research. J Hosp Med. 2008;3(4):308-313. PubMed
10. Auerbach AD, Patel MS, Metlay JP, et al. The Hospital Medicine Reengineering Network (HOMERuN): a learning organization focused on improving hospital care. Acad Med. 2014;89(3):415-420. PubMed
11. Souba WW. Academic medicine’s core values: what do they mean? J Surg Res. 2003;115(2):171-173. PubMed
12. Bonsall J, Chopra V. Building an academic pipeline: a combined society of hospital medicine committee initiative. J Hosp Med. 2016;11(10):735-736. PubMed
13. Sweigart JR, Tad YD, Kneeland P, Williams MV, Glasheen JJ. Hospital medicine resident training tracks: developing the hospital medicine pipeline. J Hosp Med. 2017;12(3):173-176. PubMed
14. Cunningham CT, Quan H, Hemmelgarn B, et al. Exploring physician specialist response rates to web-based surveys. BMC Med Res Methodol. 2015;15(1):32. PubMed

References

1. International Working Party to Promote and Revitalise Academic Medicine. Academic medicine: the evidence base. BMJ. 2004;329(7469):789-792. PubMed
2. Flanders SA, Saint S, McMahon LF, Howell JD. Where should hospitalists sit within the academic medical center? J Gen Intern Med. 2008;23(8):1269-1272. PubMed
3. Flanders SA, Centor B, Weber V, McGinn T, Desalvo K, Auerbach A. Challenges and opportunities in academic hospital medicine: report from the academic hospital medicine summit. J Gen Intern Med. 2009;24(5):636-641. PubMed
4. Dang Do AN, Munchhof AM, Terry C, Emmett T, Kara A. Research and publication trends in hospital medicine. J Hosp Med. 2014;9(3):148-154. PubMed
5. Harrison R, Hunter AJ, Sharpe B, Auerbach AD. Survey of US academic hospitalist leaders about mentorship and academic activities in hospitalist groups. J Hosp Med. 2011;6(1):5-9. PubMed
6. Sehgal NL, Sharpe BA, Auerbach AA, Wachter RM. Investing in the future: building an academic hospitalist faculty development program. J Hosp Med. 2011;6(3):161-166. PubMed
7. Nagarur A, O’Neill RM, Lawton D, Greenwald JL. Supporting faculty development in hospital medicine: design and implementation of a personalized structured mentoring program. J Hosp Med. 2018;13(2):96-99. PubMed
8. Reid MB, Misky GJ, Harrison RA, Sharpe B, Auerbach A, Glasheen JJ. Mentorship, productivity, and promotion among academic hospitalists. J Gen Intern Med. 2012;27(1):23-27. PubMed
9. Flanders SA, Kaufman SR, Nallamothu BK, Saint S. The University of Michigan Specialist-Hospitalist Allied Research Program: jumpstarting hospital medicine research. J Hosp Med. 2008;3(4):308-313. PubMed
10. Auerbach AD, Patel MS, Metlay JP, et al. The Hospital Medicine Reengineering Network (HOMERuN): a learning organization focused on improving hospital care. Acad Med. 2014;89(3):415-420. PubMed
11. Souba WW. Academic medicine’s core values: what do they mean? J Surg Res. 2003;115(2):171-173. PubMed
12. Bonsall J, Chopra V. Building an academic pipeline: a combined society of hospital medicine committee initiative. J Hosp Med. 2016;11(10):735-736. PubMed
13. Sweigart JR, Tad YD, Kneeland P, Williams MV, Glasheen JJ. Hospital medicine resident training tracks: developing the hospital medicine pipeline. J Hosp Med. 2017;12(3):173-176. PubMed
14. Cunningham CT, Quan H, Hemmelgarn B, et al. Exploring physician specialist response rates to web-based surveys. BMC Med Res Methodol. 2015;15(1):32. PubMed

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Management of Chronic Conditions

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Hospitalist and primary care physician perspectives on medication management of chronic conditions for hospitalized patients

Over the past 2 decades, the care of the hospitalized patient has changed dramatically. Hospitalists now account for the care of more than one‐third of general medicine inpatients, and this number is likely to grow.[1] The emergence of hospital medicine has resulted in a partnership between primary care physicians (PCPs) and hospitalists wherein hospitalists focus on acute medical issues requiring hospitalization, whereas more chronic issues unrelated to the reason for hospitalization remain largely the domain of the PCP.[2, 3]

However, several evolving financial and quality incentives have already begun to blur the distinction between inpatient and outpatient care. First, as private and public payers increasingly scrutinize readmission rates, it has become clear that the responsibility for patient outcomes extends beyond the day of discharge.[4] The birth of Accountable Care Organizations and patient‐centered medical homes may further blur distinctions between what has traditionally constituted inpatient and outpatient care.[5] Bundled payments may force providers to ensure that each visit, whether hospital‐ or clinic‐based, is taken as an opportunity to enact meaningful change.[6] The Centers for Medicare and Medicaid Services (CMS) are already tracking hospital performance on institution of medical therapy for certain conditions regardless of their relatedness to the reason for hospitalization.[7]

No published literature has yet examined the attitudes of inpatient and outpatient providers regarding this issue. Through a case‐based survey conducted at 3 large urban academic medical centers, we aimed to assess opinions among hospitalists and PCPs regarding the role of hospitalists in the management of conditions unrelated to the reason for admission. Our study had 2 main objectives: (1) to determine whether surveyed physicians were more likely to rate an inpatient intervention as appropriate when it related to the reason for admission as compared to interventions unrelated to the reason for admission; and (2) to determine whether these attitudes differed between PCPs and hospitalists.

METHODS

Setting and Subjects

We surveyed hospitalists and hospital‐based PCPs at Beth Israel Deaconess Medical Center (BIDMC), Brigham and Women's Hospital, and Massachusetts General Hospital, 3 large academic medical centers in Boston, Massachusetts. Each hospitalist group includes both teaching and nonteaching services and admits patients from both the surveyed hospital‐based PCP groups and other nonhospital‐based PCP groups. All 3 study sites use electronic medical records with patient information for each hospital‐based PCP available to treating hospitalists.

Survey Design

Using a commercially available online product (SurveyMonkey, Palo Alto, CA), we created a 3‐part case‐based survey instrument. The first section included demographic questions regarding age, sex, primary clinical role (hospitalist or PCP), prior experience as a PCP (for hospitalists only) or a hospitalist (for PCPs only; defined as a position with >30% of clinical time as the attending of record in the inpatient setting), years of clinical experience, and hospital affiliation.

The second section aimed to indirectly assess physician opinions on the appropriateness of inpatient management of conditions unrelated to the reason for admission. It consisted of 6 paired case scenarios, each with an inpatient management decision for a hypothetical hospitalist (Table 1). For each pair, 1 case dealt with management of the condition prompting admission (eg, starting aspirin in a patient admitted with acute nonST‐elevation myocardial infarction). The partner case involved the same intervention (eg, starting aspirin) but for a patient with a chronic condition (eg, history of prior myocardial infarction) and an alternate admitting diagnosis (eg, cellulitis). In an attempt to mitigate concerns regarding the flow of information and communication between providers, the survey asked respondents to assume that the hospitalist has access to the patient's outpatient electronic medical record, and that the hospitalist communicates the details of any hospitalizations at the time of discharge. For each case, the physician was asked to rate the appropriateness of enacting the intervention without discussing it with the PCP on a 5‐point scale from very inappropriate to very appropriate. When a physician answered that an intervention was inappropriate or very inappropriate, an additional question soliciting reasons for inappropriateness was included, with multiple predefined answer choices, as well as the option of a free‐text reply under the other designation.

Cases Descriptions
  • NOTE: Abbreviations: CHADS2, congestive heart failure, hypertension, age 75 years, diabetes mellitus, stroke/transient ischemic attack/thromboembolism; GERD, gastroesophageal reflux disease; LDL, low‐density lipoprotein; LVEF, left ventricular ejection fraction; NYHA, New York Heart Association; MI, myocardial infarction.

Starting aspirin (related to the reason for admission)A 60‐year‐old patient is admitted with a nonST‐elevation MI, medically managed without cardiac catheterization or percutaneous coronary intervention. Knowing that aspirin reduces mortality as part of secondary prevention in cardiovascular disease, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician?
Starting aspirin (unrelated to the reason for admission)A 60‐year‐old patient with a past medical history of a prior nonST‐elevation MI that was medically managed is admitted to the hospital for treatment of cellulitis. The hospitalist notes the patient is not on aspirin at home. Knowing that aspirin reduces mortality as part of secondary prevention in cardiovascular disease, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician?
Starting spironolactone (related to the reason for admission)A 70‐year‐old patient with a past medical history significant for NYHA class II congestive heart failure (LVEF of 20%) is admitted for acute on chronic, left‐sided systolic congestive heart failure. The patient has been maintained on furosemide, metoprolol, and lisinopril. Admission serum potassium and creatinine are both normal. Knowing that spironolactone decreases mortality in heart failure, how appropriate is it for the hospitalist to start this medication without discussing it with the primary care physician?
Starting spironolactone (unrelated to the reason for admission)A 70‐year‐old patient with a past history of NYHA class II congestive heart failure (LVEF of 20%) on furosemide, metoprolol, and lisinopril is admitted with pneumonia. Serum potassium and creatinine are both normal. Knowing that spironolactone decreases mortality in heart failure, how appropriate is it for the hospitalist to start this medication without discussing it with the primary care physician?
Starting warfarin (related to the reason for admission)A 75‐year‐old patient with a past medical history of hypertension and diabetes is admitted with new atrial fibrillation. Given the patient's CHADS2 score of 3, the hospitalist calculates that the patient has a significant risk of thromboembolic stroke. Knowing that warfarin will decrease the risk of thromboembolic stroke, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician (assume that an outpatient anticoagulation clinic is able to see the patient within 3 days of discharge)?
Starting warfarin (unrelated to the reason for admission)A 75‐year‐old patient with a past medical history of hypertension, diabetes, and atrial fibrillation is admitted with pneumonia. The patient is not anticoagulation therapy. Given the patient's CHADS2 score of 3, the hospitalist calculates that the patient has a significant risk of thromboembolic stroke. Knowing that warfarin will decrease the risk of thromboembolic stroke, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician (assume that an outpatient anticoagulation clinic is able to see the patient within 3 days of discharge)?
Stopping proton pump inhibitor (related to the reason for admission)A 65‐year‐old patient with a past medical history of GERD maintained on a proton pump inhibitor is admitted for treatment of Clostridium difficile colitis. The patient denies having any GERD‐like symptoms for several years. Knowing that proton pump inhibitors can increase the risk of C difficile colitis and recurrence (as well as pneumonia and osteoporosis), how appropriate is it for the hospitalist to initiate a taper of this medication without discussing it with the primary care physician?
Stopping proton pump inhibitor (unrelated to the reason for admission)A 65‐year‐old patient with a past medical history of GERD maintained on a proton pump inhibitor is admitted for treatment of a urinary tract infection. The patient denies having any GERD‐like symptoms for several years. Knowing that proton pump inhibitors can increase the risk of C difficile colitis and recurrence (as well as pneumonia and osteoporosis), how appropriate is it for the hospitalist to initiate a taper of this medication without discussing it with the primary care physician?
Stopping statin or fibrate (related to the reason for admission)A 60‐year‐old patient with a history of hyperlipidemia is admitted with an elevated creatine kinase to 5000. The hospitalist notes that the patient is on both simvastatin and gemfibrozil. The patient's most recent serum LDL was at goal. Knowing that coadministration of simvastatin and gemfibrozil can increase the risk of rhabdomyolysis, how appropriate is it for the hospitalist to stop one of these medications without discussing it with the primary care physician?
Stopping statin or fibrate (unrelated to the reason for admission)A 60‐year‐old patient is admitted with an acute diarrheal illness. The hospitalist notes that the patient is on both simvastatin and gemfibrozil. The patient's most recent LDL was at goal. Knowing that coadministration of simvastatin and gemfibrozil can increase the risk of rhabdomyolysis, how appropriate is it for the hospitalist to stop one of these medications without discussing it with the primary care physician?
Changing statin (related to the reason for admission)A 65‐year‐old patient with a past medical history of hyperlipidemia on maximum‐dose simvastatin is admitted with a nonST‐elevation MI. The patient's cholesterol is noted to be above goal. Knowing that improving lipid management reduces mortality in cardiovascular disease, how appropriate is it for the hospitalist to replace simvastatin with atorvastatin without discussing it with the primary care physician?
Changing statin (unrelated to the reason for admission)A 65‐year‐old patient with a past medical history of a prior nonST‐elevation MI that was medically managed and hyperlipidemia on maximum‐dose simvastatin is admitted with pneumonia. Incidentally, the hospitalist notes that the patient's cholesterol has been above goal for the last 2 years. Knowing that improving lipid management reduces mortality in cardiovascular disease, how appropriate is it for the hospitalist to replace simvastatin with atorvastatin without discussing it with the primary care physician?

The third section aimed to directly assess physicians' opinions. It consisted of questions regarding the appropriateness of inpatient management of conditions related to and unrelated to a patient's reason for admission.

Prior to administration, we conducted focus groups of hospitalists and PCPs to help hypothesize current physician perceptions on inpatient management, assess physician understanding of survey cases and questions, and to evaluate survey length.

Survey Administration

Between October 23, 2012 and November 10, 2012, 3 emails containing a link to the online survey were sent to all hospitalist and hospital‐based PCPs at the 3 study institutions. The BIDMC Committee on Clinical Investigations, to whom authority was ceded by the remaining 2 study institutions, certified this research protocol as exempt.

Statistical Analysis

We hypothesized that respondents as a whole would be more likely to rate an intervention as appropriate or very appropriate if it was related to the reason for admission, compared to unrelated, and that there would be no difference between PCPs and hospitalists.

We used 2 and Fisher exact tests (where applicable) to compare categorical variables, and a nonparametric median test for continuous variables. We used the Fisher exact test to compare the percent of respondents rating each intervention as appropriate or very appropriate by relatedness or unrelatedness to the reason for admission, and by PCP vs hospitalist. To derive the relative risk (RR) of rating each intervention as appropriate or very appropriate by PCPs compared to hospitalists, adjusting for potential confounders including years out of residency and sex, we used multivariable generalized estimating equation models, each with a Poisson distribution error term, a log link, and an exchangeable working correlation structure to account for dependency of observations arising from clustering at either the hospital or participant level, depending on the comparison: for comparisons within a given case, we controlled for clustering at the hospital level; for comparisons of cases in aggregate, owing to multiple responses from each participant, we controlled for clustering at the individual level.

Assuming a 50% response rate from both PCPs and hospitalists, and that 50% of PCPs would rate a given intervention as appropriate, we calculated that we would have 90% power to detect a 50% increase in the proportion of hospitalists rating an intervention as appropriate as compared to PCPs, using an of .05.

RESULTS

Demographics

One hundred sixty‐two out of 295 providers (55%) responded to the survey (Table 2). The response rate did not differ between hospitalists (70 out of 128; 55%) and PCPs (92 out of 167; 55%). Female respondents made up 58.7% of the PCP and 50.0% of the hospitalist groups (P=0.34). On average, PCPs were older (P<0.001) with a greater median number of years since graduation from residency (P<0.001). A greater percentage of hospitalists spent more than three‐quarters of their time clinically (42.9% vs 19.6%, P=0.009).

Demographics
 Total, n=162 (100.0%)PCP, n=92 (6.8%)Hospitalist, n=70 (43.2%)P Valuea
  • NOTE: Abbreviations: AOR, attending of record; BIDMC, Beth Israel Deaconess Medical Center; BWH, Brigham and Women's Hospital; FTE, full‐time equivalent; IQR, interquartile range; MGH, Massachusetts General Hospital; PCP, primary care physician.

  • Comparing hospitalists to PCPs.

  • Excluding residency.

Hospital, n (%)    
BIDMC79 (48.8)48 (60.8)31 (39.2)0.115
BWH36 (22.2)15 (41.7)21 (58.3)
MGH47 (29.0)29 (61.7)18 (38.3)
Sex, n (%)    
Male73 (45.1)38 (41.3)35 (50.0)0.339
Female89 (54.9)54 (58.7)35 (50.0)
Age interval, y, n (%)    
253436 (22.2)9 (9.8)27 (38.6)<0.001
354467 (41.4)34 (37.0)33 (47.1)
455435 (21.6)29 (31.5)6 (8.6)
556419 (11.7)16 (17.4)3 (4.3)
65745 (3.1)4 (4.4)1 (1.4)
Years out of residency, median (IQR)10 (417)15 (74)5 (211)<0.001
Clinical FTE, n (%)    
0.2530 (18.6)22 (23.9)8 (11.4)0.009
0.260.5041 (25.3)25 (27.2)16 (22.9)
0.510.7543 (26.5)27 (29.4)16 (22.9)
>0.7548 (29.6)18 (19.6)30 (42.9)
Worked as PCP?b    
Yes  6 (8.6) 
No  64 (91.4) 
Worked as hospitalist?    
Yes 11 (12.0)  
No 81 (88.0)  
AOR for admitted patients    
Always 16 (17.4)  
Mostly 8 (8.7)  
Rarely 7 (7.6)  
Never 60 (65.2)  

Appropriateness of Inpatient Management Based on Admitting Diagnosis

For each of the 6 case pairings individually and in aggregate, respondents were significantly more likely to deem the intervention appropriate or very appropriate if it was related to the reason for admission, compared to those interventions unrelated to the reason for admission (in aggregate, 78.9% vs 38.8% respectively, P<0.001). For example, whereas 96.9% felt that the addition of aspirin in a patient admitted with acute myocardial infarction (MI) was appropriate, only 54.3% felt it appropriate to start aspirin in a patient with a prior history of MI admitted with cellulitis (P<0.001). Significant differences (all P values <0.001) were seen for all case pairs: starting spironolactone (68.1% when related to the reason for reason for admission vs 43.1% when unrelated to reason for admission); starting warfarin (62.3% vs 23.3%), stopping proton pump inhibitor (72.3% vs 42.8%), stopping statin or fibrate (90.6% vs 28.3%), and changing statin (83.0% vs 40.5%).

Appropriateness of Inpatient Management based on Primary Role

Table 3 compares the percent of PCPs and hospitalists rating each intervention as appropriate or very appropriate, by relatedness of the intervention to the reason for admission. In both unadjusted and adjusted comparisons for all cases in aggregate, PCPs were significantly more likely than hospitalists to rate the inpatient interventions as appropriate or very appropriate when the intervention was related to the reason for admission (83.4% of PCP responses vs 73.0% of hospitalist responses, P<0.001; RR: 1.2, 95% confidence interval [CI]: 1.11.3), unrelated to the reason for admission (44.7% vs 31.1%, P<0.001; RR: 1.5, 95% CI: 1.11.9), and overall (64.1% vs 52.1%, P<0.001; RR: 1.3, 95% CI: 1.11.4).

Percent of PCP and Hospitalist Respondents Who Answered Very Appropriate or Appropriate by Relatedness of the Intervention to the Reason for Admission and Overall
Relationship to Admission DiagnosisPCP, n (%)Hospitalist, n (%)P ValueAdjusted RR95% CI
  • NOTE: Abbreviations: CI, confidence interval; PCP, primary care physician; RR, relative risk.

  • PCP versus hospitalist, adjusted for years out of residency, sex, clinical full‐time equivalent, and clustering by individual.

  • PCP vs hospitalist, adjusted for years out of residency, sex, clinical full‐time equivalent, relatedness of the intervention to the condition prompting admission, and clustering by individual.

Related453 (83.4)303 (73.0)<0.0011.2a1.11.3
Unrelated242 (44.7)129 (31.1)<0.0011.5a1.11.9
Overall695 (64.1)432 (52.1)<0.0011.3b1.11.4

Reasons for Inappropriate Designation

Among those respondents rating an intervention as inappropriate or very inappropriate, the 3 most common reasons selected as explanation for perceived inappropriateness from our predefined answer choices were: This medication will necessitate follow‐up testing/monitoring, for which the PCP will be responsible (chosen by physicians in 49.4% of instances); I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision (35.7%); and Even if the hospitalist has all of the medical history and reviews it, the PCP should be involved in all decisions surrounding new medications (34.6%). The least common explanation chosen was I do not believe this is an appropriate pharmacologic intervention for this particular medical problem (6.5%). See Table 4 for a complete list of explanations, overall and stratified by PCP/hospitalist.

Percent of Respondents Who Selected Each Predefined Reason for Inappropriateness
Predefined Reason for InappropriatenessTotal, n=583 (%)PCP, n=318 (%)Hospitalist, n=265 (%)P Value
  • NOTE: Abbreviations: PCP, primary care physician.

This medication will necessitate follow‐up testing/monitoring, for which the PCP will be responsible.288 (49.4)151 (47.5)137 (51.7)0.32
I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision.208 (35.7)98 (30.8)110 (41.5)0.009
Even if the hospitalist has all of the medical history and reviews it, the PCP should be involved in all decisions surrounding new medications.201 (34.5)125 (39.3)76 (28.7)0.009
I am not confident that the hospitalist will adequately review the medical history necessary to make this decision.184 (31.6)130 (40.9)54 (20.4)<0.001
Even if the hospitalist has all of the medical history, I do not believe hospitalization is the right time to start this new medication106 (21.4)69 (21.7)56 (21.1)0.92
I am not confident that the hospitalist will appropriately discuss the risks and benefits of this new medication with the patient.106 (18.2)85 (26.7)21 (7.9)<0.001
The benefit of this medication will be too remote to justify starting it in the acute setting.66 (11.3)40 (12.6)26 (9.8)0.36
I do not believe this is an appropriate pharmacologic intervention for this particular medical problem.38 (6.5)27 (8.5)11 (4.2)0.04

There were significant differences in the proportion of PCPs and hospitalists choosing several of the prespecified reasons for inappropriateness. Although hospitalists were more likely than PCPs to select I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision (chosen by 41.5% of hospitalists vs 30.8% of PCPs, P=0.009), PCPs were more likely than hospitalists to select, I am not confident that the hospitalist will adequately review the medical history necessary to make this decision (chosen by 40.9% of PCPs vs 20.4% of hospitalists, P<0.001) and I am not confident that the hospitalist will appropriately discuss the risks and benefits of this new medication with the patient (26.7% of PCPs vs 9.8% of hospitalists, P<0.001).

Opinions on Current Management of Conditions Related and Unrelated to Admission

A minority of PCPs and hospitalists agreed or strongly agreed that hospitalists should play a larger role in the management of medical conditions unrelated to the reason for admission (28.1% of PCPs vs 34.8% of hospitalists; P=0.39).

DISCUSSION

In this survey‐based study of PCPs and hospitalists across 3 Boston‐area academic medical centers, we found that: (1) physicians were more likely to see inpatient interventions as appropriate when those interventions dealt with the reason for admission as compared to interventions unrelated to the reason for admission; and (2) PCPs were more likely than hospitalists to feel that inpatient interventions were appropriate, even when they targeted chronic conditions unrelated to the reason for admission. To our knowledge, this study represents the first investigation into the attitudes of PCPs and hospitalists regarding the inpatient management of conditions unrelated to the reason for admission.

That surveyed physicians, regardless of role, were less likely to report an intervention unrelated to the reason for hospitalization as appropriateeven those with likely mortality benefitsuggests that opportunities to affect meaningful change may be missed in a healthcare system that adheres to strict inpatient and outpatient roles. For several of the cases, a change in therapy could lead to benefit soon after implementation. For example, aldosterone antagonists reduce mortality as early as 1 month after initiation in select patients.[8] If a major goal of inpatient care is to reduce 30‐day mortality, it could be argued that hospitalists should more actively adjust congestive heart failure therapy in appropriate inpatients, even when this is not their admitting diagnosis.

For some conditions, CMS is already tracking hospital performance. Since 2003, hospitals have been required to document whether a patient with congestive heart failure (either acute or chronic and regardless of the relationship to admission) was prescribed an angiotensin‐converting enzyme (ACE) inhibitor or angiotensin receptor blocker (ARB) at the time of discharge.[7] CMS has determined that the proven benefits of ACE inhibitors and ARBs confer hospital accountability for their inclusion in appropriate patients, independent of the acuity of heart failure. There are many potential therapeutic maneuvers on which health systems (and their physicians) may be graded, and accepting the view that a hospitalization provides a window of opportunity for medical optimization may allow for more fruitful interventions and more patient‐centered care.

Despite the potential benefits of addressing chronic medical issues during hospitalization, there are important limitations on what can and/or should be done in the hospital setting. Hospitalizations are a time of fluctuating clinical status, which continues beyond discharge and is often accompanied by several medication changes.[9] In our study, more than 20% of those who believed that a medication intervention was inappropriate selected I do not believe hospitalization is the right time to start this new medication as one of their explanations. Although some medication interventions have been shown in randomized controlled trials to reduce short‐term mortality, the ability to generalize these findings to the average hospitalized patient with multiple comorbidities, concurrent medication changes, and rapidly fluctuating clinical status is limited. Furthermore, there are interventions most would agree should not be dealt with in the hospital (eg, screening colonoscopy) and encounters that may be too short to allow for change (eg, 24‐hour observation). These issues notwithstanding, the average 4‐day hospitalization likely provides an opportunity for monitored change that may currently be underutilized.

Our study suggests several additional explanations for physicians' current practice and opinions. Only 6.5% of respondents who answered that an intervention was inappropriate indicated as a justification that I do not believe this is an appropriate pharmacologic intervention for this particular medical problem. This suggests that the hesitancy has little to do with a lack of benefit but instead relates to systems issues (eg, access to all pertinent records and concerns regarding follow‐up testing) and perceived limitations to what a hospitalist should and should not do without actively involving the PCP. There are likely additional concerns that the medical record and/or patient histories do not fully outline the rationale for exclusion or inclusion of particular medications. Advances in information technology that enhance information exchange and enable streamlined communication may help to address these perceived barriers. However, an additional barrier may be trust, as PCPs appear more concerned that hospitalists will not review all the pertinent records or discuss risks and benefits before enacting important medication changes. Increased attempts at communication between hospitalists and outpatient providers may help to build trust and alleviate concerns regarding the loss of information that often occurs both on admission and at discharge.

We also noted that PCPs were more likely than hospitalists to feel that inpatient interventions were appropriate, even when targeting chronic conditions unrelated to the reason for admission. It may be that PCPs, with an increasing number of problems to address per outpatient visit,[10, 11] are more open to hospitalists managing any medical problems during their patients' admissions. At the same time, with increased acuity[12, 13, 14] and shortened length of stays,[15, 16] hospitalists have only a finite amount of time to ensure acute issues are managed, leaving potentially modifiable chronic conditions to the outpatient setting. These differences aside, a minority of both PCPs and hospitalists in our study were ready to embrace the idea of hospitalists playing a larger role in the management of conditions unrelated to the reason for hospitalization.

Even though our study benefits from its multisite design, there are a number of limitations. First, although we crafted our survey with input from general medicine focus groups, our survey instrument has not been validated. In addition, the cases are necessarily contrived and do not take into account the complexities of inpatient medicine. Furthermore, though our goal was to create paired cases that isolate a management decision as being simply based on whether it was related or unrelated to the reason for admission, it is possible that other factors, not captured by our survey, influenced the responses. For example, the benefits of aspirin as part of secondary prevention are not equal to the benefits in an acute MI.[17]

In an attempt to isolate the hospitalists' role in these management decisions, respondents were instructed to assume that the decisions were being made without discussing it with the primary care physician, but that the hospitalist would communicate the details of any hospitalization at the time of discharge. They were also instructed to assume that the hospitalist has access to the patient's outpatient electronic medical record. These assumptions were made to address concerns regarding the flow of information and communication, and to simulate the ideal system from a communication and information accessibility standpoint. Had these assumptions not been placed, the responses may have differed. It is likely that PCPs and hospitalists practicing in systems without shared, accessible inpatient/outpatient medical records would be even more reluctant to enact medication changes unrelated to the reason for admission.

Along the same lines, our physician cohort consisted of several metropolitan academic physician groups, in which hospitalists have had a presence for almost 20 years. As a result, our findings may not be generalizable to other academic hospitals, community‐based hospitalist programs, or nonhospital‐based PCP practices. Finally, we do not know whether survey nonresponders differed from responders in ways that could have meaningfully affected our results.

In conclusion, our findings suggest that both PCPs and hospitalists see the management of conditions unrelated to the reason for admission as less appropriate than the management of conditions related to the reason for admission. Our findings also suggest that PCPs may be more open to this practice when compared to hospitalists. Failure to capitalize on opportunities for meaningful medical interventions, independent of patient location, suggests a possible lack of patient centeredness in the current partnership between PCPs and hospitalists. Further studies should examine existing barriers and investigate interventions designed to address those barriers, in an effort to improve both quality of care and the degree of patient‐centeredness in our current healthcare system.

Disclosures: Dr. Herzig is supported by a grant from the National Institute on Aging (K23 AG042459). Dr. Herzig had full access to all of the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. Author contributions: study concept and design, Breu, Allen‐Dicker, Mueller, Herzig; acquisition of data, Breu, Allen‐Dicker, Mueller, Palamara, Herzig; analysis and interpretation of data, Breu, Allen‐Dicker, Hinami, Herzig; drafting of the manuscript, Breu; critical revision of the manuscript for important intellectual content, Breu, Allen‐Dicker, Mueller, Palamara, Hinami, Herzig; statistical analysis, Allen‐Dicker, Hinami, Herzig; study supervision, Breu, Herzig. This study was presented as a poster at the Society of Hospital Medicine National Meeting, Washington, DC, May 17, 2013.

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References
  1. Kuo Y‐F, Sharma G, Freeman JL, Goodwin JS. Growth in the care of older patients by hospitalists in the United States. N Engl J Med. 2009;360(11):11021112.
  2. Wachter RM, Goldman L. The emerging role of “hospitalists” in the American health care system. N Engl J Med. 1996;335(7):514517.
  3. Wachter RM. An introduction to the hospitalist model. Ann Intern Med. 1999;130(4 pt 2):338342.
  4. Axon RN, Williams MV. Hospital readmission as an accountability measure. JAMA. 2011;305(5):504505.
  5. McClellan M, McKethan AN, Lewis JL, Roski J, Fisher ES. A national strategy to put accountable care into practice. Health Aff (Millwood). 2010;29(5):982990.
  6. Landon BE. Keeping score under a global payment system. N Engl J Med. 2012;366(5):393395.
  7. Reporting Hospital Quality Data for Annual Payment Update. Available at: http://www.cms.gov/Medicare/Quality‐Initiatives‐Patient‐Assessment‐Instruments/HospitalQualityInits/Downloads/HospitalRHQDAPU200808. Accessed December 18, 2013.
  8. Zannad F, McMurray JJV, Krum H, et al. Eplerenone in patients with systolic heart failure and mild symptoms. N Engl J Med. 2011;364(1):1121.
  9. Viktil KKK, Blix HSH, Eek AKA, Davies MNM, Moger TAT, Reikvam AA. How are drug regimen changes during hospitalisation handled after discharge: a cohort study. BMJ Open. 2012;2(6):e001461.
  10. Chen LM, Farwell WR, Jha AK. Primary care visit duration and quality: does good care take longer? Arch Intern Med. 2009;169(20):18661872.
  11. Abbo ED, Zhang Q, Zelder M, Huang ES. The increasing number of clinical items addressed during the time of adult primary care visits. J Gen Intern Med. 2008;23(12):20582065.
  12. Freid VM, Bernstein AB, Bush MA. Multiple chronic conditions among adults aged 45 and over: trends over the past 10 years. NCHS Data Brief. 2012;(100):18.
  13. Schneider KM, O'Donnell BE, Dean D. Prevalence of multiple chronic conditions in the United States' Medicare population. Health Qual Life Outcomes. 2009;7(1):82.
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  15. Kaboli PJ, Go JT, Hockenberry J, et al. Associations between reduced hospital length of stay and 30‐day readmission rate and mortality: 14‐year experience in 129 Veterans Affairs hospitals. Ann Intern Med. 2012;157(12):837845.
  16. Bueno H, Ross JS, Wang Y, et al. Trends in length of stay and short‐term outcomes among Medicare patients hospitalized for heart failure, 1993–2006. JAMA. 2010;303(21):21412147.
  17. Antithrombotic Trialists' Collaboration. Collaborative meta‐analysis of randomised trials of antiplatelet therapy for prevention of death, myocardial infarction, and stroke in high risk patients. BMJ. 2002;324(7329):7186.
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Over the past 2 decades, the care of the hospitalized patient has changed dramatically. Hospitalists now account for the care of more than one‐third of general medicine inpatients, and this number is likely to grow.[1] The emergence of hospital medicine has resulted in a partnership between primary care physicians (PCPs) and hospitalists wherein hospitalists focus on acute medical issues requiring hospitalization, whereas more chronic issues unrelated to the reason for hospitalization remain largely the domain of the PCP.[2, 3]

However, several evolving financial and quality incentives have already begun to blur the distinction between inpatient and outpatient care. First, as private and public payers increasingly scrutinize readmission rates, it has become clear that the responsibility for patient outcomes extends beyond the day of discharge.[4] The birth of Accountable Care Organizations and patient‐centered medical homes may further blur distinctions between what has traditionally constituted inpatient and outpatient care.[5] Bundled payments may force providers to ensure that each visit, whether hospital‐ or clinic‐based, is taken as an opportunity to enact meaningful change.[6] The Centers for Medicare and Medicaid Services (CMS) are already tracking hospital performance on institution of medical therapy for certain conditions regardless of their relatedness to the reason for hospitalization.[7]

No published literature has yet examined the attitudes of inpatient and outpatient providers regarding this issue. Through a case‐based survey conducted at 3 large urban academic medical centers, we aimed to assess opinions among hospitalists and PCPs regarding the role of hospitalists in the management of conditions unrelated to the reason for admission. Our study had 2 main objectives: (1) to determine whether surveyed physicians were more likely to rate an inpatient intervention as appropriate when it related to the reason for admission as compared to interventions unrelated to the reason for admission; and (2) to determine whether these attitudes differed between PCPs and hospitalists.

METHODS

Setting and Subjects

We surveyed hospitalists and hospital‐based PCPs at Beth Israel Deaconess Medical Center (BIDMC), Brigham and Women's Hospital, and Massachusetts General Hospital, 3 large academic medical centers in Boston, Massachusetts. Each hospitalist group includes both teaching and nonteaching services and admits patients from both the surveyed hospital‐based PCP groups and other nonhospital‐based PCP groups. All 3 study sites use electronic medical records with patient information for each hospital‐based PCP available to treating hospitalists.

Survey Design

Using a commercially available online product (SurveyMonkey, Palo Alto, CA), we created a 3‐part case‐based survey instrument. The first section included demographic questions regarding age, sex, primary clinical role (hospitalist or PCP), prior experience as a PCP (for hospitalists only) or a hospitalist (for PCPs only; defined as a position with >30% of clinical time as the attending of record in the inpatient setting), years of clinical experience, and hospital affiliation.

The second section aimed to indirectly assess physician opinions on the appropriateness of inpatient management of conditions unrelated to the reason for admission. It consisted of 6 paired case scenarios, each with an inpatient management decision for a hypothetical hospitalist (Table 1). For each pair, 1 case dealt with management of the condition prompting admission (eg, starting aspirin in a patient admitted with acute nonST‐elevation myocardial infarction). The partner case involved the same intervention (eg, starting aspirin) but for a patient with a chronic condition (eg, history of prior myocardial infarction) and an alternate admitting diagnosis (eg, cellulitis). In an attempt to mitigate concerns regarding the flow of information and communication between providers, the survey asked respondents to assume that the hospitalist has access to the patient's outpatient electronic medical record, and that the hospitalist communicates the details of any hospitalizations at the time of discharge. For each case, the physician was asked to rate the appropriateness of enacting the intervention without discussing it with the PCP on a 5‐point scale from very inappropriate to very appropriate. When a physician answered that an intervention was inappropriate or very inappropriate, an additional question soliciting reasons for inappropriateness was included, with multiple predefined answer choices, as well as the option of a free‐text reply under the other designation.

Cases Descriptions
  • NOTE: Abbreviations: CHADS2, congestive heart failure, hypertension, age 75 years, diabetes mellitus, stroke/transient ischemic attack/thromboembolism; GERD, gastroesophageal reflux disease; LDL, low‐density lipoprotein; LVEF, left ventricular ejection fraction; NYHA, New York Heart Association; MI, myocardial infarction.

Starting aspirin (related to the reason for admission)A 60‐year‐old patient is admitted with a nonST‐elevation MI, medically managed without cardiac catheterization or percutaneous coronary intervention. Knowing that aspirin reduces mortality as part of secondary prevention in cardiovascular disease, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician?
Starting aspirin (unrelated to the reason for admission)A 60‐year‐old patient with a past medical history of a prior nonST‐elevation MI that was medically managed is admitted to the hospital for treatment of cellulitis. The hospitalist notes the patient is not on aspirin at home. Knowing that aspirin reduces mortality as part of secondary prevention in cardiovascular disease, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician?
Starting spironolactone (related to the reason for admission)A 70‐year‐old patient with a past medical history significant for NYHA class II congestive heart failure (LVEF of 20%) is admitted for acute on chronic, left‐sided systolic congestive heart failure. The patient has been maintained on furosemide, metoprolol, and lisinopril. Admission serum potassium and creatinine are both normal. Knowing that spironolactone decreases mortality in heart failure, how appropriate is it for the hospitalist to start this medication without discussing it with the primary care physician?
Starting spironolactone (unrelated to the reason for admission)A 70‐year‐old patient with a past history of NYHA class II congestive heart failure (LVEF of 20%) on furosemide, metoprolol, and lisinopril is admitted with pneumonia. Serum potassium and creatinine are both normal. Knowing that spironolactone decreases mortality in heart failure, how appropriate is it for the hospitalist to start this medication without discussing it with the primary care physician?
Starting warfarin (related to the reason for admission)A 75‐year‐old patient with a past medical history of hypertension and diabetes is admitted with new atrial fibrillation. Given the patient's CHADS2 score of 3, the hospitalist calculates that the patient has a significant risk of thromboembolic stroke. Knowing that warfarin will decrease the risk of thromboembolic stroke, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician (assume that an outpatient anticoagulation clinic is able to see the patient within 3 days of discharge)?
Starting warfarin (unrelated to the reason for admission)A 75‐year‐old patient with a past medical history of hypertension, diabetes, and atrial fibrillation is admitted with pneumonia. The patient is not anticoagulation therapy. Given the patient's CHADS2 score of 3, the hospitalist calculates that the patient has a significant risk of thromboembolic stroke. Knowing that warfarin will decrease the risk of thromboembolic stroke, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician (assume that an outpatient anticoagulation clinic is able to see the patient within 3 days of discharge)?
Stopping proton pump inhibitor (related to the reason for admission)A 65‐year‐old patient with a past medical history of GERD maintained on a proton pump inhibitor is admitted for treatment of Clostridium difficile colitis. The patient denies having any GERD‐like symptoms for several years. Knowing that proton pump inhibitors can increase the risk of C difficile colitis and recurrence (as well as pneumonia and osteoporosis), how appropriate is it for the hospitalist to initiate a taper of this medication without discussing it with the primary care physician?
Stopping proton pump inhibitor (unrelated to the reason for admission)A 65‐year‐old patient with a past medical history of GERD maintained on a proton pump inhibitor is admitted for treatment of a urinary tract infection. The patient denies having any GERD‐like symptoms for several years. Knowing that proton pump inhibitors can increase the risk of C difficile colitis and recurrence (as well as pneumonia and osteoporosis), how appropriate is it for the hospitalist to initiate a taper of this medication without discussing it with the primary care physician?
Stopping statin or fibrate (related to the reason for admission)A 60‐year‐old patient with a history of hyperlipidemia is admitted with an elevated creatine kinase to 5000. The hospitalist notes that the patient is on both simvastatin and gemfibrozil. The patient's most recent serum LDL was at goal. Knowing that coadministration of simvastatin and gemfibrozil can increase the risk of rhabdomyolysis, how appropriate is it for the hospitalist to stop one of these medications without discussing it with the primary care physician?
Stopping statin or fibrate (unrelated to the reason for admission)A 60‐year‐old patient is admitted with an acute diarrheal illness. The hospitalist notes that the patient is on both simvastatin and gemfibrozil. The patient's most recent LDL was at goal. Knowing that coadministration of simvastatin and gemfibrozil can increase the risk of rhabdomyolysis, how appropriate is it for the hospitalist to stop one of these medications without discussing it with the primary care physician?
Changing statin (related to the reason for admission)A 65‐year‐old patient with a past medical history of hyperlipidemia on maximum‐dose simvastatin is admitted with a nonST‐elevation MI. The patient's cholesterol is noted to be above goal. Knowing that improving lipid management reduces mortality in cardiovascular disease, how appropriate is it for the hospitalist to replace simvastatin with atorvastatin without discussing it with the primary care physician?
Changing statin (unrelated to the reason for admission)A 65‐year‐old patient with a past medical history of a prior nonST‐elevation MI that was medically managed and hyperlipidemia on maximum‐dose simvastatin is admitted with pneumonia. Incidentally, the hospitalist notes that the patient's cholesterol has been above goal for the last 2 years. Knowing that improving lipid management reduces mortality in cardiovascular disease, how appropriate is it for the hospitalist to replace simvastatin with atorvastatin without discussing it with the primary care physician?

The third section aimed to directly assess physicians' opinions. It consisted of questions regarding the appropriateness of inpatient management of conditions related to and unrelated to a patient's reason for admission.

Prior to administration, we conducted focus groups of hospitalists and PCPs to help hypothesize current physician perceptions on inpatient management, assess physician understanding of survey cases and questions, and to evaluate survey length.

Survey Administration

Between October 23, 2012 and November 10, 2012, 3 emails containing a link to the online survey were sent to all hospitalist and hospital‐based PCPs at the 3 study institutions. The BIDMC Committee on Clinical Investigations, to whom authority was ceded by the remaining 2 study institutions, certified this research protocol as exempt.

Statistical Analysis

We hypothesized that respondents as a whole would be more likely to rate an intervention as appropriate or very appropriate if it was related to the reason for admission, compared to unrelated, and that there would be no difference between PCPs and hospitalists.

We used 2 and Fisher exact tests (where applicable) to compare categorical variables, and a nonparametric median test for continuous variables. We used the Fisher exact test to compare the percent of respondents rating each intervention as appropriate or very appropriate by relatedness or unrelatedness to the reason for admission, and by PCP vs hospitalist. To derive the relative risk (RR) of rating each intervention as appropriate or very appropriate by PCPs compared to hospitalists, adjusting for potential confounders including years out of residency and sex, we used multivariable generalized estimating equation models, each with a Poisson distribution error term, a log link, and an exchangeable working correlation structure to account for dependency of observations arising from clustering at either the hospital or participant level, depending on the comparison: for comparisons within a given case, we controlled for clustering at the hospital level; for comparisons of cases in aggregate, owing to multiple responses from each participant, we controlled for clustering at the individual level.

Assuming a 50% response rate from both PCPs and hospitalists, and that 50% of PCPs would rate a given intervention as appropriate, we calculated that we would have 90% power to detect a 50% increase in the proportion of hospitalists rating an intervention as appropriate as compared to PCPs, using an of .05.

RESULTS

Demographics

One hundred sixty‐two out of 295 providers (55%) responded to the survey (Table 2). The response rate did not differ between hospitalists (70 out of 128; 55%) and PCPs (92 out of 167; 55%). Female respondents made up 58.7% of the PCP and 50.0% of the hospitalist groups (P=0.34). On average, PCPs were older (P<0.001) with a greater median number of years since graduation from residency (P<0.001). A greater percentage of hospitalists spent more than three‐quarters of their time clinically (42.9% vs 19.6%, P=0.009).

Demographics
 Total, n=162 (100.0%)PCP, n=92 (6.8%)Hospitalist, n=70 (43.2%)P Valuea
  • NOTE: Abbreviations: AOR, attending of record; BIDMC, Beth Israel Deaconess Medical Center; BWH, Brigham and Women's Hospital; FTE, full‐time equivalent; IQR, interquartile range; MGH, Massachusetts General Hospital; PCP, primary care physician.

  • Comparing hospitalists to PCPs.

  • Excluding residency.

Hospital, n (%)    
BIDMC79 (48.8)48 (60.8)31 (39.2)0.115
BWH36 (22.2)15 (41.7)21 (58.3)
MGH47 (29.0)29 (61.7)18 (38.3)
Sex, n (%)    
Male73 (45.1)38 (41.3)35 (50.0)0.339
Female89 (54.9)54 (58.7)35 (50.0)
Age interval, y, n (%)    
253436 (22.2)9 (9.8)27 (38.6)<0.001
354467 (41.4)34 (37.0)33 (47.1)
455435 (21.6)29 (31.5)6 (8.6)
556419 (11.7)16 (17.4)3 (4.3)
65745 (3.1)4 (4.4)1 (1.4)
Years out of residency, median (IQR)10 (417)15 (74)5 (211)<0.001
Clinical FTE, n (%)    
0.2530 (18.6)22 (23.9)8 (11.4)0.009
0.260.5041 (25.3)25 (27.2)16 (22.9)
0.510.7543 (26.5)27 (29.4)16 (22.9)
>0.7548 (29.6)18 (19.6)30 (42.9)
Worked as PCP?b    
Yes  6 (8.6) 
No  64 (91.4) 
Worked as hospitalist?    
Yes 11 (12.0)  
No 81 (88.0)  
AOR for admitted patients    
Always 16 (17.4)  
Mostly 8 (8.7)  
Rarely 7 (7.6)  
Never 60 (65.2)  

Appropriateness of Inpatient Management Based on Admitting Diagnosis

For each of the 6 case pairings individually and in aggregate, respondents were significantly more likely to deem the intervention appropriate or very appropriate if it was related to the reason for admission, compared to those interventions unrelated to the reason for admission (in aggregate, 78.9% vs 38.8% respectively, P<0.001). For example, whereas 96.9% felt that the addition of aspirin in a patient admitted with acute myocardial infarction (MI) was appropriate, only 54.3% felt it appropriate to start aspirin in a patient with a prior history of MI admitted with cellulitis (P<0.001). Significant differences (all P values <0.001) were seen for all case pairs: starting spironolactone (68.1% when related to the reason for reason for admission vs 43.1% when unrelated to reason for admission); starting warfarin (62.3% vs 23.3%), stopping proton pump inhibitor (72.3% vs 42.8%), stopping statin or fibrate (90.6% vs 28.3%), and changing statin (83.0% vs 40.5%).

Appropriateness of Inpatient Management based on Primary Role

Table 3 compares the percent of PCPs and hospitalists rating each intervention as appropriate or very appropriate, by relatedness of the intervention to the reason for admission. In both unadjusted and adjusted comparisons for all cases in aggregate, PCPs were significantly more likely than hospitalists to rate the inpatient interventions as appropriate or very appropriate when the intervention was related to the reason for admission (83.4% of PCP responses vs 73.0% of hospitalist responses, P<0.001; RR: 1.2, 95% confidence interval [CI]: 1.11.3), unrelated to the reason for admission (44.7% vs 31.1%, P<0.001; RR: 1.5, 95% CI: 1.11.9), and overall (64.1% vs 52.1%, P<0.001; RR: 1.3, 95% CI: 1.11.4).

Percent of PCP and Hospitalist Respondents Who Answered Very Appropriate or Appropriate by Relatedness of the Intervention to the Reason for Admission and Overall
Relationship to Admission DiagnosisPCP, n (%)Hospitalist, n (%)P ValueAdjusted RR95% CI
  • NOTE: Abbreviations: CI, confidence interval; PCP, primary care physician; RR, relative risk.

  • PCP versus hospitalist, adjusted for years out of residency, sex, clinical full‐time equivalent, and clustering by individual.

  • PCP vs hospitalist, adjusted for years out of residency, sex, clinical full‐time equivalent, relatedness of the intervention to the condition prompting admission, and clustering by individual.

Related453 (83.4)303 (73.0)<0.0011.2a1.11.3
Unrelated242 (44.7)129 (31.1)<0.0011.5a1.11.9
Overall695 (64.1)432 (52.1)<0.0011.3b1.11.4

Reasons for Inappropriate Designation

Among those respondents rating an intervention as inappropriate or very inappropriate, the 3 most common reasons selected as explanation for perceived inappropriateness from our predefined answer choices were: This medication will necessitate follow‐up testing/monitoring, for which the PCP will be responsible (chosen by physicians in 49.4% of instances); I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision (35.7%); and Even if the hospitalist has all of the medical history and reviews it, the PCP should be involved in all decisions surrounding new medications (34.6%). The least common explanation chosen was I do not believe this is an appropriate pharmacologic intervention for this particular medical problem (6.5%). See Table 4 for a complete list of explanations, overall and stratified by PCP/hospitalist.

Percent of Respondents Who Selected Each Predefined Reason for Inappropriateness
Predefined Reason for InappropriatenessTotal, n=583 (%)PCP, n=318 (%)Hospitalist, n=265 (%)P Value
  • NOTE: Abbreviations: PCP, primary care physician.

This medication will necessitate follow‐up testing/monitoring, for which the PCP will be responsible.288 (49.4)151 (47.5)137 (51.7)0.32
I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision.208 (35.7)98 (30.8)110 (41.5)0.009
Even if the hospitalist has all of the medical history and reviews it, the PCP should be involved in all decisions surrounding new medications.201 (34.5)125 (39.3)76 (28.7)0.009
I am not confident that the hospitalist will adequately review the medical history necessary to make this decision.184 (31.6)130 (40.9)54 (20.4)<0.001
Even if the hospitalist has all of the medical history, I do not believe hospitalization is the right time to start this new medication106 (21.4)69 (21.7)56 (21.1)0.92
I am not confident that the hospitalist will appropriately discuss the risks and benefits of this new medication with the patient.106 (18.2)85 (26.7)21 (7.9)<0.001
The benefit of this medication will be too remote to justify starting it in the acute setting.66 (11.3)40 (12.6)26 (9.8)0.36
I do not believe this is an appropriate pharmacologic intervention for this particular medical problem.38 (6.5)27 (8.5)11 (4.2)0.04

There were significant differences in the proportion of PCPs and hospitalists choosing several of the prespecified reasons for inappropriateness. Although hospitalists were more likely than PCPs to select I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision (chosen by 41.5% of hospitalists vs 30.8% of PCPs, P=0.009), PCPs were more likely than hospitalists to select, I am not confident that the hospitalist will adequately review the medical history necessary to make this decision (chosen by 40.9% of PCPs vs 20.4% of hospitalists, P<0.001) and I am not confident that the hospitalist will appropriately discuss the risks and benefits of this new medication with the patient (26.7% of PCPs vs 9.8% of hospitalists, P<0.001).

Opinions on Current Management of Conditions Related and Unrelated to Admission

A minority of PCPs and hospitalists agreed or strongly agreed that hospitalists should play a larger role in the management of medical conditions unrelated to the reason for admission (28.1% of PCPs vs 34.8% of hospitalists; P=0.39).

DISCUSSION

In this survey‐based study of PCPs and hospitalists across 3 Boston‐area academic medical centers, we found that: (1) physicians were more likely to see inpatient interventions as appropriate when those interventions dealt with the reason for admission as compared to interventions unrelated to the reason for admission; and (2) PCPs were more likely than hospitalists to feel that inpatient interventions were appropriate, even when they targeted chronic conditions unrelated to the reason for admission. To our knowledge, this study represents the first investigation into the attitudes of PCPs and hospitalists regarding the inpatient management of conditions unrelated to the reason for admission.

That surveyed physicians, regardless of role, were less likely to report an intervention unrelated to the reason for hospitalization as appropriateeven those with likely mortality benefitsuggests that opportunities to affect meaningful change may be missed in a healthcare system that adheres to strict inpatient and outpatient roles. For several of the cases, a change in therapy could lead to benefit soon after implementation. For example, aldosterone antagonists reduce mortality as early as 1 month after initiation in select patients.[8] If a major goal of inpatient care is to reduce 30‐day mortality, it could be argued that hospitalists should more actively adjust congestive heart failure therapy in appropriate inpatients, even when this is not their admitting diagnosis.

For some conditions, CMS is already tracking hospital performance. Since 2003, hospitals have been required to document whether a patient with congestive heart failure (either acute or chronic and regardless of the relationship to admission) was prescribed an angiotensin‐converting enzyme (ACE) inhibitor or angiotensin receptor blocker (ARB) at the time of discharge.[7] CMS has determined that the proven benefits of ACE inhibitors and ARBs confer hospital accountability for their inclusion in appropriate patients, independent of the acuity of heart failure. There are many potential therapeutic maneuvers on which health systems (and their physicians) may be graded, and accepting the view that a hospitalization provides a window of opportunity for medical optimization may allow for more fruitful interventions and more patient‐centered care.

Despite the potential benefits of addressing chronic medical issues during hospitalization, there are important limitations on what can and/or should be done in the hospital setting. Hospitalizations are a time of fluctuating clinical status, which continues beyond discharge and is often accompanied by several medication changes.[9] In our study, more than 20% of those who believed that a medication intervention was inappropriate selected I do not believe hospitalization is the right time to start this new medication as one of their explanations. Although some medication interventions have been shown in randomized controlled trials to reduce short‐term mortality, the ability to generalize these findings to the average hospitalized patient with multiple comorbidities, concurrent medication changes, and rapidly fluctuating clinical status is limited. Furthermore, there are interventions most would agree should not be dealt with in the hospital (eg, screening colonoscopy) and encounters that may be too short to allow for change (eg, 24‐hour observation). These issues notwithstanding, the average 4‐day hospitalization likely provides an opportunity for monitored change that may currently be underutilized.

Our study suggests several additional explanations for physicians' current practice and opinions. Only 6.5% of respondents who answered that an intervention was inappropriate indicated as a justification that I do not believe this is an appropriate pharmacologic intervention for this particular medical problem. This suggests that the hesitancy has little to do with a lack of benefit but instead relates to systems issues (eg, access to all pertinent records and concerns regarding follow‐up testing) and perceived limitations to what a hospitalist should and should not do without actively involving the PCP. There are likely additional concerns that the medical record and/or patient histories do not fully outline the rationale for exclusion or inclusion of particular medications. Advances in information technology that enhance information exchange and enable streamlined communication may help to address these perceived barriers. However, an additional barrier may be trust, as PCPs appear more concerned that hospitalists will not review all the pertinent records or discuss risks and benefits before enacting important medication changes. Increased attempts at communication between hospitalists and outpatient providers may help to build trust and alleviate concerns regarding the loss of information that often occurs both on admission and at discharge.

We also noted that PCPs were more likely than hospitalists to feel that inpatient interventions were appropriate, even when targeting chronic conditions unrelated to the reason for admission. It may be that PCPs, with an increasing number of problems to address per outpatient visit,[10, 11] are more open to hospitalists managing any medical problems during their patients' admissions. At the same time, with increased acuity[12, 13, 14] and shortened length of stays,[15, 16] hospitalists have only a finite amount of time to ensure acute issues are managed, leaving potentially modifiable chronic conditions to the outpatient setting. These differences aside, a minority of both PCPs and hospitalists in our study were ready to embrace the idea of hospitalists playing a larger role in the management of conditions unrelated to the reason for hospitalization.

Even though our study benefits from its multisite design, there are a number of limitations. First, although we crafted our survey with input from general medicine focus groups, our survey instrument has not been validated. In addition, the cases are necessarily contrived and do not take into account the complexities of inpatient medicine. Furthermore, though our goal was to create paired cases that isolate a management decision as being simply based on whether it was related or unrelated to the reason for admission, it is possible that other factors, not captured by our survey, influenced the responses. For example, the benefits of aspirin as part of secondary prevention are not equal to the benefits in an acute MI.[17]

In an attempt to isolate the hospitalists' role in these management decisions, respondents were instructed to assume that the decisions were being made without discussing it with the primary care physician, but that the hospitalist would communicate the details of any hospitalization at the time of discharge. They were also instructed to assume that the hospitalist has access to the patient's outpatient electronic medical record. These assumptions were made to address concerns regarding the flow of information and communication, and to simulate the ideal system from a communication and information accessibility standpoint. Had these assumptions not been placed, the responses may have differed. It is likely that PCPs and hospitalists practicing in systems without shared, accessible inpatient/outpatient medical records would be even more reluctant to enact medication changes unrelated to the reason for admission.

Along the same lines, our physician cohort consisted of several metropolitan academic physician groups, in which hospitalists have had a presence for almost 20 years. As a result, our findings may not be generalizable to other academic hospitals, community‐based hospitalist programs, or nonhospital‐based PCP practices. Finally, we do not know whether survey nonresponders differed from responders in ways that could have meaningfully affected our results.

In conclusion, our findings suggest that both PCPs and hospitalists see the management of conditions unrelated to the reason for admission as less appropriate than the management of conditions related to the reason for admission. Our findings also suggest that PCPs may be more open to this practice when compared to hospitalists. Failure to capitalize on opportunities for meaningful medical interventions, independent of patient location, suggests a possible lack of patient centeredness in the current partnership between PCPs and hospitalists. Further studies should examine existing barriers and investigate interventions designed to address those barriers, in an effort to improve both quality of care and the degree of patient‐centeredness in our current healthcare system.

Disclosures: Dr. Herzig is supported by a grant from the National Institute on Aging (K23 AG042459). Dr. Herzig had full access to all of the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. Author contributions: study concept and design, Breu, Allen‐Dicker, Mueller, Herzig; acquisition of data, Breu, Allen‐Dicker, Mueller, Palamara, Herzig; analysis and interpretation of data, Breu, Allen‐Dicker, Hinami, Herzig; drafting of the manuscript, Breu; critical revision of the manuscript for important intellectual content, Breu, Allen‐Dicker, Mueller, Palamara, Hinami, Herzig; statistical analysis, Allen‐Dicker, Hinami, Herzig; study supervision, Breu, Herzig. This study was presented as a poster at the Society of Hospital Medicine National Meeting, Washington, DC, May 17, 2013.

Over the past 2 decades, the care of the hospitalized patient has changed dramatically. Hospitalists now account for the care of more than one‐third of general medicine inpatients, and this number is likely to grow.[1] The emergence of hospital medicine has resulted in a partnership between primary care physicians (PCPs) and hospitalists wherein hospitalists focus on acute medical issues requiring hospitalization, whereas more chronic issues unrelated to the reason for hospitalization remain largely the domain of the PCP.[2, 3]

However, several evolving financial and quality incentives have already begun to blur the distinction between inpatient and outpatient care. First, as private and public payers increasingly scrutinize readmission rates, it has become clear that the responsibility for patient outcomes extends beyond the day of discharge.[4] The birth of Accountable Care Organizations and patient‐centered medical homes may further blur distinctions between what has traditionally constituted inpatient and outpatient care.[5] Bundled payments may force providers to ensure that each visit, whether hospital‐ or clinic‐based, is taken as an opportunity to enact meaningful change.[6] The Centers for Medicare and Medicaid Services (CMS) are already tracking hospital performance on institution of medical therapy for certain conditions regardless of their relatedness to the reason for hospitalization.[7]

No published literature has yet examined the attitudes of inpatient and outpatient providers regarding this issue. Through a case‐based survey conducted at 3 large urban academic medical centers, we aimed to assess opinions among hospitalists and PCPs regarding the role of hospitalists in the management of conditions unrelated to the reason for admission. Our study had 2 main objectives: (1) to determine whether surveyed physicians were more likely to rate an inpatient intervention as appropriate when it related to the reason for admission as compared to interventions unrelated to the reason for admission; and (2) to determine whether these attitudes differed between PCPs and hospitalists.

METHODS

Setting and Subjects

We surveyed hospitalists and hospital‐based PCPs at Beth Israel Deaconess Medical Center (BIDMC), Brigham and Women's Hospital, and Massachusetts General Hospital, 3 large academic medical centers in Boston, Massachusetts. Each hospitalist group includes both teaching and nonteaching services and admits patients from both the surveyed hospital‐based PCP groups and other nonhospital‐based PCP groups. All 3 study sites use electronic medical records with patient information for each hospital‐based PCP available to treating hospitalists.

Survey Design

Using a commercially available online product (SurveyMonkey, Palo Alto, CA), we created a 3‐part case‐based survey instrument. The first section included demographic questions regarding age, sex, primary clinical role (hospitalist or PCP), prior experience as a PCP (for hospitalists only) or a hospitalist (for PCPs only; defined as a position with >30% of clinical time as the attending of record in the inpatient setting), years of clinical experience, and hospital affiliation.

The second section aimed to indirectly assess physician opinions on the appropriateness of inpatient management of conditions unrelated to the reason for admission. It consisted of 6 paired case scenarios, each with an inpatient management decision for a hypothetical hospitalist (Table 1). For each pair, 1 case dealt with management of the condition prompting admission (eg, starting aspirin in a patient admitted with acute nonST‐elevation myocardial infarction). The partner case involved the same intervention (eg, starting aspirin) but for a patient with a chronic condition (eg, history of prior myocardial infarction) and an alternate admitting diagnosis (eg, cellulitis). In an attempt to mitigate concerns regarding the flow of information and communication between providers, the survey asked respondents to assume that the hospitalist has access to the patient's outpatient electronic medical record, and that the hospitalist communicates the details of any hospitalizations at the time of discharge. For each case, the physician was asked to rate the appropriateness of enacting the intervention without discussing it with the PCP on a 5‐point scale from very inappropriate to very appropriate. When a physician answered that an intervention was inappropriate or very inappropriate, an additional question soliciting reasons for inappropriateness was included, with multiple predefined answer choices, as well as the option of a free‐text reply under the other designation.

Cases Descriptions
  • NOTE: Abbreviations: CHADS2, congestive heart failure, hypertension, age 75 years, diabetes mellitus, stroke/transient ischemic attack/thromboembolism; GERD, gastroesophageal reflux disease; LDL, low‐density lipoprotein; LVEF, left ventricular ejection fraction; NYHA, New York Heart Association; MI, myocardial infarction.

Starting aspirin (related to the reason for admission)A 60‐year‐old patient is admitted with a nonST‐elevation MI, medically managed without cardiac catheterization or percutaneous coronary intervention. Knowing that aspirin reduces mortality as part of secondary prevention in cardiovascular disease, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician?
Starting aspirin (unrelated to the reason for admission)A 60‐year‐old patient with a past medical history of a prior nonST‐elevation MI that was medically managed is admitted to the hospital for treatment of cellulitis. The hospitalist notes the patient is not on aspirin at home. Knowing that aspirin reduces mortality as part of secondary prevention in cardiovascular disease, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician?
Starting spironolactone (related to the reason for admission)A 70‐year‐old patient with a past medical history significant for NYHA class II congestive heart failure (LVEF of 20%) is admitted for acute on chronic, left‐sided systolic congestive heart failure. The patient has been maintained on furosemide, metoprolol, and lisinopril. Admission serum potassium and creatinine are both normal. Knowing that spironolactone decreases mortality in heart failure, how appropriate is it for the hospitalist to start this medication without discussing it with the primary care physician?
Starting spironolactone (unrelated to the reason for admission)A 70‐year‐old patient with a past history of NYHA class II congestive heart failure (LVEF of 20%) on furosemide, metoprolol, and lisinopril is admitted with pneumonia. Serum potassium and creatinine are both normal. Knowing that spironolactone decreases mortality in heart failure, how appropriate is it for the hospitalist to start this medication without discussing it with the primary care physician?
Starting warfarin (related to the reason for admission)A 75‐year‐old patient with a past medical history of hypertension and diabetes is admitted with new atrial fibrillation. Given the patient's CHADS2 score of 3, the hospitalist calculates that the patient has a significant risk of thromboembolic stroke. Knowing that warfarin will decrease the risk of thromboembolic stroke, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician (assume that an outpatient anticoagulation clinic is able to see the patient within 3 days of discharge)?
Starting warfarin (unrelated to the reason for admission)A 75‐year‐old patient with a past medical history of hypertension, diabetes, and atrial fibrillation is admitted with pneumonia. The patient is not anticoagulation therapy. Given the patient's CHADS2 score of 3, the hospitalist calculates that the patient has a significant risk of thromboembolic stroke. Knowing that warfarin will decrease the risk of thromboembolic stroke, how appropriate is it for the hospitalist to start the patient on this medication without discussing it with the primary care physician (assume that an outpatient anticoagulation clinic is able to see the patient within 3 days of discharge)?
Stopping proton pump inhibitor (related to the reason for admission)A 65‐year‐old patient with a past medical history of GERD maintained on a proton pump inhibitor is admitted for treatment of Clostridium difficile colitis. The patient denies having any GERD‐like symptoms for several years. Knowing that proton pump inhibitors can increase the risk of C difficile colitis and recurrence (as well as pneumonia and osteoporosis), how appropriate is it for the hospitalist to initiate a taper of this medication without discussing it with the primary care physician?
Stopping proton pump inhibitor (unrelated to the reason for admission)A 65‐year‐old patient with a past medical history of GERD maintained on a proton pump inhibitor is admitted for treatment of a urinary tract infection. The patient denies having any GERD‐like symptoms for several years. Knowing that proton pump inhibitors can increase the risk of C difficile colitis and recurrence (as well as pneumonia and osteoporosis), how appropriate is it for the hospitalist to initiate a taper of this medication without discussing it with the primary care physician?
Stopping statin or fibrate (related to the reason for admission)A 60‐year‐old patient with a history of hyperlipidemia is admitted with an elevated creatine kinase to 5000. The hospitalist notes that the patient is on both simvastatin and gemfibrozil. The patient's most recent serum LDL was at goal. Knowing that coadministration of simvastatin and gemfibrozil can increase the risk of rhabdomyolysis, how appropriate is it for the hospitalist to stop one of these medications without discussing it with the primary care physician?
Stopping statin or fibrate (unrelated to the reason for admission)A 60‐year‐old patient is admitted with an acute diarrheal illness. The hospitalist notes that the patient is on both simvastatin and gemfibrozil. The patient's most recent LDL was at goal. Knowing that coadministration of simvastatin and gemfibrozil can increase the risk of rhabdomyolysis, how appropriate is it for the hospitalist to stop one of these medications without discussing it with the primary care physician?
Changing statin (related to the reason for admission)A 65‐year‐old patient with a past medical history of hyperlipidemia on maximum‐dose simvastatin is admitted with a nonST‐elevation MI. The patient's cholesterol is noted to be above goal. Knowing that improving lipid management reduces mortality in cardiovascular disease, how appropriate is it for the hospitalist to replace simvastatin with atorvastatin without discussing it with the primary care physician?
Changing statin (unrelated to the reason for admission)A 65‐year‐old patient with a past medical history of a prior nonST‐elevation MI that was medically managed and hyperlipidemia on maximum‐dose simvastatin is admitted with pneumonia. Incidentally, the hospitalist notes that the patient's cholesterol has been above goal for the last 2 years. Knowing that improving lipid management reduces mortality in cardiovascular disease, how appropriate is it for the hospitalist to replace simvastatin with atorvastatin without discussing it with the primary care physician?

The third section aimed to directly assess physicians' opinions. It consisted of questions regarding the appropriateness of inpatient management of conditions related to and unrelated to a patient's reason for admission.

Prior to administration, we conducted focus groups of hospitalists and PCPs to help hypothesize current physician perceptions on inpatient management, assess physician understanding of survey cases and questions, and to evaluate survey length.

Survey Administration

Between October 23, 2012 and November 10, 2012, 3 emails containing a link to the online survey were sent to all hospitalist and hospital‐based PCPs at the 3 study institutions. The BIDMC Committee on Clinical Investigations, to whom authority was ceded by the remaining 2 study institutions, certified this research protocol as exempt.

Statistical Analysis

We hypothesized that respondents as a whole would be more likely to rate an intervention as appropriate or very appropriate if it was related to the reason for admission, compared to unrelated, and that there would be no difference between PCPs and hospitalists.

We used 2 and Fisher exact tests (where applicable) to compare categorical variables, and a nonparametric median test for continuous variables. We used the Fisher exact test to compare the percent of respondents rating each intervention as appropriate or very appropriate by relatedness or unrelatedness to the reason for admission, and by PCP vs hospitalist. To derive the relative risk (RR) of rating each intervention as appropriate or very appropriate by PCPs compared to hospitalists, adjusting for potential confounders including years out of residency and sex, we used multivariable generalized estimating equation models, each with a Poisson distribution error term, a log link, and an exchangeable working correlation structure to account for dependency of observations arising from clustering at either the hospital or participant level, depending on the comparison: for comparisons within a given case, we controlled for clustering at the hospital level; for comparisons of cases in aggregate, owing to multiple responses from each participant, we controlled for clustering at the individual level.

Assuming a 50% response rate from both PCPs and hospitalists, and that 50% of PCPs would rate a given intervention as appropriate, we calculated that we would have 90% power to detect a 50% increase in the proportion of hospitalists rating an intervention as appropriate as compared to PCPs, using an of .05.

RESULTS

Demographics

One hundred sixty‐two out of 295 providers (55%) responded to the survey (Table 2). The response rate did not differ between hospitalists (70 out of 128; 55%) and PCPs (92 out of 167; 55%). Female respondents made up 58.7% of the PCP and 50.0% of the hospitalist groups (P=0.34). On average, PCPs were older (P<0.001) with a greater median number of years since graduation from residency (P<0.001). A greater percentage of hospitalists spent more than three‐quarters of their time clinically (42.9% vs 19.6%, P=0.009).

Demographics
 Total, n=162 (100.0%)PCP, n=92 (6.8%)Hospitalist, n=70 (43.2%)P Valuea
  • NOTE: Abbreviations: AOR, attending of record; BIDMC, Beth Israel Deaconess Medical Center; BWH, Brigham and Women's Hospital; FTE, full‐time equivalent; IQR, interquartile range; MGH, Massachusetts General Hospital; PCP, primary care physician.

  • Comparing hospitalists to PCPs.

  • Excluding residency.

Hospital, n (%)    
BIDMC79 (48.8)48 (60.8)31 (39.2)0.115
BWH36 (22.2)15 (41.7)21 (58.3)
MGH47 (29.0)29 (61.7)18 (38.3)
Sex, n (%)    
Male73 (45.1)38 (41.3)35 (50.0)0.339
Female89 (54.9)54 (58.7)35 (50.0)
Age interval, y, n (%)    
253436 (22.2)9 (9.8)27 (38.6)<0.001
354467 (41.4)34 (37.0)33 (47.1)
455435 (21.6)29 (31.5)6 (8.6)
556419 (11.7)16 (17.4)3 (4.3)
65745 (3.1)4 (4.4)1 (1.4)
Years out of residency, median (IQR)10 (417)15 (74)5 (211)<0.001
Clinical FTE, n (%)    
0.2530 (18.6)22 (23.9)8 (11.4)0.009
0.260.5041 (25.3)25 (27.2)16 (22.9)
0.510.7543 (26.5)27 (29.4)16 (22.9)
>0.7548 (29.6)18 (19.6)30 (42.9)
Worked as PCP?b    
Yes  6 (8.6) 
No  64 (91.4) 
Worked as hospitalist?    
Yes 11 (12.0)  
No 81 (88.0)  
AOR for admitted patients    
Always 16 (17.4)  
Mostly 8 (8.7)  
Rarely 7 (7.6)  
Never 60 (65.2)  

Appropriateness of Inpatient Management Based on Admitting Diagnosis

For each of the 6 case pairings individually and in aggregate, respondents were significantly more likely to deem the intervention appropriate or very appropriate if it was related to the reason for admission, compared to those interventions unrelated to the reason for admission (in aggregate, 78.9% vs 38.8% respectively, P<0.001). For example, whereas 96.9% felt that the addition of aspirin in a patient admitted with acute myocardial infarction (MI) was appropriate, only 54.3% felt it appropriate to start aspirin in a patient with a prior history of MI admitted with cellulitis (P<0.001). Significant differences (all P values <0.001) were seen for all case pairs: starting spironolactone (68.1% when related to the reason for reason for admission vs 43.1% when unrelated to reason for admission); starting warfarin (62.3% vs 23.3%), stopping proton pump inhibitor (72.3% vs 42.8%), stopping statin or fibrate (90.6% vs 28.3%), and changing statin (83.0% vs 40.5%).

Appropriateness of Inpatient Management based on Primary Role

Table 3 compares the percent of PCPs and hospitalists rating each intervention as appropriate or very appropriate, by relatedness of the intervention to the reason for admission. In both unadjusted and adjusted comparisons for all cases in aggregate, PCPs were significantly more likely than hospitalists to rate the inpatient interventions as appropriate or very appropriate when the intervention was related to the reason for admission (83.4% of PCP responses vs 73.0% of hospitalist responses, P<0.001; RR: 1.2, 95% confidence interval [CI]: 1.11.3), unrelated to the reason for admission (44.7% vs 31.1%, P<0.001; RR: 1.5, 95% CI: 1.11.9), and overall (64.1% vs 52.1%, P<0.001; RR: 1.3, 95% CI: 1.11.4).

Percent of PCP and Hospitalist Respondents Who Answered Very Appropriate or Appropriate by Relatedness of the Intervention to the Reason for Admission and Overall
Relationship to Admission DiagnosisPCP, n (%)Hospitalist, n (%)P ValueAdjusted RR95% CI
  • NOTE: Abbreviations: CI, confidence interval; PCP, primary care physician; RR, relative risk.

  • PCP versus hospitalist, adjusted for years out of residency, sex, clinical full‐time equivalent, and clustering by individual.

  • PCP vs hospitalist, adjusted for years out of residency, sex, clinical full‐time equivalent, relatedness of the intervention to the condition prompting admission, and clustering by individual.

Related453 (83.4)303 (73.0)<0.0011.2a1.11.3
Unrelated242 (44.7)129 (31.1)<0.0011.5a1.11.9
Overall695 (64.1)432 (52.1)<0.0011.3b1.11.4

Reasons for Inappropriate Designation

Among those respondents rating an intervention as inappropriate or very inappropriate, the 3 most common reasons selected as explanation for perceived inappropriateness from our predefined answer choices were: This medication will necessitate follow‐up testing/monitoring, for which the PCP will be responsible (chosen by physicians in 49.4% of instances); I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision (35.7%); and Even if the hospitalist has all of the medical history and reviews it, the PCP should be involved in all decisions surrounding new medications (34.6%). The least common explanation chosen was I do not believe this is an appropriate pharmacologic intervention for this particular medical problem (6.5%). See Table 4 for a complete list of explanations, overall and stratified by PCP/hospitalist.

Percent of Respondents Who Selected Each Predefined Reason for Inappropriateness
Predefined Reason for InappropriatenessTotal, n=583 (%)PCP, n=318 (%)Hospitalist, n=265 (%)P Value
  • NOTE: Abbreviations: PCP, primary care physician.

This medication will necessitate follow‐up testing/monitoring, for which the PCP will be responsible.288 (49.4)151 (47.5)137 (51.7)0.32
I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision.208 (35.7)98 (30.8)110 (41.5)0.009
Even if the hospitalist has all of the medical history and reviews it, the PCP should be involved in all decisions surrounding new medications.201 (34.5)125 (39.3)76 (28.7)0.009
I am not confident that the hospitalist will adequately review the medical history necessary to make this decision.184 (31.6)130 (40.9)54 (20.4)<0.001
Even if the hospitalist has all of the medical history, I do not believe hospitalization is the right time to start this new medication106 (21.4)69 (21.7)56 (21.1)0.92
I am not confident that the hospitalist will appropriately discuss the risks and benefits of this new medication with the patient.106 (18.2)85 (26.7)21 (7.9)<0.001
The benefit of this medication will be too remote to justify starting it in the acute setting.66 (11.3)40 (12.6)26 (9.8)0.36
I do not believe this is an appropriate pharmacologic intervention for this particular medical problem.38 (6.5)27 (8.5)11 (4.2)0.04

There were significant differences in the proportion of PCPs and hospitalists choosing several of the prespecified reasons for inappropriateness. Although hospitalists were more likely than PCPs to select I am not confident that the hospitalist will have access to all of the medical history necessary to make this decision (chosen by 41.5% of hospitalists vs 30.8% of PCPs, P=0.009), PCPs were more likely than hospitalists to select, I am not confident that the hospitalist will adequately review the medical history necessary to make this decision (chosen by 40.9% of PCPs vs 20.4% of hospitalists, P<0.001) and I am not confident that the hospitalist will appropriately discuss the risks and benefits of this new medication with the patient (26.7% of PCPs vs 9.8% of hospitalists, P<0.001).

Opinions on Current Management of Conditions Related and Unrelated to Admission

A minority of PCPs and hospitalists agreed or strongly agreed that hospitalists should play a larger role in the management of medical conditions unrelated to the reason for admission (28.1% of PCPs vs 34.8% of hospitalists; P=0.39).

DISCUSSION

In this survey‐based study of PCPs and hospitalists across 3 Boston‐area academic medical centers, we found that: (1) physicians were more likely to see inpatient interventions as appropriate when those interventions dealt with the reason for admission as compared to interventions unrelated to the reason for admission; and (2) PCPs were more likely than hospitalists to feel that inpatient interventions were appropriate, even when they targeted chronic conditions unrelated to the reason for admission. To our knowledge, this study represents the first investigation into the attitudes of PCPs and hospitalists regarding the inpatient management of conditions unrelated to the reason for admission.

That surveyed physicians, regardless of role, were less likely to report an intervention unrelated to the reason for hospitalization as appropriateeven those with likely mortality benefitsuggests that opportunities to affect meaningful change may be missed in a healthcare system that adheres to strict inpatient and outpatient roles. For several of the cases, a change in therapy could lead to benefit soon after implementation. For example, aldosterone antagonists reduce mortality as early as 1 month after initiation in select patients.[8] If a major goal of inpatient care is to reduce 30‐day mortality, it could be argued that hospitalists should more actively adjust congestive heart failure therapy in appropriate inpatients, even when this is not their admitting diagnosis.

For some conditions, CMS is already tracking hospital performance. Since 2003, hospitals have been required to document whether a patient with congestive heart failure (either acute or chronic and regardless of the relationship to admission) was prescribed an angiotensin‐converting enzyme (ACE) inhibitor or angiotensin receptor blocker (ARB) at the time of discharge.[7] CMS has determined that the proven benefits of ACE inhibitors and ARBs confer hospital accountability for their inclusion in appropriate patients, independent of the acuity of heart failure. There are many potential therapeutic maneuvers on which health systems (and their physicians) may be graded, and accepting the view that a hospitalization provides a window of opportunity for medical optimization may allow for more fruitful interventions and more patient‐centered care.

Despite the potential benefits of addressing chronic medical issues during hospitalization, there are important limitations on what can and/or should be done in the hospital setting. Hospitalizations are a time of fluctuating clinical status, which continues beyond discharge and is often accompanied by several medication changes.[9] In our study, more than 20% of those who believed that a medication intervention was inappropriate selected I do not believe hospitalization is the right time to start this new medication as one of their explanations. Although some medication interventions have been shown in randomized controlled trials to reduce short‐term mortality, the ability to generalize these findings to the average hospitalized patient with multiple comorbidities, concurrent medication changes, and rapidly fluctuating clinical status is limited. Furthermore, there are interventions most would agree should not be dealt with in the hospital (eg, screening colonoscopy) and encounters that may be too short to allow for change (eg, 24‐hour observation). These issues notwithstanding, the average 4‐day hospitalization likely provides an opportunity for monitored change that may currently be underutilized.

Our study suggests several additional explanations for physicians' current practice and opinions. Only 6.5% of respondents who answered that an intervention was inappropriate indicated as a justification that I do not believe this is an appropriate pharmacologic intervention for this particular medical problem. This suggests that the hesitancy has little to do with a lack of benefit but instead relates to systems issues (eg, access to all pertinent records and concerns regarding follow‐up testing) and perceived limitations to what a hospitalist should and should not do without actively involving the PCP. There are likely additional concerns that the medical record and/or patient histories do not fully outline the rationale for exclusion or inclusion of particular medications. Advances in information technology that enhance information exchange and enable streamlined communication may help to address these perceived barriers. However, an additional barrier may be trust, as PCPs appear more concerned that hospitalists will not review all the pertinent records or discuss risks and benefits before enacting important medication changes. Increased attempts at communication between hospitalists and outpatient providers may help to build trust and alleviate concerns regarding the loss of information that often occurs both on admission and at discharge.

We also noted that PCPs were more likely than hospitalists to feel that inpatient interventions were appropriate, even when targeting chronic conditions unrelated to the reason for admission. It may be that PCPs, with an increasing number of problems to address per outpatient visit,[10, 11] are more open to hospitalists managing any medical problems during their patients' admissions. At the same time, with increased acuity[12, 13, 14] and shortened length of stays,[15, 16] hospitalists have only a finite amount of time to ensure acute issues are managed, leaving potentially modifiable chronic conditions to the outpatient setting. These differences aside, a minority of both PCPs and hospitalists in our study were ready to embrace the idea of hospitalists playing a larger role in the management of conditions unrelated to the reason for hospitalization.

Even though our study benefits from its multisite design, there are a number of limitations. First, although we crafted our survey with input from general medicine focus groups, our survey instrument has not been validated. In addition, the cases are necessarily contrived and do not take into account the complexities of inpatient medicine. Furthermore, though our goal was to create paired cases that isolate a management decision as being simply based on whether it was related or unrelated to the reason for admission, it is possible that other factors, not captured by our survey, influenced the responses. For example, the benefits of aspirin as part of secondary prevention are not equal to the benefits in an acute MI.[17]

In an attempt to isolate the hospitalists' role in these management decisions, respondents were instructed to assume that the decisions were being made without discussing it with the primary care physician, but that the hospitalist would communicate the details of any hospitalization at the time of discharge. They were also instructed to assume that the hospitalist has access to the patient's outpatient electronic medical record. These assumptions were made to address concerns regarding the flow of information and communication, and to simulate the ideal system from a communication and information accessibility standpoint. Had these assumptions not been placed, the responses may have differed. It is likely that PCPs and hospitalists practicing in systems without shared, accessible inpatient/outpatient medical records would be even more reluctant to enact medication changes unrelated to the reason for admission.

Along the same lines, our physician cohort consisted of several metropolitan academic physician groups, in which hospitalists have had a presence for almost 20 years. As a result, our findings may not be generalizable to other academic hospitals, community‐based hospitalist programs, or nonhospital‐based PCP practices. Finally, we do not know whether survey nonresponders differed from responders in ways that could have meaningfully affected our results.

In conclusion, our findings suggest that both PCPs and hospitalists see the management of conditions unrelated to the reason for admission as less appropriate than the management of conditions related to the reason for admission. Our findings also suggest that PCPs may be more open to this practice when compared to hospitalists. Failure to capitalize on opportunities for meaningful medical interventions, independent of patient location, suggests a possible lack of patient centeredness in the current partnership between PCPs and hospitalists. Further studies should examine existing barriers and investigate interventions designed to address those barriers, in an effort to improve both quality of care and the degree of patient‐centeredness in our current healthcare system.

Disclosures: Dr. Herzig is supported by a grant from the National Institute on Aging (K23 AG042459). Dr. Herzig had full access to all of the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. Author contributions: study concept and design, Breu, Allen‐Dicker, Mueller, Herzig; acquisition of data, Breu, Allen‐Dicker, Mueller, Palamara, Herzig; analysis and interpretation of data, Breu, Allen‐Dicker, Hinami, Herzig; drafting of the manuscript, Breu; critical revision of the manuscript for important intellectual content, Breu, Allen‐Dicker, Mueller, Palamara, Hinami, Herzig; statistical analysis, Allen‐Dicker, Hinami, Herzig; study supervision, Breu, Herzig. This study was presented as a poster at the Society of Hospital Medicine National Meeting, Washington, DC, May 17, 2013.

References
  1. Kuo Y‐F, Sharma G, Freeman JL, Goodwin JS. Growth in the care of older patients by hospitalists in the United States. N Engl J Med. 2009;360(11):11021112.
  2. Wachter RM, Goldman L. The emerging role of “hospitalists” in the American health care system. N Engl J Med. 1996;335(7):514517.
  3. Wachter RM. An introduction to the hospitalist model. Ann Intern Med. 1999;130(4 pt 2):338342.
  4. Axon RN, Williams MV. Hospital readmission as an accountability measure. JAMA. 2011;305(5):504505.
  5. McClellan M, McKethan AN, Lewis JL, Roski J, Fisher ES. A national strategy to put accountable care into practice. Health Aff (Millwood). 2010;29(5):982990.
  6. Landon BE. Keeping score under a global payment system. N Engl J Med. 2012;366(5):393395.
  7. Reporting Hospital Quality Data for Annual Payment Update. Available at: http://www.cms.gov/Medicare/Quality‐Initiatives‐Patient‐Assessment‐Instruments/HospitalQualityInits/Downloads/HospitalRHQDAPU200808. Accessed December 18, 2013.
  8. Zannad F, McMurray JJV, Krum H, et al. Eplerenone in patients with systolic heart failure and mild symptoms. N Engl J Med. 2011;364(1):1121.
  9. Viktil KKK, Blix HSH, Eek AKA, Davies MNM, Moger TAT, Reikvam AA. How are drug regimen changes during hospitalisation handled after discharge: a cohort study. BMJ Open. 2012;2(6):e001461.
  10. Chen LM, Farwell WR, Jha AK. Primary care visit duration and quality: does good care take longer? Arch Intern Med. 2009;169(20):18661872.
  11. Abbo ED, Zhang Q, Zelder M, Huang ES. The increasing number of clinical items addressed during the time of adult primary care visits. J Gen Intern Med. 2008;23(12):20582065.
  12. Freid VM, Bernstein AB, Bush MA. Multiple chronic conditions among adults aged 45 and over: trends over the past 10 years. NCHS Data Brief. 2012;(100):18.
  13. Schneider KM, O'Donnell BE, Dean D. Prevalence of multiple chronic conditions in the United States' Medicare population. Health Qual Life Outcomes. 2009;7(1):82.
  14. Vogeli C, Shields AE, Lee TA, et al. Multiple chronic conditions: prevalence, health consequences, and implications for quality, care management, and costs. J Gen Intern Med. 2007;22(suppl 3):391395.
  15. Kaboli PJ, Go JT, Hockenberry J, et al. Associations between reduced hospital length of stay and 30‐day readmission rate and mortality: 14‐year experience in 129 Veterans Affairs hospitals. Ann Intern Med. 2012;157(12):837845.
  16. Bueno H, Ross JS, Wang Y, et al. Trends in length of stay and short‐term outcomes among Medicare patients hospitalized for heart failure, 1993–2006. JAMA. 2010;303(21):21412147.
  17. Antithrombotic Trialists' Collaboration. Collaborative meta‐analysis of randomised trials of antiplatelet therapy for prevention of death, myocardial infarction, and stroke in high risk patients. BMJ. 2002;324(7329):7186.
References
  1. Kuo Y‐F, Sharma G, Freeman JL, Goodwin JS. Growth in the care of older patients by hospitalists in the United States. N Engl J Med. 2009;360(11):11021112.
  2. Wachter RM, Goldman L. The emerging role of “hospitalists” in the American health care system. N Engl J Med. 1996;335(7):514517.
  3. Wachter RM. An introduction to the hospitalist model. Ann Intern Med. 1999;130(4 pt 2):338342.
  4. Axon RN, Williams MV. Hospital readmission as an accountability measure. JAMA. 2011;305(5):504505.
  5. McClellan M, McKethan AN, Lewis JL, Roski J, Fisher ES. A national strategy to put accountable care into practice. Health Aff (Millwood). 2010;29(5):982990.
  6. Landon BE. Keeping score under a global payment system. N Engl J Med. 2012;366(5):393395.
  7. Reporting Hospital Quality Data for Annual Payment Update. Available at: http://www.cms.gov/Medicare/Quality‐Initiatives‐Patient‐Assessment‐Instruments/HospitalQualityInits/Downloads/HospitalRHQDAPU200808. Accessed December 18, 2013.
  8. Zannad F, McMurray JJV, Krum H, et al. Eplerenone in patients with systolic heart failure and mild symptoms. N Engl J Med. 2011;364(1):1121.
  9. Viktil KKK, Blix HSH, Eek AKA, Davies MNM, Moger TAT, Reikvam AA. How are drug regimen changes during hospitalisation handled after discharge: a cohort study. BMJ Open. 2012;2(6):e001461.
  10. Chen LM, Farwell WR, Jha AK. Primary care visit duration and quality: does good care take longer? Arch Intern Med. 2009;169(20):18661872.
  11. Abbo ED, Zhang Q, Zelder M, Huang ES. The increasing number of clinical items addressed during the time of adult primary care visits. J Gen Intern Med. 2008;23(12):20582065.
  12. Freid VM, Bernstein AB, Bush MA. Multiple chronic conditions among adults aged 45 and over: trends over the past 10 years. NCHS Data Brief. 2012;(100):18.
  13. Schneider KM, O'Donnell BE, Dean D. Prevalence of multiple chronic conditions in the United States' Medicare population. Health Qual Life Outcomes. 2009;7(1):82.
  14. Vogeli C, Shields AE, Lee TA, et al. Multiple chronic conditions: prevalence, health consequences, and implications for quality, care management, and costs. J Gen Intern Med. 2007;22(suppl 3):391395.
  15. Kaboli PJ, Go JT, Hockenberry J, et al. Associations between reduced hospital length of stay and 30‐day readmission rate and mortality: 14‐year experience in 129 Veterans Affairs hospitals. Ann Intern Med. 2012;157(12):837845.
  16. Bueno H, Ross JS, Wang Y, et al. Trends in length of stay and short‐term outcomes among Medicare patients hospitalized for heart failure, 1993–2006. JAMA. 2010;303(21):21412147.
  17. Antithrombotic Trialists' Collaboration. Collaborative meta‐analysis of randomised trials of antiplatelet therapy for prevention of death, myocardial infarction, and stroke in high risk patients. BMJ. 2002;324(7329):7186.
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Journal of Hospital Medicine - 9(5)
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Journal of Hospital Medicine - 9(5)
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Hospitalist and primary care physician perspectives on medication management of chronic conditions for hospitalized patients
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Address for correspondence and reprint requests: Anthony C. Breu, MD, VA Boston Healthcare System, Medical Service (111), 1400 VFW Parkway, West Roxbury, MA 02132; Telephone: 857‐203‐5111; Fax: 857‐203‐5549; E‐mail: anthony.breu@va.gov
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