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Interhospital transfers (IHTs) to academic medical centers (AMCs) or their affiliated hospitals may benefit patients who require unique specialty and procedural services. However, IHTs also introduce a potentially risky transition of care for patients suffering from complex or unstable medical problems.[1] Components of this risk include the dangers associated with transportation and the disrupted continuity of care that may lead to delays or errors in care.[2, 3] Furthermore, referring and accepting providers may face barriers to optimal handoffs including a lack of shared communication standards and difficulty accessing external medical records.[3, 4, 5] Although some authors have recommended the creation of formal guidelines for interhospital transfer processes for all patients to mitigate the risks of transfer, the available guidelines governing the IHT triage and communication process are limited to critically ill patients.[6]
A recent study of a diverse patient and hospital dataset demonstrated that interhospital transfer patients have a higher risk of mortality, increased length of stay (LOS), and increased risk of adverse events as compared with non‐transfer patients.[7] However, it is unknown if these findings persist in the population of patients transferred specifically to AMCs or their affiliated hospitals (the combination is hereafter referred to as academic health systems [AHSs]). AMCs provide a disproportionate share of IHT care for complex patients and have a vested interest in improving the outcomes of these transitions.[8] Prior single‐center studies of acute care adult medical patients accepted to AMCs have shown that IHT is associated with a longer LOS, increased in‐hospital mortality, and higher resource use.[9, 10] However, it is difficult to generalize from single‐center studies due to the variation in referral practices, geography, and network characteristics. Additionally, AMC referral systems, patient mix, and utilization of hospitalists have likely changed substantially in the nearly 2 decades since those reports were published.
Hospitalists and general internists often manage the transfer acceptance processes for internal medicine services at receiving hospitals, helping to triage and coordinate care for IHT patients. As a result, it is important for hospitalists to understand the characteristics and outcomes of the IHT population. In addition to informing the decision making around transfer for a given patient, such an understanding is the foundation for helping providers and institutions begin to systematically identify and mitigate peritransfer risks.
We conducted this large multicenter study to describe the characteristics and outcomes of a current, nationally representative IHT patient population discharged by hospitalists and general internists at AHSs. To identify unique features of the IHT population, we compared patients transferred from another hospital to an AHS to those admitted to the AHS directly from the AHS's emergency department (ED). Based on our anecdotal experiences and the prior single‐center study findings in adult medical populations,[9, 10] we hypothesized that the IHT population would be sicker, stay in the hospital and intensive care unit (ICU) longer, and have higher costs and in‐hospital mortality than ED patients. Although there may be fundamental differences between the 2 groups related to disease and patient condition, we hypothesized that outcome differences would persist even after adjusting for patient factors such as demographics, disease‐specific risk of mortality, and ICU utilization.
PATIENTS AND METHODS
We conducted a retrospective cohort study using data from the University HealthSystem Consortium (UHC) Clinical Database and Resource Manager (CDB/RM). UHC is an alliance of 120 academic medical centers and 300 of their affiliated hospitals for the purposes of collaboration on performance improvement. Each year, a subset of participating hospitals submits data on all of their inpatient discharges to the CDB/RM, which totals approximately 5 million records. The CDB/RM includes information from billing forms including demographics, diagnoses, and procedures as captured by International Classification of Diseases, Ninth Revision (ICD‐9) codes, discharge disposition, and line item charge detail for the type of bed (eg, floor, ICU). Most hospitals also provide detailed charge information including pharmacy, imaging, blood products, lab tests, and supplies. Some hospitals do not provide any charge data. The Beth Israel Deaconess Medical Center and University of Washington institutional review boards reviewed and approved the conduct of this study.
We included all inpatients discharged by hospitalists or general internal medicine physicians from UHC hospitals between April 1, 2011 and March 31, 2012. We excluded minors, pregnant patients, and prisoners. One hundred fifty‐eight adult academic medical centers and affiliated hospitals submitted data throughout this time period. Our primary independent variable, IHT status, was defined by patients whose admission source was another acute care institution. ED admissions were defined as patients admitted from the AHS ED whose source of origination was not another hospital or ambulatory surgery site.
Admission Characteristics
Admission characteristics of interest included age, gender, insurance status, the most common diagnoses in each cohort based on Medicare Severity Diagnosis‐Related Group (MS‐DRG), the most common Agency for Healthcare Research and Quality (AHRQ) comorbitidies,[11] the most common procedures, and the admission 3M All‐Patient Refined Diagnosis‐Related Group (APR‐DRG) risk of mortality (ROM) scores. 3M APR‐DRG ROM scores are proprietary categorical measures specific to the base APR‐DRG to which a patient is assigned, which are calculated using data available at the time of admission, including comorbid condition diagnosis codes, age, procedure codes, and principal diagnosis codes. A patient can fall into 1 of 4 categories with this score: minor, moderate, major, or extreme.[12]
Outcomes
Our primary outcome of interest was in‐hospital mortality. Secondary outcomes included LOS, the cost of care, ICU utilization, and discharge destination. The cost of care is a standardized estimate of the direct costs based on an adjustment of the charges submitted by CDB/RM participants. If an IHT is triaged through a receiving hospital's ED, the cost of care reflects those charges as well as the inpatient charges.
Statistical Analysis
We used descriptive statistics to characterize the IHT and ED patient populations. For bivariate comparisons of continuous variables, 2‐sample t tests with unequal variance were used. For categorical variables, 2 analysis was performed. We assessed the impact of IHT status on in‐hospital mortality using logistic regression to estimate unadjusted and adjusted relative risks, 95% confidence intervals (CIs), and P values. We included age, gender, insurance status, race, timing of ICU utilization, and 3M APR‐DRG ROM scores as independent variables. Prior studies have used this type of risk‐adjustment methodology with 3M APR‐DRG ROM scores,[13, 14, 15] including with interhospital transfer patients.[16] For all comparisons, a P value of <0.05 was considered statistically significant. Our sample size was determined by the data available for the 1‐year period.
Subgroup Analyses
We performed a stratified analysis based on the timing of ICU transfer to allow for additional comparisons of mortality within more homogeneous patient groups, and to control for the possibility that delays in ICU transfer could explain the association between IHT and in‐hospital mortality. We determined whether and when a patient spent time in the ICU based on daily accommodation charges. If a patient was charged for an ICU bed on the day of admission, we coded them as a direct ICU admission, and if the first ICU bed charge was on a subsequent day, they were coded as a delayed ICU admission. Approximately 20% of patients did not have the data necessary to determine the timing of ICU utilization, because the hospitals where they received care did not submit detailed charge data to the UHC.
Data analysis was performed by the UHC. Analysis was performed using Stata version 10 (StataCorp, College Station, TX). For all comparisons, a P value of <0.05 was considered significant.
RESULTS
Patient Characteristics
We identified 885,392 patients who met study criteria: 75,524 patients admitted as an IHT and 809,868 patients admitted from the ED. The proportion of each hospital's admissions that were IHTs that met our study criteria varied widely (median 9%, 25th percentile 3%, 75th percentile 14%). The average age and gender of the IHT and ED populations were similar and reflective of a nationally representative adult inpatient sample (Table 1). Racial compositions of the populations were notable for a higher portion of black patients in the ED admission group than the IHT group (25.4% vs 13.2%, P < 0.001). A slightly higher portion of the IHT population was covered by commercial insurance compared with the ED admissions (22.7% vs 19.1%, P < 0.001).
Demographic/Clinical Variables | ED | IHT | ||||
---|---|---|---|---|---|---|
1st | 2nd | 3rd | 4th | Rank | ||
| ||||||
No. of patients | 809,868 | 91.5 | 75,524 | 8.5 | ||
Age, y | 62.2 19.1 | 60.2 18.2 | ||||
Male | 381,563 | 47.1 | 38,850 | 51.4 | ||
Female | 428,303 | 52.9 | 36,672 | 48.6 | ||
Race | ||||||
White | 492,894 | 60.9 | 54,780 | 72.5 | ||
Black | 205,309 | 25.4 | 9,968 | 13.2 | ||
Other | 66,709 | 8.1 | 7,777 | 10.3 | ||
Hispanic | 44,956 | 5.6 | 2,999 | 4.0 | ||
Primary payer | ||||||
Commercial | 154,826 | 19.1 | 17,130 | 22.7 | ||
Medicaid | 193,585 | 23.9 | 15,924 | 21.1 | ||
Medicare | 445,227 | 55.0 | 39,301 | 52.0 | ||
Other | 16,230 | 2.0 | 3,169 | 4.2 | ||
Most common MS‐DRGs (top 5 for each group) | ||||||
Esophagitis, gastroenteritis, and miscellaneous digest disorders without MCC | 34,116 | 4.2 | 1st | 1,517 | 2.1 | 2nd |
Septicemia or severe sepsis without MV 96+ hours with MCC | 25,710 | 3.2 | 2nd | 2,625 | 3.7 | 1st |
Cellulitis without MCC | 21,686 | 2.7 | 3rd | 871 | 1.2 | 8th |
Kidney and urinary tract infections without MCC | 19,937 | 2.5 | 4th | 631 | 0.9 | 21st |
Chest pain | 18,056 | 2.2 | 5th | 495 | 0.7 | 34th |
Renal failure with CC | 15,478 | 1.9 | 9th | 1,018 | 1.4 | 5th |
GI hemorrhage with CC | 12,855 | 1.6 | 12th | 1,234 | 1.7 | 3rd |
Respiratory system diagnosis w ventilator support | 4,773 | 0.6 | 47th | 1,118 | 1.6 | 4th |
AHRQ comorbidities (top 5 for each group) | ||||||
Hypertension | 468,026 | 17.8 | 1st | 39,340 | 16.4 | 1st |
Fluid and electrolyte disorders | 251,339 | 9.5 | 2nd | 19,825 | 8.3 | 2nd |
Deficiency anemia | 208,722 | 7.9 | 3rd | 19,663 | 8.2 | 3rd |
Diabetes without CCs | 190,140 | 7.2 | 4th | 17,131 | 7.1 | 4th |
Chronic pulmonary disease | 178,164 | 6.8 | 5th | 16,319 | 6.8 | 5th |
Most common procedures (top 5 for each group) | ||||||
Packed cell transfusion | 72,590 | 7.0 | 1st | 9,756 | 5.0 | 2nd |
(Central) venous catheter insertion | 68,687 | 6.7 | 2nd | 13,755 | 7.0 | 1st |
Hemodialysis | 41,557 | 4.0 | 3rd | 5,351 | 2.7 | 4th |
Heart ultrasound (echocardiogram) | 37,762 | 3.7 | 4th | 5,441 | 2.8 | 3rd |
Insert endotracheal tube | 25,360 | 2.5 | 5th | 4,705 | 2.4 | 6th |
Continuous invasive mechanical ventilation | 19,221 | 1.9 | 9th | 5,280 | 2.7 | 5th |
3M APR‐DRG admission ROM score | ||||||
Minor | 271,702 | 33.6 | 18,620 | 26.1 | ||
Moderate | 286,427 | 35.4 | 21,775 | 30.5 | ||
Major | 193,652 | 23.9 | 20,531 | 28.7 | ||
Extreme | 58,081 | 7.2 | 10,527 | 14.7 |
Primary discharge diagnoses (MS‐DRGs) varied widely, with no single diagnosis accounting for more than 4.2% of admissions in either group. The most common primary diagnoses among IHTs included severe sepsis (3.7%), esophagitis and gastroenteritis (2.1%), and gastrointestinal bleeding (1.7%). The top 5 most common AHRQ comorbidities were the same between the IHT and ED populations. A higher proportion of IHTs had at least 1 procedure performed during their hospitalization (68.5% vs 49.8%, P < 0.001). Note that ICD‐9 procedure codes include interventions such as blood transfusions and dialysis (Table 1), which may not be considered procedures in common medical parlance.
As compared with those admitted from the ED, IHTs had a higher proportion of patients categorized with major or extreme admission risk of mortality score (major + extreme, ED 31.1% vs IHT 43.5%, P < 0.001).
Overall Outcomes
IHT patients experienced a 60% longer average LOS, and a higher proportion spent time in the ICU than patients admitted through the ED (Table 2). On average, care for IHT patients cost more per day than for ED patients (Table 2). A lower proportion of IHTs were discharged home (68.6% vs 77.4% of ED patients), and a higher proportion died in the hospital (4.1% vs 1.8%) (P < 0.001 for both). Of the ED or IHT patients who died during their admission, there was no significant difference between the proportion who died within 48 hours of admission (26.4% vs 25.6%, P = 0.3693). After adjusting for age, gender, insurance status, race, ICU utilization and 3M APR‐DRG admission ROM scores, IHT was independently associated with the risk of in‐hospital death (odds ratio [OR]: 1.36, 95% CI: 1.291.43) (Table 3). The C statistic for the in‐hospital mortality model was 0.88.
ED, n = 809,868 | IHT, n = 75,524 | |
---|---|---|
| ||
LOS, mean SD | 5.0 6.9 | 8.0 13.4 |
ICU days, mean SD | 0.6 2.4 | 1.7 5.2 |
Patients who spent some time in the ICU | 14.3% | 29.8% |
% LOS in the ICU (ICU days LOS) | 11.0% | 21.6% |
Average total cost SD | $10,731 $16,593 | $19,818 $34,665 |
Average cost per day (total cost LOS) | $2,139 | $2,492 |
Discharged home | 77.4% | 68.6% |
Died as inpatient | 14,869 (1.8%) | 3,051 (4.0%) |
Died within 48 hours of admission (% total deaths) | 3,918 (26.4%) | 780 (25.6%) |
Variable | Unadjusted OR (95% CI) | Adjusted OR (95% CI) |
---|---|---|
| ||
Age, y | 1.00 (1.001.00) | 1.03 (1.031.03) |
Gender | ||
Female | Ref. | Ref. |
Male | 1.13 (1.091.70) | 1.05 (1.011.09) |
Medicare status | ||
No | Ref. | Ref. |
Yes | 2.14 (2.062.22) | 1.39 (1.331.47) |
Race | ||
Nonblack | Ref. | Ref. |
Black | 0.57 (0.550.60) | 0.77 (0.730.81) |
ICU utilization | ||
No ICU admission | Ref. | Ref. |
Direct admission to the ICU | 5.56 (5.295.84) | 2.25 (2.132.38) |
Delayed ICU admission | 5.48 (5.275.69) | 2.46 (2.362.57) |
3M APR‐DRG admission ROM score | ||
Minor | Ref. | Ref. |
Moderate | 8.71 (7.5510.05) | 6.28 (5.437.25) |
Major | 43.97 (38.3150.47) | 25.84 (22.4729.71) |
Extreme | 238.65 (207.69273.80) | 107.17 (93.07123.40) |
IHT | ||
No | Ref. | Ref. |
Yes | 2.36 (2.262.48) | 1.36 (1.29 1.43) |
Subgroup Analyses
Table 4 demonstrates the unadjusted and adjusted results from our analysis stratified by timing of ICU utilization. IHT remained independently associated with in‐hospital mortality regardless of timing of ICU utilization.
Subgroup | In‐hospital Mortality, n (%) | Unadjusted OR [95% CI] | Adjusted OR [95% CI] |
---|---|---|---|
| |||
No ICU admission, n = 552,171 | |||
ED, n = 519,421 | 4,913 (0.95%) | Ref. | Ref. |
IHT, n = 32,750 | 590 (1.80%) | 1.92 [1.762.09] | 1.68 [1.531.84] |
Direct admission to the ICU, n = 44,537 | |||
ED, n = 35,614 | 1,733 (4.87%) | Ref. | Ref. |
IHT, n = 8,923 | 628 (7.04%) | 1.48 [1.351.63] | 1.24 [1.121.37] |
Delayed ICU admission, n = 110,540 | |||
ED, n = 95,573 | 4,706 (4.92%) | Ref. | Ref. |
IHT, n = 14,967 | 1,068 (7.14%) | 1.48 [1.391.59] | 1.25 [1.171.35] |
DISCUSSION
Our study of IHT patients ultimately discharged by hospitalists and general internists at US academic referral centers found significantly increased average LOS, costs, and in‐hospital mortality compared with patients admitted from the ED. The increased risk of mortality persisted after adjustment for patient characteristics and variables representing endogenous risk of mortality, and in more homogeneous subgroups after stratification by presence and timing of ICU utilization. These data confirm findings from single‐center studies and suggest that observations about the difference between IHT and ED populations may be generalizable across US academic hospitals.
Our work builds on 2 single‐center studies that examined mixed medical and surgical academic IHT populations from the late 1980s and early 1990s,[9, 10] and 1 studying surgical ICU patients in 2013.[17] These studies demonstrated longer average LOS, higher costs, and higher mortality rates (in both adjusted and unadjusted analyses). Our work confirmed these findings utilizing a more current, multicenter large dataset of IHT patients ultimately discharged by hospitalists and general internists. Our work is unique from a larger, more recent study[7] in that it focuses on patients transferred to academic health systems, and therefore has particular relevance to those settings. In addition, we divided patients into subpopulations based on the timing of ICU utilization, and found that in each of these populations, IHT remained independently associated with in‐hospital mortality.
Our analysis does not explain why the outcomes of IHTs are worse, but plausible contributing factors include that (1) patients chosen for IHT are at higher risk of death in ways uncaptured by established mortality risk scores, (2) referring, transferring, or accepting providers and institutions have provided inadequate care, (3) the transfer process itself involves harm, (4) socioeconomic bias in selection for IHT,[18] or (5) some combination of the above. Regardless of the causes of the worse outcomes observed in these outside‐hospital transfers, as these patients are colloquially known at accepting hospitals, they present challenges to everyone involved. Referring providers may feel a sense of urgency as these patients' needs exceed their management capabilities. The process is often time consuming and burdensome for referring and accepting providers because of poorly developed systems.[19] The transfer often takes patients further from their home and may make it more difficult for family to participate in their care. The transfer may delay care if the accepting institution cannot immediately accept the patient or if the time in transport is prolonged, which could result in decompensation at a critical juncture. For providers inheriting such patients, the stress of caring for these patients is compounded by the difficulty obtaining records about the prior hospitalization.[20] This frustrating experience is often translated into unfounded judgment of the institution that referred the patient and the care provided there.[21] It is important for hospitalists making decisions throughout the transfer process and for hospital leaders who determine staffing levels, measure the quality of care, manage hospital networks, or write hospital policy to appreciate that the transfer process itself may contribute to the challenges and poor outcomes we observe. Furthermore, regardless of the cause for the increased mortality that we observed, our findings imply that IHT patients require careful evaluation, management, and treatment.
Many accepting institutions have transfer centers that facilitate these transitions, utilizing protocols and templates to standardize the process.[22, 23] Future research should focus on the characteristics of these centers to learn which practices are most efficacious. Interventions to mitigate the known challenges of transfer (including patient selection and triage, handoff communication, and information sharing) could be tested by randomized studies at referring and accepting institutions. There may be a role for health information exchange or the development of enhanced pretransfer evaluation processes using telemedicine models; there is evidence that information sharing may reduce redundant imaging.[24] Perhaps targeted review of IHTs admitted to a non‐ICU portion of the hospital and subsequently transferred to the ICU could identify opportunities to improve triaging protocols and thus avert some of the bad outcomes observed in this subpopulation. A related future direction could be to create protected forumsusing the patient safety organization framework[25]to facilitate the discussion of interhospital transfer outcomes among the referring, transporting, and receiving parties. Lastly, future work should investigate the reasons for the different proportions of black patients in the ED versus IHT cohorts. Our finding that black race was associated with lower risk of mortality has been previously reported but may also benefit from more investigation.[26]
There are several limitations of our work. First, despite extensive adjustment for patient characteristics, due to the observational nature of our study it is still possible that IHTs differ from ED admissions in ways that were unaccounted for in our analysis, and which could be associated with increased mortality independent of the transfer process itself. We are unable to characterize features of the transfer process, such as the reason for transfer, differences in transfer processes among hospitals, or the distance and mode of travel, which may influence outcomes.[27] Because we used administrative data, variations in coding could incorrectly estimate the complexity or severity of illness on admission, which is a previously described risk.[28] In addition, although our dataset was very large, it was limited by incomplete charge data, which limited our ability to measure ICU utilization in our full cohort. The hospitals missing ICU charge data are of variable sizes and are distributed around the country, limiting the chance of systematic bias. Finally, in some settings, hospitalists may serve as the discharging physician for patients admitted to other services such as the ICU, introducing heterogeneity and bias to the sample. We attempted to mitigate such bias through our subgroup analysis, which allowed for comparisons within more homogeneous patient groupings.
In conclusion, our large multicenter study of academic health systems confirms the findings of prior single‐center academic studies and a large general population study that interhospital transfer patients have an increased average LOS, costs, and adjusted in‐hospital mortality than patients admitted from the ED. This difference in mortality persisted even after controlling for several other predictors of mortality. Our findings emphasize the need for future studies designed to clarify the reason for the increased risk and identify targets for interventions to improve outcomes for the interhospital transfer population.
Acknowledgements
The authors gratefully acknowledge Zachary Goldberger and Tom Gallagher for their critical reviews of this article.
Disclosures
Dr. Herzig was funded by grant number K23AG042459 from the National Institute on Aging. The funding organization had no involvement in any aspect of the study, including design and conduct of the study; collection, management, analysis, and interpretation of the data; and preparation, review, or approval of the manuscript. The authors report no conflicts of interest.
- The incomplete infrastructure for interhospital patient transfer. Crit Care Med. 2012;40(8):2470–2478. .
- AHRQ WebM23(1):68–75. .
- Improving the quality of inter‐hospital transfers. J Qual Assur. 1991;13(4):16–20. , .
- Communication errors in dispatch of air medical transport. Prehosp Emerg Care. 2011;15(1):39–43. , .
- Guidelines for the inter‐ and intrahospital transport of critically ill patients. Crit Care Med. 2004;32(1):256–262. , , , , .
- Interhospital facility transfers in the United States: a nationwide outcomes study [published online November 13, 2014]. J Patient Saf. doi: 10.1097/PTS.0000000000000148. , , , .
- Patients transferred to academic medical centers and other hospitals: characteristics, resource use, and outcomes. Acad Med. 1997;72(10):921–930. , , , et al.
- Comparing the hospitalizations of transfer and non‐transfer patients in an academic medical center. Acad Med. 1996;71(3):262–266. , , , , .
- Impact of interhospital transfers on outcomes in an academic medical center. Implications for profiling hospital quality. Med Care. 1996;34(4):295–309. , .
- Comorbidity measures for use with administrative data. Med Care. 1998;36(1):8–27. , , , .
- 3M HIS: APR DRG classification software—overview. Mortality Measurement. Available at: http://archive.ahrq.gov/professionals/quality‐patient‐safety/quality‐resources/tools/mortality/Hughessumm.html. Accessed June 14, 2011. .
- Risk‐adjusting acute myocardial infarction mortality: are APR‐DRGs the right tool? Health Serv Res. 2000;34(7):1469–1489. , .
- Hospital volume and surgical outcomes after elective hip/knee arthroplasty: a risk‐adjusted analysis of a large regional database. Arthritis Rheum. 2011;63(8):2531–2539. , , , , .
- Examination of hospital characteristics and patient quality outcomes using four inpatient quality indicators and 30‐day all‐cause mortality. Am J Med Qual. 2013;28(1):46–55. , , , .
- Observed and expected outcomes in transfer and nontransfer patients with a hip fracture. J Orthop Trauma. 2011;25(11):666–669. , , , , .
- Interhospital transfer: an independent risk factor for mortality in the surgical intensive care unit. Am Surg. 2013;79(9):909–913. , , , et al.
- Insurance status and the transfer of hospitalized patients: an observational study. Ann Intern Med. 2014;160(2):81–90. , , , .
- Which patients and where: a qualitative study of patient transfers from community hospitals. Med Care. 2011;49(6):592–598. , , .
- Overwhelmed and uninspired by lack of coordinated care: a call to action for new physicians. Acad Med. 2013;88(11):1600–1602. .
- The outside hospital. Ann Intern Med. 2013;159(7):500–501. .
- Untangling the lines: using a transfer center to assist with interfacility transfers. Nurs Econ. 2003;21(2):94–96. , , .
- Ticket to ride: reducing handoff risk during hospital patient transport. J Nurs Care Qual. 2009;24(2):109–115. , , , et al.
- Outside imaging in emergency department transfer patients: CD import reduces rates of subsequent imaging utilization. Radiology. 2011;260(2):408–413. , , .
- Agency for Healthcare Research and Quality. Patient Safety Organization (PSO) Program. Available at: http://www.pso.ahrq.gov. Accessed July 7, 2011.
- Socioeconomic status, race, and mortality: a prospective cohort study. Am J Public Health. 2014;104(12):e98–e107. , , , , , .
- Prognostic factors for mortality following interhospital transfers to the medical intensive care unit of a tertiary referral center. Crit Care Med. 2003;31(7):1981–1986. , , , .
- The accuracy of present‐on‐admission reporting in administrative data. Health Serv Res. 2011;46(6 pt 1):1946–1962. , , , .
Interhospital transfers (IHTs) to academic medical centers (AMCs) or their affiliated hospitals may benefit patients who require unique specialty and procedural services. However, IHTs also introduce a potentially risky transition of care for patients suffering from complex or unstable medical problems.[1] Components of this risk include the dangers associated with transportation and the disrupted continuity of care that may lead to delays or errors in care.[2, 3] Furthermore, referring and accepting providers may face barriers to optimal handoffs including a lack of shared communication standards and difficulty accessing external medical records.[3, 4, 5] Although some authors have recommended the creation of formal guidelines for interhospital transfer processes for all patients to mitigate the risks of transfer, the available guidelines governing the IHT triage and communication process are limited to critically ill patients.[6]
A recent study of a diverse patient and hospital dataset demonstrated that interhospital transfer patients have a higher risk of mortality, increased length of stay (LOS), and increased risk of adverse events as compared with non‐transfer patients.[7] However, it is unknown if these findings persist in the population of patients transferred specifically to AMCs or their affiliated hospitals (the combination is hereafter referred to as academic health systems [AHSs]). AMCs provide a disproportionate share of IHT care for complex patients and have a vested interest in improving the outcomes of these transitions.[8] Prior single‐center studies of acute care adult medical patients accepted to AMCs have shown that IHT is associated with a longer LOS, increased in‐hospital mortality, and higher resource use.[9, 10] However, it is difficult to generalize from single‐center studies due to the variation in referral practices, geography, and network characteristics. Additionally, AMC referral systems, patient mix, and utilization of hospitalists have likely changed substantially in the nearly 2 decades since those reports were published.
Hospitalists and general internists often manage the transfer acceptance processes for internal medicine services at receiving hospitals, helping to triage and coordinate care for IHT patients. As a result, it is important for hospitalists to understand the characteristics and outcomes of the IHT population. In addition to informing the decision making around transfer for a given patient, such an understanding is the foundation for helping providers and institutions begin to systematically identify and mitigate peritransfer risks.
We conducted this large multicenter study to describe the characteristics and outcomes of a current, nationally representative IHT patient population discharged by hospitalists and general internists at AHSs. To identify unique features of the IHT population, we compared patients transferred from another hospital to an AHS to those admitted to the AHS directly from the AHS's emergency department (ED). Based on our anecdotal experiences and the prior single‐center study findings in adult medical populations,[9, 10] we hypothesized that the IHT population would be sicker, stay in the hospital and intensive care unit (ICU) longer, and have higher costs and in‐hospital mortality than ED patients. Although there may be fundamental differences between the 2 groups related to disease and patient condition, we hypothesized that outcome differences would persist even after adjusting for patient factors such as demographics, disease‐specific risk of mortality, and ICU utilization.
PATIENTS AND METHODS
We conducted a retrospective cohort study using data from the University HealthSystem Consortium (UHC) Clinical Database and Resource Manager (CDB/RM). UHC is an alliance of 120 academic medical centers and 300 of their affiliated hospitals for the purposes of collaboration on performance improvement. Each year, a subset of participating hospitals submits data on all of their inpatient discharges to the CDB/RM, which totals approximately 5 million records. The CDB/RM includes information from billing forms including demographics, diagnoses, and procedures as captured by International Classification of Diseases, Ninth Revision (ICD‐9) codes, discharge disposition, and line item charge detail for the type of bed (eg, floor, ICU). Most hospitals also provide detailed charge information including pharmacy, imaging, blood products, lab tests, and supplies. Some hospitals do not provide any charge data. The Beth Israel Deaconess Medical Center and University of Washington institutional review boards reviewed and approved the conduct of this study.
We included all inpatients discharged by hospitalists or general internal medicine physicians from UHC hospitals between April 1, 2011 and March 31, 2012. We excluded minors, pregnant patients, and prisoners. One hundred fifty‐eight adult academic medical centers and affiliated hospitals submitted data throughout this time period. Our primary independent variable, IHT status, was defined by patients whose admission source was another acute care institution. ED admissions were defined as patients admitted from the AHS ED whose source of origination was not another hospital or ambulatory surgery site.
Admission Characteristics
Admission characteristics of interest included age, gender, insurance status, the most common diagnoses in each cohort based on Medicare Severity Diagnosis‐Related Group (MS‐DRG), the most common Agency for Healthcare Research and Quality (AHRQ) comorbitidies,[11] the most common procedures, and the admission 3M All‐Patient Refined Diagnosis‐Related Group (APR‐DRG) risk of mortality (ROM) scores. 3M APR‐DRG ROM scores are proprietary categorical measures specific to the base APR‐DRG to which a patient is assigned, which are calculated using data available at the time of admission, including comorbid condition diagnosis codes, age, procedure codes, and principal diagnosis codes. A patient can fall into 1 of 4 categories with this score: minor, moderate, major, or extreme.[12]
Outcomes
Our primary outcome of interest was in‐hospital mortality. Secondary outcomes included LOS, the cost of care, ICU utilization, and discharge destination. The cost of care is a standardized estimate of the direct costs based on an adjustment of the charges submitted by CDB/RM participants. If an IHT is triaged through a receiving hospital's ED, the cost of care reflects those charges as well as the inpatient charges.
Statistical Analysis
We used descriptive statistics to characterize the IHT and ED patient populations. For bivariate comparisons of continuous variables, 2‐sample t tests with unequal variance were used. For categorical variables, 2 analysis was performed. We assessed the impact of IHT status on in‐hospital mortality using logistic regression to estimate unadjusted and adjusted relative risks, 95% confidence intervals (CIs), and P values. We included age, gender, insurance status, race, timing of ICU utilization, and 3M APR‐DRG ROM scores as independent variables. Prior studies have used this type of risk‐adjustment methodology with 3M APR‐DRG ROM scores,[13, 14, 15] including with interhospital transfer patients.[16] For all comparisons, a P value of <0.05 was considered statistically significant. Our sample size was determined by the data available for the 1‐year period.
Subgroup Analyses
We performed a stratified analysis based on the timing of ICU transfer to allow for additional comparisons of mortality within more homogeneous patient groups, and to control for the possibility that delays in ICU transfer could explain the association between IHT and in‐hospital mortality. We determined whether and when a patient spent time in the ICU based on daily accommodation charges. If a patient was charged for an ICU bed on the day of admission, we coded them as a direct ICU admission, and if the first ICU bed charge was on a subsequent day, they were coded as a delayed ICU admission. Approximately 20% of patients did not have the data necessary to determine the timing of ICU utilization, because the hospitals where they received care did not submit detailed charge data to the UHC.
Data analysis was performed by the UHC. Analysis was performed using Stata version 10 (StataCorp, College Station, TX). For all comparisons, a P value of <0.05 was considered significant.
RESULTS
Patient Characteristics
We identified 885,392 patients who met study criteria: 75,524 patients admitted as an IHT and 809,868 patients admitted from the ED. The proportion of each hospital's admissions that were IHTs that met our study criteria varied widely (median 9%, 25th percentile 3%, 75th percentile 14%). The average age and gender of the IHT and ED populations were similar and reflective of a nationally representative adult inpatient sample (Table 1). Racial compositions of the populations were notable for a higher portion of black patients in the ED admission group than the IHT group (25.4% vs 13.2%, P < 0.001). A slightly higher portion of the IHT population was covered by commercial insurance compared with the ED admissions (22.7% vs 19.1%, P < 0.001).
Demographic/Clinical Variables | ED | IHT | ||||
---|---|---|---|---|---|---|
1st | 2nd | 3rd | 4th | Rank | ||
| ||||||
No. of patients | 809,868 | 91.5 | 75,524 | 8.5 | ||
Age, y | 62.2 19.1 | 60.2 18.2 | ||||
Male | 381,563 | 47.1 | 38,850 | 51.4 | ||
Female | 428,303 | 52.9 | 36,672 | 48.6 | ||
Race | ||||||
White | 492,894 | 60.9 | 54,780 | 72.5 | ||
Black | 205,309 | 25.4 | 9,968 | 13.2 | ||
Other | 66,709 | 8.1 | 7,777 | 10.3 | ||
Hispanic | 44,956 | 5.6 | 2,999 | 4.0 | ||
Primary payer | ||||||
Commercial | 154,826 | 19.1 | 17,130 | 22.7 | ||
Medicaid | 193,585 | 23.9 | 15,924 | 21.1 | ||
Medicare | 445,227 | 55.0 | 39,301 | 52.0 | ||
Other | 16,230 | 2.0 | 3,169 | 4.2 | ||
Most common MS‐DRGs (top 5 for each group) | ||||||
Esophagitis, gastroenteritis, and miscellaneous digest disorders without MCC | 34,116 | 4.2 | 1st | 1,517 | 2.1 | 2nd |
Septicemia or severe sepsis without MV 96+ hours with MCC | 25,710 | 3.2 | 2nd | 2,625 | 3.7 | 1st |
Cellulitis without MCC | 21,686 | 2.7 | 3rd | 871 | 1.2 | 8th |
Kidney and urinary tract infections without MCC | 19,937 | 2.5 | 4th | 631 | 0.9 | 21st |
Chest pain | 18,056 | 2.2 | 5th | 495 | 0.7 | 34th |
Renal failure with CC | 15,478 | 1.9 | 9th | 1,018 | 1.4 | 5th |
GI hemorrhage with CC | 12,855 | 1.6 | 12th | 1,234 | 1.7 | 3rd |
Respiratory system diagnosis w ventilator support | 4,773 | 0.6 | 47th | 1,118 | 1.6 | 4th |
AHRQ comorbidities (top 5 for each group) | ||||||
Hypertension | 468,026 | 17.8 | 1st | 39,340 | 16.4 | 1st |
Fluid and electrolyte disorders | 251,339 | 9.5 | 2nd | 19,825 | 8.3 | 2nd |
Deficiency anemia | 208,722 | 7.9 | 3rd | 19,663 | 8.2 | 3rd |
Diabetes without CCs | 190,140 | 7.2 | 4th | 17,131 | 7.1 | 4th |
Chronic pulmonary disease | 178,164 | 6.8 | 5th | 16,319 | 6.8 | 5th |
Most common procedures (top 5 for each group) | ||||||
Packed cell transfusion | 72,590 | 7.0 | 1st | 9,756 | 5.0 | 2nd |
(Central) venous catheter insertion | 68,687 | 6.7 | 2nd | 13,755 | 7.0 | 1st |
Hemodialysis | 41,557 | 4.0 | 3rd | 5,351 | 2.7 | 4th |
Heart ultrasound (echocardiogram) | 37,762 | 3.7 | 4th | 5,441 | 2.8 | 3rd |
Insert endotracheal tube | 25,360 | 2.5 | 5th | 4,705 | 2.4 | 6th |
Continuous invasive mechanical ventilation | 19,221 | 1.9 | 9th | 5,280 | 2.7 | 5th |
3M APR‐DRG admission ROM score | ||||||
Minor | 271,702 | 33.6 | 18,620 | 26.1 | ||
Moderate | 286,427 | 35.4 | 21,775 | 30.5 | ||
Major | 193,652 | 23.9 | 20,531 | 28.7 | ||
Extreme | 58,081 | 7.2 | 10,527 | 14.7 |
Primary discharge diagnoses (MS‐DRGs) varied widely, with no single diagnosis accounting for more than 4.2% of admissions in either group. The most common primary diagnoses among IHTs included severe sepsis (3.7%), esophagitis and gastroenteritis (2.1%), and gastrointestinal bleeding (1.7%). The top 5 most common AHRQ comorbidities were the same between the IHT and ED populations. A higher proportion of IHTs had at least 1 procedure performed during their hospitalization (68.5% vs 49.8%, P < 0.001). Note that ICD‐9 procedure codes include interventions such as blood transfusions and dialysis (Table 1), which may not be considered procedures in common medical parlance.
As compared with those admitted from the ED, IHTs had a higher proportion of patients categorized with major or extreme admission risk of mortality score (major + extreme, ED 31.1% vs IHT 43.5%, P < 0.001).
Overall Outcomes
IHT patients experienced a 60% longer average LOS, and a higher proportion spent time in the ICU than patients admitted through the ED (Table 2). On average, care for IHT patients cost more per day than for ED patients (Table 2). A lower proportion of IHTs were discharged home (68.6% vs 77.4% of ED patients), and a higher proportion died in the hospital (4.1% vs 1.8%) (P < 0.001 for both). Of the ED or IHT patients who died during their admission, there was no significant difference between the proportion who died within 48 hours of admission (26.4% vs 25.6%, P = 0.3693). After adjusting for age, gender, insurance status, race, ICU utilization and 3M APR‐DRG admission ROM scores, IHT was independently associated with the risk of in‐hospital death (odds ratio [OR]: 1.36, 95% CI: 1.291.43) (Table 3). The C statistic for the in‐hospital mortality model was 0.88.
ED, n = 809,868 | IHT, n = 75,524 | |
---|---|---|
| ||
LOS, mean SD | 5.0 6.9 | 8.0 13.4 |
ICU days, mean SD | 0.6 2.4 | 1.7 5.2 |
Patients who spent some time in the ICU | 14.3% | 29.8% |
% LOS in the ICU (ICU days LOS) | 11.0% | 21.6% |
Average total cost SD | $10,731 $16,593 | $19,818 $34,665 |
Average cost per day (total cost LOS) | $2,139 | $2,492 |
Discharged home | 77.4% | 68.6% |
Died as inpatient | 14,869 (1.8%) | 3,051 (4.0%) |
Died within 48 hours of admission (% total deaths) | 3,918 (26.4%) | 780 (25.6%) |
Variable | Unadjusted OR (95% CI) | Adjusted OR (95% CI) |
---|---|---|
| ||
Age, y | 1.00 (1.001.00) | 1.03 (1.031.03) |
Gender | ||
Female | Ref. | Ref. |
Male | 1.13 (1.091.70) | 1.05 (1.011.09) |
Medicare status | ||
No | Ref. | Ref. |
Yes | 2.14 (2.062.22) | 1.39 (1.331.47) |
Race | ||
Nonblack | Ref. | Ref. |
Black | 0.57 (0.550.60) | 0.77 (0.730.81) |
ICU utilization | ||
No ICU admission | Ref. | Ref. |
Direct admission to the ICU | 5.56 (5.295.84) | 2.25 (2.132.38) |
Delayed ICU admission | 5.48 (5.275.69) | 2.46 (2.362.57) |
3M APR‐DRG admission ROM score | ||
Minor | Ref. | Ref. |
Moderate | 8.71 (7.5510.05) | 6.28 (5.437.25) |
Major | 43.97 (38.3150.47) | 25.84 (22.4729.71) |
Extreme | 238.65 (207.69273.80) | 107.17 (93.07123.40) |
IHT | ||
No | Ref. | Ref. |
Yes | 2.36 (2.262.48) | 1.36 (1.29 1.43) |
Subgroup Analyses
Table 4 demonstrates the unadjusted and adjusted results from our analysis stratified by timing of ICU utilization. IHT remained independently associated with in‐hospital mortality regardless of timing of ICU utilization.
Subgroup | In‐hospital Mortality, n (%) | Unadjusted OR [95% CI] | Adjusted OR [95% CI] |
---|---|---|---|
| |||
No ICU admission, n = 552,171 | |||
ED, n = 519,421 | 4,913 (0.95%) | Ref. | Ref. |
IHT, n = 32,750 | 590 (1.80%) | 1.92 [1.762.09] | 1.68 [1.531.84] |
Direct admission to the ICU, n = 44,537 | |||
ED, n = 35,614 | 1,733 (4.87%) | Ref. | Ref. |
IHT, n = 8,923 | 628 (7.04%) | 1.48 [1.351.63] | 1.24 [1.121.37] |
Delayed ICU admission, n = 110,540 | |||
ED, n = 95,573 | 4,706 (4.92%) | Ref. | Ref. |
IHT, n = 14,967 | 1,068 (7.14%) | 1.48 [1.391.59] | 1.25 [1.171.35] |
DISCUSSION
Our study of IHT patients ultimately discharged by hospitalists and general internists at US academic referral centers found significantly increased average LOS, costs, and in‐hospital mortality compared with patients admitted from the ED. The increased risk of mortality persisted after adjustment for patient characteristics and variables representing endogenous risk of mortality, and in more homogeneous subgroups after stratification by presence and timing of ICU utilization. These data confirm findings from single‐center studies and suggest that observations about the difference between IHT and ED populations may be generalizable across US academic hospitals.
Our work builds on 2 single‐center studies that examined mixed medical and surgical academic IHT populations from the late 1980s and early 1990s,[9, 10] and 1 studying surgical ICU patients in 2013.[17] These studies demonstrated longer average LOS, higher costs, and higher mortality rates (in both adjusted and unadjusted analyses). Our work confirmed these findings utilizing a more current, multicenter large dataset of IHT patients ultimately discharged by hospitalists and general internists. Our work is unique from a larger, more recent study[7] in that it focuses on patients transferred to academic health systems, and therefore has particular relevance to those settings. In addition, we divided patients into subpopulations based on the timing of ICU utilization, and found that in each of these populations, IHT remained independently associated with in‐hospital mortality.
Our analysis does not explain why the outcomes of IHTs are worse, but plausible contributing factors include that (1) patients chosen for IHT are at higher risk of death in ways uncaptured by established mortality risk scores, (2) referring, transferring, or accepting providers and institutions have provided inadequate care, (3) the transfer process itself involves harm, (4) socioeconomic bias in selection for IHT,[18] or (5) some combination of the above. Regardless of the causes of the worse outcomes observed in these outside‐hospital transfers, as these patients are colloquially known at accepting hospitals, they present challenges to everyone involved. Referring providers may feel a sense of urgency as these patients' needs exceed their management capabilities. The process is often time consuming and burdensome for referring and accepting providers because of poorly developed systems.[19] The transfer often takes patients further from their home and may make it more difficult for family to participate in their care. The transfer may delay care if the accepting institution cannot immediately accept the patient or if the time in transport is prolonged, which could result in decompensation at a critical juncture. For providers inheriting such patients, the stress of caring for these patients is compounded by the difficulty obtaining records about the prior hospitalization.[20] This frustrating experience is often translated into unfounded judgment of the institution that referred the patient and the care provided there.[21] It is important for hospitalists making decisions throughout the transfer process and for hospital leaders who determine staffing levels, measure the quality of care, manage hospital networks, or write hospital policy to appreciate that the transfer process itself may contribute to the challenges and poor outcomes we observe. Furthermore, regardless of the cause for the increased mortality that we observed, our findings imply that IHT patients require careful evaluation, management, and treatment.
Many accepting institutions have transfer centers that facilitate these transitions, utilizing protocols and templates to standardize the process.[22, 23] Future research should focus on the characteristics of these centers to learn which practices are most efficacious. Interventions to mitigate the known challenges of transfer (including patient selection and triage, handoff communication, and information sharing) could be tested by randomized studies at referring and accepting institutions. There may be a role for health information exchange or the development of enhanced pretransfer evaluation processes using telemedicine models; there is evidence that information sharing may reduce redundant imaging.[24] Perhaps targeted review of IHTs admitted to a non‐ICU portion of the hospital and subsequently transferred to the ICU could identify opportunities to improve triaging protocols and thus avert some of the bad outcomes observed in this subpopulation. A related future direction could be to create protected forumsusing the patient safety organization framework[25]to facilitate the discussion of interhospital transfer outcomes among the referring, transporting, and receiving parties. Lastly, future work should investigate the reasons for the different proportions of black patients in the ED versus IHT cohorts. Our finding that black race was associated with lower risk of mortality has been previously reported but may also benefit from more investigation.[26]
There are several limitations of our work. First, despite extensive adjustment for patient characteristics, due to the observational nature of our study it is still possible that IHTs differ from ED admissions in ways that were unaccounted for in our analysis, and which could be associated with increased mortality independent of the transfer process itself. We are unable to characterize features of the transfer process, such as the reason for transfer, differences in transfer processes among hospitals, or the distance and mode of travel, which may influence outcomes.[27] Because we used administrative data, variations in coding could incorrectly estimate the complexity or severity of illness on admission, which is a previously described risk.[28] In addition, although our dataset was very large, it was limited by incomplete charge data, which limited our ability to measure ICU utilization in our full cohort. The hospitals missing ICU charge data are of variable sizes and are distributed around the country, limiting the chance of systematic bias. Finally, in some settings, hospitalists may serve as the discharging physician for patients admitted to other services such as the ICU, introducing heterogeneity and bias to the sample. We attempted to mitigate such bias through our subgroup analysis, which allowed for comparisons within more homogeneous patient groupings.
In conclusion, our large multicenter study of academic health systems confirms the findings of prior single‐center academic studies and a large general population study that interhospital transfer patients have an increased average LOS, costs, and adjusted in‐hospital mortality than patients admitted from the ED. This difference in mortality persisted even after controlling for several other predictors of mortality. Our findings emphasize the need for future studies designed to clarify the reason for the increased risk and identify targets for interventions to improve outcomes for the interhospital transfer population.
Acknowledgements
The authors gratefully acknowledge Zachary Goldberger and Tom Gallagher for their critical reviews of this article.
Disclosures
Dr. Herzig was funded by grant number K23AG042459 from the National Institute on Aging. The funding organization had no involvement in any aspect of the study, including design and conduct of the study; collection, management, analysis, and interpretation of the data; and preparation, review, or approval of the manuscript. The authors report no conflicts of interest.
Interhospital transfers (IHTs) to academic medical centers (AMCs) or their affiliated hospitals may benefit patients who require unique specialty and procedural services. However, IHTs also introduce a potentially risky transition of care for patients suffering from complex or unstable medical problems.[1] Components of this risk include the dangers associated with transportation and the disrupted continuity of care that may lead to delays or errors in care.[2, 3] Furthermore, referring and accepting providers may face barriers to optimal handoffs including a lack of shared communication standards and difficulty accessing external medical records.[3, 4, 5] Although some authors have recommended the creation of formal guidelines for interhospital transfer processes for all patients to mitigate the risks of transfer, the available guidelines governing the IHT triage and communication process are limited to critically ill patients.[6]
A recent study of a diverse patient and hospital dataset demonstrated that interhospital transfer patients have a higher risk of mortality, increased length of stay (LOS), and increased risk of adverse events as compared with non‐transfer patients.[7] However, it is unknown if these findings persist in the population of patients transferred specifically to AMCs or their affiliated hospitals (the combination is hereafter referred to as academic health systems [AHSs]). AMCs provide a disproportionate share of IHT care for complex patients and have a vested interest in improving the outcomes of these transitions.[8] Prior single‐center studies of acute care adult medical patients accepted to AMCs have shown that IHT is associated with a longer LOS, increased in‐hospital mortality, and higher resource use.[9, 10] However, it is difficult to generalize from single‐center studies due to the variation in referral practices, geography, and network characteristics. Additionally, AMC referral systems, patient mix, and utilization of hospitalists have likely changed substantially in the nearly 2 decades since those reports were published.
Hospitalists and general internists often manage the transfer acceptance processes for internal medicine services at receiving hospitals, helping to triage and coordinate care for IHT patients. As a result, it is important for hospitalists to understand the characteristics and outcomes of the IHT population. In addition to informing the decision making around transfer for a given patient, such an understanding is the foundation for helping providers and institutions begin to systematically identify and mitigate peritransfer risks.
We conducted this large multicenter study to describe the characteristics and outcomes of a current, nationally representative IHT patient population discharged by hospitalists and general internists at AHSs. To identify unique features of the IHT population, we compared patients transferred from another hospital to an AHS to those admitted to the AHS directly from the AHS's emergency department (ED). Based on our anecdotal experiences and the prior single‐center study findings in adult medical populations,[9, 10] we hypothesized that the IHT population would be sicker, stay in the hospital and intensive care unit (ICU) longer, and have higher costs and in‐hospital mortality than ED patients. Although there may be fundamental differences between the 2 groups related to disease and patient condition, we hypothesized that outcome differences would persist even after adjusting for patient factors such as demographics, disease‐specific risk of mortality, and ICU utilization.
PATIENTS AND METHODS
We conducted a retrospective cohort study using data from the University HealthSystem Consortium (UHC) Clinical Database and Resource Manager (CDB/RM). UHC is an alliance of 120 academic medical centers and 300 of their affiliated hospitals for the purposes of collaboration on performance improvement. Each year, a subset of participating hospitals submits data on all of their inpatient discharges to the CDB/RM, which totals approximately 5 million records. The CDB/RM includes information from billing forms including demographics, diagnoses, and procedures as captured by International Classification of Diseases, Ninth Revision (ICD‐9) codes, discharge disposition, and line item charge detail for the type of bed (eg, floor, ICU). Most hospitals also provide detailed charge information including pharmacy, imaging, blood products, lab tests, and supplies. Some hospitals do not provide any charge data. The Beth Israel Deaconess Medical Center and University of Washington institutional review boards reviewed and approved the conduct of this study.
We included all inpatients discharged by hospitalists or general internal medicine physicians from UHC hospitals between April 1, 2011 and March 31, 2012. We excluded minors, pregnant patients, and prisoners. One hundred fifty‐eight adult academic medical centers and affiliated hospitals submitted data throughout this time period. Our primary independent variable, IHT status, was defined by patients whose admission source was another acute care institution. ED admissions were defined as patients admitted from the AHS ED whose source of origination was not another hospital or ambulatory surgery site.
Admission Characteristics
Admission characteristics of interest included age, gender, insurance status, the most common diagnoses in each cohort based on Medicare Severity Diagnosis‐Related Group (MS‐DRG), the most common Agency for Healthcare Research and Quality (AHRQ) comorbitidies,[11] the most common procedures, and the admission 3M All‐Patient Refined Diagnosis‐Related Group (APR‐DRG) risk of mortality (ROM) scores. 3M APR‐DRG ROM scores are proprietary categorical measures specific to the base APR‐DRG to which a patient is assigned, which are calculated using data available at the time of admission, including comorbid condition diagnosis codes, age, procedure codes, and principal diagnosis codes. A patient can fall into 1 of 4 categories with this score: minor, moderate, major, or extreme.[12]
Outcomes
Our primary outcome of interest was in‐hospital mortality. Secondary outcomes included LOS, the cost of care, ICU utilization, and discharge destination. The cost of care is a standardized estimate of the direct costs based on an adjustment of the charges submitted by CDB/RM participants. If an IHT is triaged through a receiving hospital's ED, the cost of care reflects those charges as well as the inpatient charges.
Statistical Analysis
We used descriptive statistics to characterize the IHT and ED patient populations. For bivariate comparisons of continuous variables, 2‐sample t tests with unequal variance were used. For categorical variables, 2 analysis was performed. We assessed the impact of IHT status on in‐hospital mortality using logistic regression to estimate unadjusted and adjusted relative risks, 95% confidence intervals (CIs), and P values. We included age, gender, insurance status, race, timing of ICU utilization, and 3M APR‐DRG ROM scores as independent variables. Prior studies have used this type of risk‐adjustment methodology with 3M APR‐DRG ROM scores,[13, 14, 15] including with interhospital transfer patients.[16] For all comparisons, a P value of <0.05 was considered statistically significant. Our sample size was determined by the data available for the 1‐year period.
Subgroup Analyses
We performed a stratified analysis based on the timing of ICU transfer to allow for additional comparisons of mortality within more homogeneous patient groups, and to control for the possibility that delays in ICU transfer could explain the association between IHT and in‐hospital mortality. We determined whether and when a patient spent time in the ICU based on daily accommodation charges. If a patient was charged for an ICU bed on the day of admission, we coded them as a direct ICU admission, and if the first ICU bed charge was on a subsequent day, they were coded as a delayed ICU admission. Approximately 20% of patients did not have the data necessary to determine the timing of ICU utilization, because the hospitals where they received care did not submit detailed charge data to the UHC.
Data analysis was performed by the UHC. Analysis was performed using Stata version 10 (StataCorp, College Station, TX). For all comparisons, a P value of <0.05 was considered significant.
RESULTS
Patient Characteristics
We identified 885,392 patients who met study criteria: 75,524 patients admitted as an IHT and 809,868 patients admitted from the ED. The proportion of each hospital's admissions that were IHTs that met our study criteria varied widely (median 9%, 25th percentile 3%, 75th percentile 14%). The average age and gender of the IHT and ED populations were similar and reflective of a nationally representative adult inpatient sample (Table 1). Racial compositions of the populations were notable for a higher portion of black patients in the ED admission group than the IHT group (25.4% vs 13.2%, P < 0.001). A slightly higher portion of the IHT population was covered by commercial insurance compared with the ED admissions (22.7% vs 19.1%, P < 0.001).
Demographic/Clinical Variables | ED | IHT | ||||
---|---|---|---|---|---|---|
1st | 2nd | 3rd | 4th | Rank | ||
| ||||||
No. of patients | 809,868 | 91.5 | 75,524 | 8.5 | ||
Age, y | 62.2 19.1 | 60.2 18.2 | ||||
Male | 381,563 | 47.1 | 38,850 | 51.4 | ||
Female | 428,303 | 52.9 | 36,672 | 48.6 | ||
Race | ||||||
White | 492,894 | 60.9 | 54,780 | 72.5 | ||
Black | 205,309 | 25.4 | 9,968 | 13.2 | ||
Other | 66,709 | 8.1 | 7,777 | 10.3 | ||
Hispanic | 44,956 | 5.6 | 2,999 | 4.0 | ||
Primary payer | ||||||
Commercial | 154,826 | 19.1 | 17,130 | 22.7 | ||
Medicaid | 193,585 | 23.9 | 15,924 | 21.1 | ||
Medicare | 445,227 | 55.0 | 39,301 | 52.0 | ||
Other | 16,230 | 2.0 | 3,169 | 4.2 | ||
Most common MS‐DRGs (top 5 for each group) | ||||||
Esophagitis, gastroenteritis, and miscellaneous digest disorders without MCC | 34,116 | 4.2 | 1st | 1,517 | 2.1 | 2nd |
Septicemia or severe sepsis without MV 96+ hours with MCC | 25,710 | 3.2 | 2nd | 2,625 | 3.7 | 1st |
Cellulitis without MCC | 21,686 | 2.7 | 3rd | 871 | 1.2 | 8th |
Kidney and urinary tract infections without MCC | 19,937 | 2.5 | 4th | 631 | 0.9 | 21st |
Chest pain | 18,056 | 2.2 | 5th | 495 | 0.7 | 34th |
Renal failure with CC | 15,478 | 1.9 | 9th | 1,018 | 1.4 | 5th |
GI hemorrhage with CC | 12,855 | 1.6 | 12th | 1,234 | 1.7 | 3rd |
Respiratory system diagnosis w ventilator support | 4,773 | 0.6 | 47th | 1,118 | 1.6 | 4th |
AHRQ comorbidities (top 5 for each group) | ||||||
Hypertension | 468,026 | 17.8 | 1st | 39,340 | 16.4 | 1st |
Fluid and electrolyte disorders | 251,339 | 9.5 | 2nd | 19,825 | 8.3 | 2nd |
Deficiency anemia | 208,722 | 7.9 | 3rd | 19,663 | 8.2 | 3rd |
Diabetes without CCs | 190,140 | 7.2 | 4th | 17,131 | 7.1 | 4th |
Chronic pulmonary disease | 178,164 | 6.8 | 5th | 16,319 | 6.8 | 5th |
Most common procedures (top 5 for each group) | ||||||
Packed cell transfusion | 72,590 | 7.0 | 1st | 9,756 | 5.0 | 2nd |
(Central) venous catheter insertion | 68,687 | 6.7 | 2nd | 13,755 | 7.0 | 1st |
Hemodialysis | 41,557 | 4.0 | 3rd | 5,351 | 2.7 | 4th |
Heart ultrasound (echocardiogram) | 37,762 | 3.7 | 4th | 5,441 | 2.8 | 3rd |
Insert endotracheal tube | 25,360 | 2.5 | 5th | 4,705 | 2.4 | 6th |
Continuous invasive mechanical ventilation | 19,221 | 1.9 | 9th | 5,280 | 2.7 | 5th |
3M APR‐DRG admission ROM score | ||||||
Minor | 271,702 | 33.6 | 18,620 | 26.1 | ||
Moderate | 286,427 | 35.4 | 21,775 | 30.5 | ||
Major | 193,652 | 23.9 | 20,531 | 28.7 | ||
Extreme | 58,081 | 7.2 | 10,527 | 14.7 |
Primary discharge diagnoses (MS‐DRGs) varied widely, with no single diagnosis accounting for more than 4.2% of admissions in either group. The most common primary diagnoses among IHTs included severe sepsis (3.7%), esophagitis and gastroenteritis (2.1%), and gastrointestinal bleeding (1.7%). The top 5 most common AHRQ comorbidities were the same between the IHT and ED populations. A higher proportion of IHTs had at least 1 procedure performed during their hospitalization (68.5% vs 49.8%, P < 0.001). Note that ICD‐9 procedure codes include interventions such as blood transfusions and dialysis (Table 1), which may not be considered procedures in common medical parlance.
As compared with those admitted from the ED, IHTs had a higher proportion of patients categorized with major or extreme admission risk of mortality score (major + extreme, ED 31.1% vs IHT 43.5%, P < 0.001).
Overall Outcomes
IHT patients experienced a 60% longer average LOS, and a higher proportion spent time in the ICU than patients admitted through the ED (Table 2). On average, care for IHT patients cost more per day than for ED patients (Table 2). A lower proportion of IHTs were discharged home (68.6% vs 77.4% of ED patients), and a higher proportion died in the hospital (4.1% vs 1.8%) (P < 0.001 for both). Of the ED or IHT patients who died during their admission, there was no significant difference between the proportion who died within 48 hours of admission (26.4% vs 25.6%, P = 0.3693). After adjusting for age, gender, insurance status, race, ICU utilization and 3M APR‐DRG admission ROM scores, IHT was independently associated with the risk of in‐hospital death (odds ratio [OR]: 1.36, 95% CI: 1.291.43) (Table 3). The C statistic for the in‐hospital mortality model was 0.88.
ED, n = 809,868 | IHT, n = 75,524 | |
---|---|---|
| ||
LOS, mean SD | 5.0 6.9 | 8.0 13.4 |
ICU days, mean SD | 0.6 2.4 | 1.7 5.2 |
Patients who spent some time in the ICU | 14.3% | 29.8% |
% LOS in the ICU (ICU days LOS) | 11.0% | 21.6% |
Average total cost SD | $10,731 $16,593 | $19,818 $34,665 |
Average cost per day (total cost LOS) | $2,139 | $2,492 |
Discharged home | 77.4% | 68.6% |
Died as inpatient | 14,869 (1.8%) | 3,051 (4.0%) |
Died within 48 hours of admission (% total deaths) | 3,918 (26.4%) | 780 (25.6%) |
Variable | Unadjusted OR (95% CI) | Adjusted OR (95% CI) |
---|---|---|
| ||
Age, y | 1.00 (1.001.00) | 1.03 (1.031.03) |
Gender | ||
Female | Ref. | Ref. |
Male | 1.13 (1.091.70) | 1.05 (1.011.09) |
Medicare status | ||
No | Ref. | Ref. |
Yes | 2.14 (2.062.22) | 1.39 (1.331.47) |
Race | ||
Nonblack | Ref. | Ref. |
Black | 0.57 (0.550.60) | 0.77 (0.730.81) |
ICU utilization | ||
No ICU admission | Ref. | Ref. |
Direct admission to the ICU | 5.56 (5.295.84) | 2.25 (2.132.38) |
Delayed ICU admission | 5.48 (5.275.69) | 2.46 (2.362.57) |
3M APR‐DRG admission ROM score | ||
Minor | Ref. | Ref. |
Moderate | 8.71 (7.5510.05) | 6.28 (5.437.25) |
Major | 43.97 (38.3150.47) | 25.84 (22.4729.71) |
Extreme | 238.65 (207.69273.80) | 107.17 (93.07123.40) |
IHT | ||
No | Ref. | Ref. |
Yes | 2.36 (2.262.48) | 1.36 (1.29 1.43) |
Subgroup Analyses
Table 4 demonstrates the unadjusted and adjusted results from our analysis stratified by timing of ICU utilization. IHT remained independently associated with in‐hospital mortality regardless of timing of ICU utilization.
Subgroup | In‐hospital Mortality, n (%) | Unadjusted OR [95% CI] | Adjusted OR [95% CI] |
---|---|---|---|
| |||
No ICU admission, n = 552,171 | |||
ED, n = 519,421 | 4,913 (0.95%) | Ref. | Ref. |
IHT, n = 32,750 | 590 (1.80%) | 1.92 [1.762.09] | 1.68 [1.531.84] |
Direct admission to the ICU, n = 44,537 | |||
ED, n = 35,614 | 1,733 (4.87%) | Ref. | Ref. |
IHT, n = 8,923 | 628 (7.04%) | 1.48 [1.351.63] | 1.24 [1.121.37] |
Delayed ICU admission, n = 110,540 | |||
ED, n = 95,573 | 4,706 (4.92%) | Ref. | Ref. |
IHT, n = 14,967 | 1,068 (7.14%) | 1.48 [1.391.59] | 1.25 [1.171.35] |
DISCUSSION
Our study of IHT patients ultimately discharged by hospitalists and general internists at US academic referral centers found significantly increased average LOS, costs, and in‐hospital mortality compared with patients admitted from the ED. The increased risk of mortality persisted after adjustment for patient characteristics and variables representing endogenous risk of mortality, and in more homogeneous subgroups after stratification by presence and timing of ICU utilization. These data confirm findings from single‐center studies and suggest that observations about the difference between IHT and ED populations may be generalizable across US academic hospitals.
Our work builds on 2 single‐center studies that examined mixed medical and surgical academic IHT populations from the late 1980s and early 1990s,[9, 10] and 1 studying surgical ICU patients in 2013.[17] These studies demonstrated longer average LOS, higher costs, and higher mortality rates (in both adjusted and unadjusted analyses). Our work confirmed these findings utilizing a more current, multicenter large dataset of IHT patients ultimately discharged by hospitalists and general internists. Our work is unique from a larger, more recent study[7] in that it focuses on patients transferred to academic health systems, and therefore has particular relevance to those settings. In addition, we divided patients into subpopulations based on the timing of ICU utilization, and found that in each of these populations, IHT remained independently associated with in‐hospital mortality.
Our analysis does not explain why the outcomes of IHTs are worse, but plausible contributing factors include that (1) patients chosen for IHT are at higher risk of death in ways uncaptured by established mortality risk scores, (2) referring, transferring, or accepting providers and institutions have provided inadequate care, (3) the transfer process itself involves harm, (4) socioeconomic bias in selection for IHT,[18] or (5) some combination of the above. Regardless of the causes of the worse outcomes observed in these outside‐hospital transfers, as these patients are colloquially known at accepting hospitals, they present challenges to everyone involved. Referring providers may feel a sense of urgency as these patients' needs exceed their management capabilities. The process is often time consuming and burdensome for referring and accepting providers because of poorly developed systems.[19] The transfer often takes patients further from their home and may make it more difficult for family to participate in their care. The transfer may delay care if the accepting institution cannot immediately accept the patient or if the time in transport is prolonged, which could result in decompensation at a critical juncture. For providers inheriting such patients, the stress of caring for these patients is compounded by the difficulty obtaining records about the prior hospitalization.[20] This frustrating experience is often translated into unfounded judgment of the institution that referred the patient and the care provided there.[21] It is important for hospitalists making decisions throughout the transfer process and for hospital leaders who determine staffing levels, measure the quality of care, manage hospital networks, or write hospital policy to appreciate that the transfer process itself may contribute to the challenges and poor outcomes we observe. Furthermore, regardless of the cause for the increased mortality that we observed, our findings imply that IHT patients require careful evaluation, management, and treatment.
Many accepting institutions have transfer centers that facilitate these transitions, utilizing protocols and templates to standardize the process.[22, 23] Future research should focus on the characteristics of these centers to learn which practices are most efficacious. Interventions to mitigate the known challenges of transfer (including patient selection and triage, handoff communication, and information sharing) could be tested by randomized studies at referring and accepting institutions. There may be a role for health information exchange or the development of enhanced pretransfer evaluation processes using telemedicine models; there is evidence that information sharing may reduce redundant imaging.[24] Perhaps targeted review of IHTs admitted to a non‐ICU portion of the hospital and subsequently transferred to the ICU could identify opportunities to improve triaging protocols and thus avert some of the bad outcomes observed in this subpopulation. A related future direction could be to create protected forumsusing the patient safety organization framework[25]to facilitate the discussion of interhospital transfer outcomes among the referring, transporting, and receiving parties. Lastly, future work should investigate the reasons for the different proportions of black patients in the ED versus IHT cohorts. Our finding that black race was associated with lower risk of mortality has been previously reported but may also benefit from more investigation.[26]
There are several limitations of our work. First, despite extensive adjustment for patient characteristics, due to the observational nature of our study it is still possible that IHTs differ from ED admissions in ways that were unaccounted for in our analysis, and which could be associated with increased mortality independent of the transfer process itself. We are unable to characterize features of the transfer process, such as the reason for transfer, differences in transfer processes among hospitals, or the distance and mode of travel, which may influence outcomes.[27] Because we used administrative data, variations in coding could incorrectly estimate the complexity or severity of illness on admission, which is a previously described risk.[28] In addition, although our dataset was very large, it was limited by incomplete charge data, which limited our ability to measure ICU utilization in our full cohort. The hospitals missing ICU charge data are of variable sizes and are distributed around the country, limiting the chance of systematic bias. Finally, in some settings, hospitalists may serve as the discharging physician for patients admitted to other services such as the ICU, introducing heterogeneity and bias to the sample. We attempted to mitigate such bias through our subgroup analysis, which allowed for comparisons within more homogeneous patient groupings.
In conclusion, our large multicenter study of academic health systems confirms the findings of prior single‐center academic studies and a large general population study that interhospital transfer patients have an increased average LOS, costs, and adjusted in‐hospital mortality than patients admitted from the ED. This difference in mortality persisted even after controlling for several other predictors of mortality. Our findings emphasize the need for future studies designed to clarify the reason for the increased risk and identify targets for interventions to improve outcomes for the interhospital transfer population.
Acknowledgements
The authors gratefully acknowledge Zachary Goldberger and Tom Gallagher for their critical reviews of this article.
Disclosures
Dr. Herzig was funded by grant number K23AG042459 from the National Institute on Aging. The funding organization had no involvement in any aspect of the study, including design and conduct of the study; collection, management, analysis, and interpretation of the data; and preparation, review, or approval of the manuscript. The authors report no conflicts of interest.
- The incomplete infrastructure for interhospital patient transfer. Crit Care Med. 2012;40(8):2470–2478. .
- AHRQ WebM23(1):68–75. .
- Improving the quality of inter‐hospital transfers. J Qual Assur. 1991;13(4):16–20. , .
- Communication errors in dispatch of air medical transport. Prehosp Emerg Care. 2011;15(1):39–43. , .
- Guidelines for the inter‐ and intrahospital transport of critically ill patients. Crit Care Med. 2004;32(1):256–262. , , , , .
- Interhospital facility transfers in the United States: a nationwide outcomes study [published online November 13, 2014]. J Patient Saf. doi: 10.1097/PTS.0000000000000148. , , , .
- Patients transferred to academic medical centers and other hospitals: characteristics, resource use, and outcomes. Acad Med. 1997;72(10):921–930. , , , et al.
- Comparing the hospitalizations of transfer and non‐transfer patients in an academic medical center. Acad Med. 1996;71(3):262–266. , , , , .
- Impact of interhospital transfers on outcomes in an academic medical center. Implications for profiling hospital quality. Med Care. 1996;34(4):295–309. , .
- Comorbidity measures for use with administrative data. Med Care. 1998;36(1):8–27. , , , .
- 3M HIS: APR DRG classification software—overview. Mortality Measurement. Available at: http://archive.ahrq.gov/professionals/quality‐patient‐safety/quality‐resources/tools/mortality/Hughessumm.html. Accessed June 14, 2011. .
- Risk‐adjusting acute myocardial infarction mortality: are APR‐DRGs the right tool? Health Serv Res. 2000;34(7):1469–1489. , .
- Hospital volume and surgical outcomes after elective hip/knee arthroplasty: a risk‐adjusted analysis of a large regional database. Arthritis Rheum. 2011;63(8):2531–2539. , , , , .
- Examination of hospital characteristics and patient quality outcomes using four inpatient quality indicators and 30‐day all‐cause mortality. Am J Med Qual. 2013;28(1):46–55. , , , .
- Observed and expected outcomes in transfer and nontransfer patients with a hip fracture. J Orthop Trauma. 2011;25(11):666–669. , , , , .
- Interhospital transfer: an independent risk factor for mortality in the surgical intensive care unit. Am Surg. 2013;79(9):909–913. , , , et al.
- Insurance status and the transfer of hospitalized patients: an observational study. Ann Intern Med. 2014;160(2):81–90. , , , .
- Which patients and where: a qualitative study of patient transfers from community hospitals. Med Care. 2011;49(6):592–598. , , .
- Overwhelmed and uninspired by lack of coordinated care: a call to action for new physicians. Acad Med. 2013;88(11):1600–1602. .
- The outside hospital. Ann Intern Med. 2013;159(7):500–501. .
- Untangling the lines: using a transfer center to assist with interfacility transfers. Nurs Econ. 2003;21(2):94–96. , , .
- Ticket to ride: reducing handoff risk during hospital patient transport. J Nurs Care Qual. 2009;24(2):109–115. , , , et al.
- Outside imaging in emergency department transfer patients: CD import reduces rates of subsequent imaging utilization. Radiology. 2011;260(2):408–413. , , .
- Agency for Healthcare Research and Quality. Patient Safety Organization (PSO) Program. Available at: http://www.pso.ahrq.gov. Accessed July 7, 2011.
- Socioeconomic status, race, and mortality: a prospective cohort study. Am J Public Health. 2014;104(12):e98–e107. , , , , , .
- Prognostic factors for mortality following interhospital transfers to the medical intensive care unit of a tertiary referral center. Crit Care Med. 2003;31(7):1981–1986. , , , .
- The accuracy of present‐on‐admission reporting in administrative data. Health Serv Res. 2011;46(6 pt 1):1946–1962. , , , .
- The incomplete infrastructure for interhospital patient transfer. Crit Care Med. 2012;40(8):2470–2478. .
- AHRQ WebM23(1):68–75. .
- Improving the quality of inter‐hospital transfers. J Qual Assur. 1991;13(4):16–20. , .
- Communication errors in dispatch of air medical transport. Prehosp Emerg Care. 2011;15(1):39–43. , .
- Guidelines for the inter‐ and intrahospital transport of critically ill patients. Crit Care Med. 2004;32(1):256–262. , , , , .
- Interhospital facility transfers in the United States: a nationwide outcomes study [published online November 13, 2014]. J Patient Saf. doi: 10.1097/PTS.0000000000000148. , , , .
- Patients transferred to academic medical centers and other hospitals: characteristics, resource use, and outcomes. Acad Med. 1997;72(10):921–930. , , , et al.
- Comparing the hospitalizations of transfer and non‐transfer patients in an academic medical center. Acad Med. 1996;71(3):262–266. , , , , .
- Impact of interhospital transfers on outcomes in an academic medical center. Implications for profiling hospital quality. Med Care. 1996;34(4):295–309. , .
- Comorbidity measures for use with administrative data. Med Care. 1998;36(1):8–27. , , , .
- 3M HIS: APR DRG classification software—overview. Mortality Measurement. Available at: http://archive.ahrq.gov/professionals/quality‐patient‐safety/quality‐resources/tools/mortality/Hughessumm.html. Accessed June 14, 2011. .
- Risk‐adjusting acute myocardial infarction mortality: are APR‐DRGs the right tool? Health Serv Res. 2000;34(7):1469–1489. , .
- Hospital volume and surgical outcomes after elective hip/knee arthroplasty: a risk‐adjusted analysis of a large regional database. Arthritis Rheum. 2011;63(8):2531–2539. , , , , .
- Examination of hospital characteristics and patient quality outcomes using four inpatient quality indicators and 30‐day all‐cause mortality. Am J Med Qual. 2013;28(1):46–55. , , , .
- Observed and expected outcomes in transfer and nontransfer patients with a hip fracture. J Orthop Trauma. 2011;25(11):666–669. , , , , .
- Interhospital transfer: an independent risk factor for mortality in the surgical intensive care unit. Am Surg. 2013;79(9):909–913. , , , et al.
- Insurance status and the transfer of hospitalized patients: an observational study. Ann Intern Med. 2014;160(2):81–90. , , , .
- Which patients and where: a qualitative study of patient transfers from community hospitals. Med Care. 2011;49(6):592–598. , , .
- Overwhelmed and uninspired by lack of coordinated care: a call to action for new physicians. Acad Med. 2013;88(11):1600–1602. .
- The outside hospital. Ann Intern Med. 2013;159(7):500–501. .
- Untangling the lines: using a transfer center to assist with interfacility transfers. Nurs Econ. 2003;21(2):94–96. , , .
- Ticket to ride: reducing handoff risk during hospital patient transport. J Nurs Care Qual. 2009;24(2):109–115. , , , et al.
- Outside imaging in emergency department transfer patients: CD import reduces rates of subsequent imaging utilization. Radiology. 2011;260(2):408–413. , , .
- Agency for Healthcare Research and Quality. Patient Safety Organization (PSO) Program. Available at: http://www.pso.ahrq.gov. Accessed July 7, 2011.
- Socioeconomic status, race, and mortality: a prospective cohort study. Am J Public Health. 2014;104(12):e98–e107. , , , , , .
- Prognostic factors for mortality following interhospital transfers to the medical intensive care unit of a tertiary referral center. Crit Care Med. 2003;31(7):1981–1986. , , , .
- The accuracy of present‐on‐admission reporting in administrative data. Health Serv Res. 2011;46(6 pt 1):1946–1962. , , , .
© 2015 Society of Hospital Medicine