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The Learning Hospital System
In the landmark Best Care at Lower Cost report, the Institute of Medicine presents a compelling vision of a US healthcare system where science, information technology, incentives, and care culture are brought together seamlessly to produce high‐quality healthcare.[1] At the center of this transformation is the learning healthcare system, a system characterized by its ability to leverage data arising from care provision to drive rapid improvements in care delivery.[2] When steeped within the right organizational milieu, these data help to close the virtuous cycle of continuous learning moving from science to evidence to care and back to new science. The anticipated end result is a healthcare system that can provide Americans with superior care at lower cost.
Hospital‐based practitioners will recognize the inpatient setting as an ideal demonstration opportunity for continuous learning. Hospital care is costly, accounting for more than 30% of all US healthcare costs[3]; intensive care alone accounts for a notable proportion of the US gross domestic product.[4] Inpatient care is associated with significant mortality and morbidity, and its use is often greatly increased in patients' last days.[5, 6] Fortunately, the inpatient setting also offers an ideal opportunity to leverage high‐quality data to help inform and improve care. The digitization of medicine means that far more data are now available through electronic health records, medical devices, and tests.[7] This is particularly true for inpatients, for whom a large volume of data are produced even over relatively short hospital stays.
Whereas the challenge to improve hospital care is daunting, there is an incredible opportunity to advance the quality of inpatient care through realizing the vision of the learning hospital system. In the sections that follow, we use an object lessonsepsis care within hospitals of the Kaiser Permanente Northern California (KPNC) integrated healthcare delivery systemto evaluate the challenges and insights gleaned from working toward building a learning hospital system. Then, we describe further steps that could enhance the use of inpatient data to drive improved care.
THE FRAMEWORK OF A LEARNING HEALTHCARE SYSTEM
Best Care at Lower Cost notes a fundamental paradox in US healthcare: although we have witnessed a dramatic expansion in biomedical knowledge, innovative therapies and surgical procedures, and clinical treatments to extend survival, US healthcare persistently falls short on the basic dimensions of quality, outcomes, cost, and equity.[1] The proposed path forward lies in building the learning healthcare system, a system characterized by continuous knowledge development, improvement, and application. Figure 1 shows the critical nodes in the framework for continuous learning, which include: (1) the development of new scientific knowledge (science), (2) the translation of science into clinical evidence of efficacy (evidence), and (3) the application of efficacious interventions through effective care delivery (care). In healthcare today, transitions between these nodes are rife with missed or wasted opportunities like delays in applying high‐quality evidence or poorly managed insights arising from scientific discovery. If such opportunities could be recovered, however, the quality of healthcare could be improved dramatically.[8]
The pursuit of continuous learning is aided by rapid changes in the quality and quantity of biomedical data available over the past decade, especially through the use of electronic health records, novel biomolecular tools, and digital sensors.[2, 7, 9] The Internet has ushered in a new era of data connectivity, for example, allowing for highly engaged communication between patients and providers as well as collaboration between professional or citizen scientists on data of unprecedented scale.[10] New methodologic approaches, including data mining and machine learning, increasingly leverage commodity hardware to conduct previously computationally intractable analyses.[9] Moreover, the development of domain ontologies fosters the discovery of meaningful insights from data of heterogeneous types.[11]
Ultimately, however, improvements in data alone are inadequate to achieve continuous learning. As shown in Figure 1, whereas data form the channels that allow for transitions from science to evidence to care, novel insights need to be steeped within the right culture, motivated by the right incentives, and supported by the right leaders.[1, 12] Within the sustainable learning healthcare system, knowledge generation feeds practice change with the support and guidance of system leadership; improved practice, in turn, generates new knowledge and completes the virtuous cycle of learning.
THE PROMISE OF CONTINUOUS LEARNING IN HOSPITAL SETTINGS
The hospital is an ideal setting in which to foster continuous learning because advances in inpatient care have the potential to substantially improve healthcare quality and value.[8] Americans were hospitalized roughly 37 million times in 2012; in total, these episodes cost $378 billion.[3] Over 700,000 patients die in US hospitals annually, with reports showing that many patients utilize greatly increased inpatient and critical care services near the end of their lives in a manner that appears misaligned with their preferences.[11, 13] Hospital care is also highly variable in quality and cost; this heterogeneity is not closely associated with improved outcomes.[14, 15] Preventable harm and medical injury occur commonly in hospitals and are now recognized to be a leading cause of inpatient death.[16] Finally, emerging research illuminates the substantial toll that acute care has on patients and families resulting in new comorbidity, functional or neuropsychiatric impairment, rehospitalization, and financial burden that persist long after patients are discharged.[17]
Fortunately, inpatient care also exhibits several qualities that improve the likelihood that continuous learning can be achieved. Although it is clear that hospitalizations occur within the arc of a patient's larger health trajectory, these distinct episodes offer the potential to observe patient trajectories and treatments evolving within relatively compressed time intervals; over that same interval, a large volume of data are produced. Stored within comprehensive electronic health records, these granular data now allow inpatient episodes to be digitally recapitulated with high fidelity, bolstering their use in driving care improvements.[18]
AN OBJECT LESSON IN THE LEARNING FRAMEWORK: SEPSIS CARE
Translating Science to Evidence in Sepsis
Although sepsis has attracted great attention in modern hospital care, sepsis was described long ago by Hippocrates to describe the process by which wounds fester.[19] Recast after the confirmation of germ theory, sepsis came to be known primarily as the blood poisoning resulting from pathogenic organisms.[20] However, with the advent of antibiotics, numerous scientific studies now recognize that sepsis actually results from the dysregulated host immune response to systemic infection, which can also cause organ dysfunction.[21] Based on this knowledge, landmark translational and clinical studies in the 2000s provided strong evidence that early identification of sepsis patients and aggressive infection control and resuscitation were associated with improved mortality (Figure 2, step 1).[22]
Translating Evidence to Care in Sepsis at KPNC
In 2007, the leadership of KPNC initiated a regional effort to improve the quality of care and reduce the variability in performance at its medical centers (Table 1).[23] Reviewing data from nearly 1000 inpatientsthe last 50 consecutive hospital deaths from each of 19 medical centersa mortality diagnostic based on Institute for Healthcare Improvement recommendations[24] revealed that sepsis had a major impact on hospital outcomes. For example, even though sepsis patients were still relatively under‐recognized at the time, accounting for fewer than 3% of hospitalizations, they contributed to one‐quarter of hospital deaths. In light of these compelling data, senior regional leadership identified reducing sepsis mortality as a key performance improvement goal (Figure 2, step 2).
| Time Period | Event Summary |
|---|---|
| |
| 2007 | Variability in hospital standardized mortality ratio observed, indicating an opportunity to drive improved outcomes. |
| Initiation of staggered implementation of unified electronic medical record across all KP sites (starting in 2006 and ending in 2009). | |
| Spring 2008 | Mortality diagnostic chart review completed identifying sepsis and infection‐related causes as key factors in hospital outcomes. |
| May 2008 | Regional Mortality Summit held with a focus on patient safety and mortality reduction efforts through performance improvement. Executive regional and local leadership alignment to focus on sepsis performance improvement. |
| Summer 2008 | Sepsis Steering Committee evaluates best available evidence, develops treatment algorithms, and plans for medical center pilots. |
| Fall 2008 | Pilot intervention deployed at 2 medical centers. |
| November 2008 | First Regional Sepsis Summit: development of sepsis performance improvement playbook, training materials, implementation plans, and measurement strategy. |
| November 2008 | All medical centers begin to form multidisciplinary sepsis teams and performance improvement committees, obtain equipment and supplies including assembly of a sepsis cart. Multidisciplinary teams included ED physician champion, ED nurse champion, improvement advisor, hospitalists, intensivists, quality improvement personnel, nurse educators, and even resident physicians. |
| January 2009 | Performance data collection begins on EGDT processes and outcomes. Initiation of 2 key elements to enhance screening for and detection of sepsis: (1) concomitant ordering of serum lactic acid along with blood cultures, and (2) definition of lactate >2.0 as a critical lab value. |
| Use of manual chart review for case finding and central database entry because of ongoing implementation of electronic medical record and limited sepsis‐specific data infrastructure. | |
| March 2009 | Regional train the trainer sessions occur and local educational spread efforts begin including: collaborative calls, in‐person training events, and medical center site visits. |
| August 2009 | Grant funding from the Gordon and Betty Moore Foundation begins with a planned 2‐year duration providing funding for improvement advisors with performance improvement expertise and data infrastructure development. |
| November 2009 | Second Regional Sepsis Summit. Identification of intermediate lactate sepsis patients having significant mortality. |
| January 2010 | Initiate measurement of performance for intermediate lactate sepsis patients with a focus on lactate clearance as an outcome measure of interest. |
| 2010 | Development of an intranet Web‐based data abstraction tool to identify cases and auto‐populate specific fields for review. Facilities were responsible for review of cases at the local level to foster rapid feedback cycles for local performance improvement. Standardized data query tools were deployed to foster local medical center engagement and system‐level evaluation. |
| Accompanying development of a sepsis performance improvement scorecard allowing for comparison of longitudinal performance metrics across all facilities. Scorecard elements included: proportion of lactates drawn following ED blood culture, EGDT‐specific bundle elements (ie, number of EGDT cases, antibiotics within 1 hour, first central venous pressure within 2 hours of EGDT start, target mean arterial pressure achievement), repeat lactate elements, balancing measures for central line placement (ie, pneumothorax, central line infection), and overall sepsis statistics. | |
| April 2011 | Third Regional Sepsis Summit. Refinement of EGDT bundle and further development of intermediate lactate bundle approach, including piloting specific treatment bundles targeting this population. Collaborative performance improvement environment in which successful strategies at 1 site were rapidly disseminated to other sites including the Sepsis Alert and the Sepsis Clock. |
| May 2012 | Research analysis of fluid volume and lactate clearance in intermediate lactate sepsis population begins. |
| February 2013 | Fourth Regional Sepsis Summit. Regional spread of intermediate lactate bundle including the use of fluids, antibiotics, and repeat lactate measurements. |
| May 2013 | Research analysis of the contribution of sepsis to hospital deaths (within KP and in national sample) as well as post‐sepsis resource utilization and mortality |
| March 2014 | Publication of ProCESS randomized clinical trial, requiring systemic reevaluation of EGDT‐based sepsis strategy. Subsequent publications of ARISE and ProMISe trials confirming findings from ProCESS. Updated approach under consideration and informally disseminated to practitioners. |
| October 2014 | Updated sepsis treatment guidelines and data capture strategy fully implemented moving away from a catheter‐based strategy for all EGDT‐eligible patients. |
| October 2015 | Sixth Regional Sepsis Summit held to adjust sepsis treatment and data measurement strategy to align more closely with CMS SEP‐1 guidelines. |
Based on the principles of performance improvement methodology, clinical and operational leaders established an environment with aligned culture, incentives, and leadership around sepsis care. The effort was launched in late 2008 at a Sepsis Summit, bringing together a multidisciplinary group of stakeholders (eg, hospitalist, emergency department, and intensive care chiefs of staff and nursing managers; medical center and nursing executive and operational leadership) and providing sepsis care pathways based on the best available evidence.[23] Regional investments in the digital infrastructure to support implementation resulted in the provision of granular data within monthly sepsis scorecards quantifying each medical center's performance and trends for a diverse set of sepsis bundle metrics.
The resulting changes in sepsis care were substantial. For example, improved early recognition of infected patients meeting the criteria for sepsis resulted in large changes in the standardized diagnostic criteria used to label patients (Figure 3A). Implementing screening strategies using serum lactate testing for any patient receiving blood cultures resulted in a roughly 10‐fold increase in the use of lactate testing in the emergency department (Figure 3B). Earlier recognition of sepsis also increased the number of patients receiving early antibiotics and receiving central venous catheters for quantitative resuscitation.[23]
CLOSING THE LOOP TOWARD CONTINUOUS LEARNING IN SEPSIS
Leveraging timely and actionable data steeped within an aligned organizational milieu resulted in large‐scale changes across a heterogeneous set of hospitals. However, to realize the true vision of a learning hospital system, a looming question remained: Could the data generated as the byproduct of routine care now be used to complete the virtuous cycle and drive new scientific discovery (Figure 2, step 3)?
Confirming Concordance in the Impact of Sepsis Nationally
The heightened identification of sepsis patients through program implementation revealed that the impact of sepsis on hospital mortality was greater than originally estimated; based on improved patient identification, sepsis now accounted for upward of 1 in 2 hospital deaths.[25] This sobering statistic confirmed that the investments in standardizing best sepsis care following the mortality diagnostic were critical. However, were similar estimates of sepsis‐attributable mortality consistent outside of the KPNC system? To study this, we examined US hospitalizations occurring across >1000 hospitals and involving >6 million hospital stays to estimate corresponding prevalence.[25] In this national sample, sepsis contributed to as many as half of hospital deaths in the United States in 2010, lending strong support to ongoing international and state‐based efforts to improve sepsis care. These studies also paved the way to use these data drawn from our large sepsis population to inform updated international consensus definitions for sepsis and septic shock.[26, 27, 28]
Identifying New Avenues for Reducing the Toll of Sepsis
A major concern of sepsis program leaders was the prior findings that sepsis hospitalizations among Medicare beneficiaries were associated with substantial new cognitive and functional disability.[29] This lingering toll of sepsis had been termed a hidden public health disaster.[30] To further understand the posthospital impact of sepsis and to begin investigating new avenues to reduce this impact, a cohort of patients was followed for 1 year following sepsis hospitalization.[31] Over that period, nearly half of sepsis survivors were rehospitalized. When compared with their presepsis levels of healthcare utilization, middle‐aged and elderly sepsis patients experienced a 3‐fold increase in their days using facility‐based care. Subsequent studies in other populations outside of KPNC have confirmed these concerning findings, resulting in new efforts to address postsepsis survivorship care.[32, 33]
Phenotyping New Targets for Standardized Sepsis Care
At its outset, the sepsis improvement program applied the best available evidence to treat patients with the most severe forms of sepsisseptic shock. However, once the initial implementation phase had succeeded, clinicians and operational leaders quickly realized from the emerging data that there was a far larger group of sepsis patients for whom treatment guidelines were poorly defined.[25, 34, 35] These were severe sepsis patients with so‐called intermediate lactate values between 2 mmol/L and 4 mmol/L; they comprised a substantial proportion of all sepsis patients dying in the hospital. Using data generated from the routine care of sepsis patients treated across 21 hospitals, the sepsis leadership group was able to rapidly assemble a cohort of intermediate lactate sepsis patients up to 20‐ to 100‐fold larger than that reported in prior studies and evaluate their outcomes.[34, 35]
The data used to evaluate these intermediate lactate sepsis patients now spurred a new implementation program in 2013 for a group of patients in whom there was essentially no existing evidence to guide care. Rapidly implemented within a mature sepsis performance improvement program, evaluations at the 6‐month and 1‐year intervals demonstrated significant decreases in mortality.[36] Importantly, to allay the justified concerns of clinicians, these evaluations also clearly showed no evidence of harm from more aggressive fluid resuscitation (eg, increased transfer to intensive care, increased rates of mechanical ventilation). Again, driven by clinician input, subgroup analyses further revealed that the implementation program was only associated with reduced mortality in patients who could be at risk for iatrogenic fluid overload (ie, those with a history of congestive heart failure or chronic kidney disease).[36] Spurred by these provocative findings, operational and clinical leaders are currently considering how to guide future care in these patients, especially with the emerging use of noninvasive methods to quantify patients' fluid responsiveness.
PRINCIPLES FOR LEVERAGING DATA IN THE LEARNING HOSPITAL SYSTEM
The object lesson of using data to drive improved sepsis care and further new scientific discovery offers some important insights for continuous learning.
Building a Digital Infrastructure for Utilizing Granular Hospital Data
As described above, current transitions between the nodes of the learning framework are rife with missed opportunities. Perhaps one of the most glaring is the inability to use highly granular data already collected within the electronic health record (eg, trajectories and trends across vital signs or laboratory results, large‐scale medication administration records to evaluate multidrug interactions). An essential starting point for continuous learning is investing in the digital infrastructure to improve the use of data beyond traditional claims (administrative dataadmission source codes, disposition codes, diagnoses, and procedures). As shown in Table 2, the first key step is incorporating laboratory data into the quality assessment/emmprovement process. In addition, using these data to automate severity of illness and risk adjustment metrics fosters use of similar comparison cohorts across time or disease types.[18, 37, 38, 39, 40]
| Data Type | Contents | Degree of Difficulty in Accessing | Degree of Difficulty in Analyzing |
|---|---|---|---|
| Administrative | Traditional claims data, diagnostic or procedural codes | Low | Low to moderate |
| Standard cohort profiling | Limited instances of vitals signs, laboratory, diagnostic testing, or treatment data | Low to moderate | Low to moderate |
| Metrics reporting for care improvement | Standard cohort identification, aggregated achievement of treatment targets, scorecard dissemination | Moderate | Moderate |
| Advanced cohort profiling | Time series of physiologic data, inpatient triage and treatment data within short temporal intervals | Moderate to high | High |
| Research‐grade discovery | Data with breadth (representative sample size) and depth (highly granular physiologic and treatment data) | High | Very high |
| Patient‐reported outcomes | Quality of life, functional and cognitive disability | Very high | High |
Employing Novel Methods to Address the Limitations of Using Real‐World Data
The rapid digitization of medicine through the use of electronic medical records offers tremendous opportunities to facilitate continuous learning. However, these opportunities are accompanied by important limitations.[41] Data collected as a byproduct of real‐world care can be vulnerable to many forms of bias and confounding, potentially clouding the validity and robustness of corresponding analytic results. Fortunately, advanced methods including causal inference are now used routinely to address some limitations.[42] In the context of a learning healthcare system, other opportunities for improved study design including cluster randomized trials or stepped wedge implementation can also be employed to preserve the statistical rigor of subsequent analyses.[43] Finally, emerging methods employing randomization through the electronic medical record alongside adaptive trial design offer great potential to increase the efficiency of continuous learning.[44]
Evaluating the Hospital as a Single System
Advances in contemporary hospital care require seamless transitions of patient care, screening strategies, and therapeutic approaches across multiple hospital domains and with diverse providers; these interventions also need to happen rapidly. Many traditional approaches to inpatient care have taken a bottom‐up approach (eg, studying a specific disease within a specific hospital ward like the intensive care unit) that have proven useful but may limit generalizability when applied to a real‐world hospital operating with Pareto optimality (ie, the trade‐off scenario where new resource allocation to 1 area also requires resource withdrawal from another area). In certain cases, an empiric approach, without initial preference for any specific ward or disease, can aid decision making by hospital operational and clinical leaders by providing a global picture of impact and value.
Focusing on Early Detection in Hospital Settings as Secondary Prevention
Once patients have been admitted to the hospital, a race against the clock begins. Each additional hour of hospitalization increases the risks of iatrogenic injury or medical harm manifested by immobility, disorientation and delirium, nosocomial infections, or medication errors, among others. In this context, detection systems that use granular hospital data to focus on the earliest detection of risk can aid critical approaches to secondary prevention (Although the hospitalization for sepsis cannot be avoided, careful attention to mobility can limit the risk of developing delirium. In turn, preventing delirium can limit the risk of new functional disability).
Contextualizing Hospital Care Within a Longitudinal Trajectory
Although we described the benefit of hospital episodes having well‐demarcated beginning and ending points, it remains essential to recognize that the harms associated with hospitalization extend well beyond discharge. In this context, hospitalizations can serve as waypoints in patients' health trajectories as well as an opportunity to achieve patient‐centered care including discussing and aligning goals of care with actual care provision. Furthermore, although we have seen steady declines in hospital mortality over time, it is highly likely that we will reach a nadir in mortality where additional metrics of hospital outcomes will need to include postdischarge events like readmission, long‐term mortality, quality of life, and the prevention of disability or decline.
CONCLUSION
Hospitalizations in the United States are costly and associated with high mortality and morbidity; the toll of hospitalization also extends well beyond hospital discharge. The promise of the learning hospital system has marked improvements in the quality of hospital care, especially where healthcare systems can steep critical investments in data and digital infrastructure within the right culture, incentives, and leadership. Where continuous learning is achieved, data generated during routine care offer the potential to yield new scientific discovery and drive further improvements in hospital care.
Disclosures
As part of our agreement with the Gordon and Betty Moore Foundation, we made a commitment to disseminate our findings in articles such as this one. However, the Foundation and its staff played no role in how we actually structured our articles, nor did they review or preapprove any of the manuscripts submitted as part of the dissemination component. None of the authors has any conflicts of interest to declare of relevance to this work, which was funded by a combination of funding from the Gordon and Betty Moore Foundation, The Permanente Medical Group, Inc., and Kaiser Foundation Hospitals, Inc. VXL was supported by NIH K23GM112018.
- Institute of Medicine. Best Care at Lower Cost: The Path to Continuously Learning Health Care in America. Washington, DC: The National Academies Press; 2012.
- , , , et al. Toward a science of learning systems: a research agenda for the high‐functioning Learning Health System. J Am Med Inform Assoc. 2015;22(1):43–50.
- National Center for Health Statistics. Health, United States, 2014: With Special Feature on Adults Aged 55–64. Hyattsville, MD; 2015.
- , . Critical care medicine in the United States 2000‐2005: an analysis of bed numbers, occupancy rates, payer mix, and costs. Crit Care Med. 2010;38(1):65–71.
- , , , . Trends and variation in end‐of‐life care for medicare beneficiaries with severe chronic illness. A report of the Dartmouth Atlas Project. Lebanon, NH: The Dartmouth Institute for Health Policy and Clinical Practice; 2011.
- , , , et al. Change in end‐of‐life care for Medicare beneficiaries: site of death, place of care, and health care transitions in 2000, 2005, and 2009. JAMA. 2013;309(5):470–477.
- , , . Finding the missing link for big biomedical data. JAMA. 2014;311(24):2479–2480.
- . Code red and blue—safely limiting health care's GDP footprint. N Engl J Med. 2013;368(1):1–3.
- , . The inevitable application of big data to health care. JAMA. 2013;309(13):1351–1352.
- , . What is citizen science?—a scientometric meta‐analysis. PLoS One. 2016;11(1):e0147152.
- , , . Biomedical ontologies: a functional perspective. Brief Bioinform. 2008;9(1):75–90.
- . Rapid learning: a breakthrough agenda. Health Aff (Millwood). 2014;33(7):1155–1162.
- , , , et al. Are regional variations in end‐of‐life care intensity explained by patient preferences?: a study of the US Medicare population. Med Care. 2007;45(5):386–393.
- , . Extreme markup: the fifty US hospitals with the highest charge‐to‐cost ratios. Health Aff (Millwood). 2015;34(6):922–928.
- , , , . The price ain't right? Hospital prices and health spending on the privately insured. Health Care Pricing Project website. Available at: http://www.healthcarepricingproject.org/sites/default/files/pricing_variation_manuscript_0.pdf. Accessed February 15, 2016
- . A new, evidence‐based estimate of patient harms associated with hospital care. J Patient Saf. 2013;9(3):122–128.
- , , . Hospitalization‐associated disability: “she was probably able to ambulate, but I'm not sure”. JAMA. 2011;306(16):1782–1793.
- , , , , . Risk‐adjusting hospital mortality using a comprehensive electronic record in an integrated health care delivery system. Med Care. 2013;51(5):446–453.
- . New definitions for sepsis and septic shock: continuing evolution but with much still to be done. JAMA. 2016;315(8):757–759.
- , . Severe sepsis and septic shock. N Engl J Med. 2013;369(21):2063.
- , , . Sepsis‐induced immunosuppression: from cellular dysfunctions to immunotherapy. Nat Rev Immunol. 2013;13(12):862–874.
- , , , et al. Early goal‐directed therapy in the treatment of severe sepsis and septic shock. N Engl J Med. 2001;345(19):1368–1377.
- , , , et al. Kaiser Permanente's performance improvement system, part 3: multisite improvements in care for patients with sepsis. Jt Comm J Qual Patient Saf. 2011;37(11):483–493.
- , , , , . Understanding the components of quality improvement collaboratives: a systematic literature review. Milbank Q. 2013;91(2):354–394.
- , , , et al. Hospital deaths in patients with sepsis from 2 independent cohorts. JAMA. 2014;312(1):90–92.
- , , , et al. Assessment of clinical criteria for sepsis: for the Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):762–774.
- , , , et al. Developing a new definition and assessing new clinical criteria for septic shock: for the Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):775–787.
- , , , et al. The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):801–810.
- , , , . Long‐term cognitive impairment and functional disability among survivors of severe sepsis. JAMA. 2010;304(16):1787–1794.
- . The lingering consequences of sepsis: a hidden public health disaster? JAMA. 2010;304(16):1833–1834.
- , , , , , . Hospital readmission and healthcare utilization following sepsis in community settings. J Hosp Med. 2014;9(8):502–507.
- , , , , . Increased 1‐year healthcare use in survivors of severe sepsis. Am J Respir Crit Care Med. 2014;190(1):62–69.
- , , , et al. Post‐acute care use and hospital readmission after sepsis. Ann Am Thorac Soc. 2015;12(6):904–913.
- , , , , . Fluid volume, lactate values, and mortality in sepsis patients with intermediate lactate values. Ann Am Thorac Soc. 2013;10(5):466–473.
- , , . Prognosis of emergency department patients with suspected infection and intermediate lactate levels: a systematic review. J Crit Care. 2014;29(3):334–339.
- , , , et al. Multicenter implementation of a treatment bundle for sepsis patients with intermediate lactate values. Am J Respir Crit Care Med. 2016;193(11):1264–1270.
- , , , et al. Risk adjusting community‐acquired pneumonia hospital outcomes using automated databases. Am J Manag Care. 2008;14(3):158–166.
- , , , , , . Intra‐hospital transfers to a higher level of care: contribution to total hospital and intensive care unit (ICU) mortality and length of stay (LOS). J Hosp Med. 2011;6(2):74–80.
- , , , , , . Early detection of impending physiologic deterioration among patients who are not in intensive care: development of predictive models using data from an automated electronic medical record. J Hosp Med. 2012;7(5):388–395.
- , , , , . An electronic Simplified Acute Physiology Score‐based risk adjustment score for critical illness in an integrated healthcare system. Crit Care Med. 2013;41(1):41–48.
- . Learning from big health care data. N Engl J Med. 2014;370(23):2161–2163.
- , . Getting the methods right—the foundation of patient‐centered outcomes research. N Engl J Med. 2012;367(9):787–790.
- , , , , . The stepped wedge cluster randomised trial: rationale, design, analysis, and reporting. BMJ. 2015;350:h391.
- . Fusing randomized trials with big data: the key to self‐learning health care systems? JAMA. 2015;314(8):767–768.
In the landmark Best Care at Lower Cost report, the Institute of Medicine presents a compelling vision of a US healthcare system where science, information technology, incentives, and care culture are brought together seamlessly to produce high‐quality healthcare.[1] At the center of this transformation is the learning healthcare system, a system characterized by its ability to leverage data arising from care provision to drive rapid improvements in care delivery.[2] When steeped within the right organizational milieu, these data help to close the virtuous cycle of continuous learning moving from science to evidence to care and back to new science. The anticipated end result is a healthcare system that can provide Americans with superior care at lower cost.
Hospital‐based practitioners will recognize the inpatient setting as an ideal demonstration opportunity for continuous learning. Hospital care is costly, accounting for more than 30% of all US healthcare costs[3]; intensive care alone accounts for a notable proportion of the US gross domestic product.[4] Inpatient care is associated with significant mortality and morbidity, and its use is often greatly increased in patients' last days.[5, 6] Fortunately, the inpatient setting also offers an ideal opportunity to leverage high‐quality data to help inform and improve care. The digitization of medicine means that far more data are now available through electronic health records, medical devices, and tests.[7] This is particularly true for inpatients, for whom a large volume of data are produced even over relatively short hospital stays.
Whereas the challenge to improve hospital care is daunting, there is an incredible opportunity to advance the quality of inpatient care through realizing the vision of the learning hospital system. In the sections that follow, we use an object lessonsepsis care within hospitals of the Kaiser Permanente Northern California (KPNC) integrated healthcare delivery systemto evaluate the challenges and insights gleaned from working toward building a learning hospital system. Then, we describe further steps that could enhance the use of inpatient data to drive improved care.
THE FRAMEWORK OF A LEARNING HEALTHCARE SYSTEM
Best Care at Lower Cost notes a fundamental paradox in US healthcare: although we have witnessed a dramatic expansion in biomedical knowledge, innovative therapies and surgical procedures, and clinical treatments to extend survival, US healthcare persistently falls short on the basic dimensions of quality, outcomes, cost, and equity.[1] The proposed path forward lies in building the learning healthcare system, a system characterized by continuous knowledge development, improvement, and application. Figure 1 shows the critical nodes in the framework for continuous learning, which include: (1) the development of new scientific knowledge (science), (2) the translation of science into clinical evidence of efficacy (evidence), and (3) the application of efficacious interventions through effective care delivery (care). In healthcare today, transitions between these nodes are rife with missed or wasted opportunities like delays in applying high‐quality evidence or poorly managed insights arising from scientific discovery. If such opportunities could be recovered, however, the quality of healthcare could be improved dramatically.[8]
The pursuit of continuous learning is aided by rapid changes in the quality and quantity of biomedical data available over the past decade, especially through the use of electronic health records, novel biomolecular tools, and digital sensors.[2, 7, 9] The Internet has ushered in a new era of data connectivity, for example, allowing for highly engaged communication between patients and providers as well as collaboration between professional or citizen scientists on data of unprecedented scale.[10] New methodologic approaches, including data mining and machine learning, increasingly leverage commodity hardware to conduct previously computationally intractable analyses.[9] Moreover, the development of domain ontologies fosters the discovery of meaningful insights from data of heterogeneous types.[11]
Ultimately, however, improvements in data alone are inadequate to achieve continuous learning. As shown in Figure 1, whereas data form the channels that allow for transitions from science to evidence to care, novel insights need to be steeped within the right culture, motivated by the right incentives, and supported by the right leaders.[1, 12] Within the sustainable learning healthcare system, knowledge generation feeds practice change with the support and guidance of system leadership; improved practice, in turn, generates new knowledge and completes the virtuous cycle of learning.
THE PROMISE OF CONTINUOUS LEARNING IN HOSPITAL SETTINGS
The hospital is an ideal setting in which to foster continuous learning because advances in inpatient care have the potential to substantially improve healthcare quality and value.[8] Americans were hospitalized roughly 37 million times in 2012; in total, these episodes cost $378 billion.[3] Over 700,000 patients die in US hospitals annually, with reports showing that many patients utilize greatly increased inpatient and critical care services near the end of their lives in a manner that appears misaligned with their preferences.[11, 13] Hospital care is also highly variable in quality and cost; this heterogeneity is not closely associated with improved outcomes.[14, 15] Preventable harm and medical injury occur commonly in hospitals and are now recognized to be a leading cause of inpatient death.[16] Finally, emerging research illuminates the substantial toll that acute care has on patients and families resulting in new comorbidity, functional or neuropsychiatric impairment, rehospitalization, and financial burden that persist long after patients are discharged.[17]
Fortunately, inpatient care also exhibits several qualities that improve the likelihood that continuous learning can be achieved. Although it is clear that hospitalizations occur within the arc of a patient's larger health trajectory, these distinct episodes offer the potential to observe patient trajectories and treatments evolving within relatively compressed time intervals; over that same interval, a large volume of data are produced. Stored within comprehensive electronic health records, these granular data now allow inpatient episodes to be digitally recapitulated with high fidelity, bolstering their use in driving care improvements.[18]
AN OBJECT LESSON IN THE LEARNING FRAMEWORK: SEPSIS CARE
Translating Science to Evidence in Sepsis
Although sepsis has attracted great attention in modern hospital care, sepsis was described long ago by Hippocrates to describe the process by which wounds fester.[19] Recast after the confirmation of germ theory, sepsis came to be known primarily as the blood poisoning resulting from pathogenic organisms.[20] However, with the advent of antibiotics, numerous scientific studies now recognize that sepsis actually results from the dysregulated host immune response to systemic infection, which can also cause organ dysfunction.[21] Based on this knowledge, landmark translational and clinical studies in the 2000s provided strong evidence that early identification of sepsis patients and aggressive infection control and resuscitation were associated with improved mortality (Figure 2, step 1).[22]
Translating Evidence to Care in Sepsis at KPNC
In 2007, the leadership of KPNC initiated a regional effort to improve the quality of care and reduce the variability in performance at its medical centers (Table 1).[23] Reviewing data from nearly 1000 inpatientsthe last 50 consecutive hospital deaths from each of 19 medical centersa mortality diagnostic based on Institute for Healthcare Improvement recommendations[24] revealed that sepsis had a major impact on hospital outcomes. For example, even though sepsis patients were still relatively under‐recognized at the time, accounting for fewer than 3% of hospitalizations, they contributed to one‐quarter of hospital deaths. In light of these compelling data, senior regional leadership identified reducing sepsis mortality as a key performance improvement goal (Figure 2, step 2).
| Time Period | Event Summary |
|---|---|
| |
| 2007 | Variability in hospital standardized mortality ratio observed, indicating an opportunity to drive improved outcomes. |
| Initiation of staggered implementation of unified electronic medical record across all KP sites (starting in 2006 and ending in 2009). | |
| Spring 2008 | Mortality diagnostic chart review completed identifying sepsis and infection‐related causes as key factors in hospital outcomes. |
| May 2008 | Regional Mortality Summit held with a focus on patient safety and mortality reduction efforts through performance improvement. Executive regional and local leadership alignment to focus on sepsis performance improvement. |
| Summer 2008 | Sepsis Steering Committee evaluates best available evidence, develops treatment algorithms, and plans for medical center pilots. |
| Fall 2008 | Pilot intervention deployed at 2 medical centers. |
| November 2008 | First Regional Sepsis Summit: development of sepsis performance improvement playbook, training materials, implementation plans, and measurement strategy. |
| November 2008 | All medical centers begin to form multidisciplinary sepsis teams and performance improvement committees, obtain equipment and supplies including assembly of a sepsis cart. Multidisciplinary teams included ED physician champion, ED nurse champion, improvement advisor, hospitalists, intensivists, quality improvement personnel, nurse educators, and even resident physicians. |
| January 2009 | Performance data collection begins on EGDT processes and outcomes. Initiation of 2 key elements to enhance screening for and detection of sepsis: (1) concomitant ordering of serum lactic acid along with blood cultures, and (2) definition of lactate >2.0 as a critical lab value. |
| Use of manual chart review for case finding and central database entry because of ongoing implementation of electronic medical record and limited sepsis‐specific data infrastructure. | |
| March 2009 | Regional train the trainer sessions occur and local educational spread efforts begin including: collaborative calls, in‐person training events, and medical center site visits. |
| August 2009 | Grant funding from the Gordon and Betty Moore Foundation begins with a planned 2‐year duration providing funding for improvement advisors with performance improvement expertise and data infrastructure development. |
| November 2009 | Second Regional Sepsis Summit. Identification of intermediate lactate sepsis patients having significant mortality. |
| January 2010 | Initiate measurement of performance for intermediate lactate sepsis patients with a focus on lactate clearance as an outcome measure of interest. |
| 2010 | Development of an intranet Web‐based data abstraction tool to identify cases and auto‐populate specific fields for review. Facilities were responsible for review of cases at the local level to foster rapid feedback cycles for local performance improvement. Standardized data query tools were deployed to foster local medical center engagement and system‐level evaluation. |
| Accompanying development of a sepsis performance improvement scorecard allowing for comparison of longitudinal performance metrics across all facilities. Scorecard elements included: proportion of lactates drawn following ED blood culture, EGDT‐specific bundle elements (ie, number of EGDT cases, antibiotics within 1 hour, first central venous pressure within 2 hours of EGDT start, target mean arterial pressure achievement), repeat lactate elements, balancing measures for central line placement (ie, pneumothorax, central line infection), and overall sepsis statistics. | |
| April 2011 | Third Regional Sepsis Summit. Refinement of EGDT bundle and further development of intermediate lactate bundle approach, including piloting specific treatment bundles targeting this population. Collaborative performance improvement environment in which successful strategies at 1 site were rapidly disseminated to other sites including the Sepsis Alert and the Sepsis Clock. |
| May 2012 | Research analysis of fluid volume and lactate clearance in intermediate lactate sepsis population begins. |
| February 2013 | Fourth Regional Sepsis Summit. Regional spread of intermediate lactate bundle including the use of fluids, antibiotics, and repeat lactate measurements. |
| May 2013 | Research analysis of the contribution of sepsis to hospital deaths (within KP and in national sample) as well as post‐sepsis resource utilization and mortality |
| March 2014 | Publication of ProCESS randomized clinical trial, requiring systemic reevaluation of EGDT‐based sepsis strategy. Subsequent publications of ARISE and ProMISe trials confirming findings from ProCESS. Updated approach under consideration and informally disseminated to practitioners. |
| October 2014 | Updated sepsis treatment guidelines and data capture strategy fully implemented moving away from a catheter‐based strategy for all EGDT‐eligible patients. |
| October 2015 | Sixth Regional Sepsis Summit held to adjust sepsis treatment and data measurement strategy to align more closely with CMS SEP‐1 guidelines. |
Based on the principles of performance improvement methodology, clinical and operational leaders established an environment with aligned culture, incentives, and leadership around sepsis care. The effort was launched in late 2008 at a Sepsis Summit, bringing together a multidisciplinary group of stakeholders (eg, hospitalist, emergency department, and intensive care chiefs of staff and nursing managers; medical center and nursing executive and operational leadership) and providing sepsis care pathways based on the best available evidence.[23] Regional investments in the digital infrastructure to support implementation resulted in the provision of granular data within monthly sepsis scorecards quantifying each medical center's performance and trends for a diverse set of sepsis bundle metrics.
The resulting changes in sepsis care were substantial. For example, improved early recognition of infected patients meeting the criteria for sepsis resulted in large changes in the standardized diagnostic criteria used to label patients (Figure 3A). Implementing screening strategies using serum lactate testing for any patient receiving blood cultures resulted in a roughly 10‐fold increase in the use of lactate testing in the emergency department (Figure 3B). Earlier recognition of sepsis also increased the number of patients receiving early antibiotics and receiving central venous catheters for quantitative resuscitation.[23]
CLOSING THE LOOP TOWARD CONTINUOUS LEARNING IN SEPSIS
Leveraging timely and actionable data steeped within an aligned organizational milieu resulted in large‐scale changes across a heterogeneous set of hospitals. However, to realize the true vision of a learning hospital system, a looming question remained: Could the data generated as the byproduct of routine care now be used to complete the virtuous cycle and drive new scientific discovery (Figure 2, step 3)?
Confirming Concordance in the Impact of Sepsis Nationally
The heightened identification of sepsis patients through program implementation revealed that the impact of sepsis on hospital mortality was greater than originally estimated; based on improved patient identification, sepsis now accounted for upward of 1 in 2 hospital deaths.[25] This sobering statistic confirmed that the investments in standardizing best sepsis care following the mortality diagnostic were critical. However, were similar estimates of sepsis‐attributable mortality consistent outside of the KPNC system? To study this, we examined US hospitalizations occurring across >1000 hospitals and involving >6 million hospital stays to estimate corresponding prevalence.[25] In this national sample, sepsis contributed to as many as half of hospital deaths in the United States in 2010, lending strong support to ongoing international and state‐based efforts to improve sepsis care. These studies also paved the way to use these data drawn from our large sepsis population to inform updated international consensus definitions for sepsis and septic shock.[26, 27, 28]
Identifying New Avenues for Reducing the Toll of Sepsis
A major concern of sepsis program leaders was the prior findings that sepsis hospitalizations among Medicare beneficiaries were associated with substantial new cognitive and functional disability.[29] This lingering toll of sepsis had been termed a hidden public health disaster.[30] To further understand the posthospital impact of sepsis and to begin investigating new avenues to reduce this impact, a cohort of patients was followed for 1 year following sepsis hospitalization.[31] Over that period, nearly half of sepsis survivors were rehospitalized. When compared with their presepsis levels of healthcare utilization, middle‐aged and elderly sepsis patients experienced a 3‐fold increase in their days using facility‐based care. Subsequent studies in other populations outside of KPNC have confirmed these concerning findings, resulting in new efforts to address postsepsis survivorship care.[32, 33]
Phenotyping New Targets for Standardized Sepsis Care
At its outset, the sepsis improvement program applied the best available evidence to treat patients with the most severe forms of sepsisseptic shock. However, once the initial implementation phase had succeeded, clinicians and operational leaders quickly realized from the emerging data that there was a far larger group of sepsis patients for whom treatment guidelines were poorly defined.[25, 34, 35] These were severe sepsis patients with so‐called intermediate lactate values between 2 mmol/L and 4 mmol/L; they comprised a substantial proportion of all sepsis patients dying in the hospital. Using data generated from the routine care of sepsis patients treated across 21 hospitals, the sepsis leadership group was able to rapidly assemble a cohort of intermediate lactate sepsis patients up to 20‐ to 100‐fold larger than that reported in prior studies and evaluate their outcomes.[34, 35]
The data used to evaluate these intermediate lactate sepsis patients now spurred a new implementation program in 2013 for a group of patients in whom there was essentially no existing evidence to guide care. Rapidly implemented within a mature sepsis performance improvement program, evaluations at the 6‐month and 1‐year intervals demonstrated significant decreases in mortality.[36] Importantly, to allay the justified concerns of clinicians, these evaluations also clearly showed no evidence of harm from more aggressive fluid resuscitation (eg, increased transfer to intensive care, increased rates of mechanical ventilation). Again, driven by clinician input, subgroup analyses further revealed that the implementation program was only associated with reduced mortality in patients who could be at risk for iatrogenic fluid overload (ie, those with a history of congestive heart failure or chronic kidney disease).[36] Spurred by these provocative findings, operational and clinical leaders are currently considering how to guide future care in these patients, especially with the emerging use of noninvasive methods to quantify patients' fluid responsiveness.
PRINCIPLES FOR LEVERAGING DATA IN THE LEARNING HOSPITAL SYSTEM
The object lesson of using data to drive improved sepsis care and further new scientific discovery offers some important insights for continuous learning.
Building a Digital Infrastructure for Utilizing Granular Hospital Data
As described above, current transitions between the nodes of the learning framework are rife with missed opportunities. Perhaps one of the most glaring is the inability to use highly granular data already collected within the electronic health record (eg, trajectories and trends across vital signs or laboratory results, large‐scale medication administration records to evaluate multidrug interactions). An essential starting point for continuous learning is investing in the digital infrastructure to improve the use of data beyond traditional claims (administrative dataadmission source codes, disposition codes, diagnoses, and procedures). As shown in Table 2, the first key step is incorporating laboratory data into the quality assessment/emmprovement process. In addition, using these data to automate severity of illness and risk adjustment metrics fosters use of similar comparison cohorts across time or disease types.[18, 37, 38, 39, 40]
| Data Type | Contents | Degree of Difficulty in Accessing | Degree of Difficulty in Analyzing |
|---|---|---|---|
| Administrative | Traditional claims data, diagnostic or procedural codes | Low | Low to moderate |
| Standard cohort profiling | Limited instances of vitals signs, laboratory, diagnostic testing, or treatment data | Low to moderate | Low to moderate |
| Metrics reporting for care improvement | Standard cohort identification, aggregated achievement of treatment targets, scorecard dissemination | Moderate | Moderate |
| Advanced cohort profiling | Time series of physiologic data, inpatient triage and treatment data within short temporal intervals | Moderate to high | High |
| Research‐grade discovery | Data with breadth (representative sample size) and depth (highly granular physiologic and treatment data) | High | Very high |
| Patient‐reported outcomes | Quality of life, functional and cognitive disability | Very high | High |
Employing Novel Methods to Address the Limitations of Using Real‐World Data
The rapid digitization of medicine through the use of electronic medical records offers tremendous opportunities to facilitate continuous learning. However, these opportunities are accompanied by important limitations.[41] Data collected as a byproduct of real‐world care can be vulnerable to many forms of bias and confounding, potentially clouding the validity and robustness of corresponding analytic results. Fortunately, advanced methods including causal inference are now used routinely to address some limitations.[42] In the context of a learning healthcare system, other opportunities for improved study design including cluster randomized trials or stepped wedge implementation can also be employed to preserve the statistical rigor of subsequent analyses.[43] Finally, emerging methods employing randomization through the electronic medical record alongside adaptive trial design offer great potential to increase the efficiency of continuous learning.[44]
Evaluating the Hospital as a Single System
Advances in contemporary hospital care require seamless transitions of patient care, screening strategies, and therapeutic approaches across multiple hospital domains and with diverse providers; these interventions also need to happen rapidly. Many traditional approaches to inpatient care have taken a bottom‐up approach (eg, studying a specific disease within a specific hospital ward like the intensive care unit) that have proven useful but may limit generalizability when applied to a real‐world hospital operating with Pareto optimality (ie, the trade‐off scenario where new resource allocation to 1 area also requires resource withdrawal from another area). In certain cases, an empiric approach, without initial preference for any specific ward or disease, can aid decision making by hospital operational and clinical leaders by providing a global picture of impact and value.
Focusing on Early Detection in Hospital Settings as Secondary Prevention
Once patients have been admitted to the hospital, a race against the clock begins. Each additional hour of hospitalization increases the risks of iatrogenic injury or medical harm manifested by immobility, disorientation and delirium, nosocomial infections, or medication errors, among others. In this context, detection systems that use granular hospital data to focus on the earliest detection of risk can aid critical approaches to secondary prevention (Although the hospitalization for sepsis cannot be avoided, careful attention to mobility can limit the risk of developing delirium. In turn, preventing delirium can limit the risk of new functional disability).
Contextualizing Hospital Care Within a Longitudinal Trajectory
Although we described the benefit of hospital episodes having well‐demarcated beginning and ending points, it remains essential to recognize that the harms associated with hospitalization extend well beyond discharge. In this context, hospitalizations can serve as waypoints in patients' health trajectories as well as an opportunity to achieve patient‐centered care including discussing and aligning goals of care with actual care provision. Furthermore, although we have seen steady declines in hospital mortality over time, it is highly likely that we will reach a nadir in mortality where additional metrics of hospital outcomes will need to include postdischarge events like readmission, long‐term mortality, quality of life, and the prevention of disability or decline.
CONCLUSION
Hospitalizations in the United States are costly and associated with high mortality and morbidity; the toll of hospitalization also extends well beyond hospital discharge. The promise of the learning hospital system has marked improvements in the quality of hospital care, especially where healthcare systems can steep critical investments in data and digital infrastructure within the right culture, incentives, and leadership. Where continuous learning is achieved, data generated during routine care offer the potential to yield new scientific discovery and drive further improvements in hospital care.
Disclosures
As part of our agreement with the Gordon and Betty Moore Foundation, we made a commitment to disseminate our findings in articles such as this one. However, the Foundation and its staff played no role in how we actually structured our articles, nor did they review or preapprove any of the manuscripts submitted as part of the dissemination component. None of the authors has any conflicts of interest to declare of relevance to this work, which was funded by a combination of funding from the Gordon and Betty Moore Foundation, The Permanente Medical Group, Inc., and Kaiser Foundation Hospitals, Inc. VXL was supported by NIH K23GM112018.
In the landmark Best Care at Lower Cost report, the Institute of Medicine presents a compelling vision of a US healthcare system where science, information technology, incentives, and care culture are brought together seamlessly to produce high‐quality healthcare.[1] At the center of this transformation is the learning healthcare system, a system characterized by its ability to leverage data arising from care provision to drive rapid improvements in care delivery.[2] When steeped within the right organizational milieu, these data help to close the virtuous cycle of continuous learning moving from science to evidence to care and back to new science. The anticipated end result is a healthcare system that can provide Americans with superior care at lower cost.
Hospital‐based practitioners will recognize the inpatient setting as an ideal demonstration opportunity for continuous learning. Hospital care is costly, accounting for more than 30% of all US healthcare costs[3]; intensive care alone accounts for a notable proportion of the US gross domestic product.[4] Inpatient care is associated with significant mortality and morbidity, and its use is often greatly increased in patients' last days.[5, 6] Fortunately, the inpatient setting also offers an ideal opportunity to leverage high‐quality data to help inform and improve care. The digitization of medicine means that far more data are now available through electronic health records, medical devices, and tests.[7] This is particularly true for inpatients, for whom a large volume of data are produced even over relatively short hospital stays.
Whereas the challenge to improve hospital care is daunting, there is an incredible opportunity to advance the quality of inpatient care through realizing the vision of the learning hospital system. In the sections that follow, we use an object lessonsepsis care within hospitals of the Kaiser Permanente Northern California (KPNC) integrated healthcare delivery systemto evaluate the challenges and insights gleaned from working toward building a learning hospital system. Then, we describe further steps that could enhance the use of inpatient data to drive improved care.
THE FRAMEWORK OF A LEARNING HEALTHCARE SYSTEM
Best Care at Lower Cost notes a fundamental paradox in US healthcare: although we have witnessed a dramatic expansion in biomedical knowledge, innovative therapies and surgical procedures, and clinical treatments to extend survival, US healthcare persistently falls short on the basic dimensions of quality, outcomes, cost, and equity.[1] The proposed path forward lies in building the learning healthcare system, a system characterized by continuous knowledge development, improvement, and application. Figure 1 shows the critical nodes in the framework for continuous learning, which include: (1) the development of new scientific knowledge (science), (2) the translation of science into clinical evidence of efficacy (evidence), and (3) the application of efficacious interventions through effective care delivery (care). In healthcare today, transitions between these nodes are rife with missed or wasted opportunities like delays in applying high‐quality evidence or poorly managed insights arising from scientific discovery. If such opportunities could be recovered, however, the quality of healthcare could be improved dramatically.[8]
The pursuit of continuous learning is aided by rapid changes in the quality and quantity of biomedical data available over the past decade, especially through the use of electronic health records, novel biomolecular tools, and digital sensors.[2, 7, 9] The Internet has ushered in a new era of data connectivity, for example, allowing for highly engaged communication between patients and providers as well as collaboration between professional or citizen scientists on data of unprecedented scale.[10] New methodologic approaches, including data mining and machine learning, increasingly leverage commodity hardware to conduct previously computationally intractable analyses.[9] Moreover, the development of domain ontologies fosters the discovery of meaningful insights from data of heterogeneous types.[11]
Ultimately, however, improvements in data alone are inadequate to achieve continuous learning. As shown in Figure 1, whereas data form the channels that allow for transitions from science to evidence to care, novel insights need to be steeped within the right culture, motivated by the right incentives, and supported by the right leaders.[1, 12] Within the sustainable learning healthcare system, knowledge generation feeds practice change with the support and guidance of system leadership; improved practice, in turn, generates new knowledge and completes the virtuous cycle of learning.
THE PROMISE OF CONTINUOUS LEARNING IN HOSPITAL SETTINGS
The hospital is an ideal setting in which to foster continuous learning because advances in inpatient care have the potential to substantially improve healthcare quality and value.[8] Americans were hospitalized roughly 37 million times in 2012; in total, these episodes cost $378 billion.[3] Over 700,000 patients die in US hospitals annually, with reports showing that many patients utilize greatly increased inpatient and critical care services near the end of their lives in a manner that appears misaligned with their preferences.[11, 13] Hospital care is also highly variable in quality and cost; this heterogeneity is not closely associated with improved outcomes.[14, 15] Preventable harm and medical injury occur commonly in hospitals and are now recognized to be a leading cause of inpatient death.[16] Finally, emerging research illuminates the substantial toll that acute care has on patients and families resulting in new comorbidity, functional or neuropsychiatric impairment, rehospitalization, and financial burden that persist long after patients are discharged.[17]
Fortunately, inpatient care also exhibits several qualities that improve the likelihood that continuous learning can be achieved. Although it is clear that hospitalizations occur within the arc of a patient's larger health trajectory, these distinct episodes offer the potential to observe patient trajectories and treatments evolving within relatively compressed time intervals; over that same interval, a large volume of data are produced. Stored within comprehensive electronic health records, these granular data now allow inpatient episodes to be digitally recapitulated with high fidelity, bolstering their use in driving care improvements.[18]
AN OBJECT LESSON IN THE LEARNING FRAMEWORK: SEPSIS CARE
Translating Science to Evidence in Sepsis
Although sepsis has attracted great attention in modern hospital care, sepsis was described long ago by Hippocrates to describe the process by which wounds fester.[19] Recast after the confirmation of germ theory, sepsis came to be known primarily as the blood poisoning resulting from pathogenic organisms.[20] However, with the advent of antibiotics, numerous scientific studies now recognize that sepsis actually results from the dysregulated host immune response to systemic infection, which can also cause organ dysfunction.[21] Based on this knowledge, landmark translational and clinical studies in the 2000s provided strong evidence that early identification of sepsis patients and aggressive infection control and resuscitation were associated with improved mortality (Figure 2, step 1).[22]
Translating Evidence to Care in Sepsis at KPNC
In 2007, the leadership of KPNC initiated a regional effort to improve the quality of care and reduce the variability in performance at its medical centers (Table 1).[23] Reviewing data from nearly 1000 inpatientsthe last 50 consecutive hospital deaths from each of 19 medical centersa mortality diagnostic based on Institute for Healthcare Improvement recommendations[24] revealed that sepsis had a major impact on hospital outcomes. For example, even though sepsis patients were still relatively under‐recognized at the time, accounting for fewer than 3% of hospitalizations, they contributed to one‐quarter of hospital deaths. In light of these compelling data, senior regional leadership identified reducing sepsis mortality as a key performance improvement goal (Figure 2, step 2).
| Time Period | Event Summary |
|---|---|
| |
| 2007 | Variability in hospital standardized mortality ratio observed, indicating an opportunity to drive improved outcomes. |
| Initiation of staggered implementation of unified electronic medical record across all KP sites (starting in 2006 and ending in 2009). | |
| Spring 2008 | Mortality diagnostic chart review completed identifying sepsis and infection‐related causes as key factors in hospital outcomes. |
| May 2008 | Regional Mortality Summit held with a focus on patient safety and mortality reduction efforts through performance improvement. Executive regional and local leadership alignment to focus on sepsis performance improvement. |
| Summer 2008 | Sepsis Steering Committee evaluates best available evidence, develops treatment algorithms, and plans for medical center pilots. |
| Fall 2008 | Pilot intervention deployed at 2 medical centers. |
| November 2008 | First Regional Sepsis Summit: development of sepsis performance improvement playbook, training materials, implementation plans, and measurement strategy. |
| November 2008 | All medical centers begin to form multidisciplinary sepsis teams and performance improvement committees, obtain equipment and supplies including assembly of a sepsis cart. Multidisciplinary teams included ED physician champion, ED nurse champion, improvement advisor, hospitalists, intensivists, quality improvement personnel, nurse educators, and even resident physicians. |
| January 2009 | Performance data collection begins on EGDT processes and outcomes. Initiation of 2 key elements to enhance screening for and detection of sepsis: (1) concomitant ordering of serum lactic acid along with blood cultures, and (2) definition of lactate >2.0 as a critical lab value. |
| Use of manual chart review for case finding and central database entry because of ongoing implementation of electronic medical record and limited sepsis‐specific data infrastructure. | |
| March 2009 | Regional train the trainer sessions occur and local educational spread efforts begin including: collaborative calls, in‐person training events, and medical center site visits. |
| August 2009 | Grant funding from the Gordon and Betty Moore Foundation begins with a planned 2‐year duration providing funding for improvement advisors with performance improvement expertise and data infrastructure development. |
| November 2009 | Second Regional Sepsis Summit. Identification of intermediate lactate sepsis patients having significant mortality. |
| January 2010 | Initiate measurement of performance for intermediate lactate sepsis patients with a focus on lactate clearance as an outcome measure of interest. |
| 2010 | Development of an intranet Web‐based data abstraction tool to identify cases and auto‐populate specific fields for review. Facilities were responsible for review of cases at the local level to foster rapid feedback cycles for local performance improvement. Standardized data query tools were deployed to foster local medical center engagement and system‐level evaluation. |
| Accompanying development of a sepsis performance improvement scorecard allowing for comparison of longitudinal performance metrics across all facilities. Scorecard elements included: proportion of lactates drawn following ED blood culture, EGDT‐specific bundle elements (ie, number of EGDT cases, antibiotics within 1 hour, first central venous pressure within 2 hours of EGDT start, target mean arterial pressure achievement), repeat lactate elements, balancing measures for central line placement (ie, pneumothorax, central line infection), and overall sepsis statistics. | |
| April 2011 | Third Regional Sepsis Summit. Refinement of EGDT bundle and further development of intermediate lactate bundle approach, including piloting specific treatment bundles targeting this population. Collaborative performance improvement environment in which successful strategies at 1 site were rapidly disseminated to other sites including the Sepsis Alert and the Sepsis Clock. |
| May 2012 | Research analysis of fluid volume and lactate clearance in intermediate lactate sepsis population begins. |
| February 2013 | Fourth Regional Sepsis Summit. Regional spread of intermediate lactate bundle including the use of fluids, antibiotics, and repeat lactate measurements. |
| May 2013 | Research analysis of the contribution of sepsis to hospital deaths (within KP and in national sample) as well as post‐sepsis resource utilization and mortality |
| March 2014 | Publication of ProCESS randomized clinical trial, requiring systemic reevaluation of EGDT‐based sepsis strategy. Subsequent publications of ARISE and ProMISe trials confirming findings from ProCESS. Updated approach under consideration and informally disseminated to practitioners. |
| October 2014 | Updated sepsis treatment guidelines and data capture strategy fully implemented moving away from a catheter‐based strategy for all EGDT‐eligible patients. |
| October 2015 | Sixth Regional Sepsis Summit held to adjust sepsis treatment and data measurement strategy to align more closely with CMS SEP‐1 guidelines. |
Based on the principles of performance improvement methodology, clinical and operational leaders established an environment with aligned culture, incentives, and leadership around sepsis care. The effort was launched in late 2008 at a Sepsis Summit, bringing together a multidisciplinary group of stakeholders (eg, hospitalist, emergency department, and intensive care chiefs of staff and nursing managers; medical center and nursing executive and operational leadership) and providing sepsis care pathways based on the best available evidence.[23] Regional investments in the digital infrastructure to support implementation resulted in the provision of granular data within monthly sepsis scorecards quantifying each medical center's performance and trends for a diverse set of sepsis bundle metrics.
The resulting changes in sepsis care were substantial. For example, improved early recognition of infected patients meeting the criteria for sepsis resulted in large changes in the standardized diagnostic criteria used to label patients (Figure 3A). Implementing screening strategies using serum lactate testing for any patient receiving blood cultures resulted in a roughly 10‐fold increase in the use of lactate testing in the emergency department (Figure 3B). Earlier recognition of sepsis also increased the number of patients receiving early antibiotics and receiving central venous catheters for quantitative resuscitation.[23]
CLOSING THE LOOP TOWARD CONTINUOUS LEARNING IN SEPSIS
Leveraging timely and actionable data steeped within an aligned organizational milieu resulted in large‐scale changes across a heterogeneous set of hospitals. However, to realize the true vision of a learning hospital system, a looming question remained: Could the data generated as the byproduct of routine care now be used to complete the virtuous cycle and drive new scientific discovery (Figure 2, step 3)?
Confirming Concordance in the Impact of Sepsis Nationally
The heightened identification of sepsis patients through program implementation revealed that the impact of sepsis on hospital mortality was greater than originally estimated; based on improved patient identification, sepsis now accounted for upward of 1 in 2 hospital deaths.[25] This sobering statistic confirmed that the investments in standardizing best sepsis care following the mortality diagnostic were critical. However, were similar estimates of sepsis‐attributable mortality consistent outside of the KPNC system? To study this, we examined US hospitalizations occurring across >1000 hospitals and involving >6 million hospital stays to estimate corresponding prevalence.[25] In this national sample, sepsis contributed to as many as half of hospital deaths in the United States in 2010, lending strong support to ongoing international and state‐based efforts to improve sepsis care. These studies also paved the way to use these data drawn from our large sepsis population to inform updated international consensus definitions for sepsis and septic shock.[26, 27, 28]
Identifying New Avenues for Reducing the Toll of Sepsis
A major concern of sepsis program leaders was the prior findings that sepsis hospitalizations among Medicare beneficiaries were associated with substantial new cognitive and functional disability.[29] This lingering toll of sepsis had been termed a hidden public health disaster.[30] To further understand the posthospital impact of sepsis and to begin investigating new avenues to reduce this impact, a cohort of patients was followed for 1 year following sepsis hospitalization.[31] Over that period, nearly half of sepsis survivors were rehospitalized. When compared with their presepsis levels of healthcare utilization, middle‐aged and elderly sepsis patients experienced a 3‐fold increase in their days using facility‐based care. Subsequent studies in other populations outside of KPNC have confirmed these concerning findings, resulting in new efforts to address postsepsis survivorship care.[32, 33]
Phenotyping New Targets for Standardized Sepsis Care
At its outset, the sepsis improvement program applied the best available evidence to treat patients with the most severe forms of sepsisseptic shock. However, once the initial implementation phase had succeeded, clinicians and operational leaders quickly realized from the emerging data that there was a far larger group of sepsis patients for whom treatment guidelines were poorly defined.[25, 34, 35] These were severe sepsis patients with so‐called intermediate lactate values between 2 mmol/L and 4 mmol/L; they comprised a substantial proportion of all sepsis patients dying in the hospital. Using data generated from the routine care of sepsis patients treated across 21 hospitals, the sepsis leadership group was able to rapidly assemble a cohort of intermediate lactate sepsis patients up to 20‐ to 100‐fold larger than that reported in prior studies and evaluate their outcomes.[34, 35]
The data used to evaluate these intermediate lactate sepsis patients now spurred a new implementation program in 2013 for a group of patients in whom there was essentially no existing evidence to guide care. Rapidly implemented within a mature sepsis performance improvement program, evaluations at the 6‐month and 1‐year intervals demonstrated significant decreases in mortality.[36] Importantly, to allay the justified concerns of clinicians, these evaluations also clearly showed no evidence of harm from more aggressive fluid resuscitation (eg, increased transfer to intensive care, increased rates of mechanical ventilation). Again, driven by clinician input, subgroup analyses further revealed that the implementation program was only associated with reduced mortality in patients who could be at risk for iatrogenic fluid overload (ie, those with a history of congestive heart failure or chronic kidney disease).[36] Spurred by these provocative findings, operational and clinical leaders are currently considering how to guide future care in these patients, especially with the emerging use of noninvasive methods to quantify patients' fluid responsiveness.
PRINCIPLES FOR LEVERAGING DATA IN THE LEARNING HOSPITAL SYSTEM
The object lesson of using data to drive improved sepsis care and further new scientific discovery offers some important insights for continuous learning.
Building a Digital Infrastructure for Utilizing Granular Hospital Data
As described above, current transitions between the nodes of the learning framework are rife with missed opportunities. Perhaps one of the most glaring is the inability to use highly granular data already collected within the electronic health record (eg, trajectories and trends across vital signs or laboratory results, large‐scale medication administration records to evaluate multidrug interactions). An essential starting point for continuous learning is investing in the digital infrastructure to improve the use of data beyond traditional claims (administrative dataadmission source codes, disposition codes, diagnoses, and procedures). As shown in Table 2, the first key step is incorporating laboratory data into the quality assessment/emmprovement process. In addition, using these data to automate severity of illness and risk adjustment metrics fosters use of similar comparison cohorts across time or disease types.[18, 37, 38, 39, 40]
| Data Type | Contents | Degree of Difficulty in Accessing | Degree of Difficulty in Analyzing |
|---|---|---|---|
| Administrative | Traditional claims data, diagnostic or procedural codes | Low | Low to moderate |
| Standard cohort profiling | Limited instances of vitals signs, laboratory, diagnostic testing, or treatment data | Low to moderate | Low to moderate |
| Metrics reporting for care improvement | Standard cohort identification, aggregated achievement of treatment targets, scorecard dissemination | Moderate | Moderate |
| Advanced cohort profiling | Time series of physiologic data, inpatient triage and treatment data within short temporal intervals | Moderate to high | High |
| Research‐grade discovery | Data with breadth (representative sample size) and depth (highly granular physiologic and treatment data) | High | Very high |
| Patient‐reported outcomes | Quality of life, functional and cognitive disability | Very high | High |
Employing Novel Methods to Address the Limitations of Using Real‐World Data
The rapid digitization of medicine through the use of electronic medical records offers tremendous opportunities to facilitate continuous learning. However, these opportunities are accompanied by important limitations.[41] Data collected as a byproduct of real‐world care can be vulnerable to many forms of bias and confounding, potentially clouding the validity and robustness of corresponding analytic results. Fortunately, advanced methods including causal inference are now used routinely to address some limitations.[42] In the context of a learning healthcare system, other opportunities for improved study design including cluster randomized trials or stepped wedge implementation can also be employed to preserve the statistical rigor of subsequent analyses.[43] Finally, emerging methods employing randomization through the electronic medical record alongside adaptive trial design offer great potential to increase the efficiency of continuous learning.[44]
Evaluating the Hospital as a Single System
Advances in contemporary hospital care require seamless transitions of patient care, screening strategies, and therapeutic approaches across multiple hospital domains and with diverse providers; these interventions also need to happen rapidly. Many traditional approaches to inpatient care have taken a bottom‐up approach (eg, studying a specific disease within a specific hospital ward like the intensive care unit) that have proven useful but may limit generalizability when applied to a real‐world hospital operating with Pareto optimality (ie, the trade‐off scenario where new resource allocation to 1 area also requires resource withdrawal from another area). In certain cases, an empiric approach, without initial preference for any specific ward or disease, can aid decision making by hospital operational and clinical leaders by providing a global picture of impact and value.
Focusing on Early Detection in Hospital Settings as Secondary Prevention
Once patients have been admitted to the hospital, a race against the clock begins. Each additional hour of hospitalization increases the risks of iatrogenic injury or medical harm manifested by immobility, disorientation and delirium, nosocomial infections, or medication errors, among others. In this context, detection systems that use granular hospital data to focus on the earliest detection of risk can aid critical approaches to secondary prevention (Although the hospitalization for sepsis cannot be avoided, careful attention to mobility can limit the risk of developing delirium. In turn, preventing delirium can limit the risk of new functional disability).
Contextualizing Hospital Care Within a Longitudinal Trajectory
Although we described the benefit of hospital episodes having well‐demarcated beginning and ending points, it remains essential to recognize that the harms associated with hospitalization extend well beyond discharge. In this context, hospitalizations can serve as waypoints in patients' health trajectories as well as an opportunity to achieve patient‐centered care including discussing and aligning goals of care with actual care provision. Furthermore, although we have seen steady declines in hospital mortality over time, it is highly likely that we will reach a nadir in mortality where additional metrics of hospital outcomes will need to include postdischarge events like readmission, long‐term mortality, quality of life, and the prevention of disability or decline.
CONCLUSION
Hospitalizations in the United States are costly and associated with high mortality and morbidity; the toll of hospitalization also extends well beyond hospital discharge. The promise of the learning hospital system has marked improvements in the quality of hospital care, especially where healthcare systems can steep critical investments in data and digital infrastructure within the right culture, incentives, and leadership. Where continuous learning is achieved, data generated during routine care offer the potential to yield new scientific discovery and drive further improvements in hospital care.
Disclosures
As part of our agreement with the Gordon and Betty Moore Foundation, we made a commitment to disseminate our findings in articles such as this one. However, the Foundation and its staff played no role in how we actually structured our articles, nor did they review or preapprove any of the manuscripts submitted as part of the dissemination component. None of the authors has any conflicts of interest to declare of relevance to this work, which was funded by a combination of funding from the Gordon and Betty Moore Foundation, The Permanente Medical Group, Inc., and Kaiser Foundation Hospitals, Inc. VXL was supported by NIH K23GM112018.
- Institute of Medicine. Best Care at Lower Cost: The Path to Continuously Learning Health Care in America. Washington, DC: The National Academies Press; 2012.
- , , , et al. Toward a science of learning systems: a research agenda for the high‐functioning Learning Health System. J Am Med Inform Assoc. 2015;22(1):43–50.
- National Center for Health Statistics. Health, United States, 2014: With Special Feature on Adults Aged 55–64. Hyattsville, MD; 2015.
- , . Critical care medicine in the United States 2000‐2005: an analysis of bed numbers, occupancy rates, payer mix, and costs. Crit Care Med. 2010;38(1):65–71.
- , , , . Trends and variation in end‐of‐life care for medicare beneficiaries with severe chronic illness. A report of the Dartmouth Atlas Project. Lebanon, NH: The Dartmouth Institute for Health Policy and Clinical Practice; 2011.
- , , , et al. Change in end‐of‐life care for Medicare beneficiaries: site of death, place of care, and health care transitions in 2000, 2005, and 2009. JAMA. 2013;309(5):470–477.
- , , . Finding the missing link for big biomedical data. JAMA. 2014;311(24):2479–2480.
- . Code red and blue—safely limiting health care's GDP footprint. N Engl J Med. 2013;368(1):1–3.
- , . The inevitable application of big data to health care. JAMA. 2013;309(13):1351–1352.
- , . What is citizen science?—a scientometric meta‐analysis. PLoS One. 2016;11(1):e0147152.
- , , . Biomedical ontologies: a functional perspective. Brief Bioinform. 2008;9(1):75–90.
- . Rapid learning: a breakthrough agenda. Health Aff (Millwood). 2014;33(7):1155–1162.
- , , , et al. Are regional variations in end‐of‐life care intensity explained by patient preferences?: a study of the US Medicare population. Med Care. 2007;45(5):386–393.
- , . Extreme markup: the fifty US hospitals with the highest charge‐to‐cost ratios. Health Aff (Millwood). 2015;34(6):922–928.
- , , , . The price ain't right? Hospital prices and health spending on the privately insured. Health Care Pricing Project website. Available at: http://www.healthcarepricingproject.org/sites/default/files/pricing_variation_manuscript_0.pdf. Accessed February 15, 2016
- . A new, evidence‐based estimate of patient harms associated with hospital care. J Patient Saf. 2013;9(3):122–128.
- , , . Hospitalization‐associated disability: “she was probably able to ambulate, but I'm not sure”. JAMA. 2011;306(16):1782–1793.
- , , , , . Risk‐adjusting hospital mortality using a comprehensive electronic record in an integrated health care delivery system. Med Care. 2013;51(5):446–453.
- . New definitions for sepsis and septic shock: continuing evolution but with much still to be done. JAMA. 2016;315(8):757–759.
- , . Severe sepsis and septic shock. N Engl J Med. 2013;369(21):2063.
- , , . Sepsis‐induced immunosuppression: from cellular dysfunctions to immunotherapy. Nat Rev Immunol. 2013;13(12):862–874.
- , , , et al. Early goal‐directed therapy in the treatment of severe sepsis and septic shock. N Engl J Med. 2001;345(19):1368–1377.
- , , , et al. Kaiser Permanente's performance improvement system, part 3: multisite improvements in care for patients with sepsis. Jt Comm J Qual Patient Saf. 2011;37(11):483–493.
- , , , , . Understanding the components of quality improvement collaboratives: a systematic literature review. Milbank Q. 2013;91(2):354–394.
- , , , et al. Hospital deaths in patients with sepsis from 2 independent cohorts. JAMA. 2014;312(1):90–92.
- , , , et al. Assessment of clinical criteria for sepsis: for the Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):762–774.
- , , , et al. Developing a new definition and assessing new clinical criteria for septic shock: for the Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):775–787.
- , , , et al. The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):801–810.
- , , , . Long‐term cognitive impairment and functional disability among survivors of severe sepsis. JAMA. 2010;304(16):1787–1794.
- . The lingering consequences of sepsis: a hidden public health disaster? JAMA. 2010;304(16):1833–1834.
- , , , , , . Hospital readmission and healthcare utilization following sepsis in community settings. J Hosp Med. 2014;9(8):502–507.
- , , , , . Increased 1‐year healthcare use in survivors of severe sepsis. Am J Respir Crit Care Med. 2014;190(1):62–69.
- , , , et al. Post‐acute care use and hospital readmission after sepsis. Ann Am Thorac Soc. 2015;12(6):904–913.
- , , , , . Fluid volume, lactate values, and mortality in sepsis patients with intermediate lactate values. Ann Am Thorac Soc. 2013;10(5):466–473.
- , , . Prognosis of emergency department patients with suspected infection and intermediate lactate levels: a systematic review. J Crit Care. 2014;29(3):334–339.
- , , , et al. Multicenter implementation of a treatment bundle for sepsis patients with intermediate lactate values. Am J Respir Crit Care Med. 2016;193(11):1264–1270.
- , , , et al. Risk adjusting community‐acquired pneumonia hospital outcomes using automated databases. Am J Manag Care. 2008;14(3):158–166.
- , , , , , . Intra‐hospital transfers to a higher level of care: contribution to total hospital and intensive care unit (ICU) mortality and length of stay (LOS). J Hosp Med. 2011;6(2):74–80.
- , , , , , . Early detection of impending physiologic deterioration among patients who are not in intensive care: development of predictive models using data from an automated electronic medical record. J Hosp Med. 2012;7(5):388–395.
- , , , , . An electronic Simplified Acute Physiology Score‐based risk adjustment score for critical illness in an integrated healthcare system. Crit Care Med. 2013;41(1):41–48.
- . Learning from big health care data. N Engl J Med. 2014;370(23):2161–2163.
- , . Getting the methods right—the foundation of patient‐centered outcomes research. N Engl J Med. 2012;367(9):787–790.
- , , , , . The stepped wedge cluster randomised trial: rationale, design, analysis, and reporting. BMJ. 2015;350:h391.
- . Fusing randomized trials with big data: the key to self‐learning health care systems? JAMA. 2015;314(8):767–768.
- Institute of Medicine. Best Care at Lower Cost: The Path to Continuously Learning Health Care in America. Washington, DC: The National Academies Press; 2012.
- , , , et al. Toward a science of learning systems: a research agenda for the high‐functioning Learning Health System. J Am Med Inform Assoc. 2015;22(1):43–50.
- National Center for Health Statistics. Health, United States, 2014: With Special Feature on Adults Aged 55–64. Hyattsville, MD; 2015.
- , . Critical care medicine in the United States 2000‐2005: an analysis of bed numbers, occupancy rates, payer mix, and costs. Crit Care Med. 2010;38(1):65–71.
- , , , . Trends and variation in end‐of‐life care for medicare beneficiaries with severe chronic illness. A report of the Dartmouth Atlas Project. Lebanon, NH: The Dartmouth Institute for Health Policy and Clinical Practice; 2011.
- , , , et al. Change in end‐of‐life care for Medicare beneficiaries: site of death, place of care, and health care transitions in 2000, 2005, and 2009. JAMA. 2013;309(5):470–477.
- , , . Finding the missing link for big biomedical data. JAMA. 2014;311(24):2479–2480.
- . Code red and blue—safely limiting health care's GDP footprint. N Engl J Med. 2013;368(1):1–3.
- , . The inevitable application of big data to health care. JAMA. 2013;309(13):1351–1352.
- , . What is citizen science?—a scientometric meta‐analysis. PLoS One. 2016;11(1):e0147152.
- , , . Biomedical ontologies: a functional perspective. Brief Bioinform. 2008;9(1):75–90.
- . Rapid learning: a breakthrough agenda. Health Aff (Millwood). 2014;33(7):1155–1162.
- , , , et al. Are regional variations in end‐of‐life care intensity explained by patient preferences?: a study of the US Medicare population. Med Care. 2007;45(5):386–393.
- , . Extreme markup: the fifty US hospitals with the highest charge‐to‐cost ratios. Health Aff (Millwood). 2015;34(6):922–928.
- , , , . The price ain't right? Hospital prices and health spending on the privately insured. Health Care Pricing Project website. Available at: http://www.healthcarepricingproject.org/sites/default/files/pricing_variation_manuscript_0.pdf. Accessed February 15, 2016
- . A new, evidence‐based estimate of patient harms associated with hospital care. J Patient Saf. 2013;9(3):122–128.
- , , . Hospitalization‐associated disability: “she was probably able to ambulate, but I'm not sure”. JAMA. 2011;306(16):1782–1793.
- , , , , . Risk‐adjusting hospital mortality using a comprehensive electronic record in an integrated health care delivery system. Med Care. 2013;51(5):446–453.
- . New definitions for sepsis and septic shock: continuing evolution but with much still to be done. JAMA. 2016;315(8):757–759.
- , . Severe sepsis and septic shock. N Engl J Med. 2013;369(21):2063.
- , , . Sepsis‐induced immunosuppression: from cellular dysfunctions to immunotherapy. Nat Rev Immunol. 2013;13(12):862–874.
- , , , et al. Early goal‐directed therapy in the treatment of severe sepsis and septic shock. N Engl J Med. 2001;345(19):1368–1377.
- , , , et al. Kaiser Permanente's performance improvement system, part 3: multisite improvements in care for patients with sepsis. Jt Comm J Qual Patient Saf. 2011;37(11):483–493.
- , , , , . Understanding the components of quality improvement collaboratives: a systematic literature review. Milbank Q. 2013;91(2):354–394.
- , , , et al. Hospital deaths in patients with sepsis from 2 independent cohorts. JAMA. 2014;312(1):90–92.
- , , , et al. Assessment of clinical criteria for sepsis: for the Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):762–774.
- , , , et al. Developing a new definition and assessing new clinical criteria for septic shock: for the Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):775–787.
- , , , et al. The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis‐3). JAMA. 2016;315(8):801–810.
- , , , . Long‐term cognitive impairment and functional disability among survivors of severe sepsis. JAMA. 2010;304(16):1787–1794.
- . The lingering consequences of sepsis: a hidden public health disaster? JAMA. 2010;304(16):1833–1834.
- , , , , , . Hospital readmission and healthcare utilization following sepsis in community settings. J Hosp Med. 2014;9(8):502–507.
- , , , , . Increased 1‐year healthcare use in survivors of severe sepsis. Am J Respir Crit Care Med. 2014;190(1):62–69.
- , , , et al. Post‐acute care use and hospital readmission after sepsis. Ann Am Thorac Soc. 2015;12(6):904–913.
- , , , , . Fluid volume, lactate values, and mortality in sepsis patients with intermediate lactate values. Ann Am Thorac Soc. 2013;10(5):466–473.
- , , . Prognosis of emergency department patients with suspected infection and intermediate lactate levels: a systematic review. J Crit Care. 2014;29(3):334–339.
- , , , et al. Multicenter implementation of a treatment bundle for sepsis patients with intermediate lactate values. Am J Respir Crit Care Med. 2016;193(11):1264–1270.
- , , , et al. Risk adjusting community‐acquired pneumonia hospital outcomes using automated databases. Am J Manag Care. 2008;14(3):158–166.
- , , , , , . Intra‐hospital transfers to a higher level of care: contribution to total hospital and intensive care unit (ICU) mortality and length of stay (LOS). J Hosp Med. 2011;6(2):74–80.
- , , , , , . Early detection of impending physiologic deterioration among patients who are not in intensive care: development of predictive models using data from an automated electronic medical record. J Hosp Med. 2012;7(5):388–395.
- , , , , . An electronic Simplified Acute Physiology Score‐based risk adjustment score for critical illness in an integrated healthcare system. Crit Care Med. 2013;41(1):41–48.
- . Learning from big health care data. N Engl J Med. 2014;370(23):2161–2163.
- , . Getting the methods right—the foundation of patient‐centered outcomes research. N Engl J Med. 2012;367(9):787–790.
- , , , , . The stepped wedge cluster randomised trial: rationale, design, analysis, and reporting. BMJ. 2015;350:h391.
- . Fusing randomized trials with big data: the key to self‐learning health care systems? JAMA. 2015;314(8):767–768.
Continuing Medical Education Program in
If you wish to receive credit for this activity, which begins on the next page, please refer to the website:
Accreditation and Designation Statement
Blackwell Futura Media Services designates this educational activity for a 1 AMA PRA Category 1 Credit. Physicians should only claim credit commensurate with the extent of their participation in the activity.
Blackwell Futura Media Services is accredited by the Accreditation Council for Continuing Medical Education to provide continuing medical education for physicians.
Educational Objectives
Upon completion of this educational activity, participants will be better able to employ automated bed history data to examine outcomes of intra‐hospital transfers using all hospital admissions as the denominator.
Continuous participation in the Journal of Hospital Medicine CME program will enable learners to be better able to:
-
Interpret clinical guidelines and their applications for higher quality and more efficient care for all hospitalized patients.
-
Describe the standard of care for common illnesses and conditions treated in the hospital; such as pneumonia, COPD exacerbation, acute coronary syndrome, HF exacerbation, glycemic control, venous thromboembolic disease, stroke, etc.
-
Discuss evidence‐based recommendations involving transitions of care, including the hospital discharge process.
-
Gain insights into the roles of hospitalists as medical educators, researchers, medical ethicists, palliative care providers, and hospital‐based geriatricians.
-
Incorporate best practices for hospitalist administration, including quality improvement, patient safety, practice management, leadership, and demonstrating hospitalist value.
-
Identify evidence‐based best practices and trends for both adult and pediatric hospital medicine.
Instructions on Receiving Credit
For information on applicability and acceptance of continuing medical education credit for this activity, please consult your professional licensing board.
This activity is designed to be completed within the time designated on the title page; physicians should claim only those credits that reflect the time actually spent in the activity. To successfully earn credit, participants must complete the activity during the valid credit period that is noted on the title page.
Follow these steps to earn credit:
-
Log on to
www.blackwellpublishing.com/cme . -
Read the target audience, learning objectives, and author disclosures.
-
Read the article in print or online format.
-
Reflect on the article.
-
Access the CME Exam, and choose the best answer to each question.
-
Complete the required evaluation component of the activity.
If you wish to receive credit for this activity, which begins on the next page, please refer to the website:
Accreditation and Designation Statement
Blackwell Futura Media Services designates this educational activity for a 1 AMA PRA Category 1 Credit. Physicians should only claim credit commensurate with the extent of their participation in the activity.
Blackwell Futura Media Services is accredited by the Accreditation Council for Continuing Medical Education to provide continuing medical education for physicians.
Educational Objectives
Upon completion of this educational activity, participants will be better able to employ automated bed history data to examine outcomes of intra‐hospital transfers using all hospital admissions as the denominator.
Continuous participation in the Journal of Hospital Medicine CME program will enable learners to be better able to:
-
Interpret clinical guidelines and their applications for higher quality and more efficient care for all hospitalized patients.
-
Describe the standard of care for common illnesses and conditions treated in the hospital; such as pneumonia, COPD exacerbation, acute coronary syndrome, HF exacerbation, glycemic control, venous thromboembolic disease, stroke, etc.
-
Discuss evidence‐based recommendations involving transitions of care, including the hospital discharge process.
-
Gain insights into the roles of hospitalists as medical educators, researchers, medical ethicists, palliative care providers, and hospital‐based geriatricians.
-
Incorporate best practices for hospitalist administration, including quality improvement, patient safety, practice management, leadership, and demonstrating hospitalist value.
-
Identify evidence‐based best practices and trends for both adult and pediatric hospital medicine.
Instructions on Receiving Credit
For information on applicability and acceptance of continuing medical education credit for this activity, please consult your professional licensing board.
This activity is designed to be completed within the time designated on the title page; physicians should claim only those credits that reflect the time actually spent in the activity. To successfully earn credit, participants must complete the activity during the valid credit period that is noted on the title page.
Follow these steps to earn credit:
-
Log on to
www.blackwellpublishing.com/cme . -
Read the target audience, learning objectives, and author disclosures.
-
Read the article in print or online format.
-
Reflect on the article.
-
Access the CME Exam, and choose the best answer to each question.
-
Complete the required evaluation component of the activity.
If you wish to receive credit for this activity, which begins on the next page, please refer to the website:
Accreditation and Designation Statement
Blackwell Futura Media Services designates this educational activity for a 1 AMA PRA Category 1 Credit. Physicians should only claim credit commensurate with the extent of their participation in the activity.
Blackwell Futura Media Services is accredited by the Accreditation Council for Continuing Medical Education to provide continuing medical education for physicians.
Educational Objectives
Upon completion of this educational activity, participants will be better able to employ automated bed history data to examine outcomes of intra‐hospital transfers using all hospital admissions as the denominator.
Continuous participation in the Journal of Hospital Medicine CME program will enable learners to be better able to:
-
Interpret clinical guidelines and their applications for higher quality and more efficient care for all hospitalized patients.
-
Describe the standard of care for common illnesses and conditions treated in the hospital; such as pneumonia, COPD exacerbation, acute coronary syndrome, HF exacerbation, glycemic control, venous thromboembolic disease, stroke, etc.
-
Discuss evidence‐based recommendations involving transitions of care, including the hospital discharge process.
-
Gain insights into the roles of hospitalists as medical educators, researchers, medical ethicists, palliative care providers, and hospital‐based geriatricians.
-
Incorporate best practices for hospitalist administration, including quality improvement, patient safety, practice management, leadership, and demonstrating hospitalist value.
-
Identify evidence‐based best practices and trends for both adult and pediatric hospital medicine.
Instructions on Receiving Credit
For information on applicability and acceptance of continuing medical education credit for this activity, please consult your professional licensing board.
This activity is designed to be completed within the time designated on the title page; physicians should claim only those credits that reflect the time actually spent in the activity. To successfully earn credit, participants must complete the activity during the valid credit period that is noted on the title page.
Follow these steps to earn credit:
-
Log on to
www.blackwellpublishing.com/cme . -
Read the target audience, learning objectives, and author disclosures.
-
Read the article in print or online format.
-
Reflect on the article.
-
Access the CME Exam, and choose the best answer to each question.
-
Complete the required evaluation component of the activity.
Intra‐Hospital Transfer to a Higher Level of Care
Considerable research and public attention is being paid to the quantification, risk adjustment, and reporting of inpatient mortality.15 Inpatient mortality is reported as aggregate mortality (for all hospitalized patients or those with a specific diagnosis3, 6) or intensive care unit (ICU) mortality.7, 8 While reporting aggregate hospital or aggregate ICU mortality rates is useful, it is also important to develop reporting strategies that go beyond simply using data elements found in administrative databases (eg, diagnosis and procedure codes) to quantify practice variation. Ideally, such strategies would permit delineating processes of careparticularly those potentially under the control of hospitalists, not only intensiviststo identify improvement opportunities. One such process, which can be tracked using the bed history component of a patient's electronic medical record, is the transfer of patients between different units within the same hospital.
Several studies have documented that risk of ICU death is highest among patients transferred from general medical‐surgical wards, intermediate among direct admissions from the emergency department, and lowest among surgical admissions.911 Opportunities to reduce subsequent ICU mortality have been studied among ward patients who develop sepsis and are then transferred to the ICU,12 among patients who experience cardiac arrest,13, 14 as well as among patients with any physiological deterioration (eg, through the use of rapid response teams).1517 Most of these studies have been single‐center studies and/or studies reporting only an ICU denominator. While useful in some respects, such studies are less helpful to hospitalists, who would benefit from better understanding of the types of patients transferred and the total impact that transfers to a higher level of care make on general medical‐surgical wards. In addition, entities such as the Institute for Healthcare Improvement recommend the manual review of records of patients who were transferred from the ward to the ICU18 to identify performance improvement opportunities. While laudable, such approaches do not lend themselves to automated reporting strategies.
We recently described a new risk adjustment methodology for inpatient mortality based entirely on automated data preceding hospital admission and not restricted to ICU patients. This methodology, which has been externally validated in Ottawa, Canada, after development in the Kaiser Permanente Medical Care Program (KPMCP), permits quantification of a patient's pre‐existing comorbidity burden, physiologic derangement at the time of admission, and overall inpatient mortality risk.19, 20 The primary purpose of this study was to combine this methodology with bed history analysis to quantify the in‐hospital mortality and length of stay (LOS) of patients who experienced intra‐hospital transfers in a large, multihospital system. As a secondary goal, we also wanted to assess the degree to which these transfers could be predicted based on information available prior to a patient's admission.
ABBREVIATIONS AND TERMS USED IN TEXT
COPS: COmorbidity Point Score. Point score based on a patient's health care utilization diagnoses (during the year preceding admission to the hospital. Analogous to POA (present on admission) coding. Scores can range from 0 to a theoretical maximum of 701 but scores >200 are rare. With respect to a patient's pre‐existing comorbidity burden, the unadjusted relationship of COPS and inpatient mortality is as follows: a COPS <50 is associated with a mortality risk of <1%, <100 with a mortality risk of <5%, 100 to 145 with a mortality risk of 5% to 10%, and >145 with a mortality risk of 10% or more.
ICU: Intensive Care Unit. In this study, all ICUs have a minimum registered nurse to patient ratio of 1:2.
LAPS: Laboratory Acute Physiology Score. Point score based on 14 laboratory test results obtained in the 72 hours preceding hospitalization. With respect to a patient's physiologic derangement, the unadjusted relationship of LAPS and inpatient mortality is as follows: a LAPS <7 is associated with a mortality risk of <1%, <7 to 30 with a mortality risk of <5%, 30 to 60 with a mortality risk of 5% to 9%, and >60 with a mortality risk of 10% or more.
LOS: Exact hospital Length Of Stay. LOS is calculated from admission until first discharge home (i.e., it may span more than one hospital stay if a patient experienced inter‐hospital transport).
Predicted (expected) mortality risk: the % risk of death for a given patient based on his/her age, sex, admission diagnosis, COPS, and LAPS.
OEMR: Observed to Expected Mortality Ratio. For a given patient subset, the ratio of the actual mortality experienced by the subset to the expected (predicted) mortality for the subset. Predicted mortality is based on patients' age, sex, admission diagnosis, COPS, and LAPS.
OMELOS: Observed Minus Expected LOS. For a given patient subset, the difference between the actual number of hospital days experienced by the subset and the expected (predicted) number of hospital days for the subset. Predicted LOS is based on patients' age, sex, admission diagnosis, COPS, and LAPS.
TCU: Transitional Care Unit (also called intermediate care unit or stepdown unit). In this study, TCUs have variable nurse to patient ratios ranging from 1:2.5 to 1:3 and did not provide assisted ventilation, continuous pressor infusions, or invasive monitoring.
Materials and Methods
This project was approved by the Northern California KPMCP Institutional Review Board for the Protection of Human Subjects.
The Northern California KPMCP serves a total population of approximately 3.3 million members. Under a mutual exclusivity arrangement, physicians of The Permanente Medical Group, Inc., care for Kaiser Foundation Health Plan, Inc. members at facilities owned by Kaiser Foundation Hospitals, Inc. All Northern California KPMCP hospitals and clinics employ the same information systems with a common medical record number and can track care covered by the plan but delivered elsewhere. Databases maintained by the KPMCP capture admission and discharge times, admission and discharge diagnoses and procedures (assigned by professional coders), bed histories, inter‐hospital transfers, as well as the results of all inpatient and outpatient laboratory tests. The use of these databases for research has been described in multiple reports.2124
Our setting consisted of all 19 hospitals owned and operated by the KPMCP, whose characteristics are summarized in the Supporting Information Appendix available to interested readers. These include the 17 described in our previous report19 as well as 2 new hospitals (Antioch and Manteca) which are similar in size and type of population served. Our study population consisted of all patients admitted to these 19 hospitals who met these criteria: 1) hospitalization began from November 1st, 2006 through January 31st, 2008; 2) initial hospitalization occurred at a Northern California KPMCP hospital (ie, for inter‐hospital transfers, the first hospital stay occurred within the KPMCP); 3) age 15 years; and 4) hospitalization was not for childbirth.
We defined a linked hospitalization as the time period that began with a patient's admission to the hospital and ended with the patient's discharge (home, to a nursing home, or death). Linked hospitalizations can thus involve more than 1 hospital stay and could include a patient transfer from one hospital to another prior to definitive discharge. For linked hospitalizations, mortality was attributed to the admitting KPMCP hospital (ie, if a patient was admitted to hospital A, transferred to B, and died at hospital B, mortality was attributed to hospital A). We defined total LOS as the exact time in hours from when a patient was first admitted to the hospital until death or final discharge home or to a nursing home, while total ICU or transitional care unit (TCU, referred to as stepdown unit in some hospitals) LOS was calculated for all individual ICU or TCU stays during the hospital stay.
Intra‐Hospital Transfers
We grouped all possible hospital units into four types: general medical‐surgical ward (henceforth, ward); operating room (OR)/post‐anesthesia recovery (PAR); TCU; and ICU. In 2003, the KPMCP implemented a mandatory minimum staffing ratio of one registered nurse for every four patients in all its hospital units; in addition, staffing levels for designated ICUs adhered to the previously mandated minimum of one nurse for every 2 patients. So long as they adhere to these minimum ratios, individual hospitals have considerable autonomy with respect to how they staff or designate individual hospital units. Registered nurse‐to‐patient ratios during the time of this study were as follows: ward patients, 1:3.5 to 1:4; TCU patients, 1:2.5 to 1:3; and ICU patients, 1:1 to 1:2. Staffing ratios for the OR and PAR are more variable, depending on the surgical procedures involved. Current KPMCP databases do not permit accurate quantification of physician staffing. All 19 study hospitals had designated ICUs, 6 were teaching hospitals, and 11 had designated TCUs. None of the study hospitals had closed ICUs (units where only intensivists admit patients) and none had continuous coverage of the ICU by intensivists. While we were not able to employ electronic data to determine who made the decision to transfer, we did find considerable variation with respect to how intensivists covered the ICUs and how they interfaced with hospitalists. Staffing levels for specialized coronary care units and non‐ICU monitored beds were not standardized. All study hospitals had rapid response teams as well as code blue teams during the time period covered by this report. Respiratory care practitioners were available to patients in all hospital units, but considerable variation existed with respect to other services available (eg, cardiac catheterization units, provision of noninvasive positive pressure ventilation outside the ICU, etc.).
This report focuses on intra‐hospital transfers to the ICU and TCU, with special emphasis on nonsurgical transfers (due to space limitations, we are not reporting on the outcomes of patients whose first hospital unit was the OR; additional details on these patients are provided in the Supporting Information Appendix). For the purposes of this report, we defined the following admission types: direct admits (patients admitted to the ICU or TCU whose first hospital unit on admission was the ICU or TCU); and nonsurgical transfers to a higher level of care. These latter transfers could be of 3 types: ward to ICU, ward to TCU, and TCU to ICU. We also quantified the effect of inter‐hospital transfers.
Independent Variables
In addition to patients' age and sex, we employed the following independent variables to predict transfer to a higher level of care. These variables are part of the risk adjustment model described in greater detail in our previous report19 and were available electronically for all patients in the cohort. We grouped admission diagnoses into 44 broad diagnostic categories (Primary Conditions), and admission types into 4 groups (emergency medical, emergency surgical, elective medical, and elective surgical). We quantified patients' degree of physiologic derangement using a Laboratory‐based Acute Physiology Score (LAPS) using laboratory test results prior to hospitalization. We quantified patients' comorbid illness burden using a Comorbidity Point Score (COPS) based on patients' pre‐existing diagnoses over the 12‐month period preceding hospitalization. Lastly, we assigned each patient a predicted mortality risk (%) and LOS based on the above predictors,19 permitting calculation of observed to expected mortality ratios (OEMRs) and observed minus expected LOS (OMELOS).
Statistical Methods
All analyses were performed in SAS.25 We calculated standard descriptive statistics (medians, means, standard deviations) and compared different patient groupings using t and chi‐square tests. We employed a similar approach to that reported by Render et al.7 to calculate OEMR and OMELOS.
To determine the degree to which transfers to a higher level of care from the ward or TCU would be predictable using information available at the time of admission, we performed 4 sets of logistic regression analyses using the above‐mentioned predictors in which the outcome variables were as follows: 1) transfer occurring in the first 48 hours after admission (time frame by which point approximately half of the transferred patients experienced a transfer) among ward or TCU patients and 2) transfer occurring after 48 hours among ward or TCU patients. We evaluated the discrimination and calibration of these models using the same methods described in our original report (measuring the area under the receiver operator characteristic curve, or c statistic, and visually examining observed and expected mortality rates among predicted risk bands as well as risk deciles) as well as additional statistical tests recommended by Cook.19, 26
Results
During the study period, a total of 249,129 individual hospital stays involving 170,151 patients occurred at these 19 hospitals. After concatenation of inter‐hospital transfers, we were left with 237,208 linked hospitalizations. We excluded 26,738 linked hospitalizations that began at a non‐KPMCP hospital (ie, they were transported in), leaving a total of 210,470 linked hospitalizations involving 150,495 patients. The overall linked hospitalization mortality rate was 3.30%.
Table 1 summarizes cohort characteristics based on initial hospital location. On admission, ICU patients had the highest degree of physiologic derangement as well as the highest predicted mortality. Considerable inter‐hospital variation was present in both predictors and outcomes; details on these variations are provided in the Supporting Information Appendix.
| Ward | TCU | ICU | All* | |
|---|---|---|---|---|
| ||||
| n | 121,237 | 20,556 | 16,001 | 210,470 |
| Admitted via emergency department, n (%) | 99,909 (82.4) | 18,612 (90.5) | 13,847 (86.5) | 139,036 (66.1) |
| % range across hospitals | 55.0‐94.2 | 64.7‐97.6 | 49.5‐97.4 | 53.6‐76.9 |
| Male, n (%) | 53,744 (44.3) | 10,362 (50.4) | 8,378 (52.4) | 94,451 (44.9) |
| Age in years (mean SD) | 64.5 19.2 | 69.0 15.6 | 63.7 17.8 | 63.2 18.6 |
| LAPS (mean SD) | 19.2 18.0 | 23.3 19.5 | 31.7 25.7 | 16.7 19.0 |
| COPS (mean SD) | 90.4 64.0 | 99.2 65.9 | 94.5 67.5 | 84.7 61.8 |
| % predicted mortality (mean SD) | 4.0 7.1 | 4.6 7.3 | 8.7 12.8 | 3.6 7.3 |
| Observed in‐hospital deaths (n, %) | 3,793 (3.1) | 907 (4.4) | 1,995 (12.5) | 6,952 (3.3) |
| Observed to expected mortality ratio | 0.79 (0.77‐0.82) | 0.95 (0.89‐1.02) | 1.43 (1.36‐1.49) | 0.92 (0.89‐0.94) |
| Total hospital LOS, days (mean SD) | 4.6 7.5 | 5.3 10.0 | 7.8 14.0 | 4.6 8.1 |
Table 2 summarizes data from 3 groups of patients: patients initially admitted to the ward, or TCU, who did not experience a transfer to a higher level of care and patients admitted to these 2 units who did experience such a transfer. Patients who experienced a transfer constituted 5.3% (6,484/121,237) of ward patients and 6.7% (1,384/20,556) of TCU patients. Transferred patients tended to be older, have more acute physiologic derangement (higher LAPS), a greater pre‐existing illness burden (higher COPS), and a higher predicted mortality risk. Among ward patients, those with the following admission diagnoses were most likely to experience a transfer to a higher level of care: gastrointestinal bleeding (10.8% of all transfers), pneumonia (8.7%), and other infections (8.2%). The diagnoses most likely to be associated with death following transfer were cancer (death rate among transferred patients, 48%), renal disease (death rate, 36%), and liver disease (33%). Similar distributions were observed for TCU patients.
| Patients Initially Admitted to Ward, Remained There | Patients Initially Admitted to TCU, Remained There | Patients Transferred to Higher Level of Care | All | |
|---|---|---|---|---|
| ||||
| n | 114,753 | 19,172 | 7,868 | 141,793 |
| Male, n (%) | 50,586 (44.1) | 9,626 (50.2) | 3,894 (49.5) | 64,106 (45.2) |
| Age (mean SD) | 64.3 19.4 | 69.0 15.7 | 68.1 16.1 | 65.2 18.8 |
| LAPS (mean SD) | 18.9 17.8 | 22.7 19.1 | 26.7 21.0 | 19.8 18.3 |
| COPS (mean SD) | 89.4 63.7 | 98.3 65.5 | 107.9 67.6 | 91.7 64.4 |
| % predicted mortality risk (mean SD) | 3.8 7.0 | 4.4 7.0 | 6.5 8.8 | 4.1 7.1 |
| Admission diagnosis of pneumonia, n (%) | 5,624 (4.9) | 865 (4.5) | 684 (8.7) | 7,173 (5.1) |
| Admission diagnosis of sepsis, n (%) | 1,181 (1.0) | 227 (1.2) | 168 (2.1) | 1,576 (1.1) |
| Admission diagnosis of GI bleed, n (%) | 13,615 (11.9) | 1,448 (7.6) | 851 (10.8) | 15,914 (11.2) |
| Admission diagnosis of cancer, n (%) | 2,406 (2.1) | 80 (0.4) | 186 (2.4) | 2,672 (1.9) |
Table 3 compares outcomes among ward and TCU patients who did and did not experience a transfer to a higher level of care. The table shows that transferred patients were almost 3 times as likely to die, even after controlling for severity of illness, and that their hospital LOS was 9 days higher than expected. This increased risk was seen in all hospitals and among all transfer types (ward to ICU, ward to TCU, and TCU to ICU).
| Patients Initially Admitted to Ward, Remained There | Patients Initially Admitted to TCU, Remained There | Patients Transferred to Higher Level of Care | |
|---|---|---|---|
| |||
| n | 114,753 | 19,172 | 7,868 |
| Admitted to ICU, n (%) | 0 (0.0) | 0 (0.0) | 5,245 (66.7) |
| Ventilated, n (%) | 0 (0.0) | 0 (0.0) | 1,346 (17.1) |
| Died in the hospital, n (%) | 2,619 (2.3) | 572 (3.0) | 1,509 (19.2) |
| Length of stay, in days, at time of death (mean SD) | 7.0 11.9 | 8.3 12.4 | 16.2 23.7 |
| Observed to expected mortality ratio (95% CI) | 0.60 (0.57‐0.62) | 0.68 (0.63‐0.74) | 2.93 (2.79‐3.09) |
| Total hospital length of stay, days (mean SD) | 4.0 5.7 | 4.4 6.9 | 14.3 21.3 |
| Observed minus expected length of stay (95% CI) | 0.4 (0.3‐0.4) | 0.8 (0.7‐0.9) | 9.1 (8.6‐9.5) |
| Length of stay, in hours, at time of transfer (mean SD) | 80.8 167.2 | ||
Table 3 also shows that, among decedent patients, those who never left the ward or TCU died much sooner than those who died following transfer. Among direct admits to the ICU, the median LOS at time of death was 3.9 days, with a mean of 9.4 standard deviation of 19.9 days, while the corresponding times for TCU direct admits were a median and mean LOS of 6.5 and 11.7 19.5 days.
Table 4 summarizes outcomes among different patient subgroups that did and did not experience a transfer to a higher level of care. Based on location, patients who experienced a transfer from the TCU to the ICU had the highest crude death rate, but patients transferred from the ward to the ICU had the highest OEMR. On the other hand, if one divides patients by the degree of physiologic derangement, patients with low LAPS who experienced a transfer had the highest OEMR. With respect to LOS, patients transferred from the TCU to the ICU had the highest OMELOS (13.4 extra days).
| n (%)* | Death Rate (%) | OEMR | LOS (mean SD) | OMELOS | |
|---|---|---|---|---|---|
| |||||
| Never admitted to TCU or ICU | 157,632 (74.9) | 1.6 | 0.55 (0.53‐0.57) | 3.6 4.6 | 0.04 (0.02‐0.07) |
| Direct admit to TCU | 18,464 (8.8) | 2.9 | 0.66 (0.61‐0.72) | 4.2 5.8 | 0.60 (0.52‐0.68) |
| Direct admit to ICU | 14,655 (7.0) | 11.9 | 1.38 (1.32‐1.45) | 6.4 9.4 | 2.28 (2.14‐2.43) |
| Transferred from ward to ICU | 5,145 (2.4) | 21.5 | 3.23 (3.04‐3.42) | 15.7 21.6 | 10.33 (9.70‐10.96) |
| Transferred from ward to TCU | 3,144 (1.5) | 11.9 | 1.99 (1.79‐2.20) | 13.6 23.2 | 8.02 (7.23‐8.82) |
| Transferred from TCU to ICU | 1,107 (0.5) | 25.7 | 2.94 (2.61‐3.31) | 18.0 28.2 | 13.35 (11.49‐15.21) |
| Admitted to ward, COPS 80, no transfer to ICU or TCU | 55,405 (26.3) | 3.4 | 0.59 (0.56‐0.62) | 4.5 5.9 | 0.29 (0.24‐0.34) |
| Admitted to ward, COPS 80, did experience transfer to ICU or TCU | 4,851 (2.3) | 19.3 | 2.72 (2.55‐2.90) | 14.2 20.0 | 8.14 (7.56‐8.71) |
| Admitted to ward, COPS <80, no transfer to ICU or TCU | 57,421 (27.3) | 1.1 | 0.55 (0.51‐0.59) | 3.4 4.2 | 0.23 (0.19‐0.26) |
| Admitted to ward, COPS <80, did experience transfer to ICU or TCU | 3,560 (1.7) | 9.8 | 2.93 (2.63‐3.26) | 12.0 19.0 | 7.52 (6.89‐8.15) |
| Admitted to ward, LAPS 20, no transfer to ICU or TCU | 46,492 (22.1) | 4.2 | 0.59 (0.56‐0.61) | 4.6 5.4 | 0.16 (0.12‐0.21) |
| Admitted to ward, LAPS 20, did experience transfer to ICU or TCU | 4,070 (1.9) | 21.4 | 2.37 (2.22‐2.54) | 14.8 21.0 | 8.76 (8.06‐9.47) |
| Admitted to ward, LAPS <20, no transfer to ICU or TCU | 66,334 (31.5) | 0.9 | 0.55 (0.51‐0.60) | 3.5 4.9 | 0.32 (0.28‐0.36) |
| Admitted to ward, LAPS <20, did experience transfer to ICU or TCU | 4,341 (2.1) | 9.5 | 4.31 (3.90‐4.74) | 11.8 18.1 | 7.12 (6.61‐7.64) |
Transfers to a higher level of care at a different hospital, which in the KPMCP are usually planned, experienced lower mortality than transfers within the same hospital. For ward to TCU transfers, intra‐hospital transfers had a mortality of 12.1% while inter‐hospital transfers had a mortality of 5.7%. Corresponding rates for ward to ICU transfers were 21.7% and 11.2%, and for TCU to ICU transfers the rates were 25.9% and 12.5%, respectively.
Among patients initially admitted to the ward, a model to predict the occurrence of a transfer to a higher level of care (within 48 hours after admission) that included age, sex, admission type, primary condition, LAPS, COPS, and interaction terms had poor discrimination, with an area under the receiver operator characteristic (c statistic) of only 0.64. The c statistic for a model to predict transfer after 48 hours was 0.66. The corresponding models for TCU admits had c statistics of 0.67 and 0.68. All four models had poor calibration.
Discussion
Using automated bed history data permits characterizing a patient population with disproportionate mortality and LOS: intra‐hospital transfers to special care units (ICUs or TCUs). Indeed, the largest subset of these patients (those initially admitted to the ward or TCU) constituted only 3.7% of all admissions, but accounted for 24.2% of all ICU admissions, 21.7% of all hospital deaths, and 13.2% of all hospital days. These patients also had very elevated OEMRs and OMELOS. Models based on age, sex, preadmission laboratory test results, and comorbidities did not predict the occurrence of these transfers.
We performed multivariate analyses to explore the degree to which electronically assigned preadmission severity scores could predict these transfers. These analyses found that, compared to our ability to predict inpatient or 30‐day mortality at the time of admission, which is excellent, our ability to predict the occurrence of transfer after admission is much more limited. These results highlight the limitations of severity scores that rely on automated data, which may not have adequate discrimination when it comes to determining the risk of an adverse outcome within a narrow time frame. For example, among the 121,237 patients initially admitted to the ward who did not experience an intra‐hospital transfer, the mean LAPS was 18.9, while the mean LAPS among the 6,484 ward patients who did experience a transfer was 25.5. Differences between the mean and median LAPS, COPS, and predicted mortality risk among transferred and non‐transferred patients were significant (P < 0.0001 for all comparisons). However, examination of the distribution of LAPS, COPS, and predicted mortality risk between these two groups of patients showed considerable overlap.
Our methodology resembles Silber et al.'s27, 28 concept of failure to rescue in that it focuses on events occurring after hospitalization. Silber et al. argue that a hospital's quality can be measured by quantifying the degree to which patients who experience new problems are successfully rescued. Furthermore, quantification of those situations where rescue attempts are unsuccessful is felt to be superior to simply comparing raw or adjusted mortality rates because these are primarily determined by underlying case mix. The primary difference between Silber et al.'s approach and ours is at the level of detailthey specified a specific set of complications, whereas our measure is more generic and would include patients with many of the complications specified by Silber et al.27, 28
Most of the patients transferred to a higher level of care in our cohort survived (ie, were rescued), indicating that intensive care is beneficial. However, the fact that these patients had elevated OEMRs and OMELOS indicates that the real challenge facing hospitalists involves the timing of provision of a beneficial intervention. In theory, improved timing could result from earlier detection of problems, which is the underlying rationale for employing rapid response teams. However, the fact that our electronic tools (LAPS, COPS) cannot predict patient deteriorations within a narrow time frame suggests that early detection will remain a major challenge. Manually assigned vital signs scores designed for this purpose do not have good discrimination either.29, 30 This raises the possibility that, though patient groups may differ in terms of overall illness severity and mortality risk, differences at the individual patient level may be too subtle for clinicians to detect. Future research may thus need to focus on scores that combine laboratory data, vital signs, trends in data,31, 32 and newer proteomic markers (eg, procalcitonin).33 We also found that most transfers occurred early (within <72 hours), raising the possibility that at least some of these transfers may involve issues around triage rather than sudden deterioration.
Our study has important limitations. Due to resource constraints and limited data availability, we could not characterize the patients as well as might be desirable; in particular, we could not make full determinations of the actual reasons for patients' transfer for all patients. Broadly speaking, transfer to a higher level of care could be due to inappropriate triage, appropriate (preventive) transfer (which could include transfer to a more richly staffed unit for a specific procedure), relentless progression of disease despite maximal therapy, the occurrence of management errors, patient and family uncertainty about goals of care or inadequate understanding of treatment options and prognoses, or a combination of these factors. We could not make these distinctions with currently available electronic data. This is also true of postsurgical patients, in whom it is difficult to determine which transfers to intensive care might be planned (eg, in the case of surgical procedures where ICU care is anticipated) as opposed to the occurrence of a deterioration during or following surgery. Another major limitation of this study is our inability to identify code or no code status electronically. The elapsed LOS at time of death among patients who experienced a transfer to a higher level of care (as compared to patients who died in the ward without ever experiencing intra‐hospital transfer) suggests, but does not prove, that prolonged efforts were being made to keep them alive. We were also limited in terms of having access to other process data (eg, physician staffing levels, provision and timing of palliative care). Having ICU severity of illness scores would have permitted us to compare our cohort to those of other recent studies showing elevated mortality rates among transfer patients,911 but we have not yet developed that capability.
Consideration of our study findings suggests a possible research agenda that could be implemented by hospitalist researchers. This agenda should emphasize three areas: detection, intervention, and reflection.
With respect to detection, attention needs to be paid to better tools for quantifying patient risk at the time a decision to admit to the ward is made. It is likely that such tools will need to combine the attributes of our severity score (LAPS) with those of the manually assigned scores.30, 34 In some cases, use of these tools could lead a physician to change the locus of admission from the ward to the TCU or ICU, which could improve outcomes by ensuring more timely provision of intensive care. Since problems with initial triage could be due to factors other than the failure to suspect or anticipate impending instability, future research should also include a cognitive component (eg, quantifying what proportion of subsequent patient deteriorations could be ascribed to missed diagnoses35). Additional work also needs to be done on developing mathematical models that can inform electronic monitoring of ward (not just ICU) patients.
Research on interventions that hospitalists can use to prevent the need for intensive care or to improve the rescue rate should take two routes. The first is a disease‐specific route, which builds on the fact that a relatively small set of conditions (pneumonia, sepsis, gastrointestinal bleeding) account for most transfers to a higher level of care. Condition‐specific protocols, checklists, and bundles36 tailored to a ward environment (as opposed to the ICU or to the entire hospital) might prevent deteriorations in these patients, as has been reported for sepsis.37 The second route is to improve the overall capabilities of rapid response and code blue teams. Such research would need to include a more careful assessment of what commonalities exist among patients who were and were not successfully rescued by these teams. This approach would probably yield more insights than the current literature, which focuses on whether rapid response teams are a good thing or not.
Finally, research also needs to be performed on how hospitalists reflect on adverse outcomes among ward patients. Greater emphasis needs to be placed on moving beyond trigger tool approaches that rely on manual chart review. In an era of expanding use of electronic medical record systems, more work needs to be done on how to harness these to provide hospitalists with better quantitative and risk‐adjusted information. This information should not be limited to simply reporting rates of transfers and deaths. Rather, finer distinctions must be provided with respect of the type of patients (ie, more diagnostic detail), the clinical status of patients (ie, more physiologic detail), as well as the effects of including or excluding patients in whom therapeutic options may be limited (ie, do not resuscitate and comfort care patients) on reported rates. Ideally, researchers should develop better process and outcomes measures that could be tested in collaborative networks that include multiple nonacademic general medical‐surgical wards.
Acknowledgements
The authors thank Drs. Paul Feigenbaum, Alan Whippy, Joseph V. Selby, and Philip Madvig for reviewing the manuscript and Ms. Jennifer Calhoun for formatting the manuscript.
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Considerable research and public attention is being paid to the quantification, risk adjustment, and reporting of inpatient mortality.15 Inpatient mortality is reported as aggregate mortality (for all hospitalized patients or those with a specific diagnosis3, 6) or intensive care unit (ICU) mortality.7, 8 While reporting aggregate hospital or aggregate ICU mortality rates is useful, it is also important to develop reporting strategies that go beyond simply using data elements found in administrative databases (eg, diagnosis and procedure codes) to quantify practice variation. Ideally, such strategies would permit delineating processes of careparticularly those potentially under the control of hospitalists, not only intensiviststo identify improvement opportunities. One such process, which can be tracked using the bed history component of a patient's electronic medical record, is the transfer of patients between different units within the same hospital.
Several studies have documented that risk of ICU death is highest among patients transferred from general medical‐surgical wards, intermediate among direct admissions from the emergency department, and lowest among surgical admissions.911 Opportunities to reduce subsequent ICU mortality have been studied among ward patients who develop sepsis and are then transferred to the ICU,12 among patients who experience cardiac arrest,13, 14 as well as among patients with any physiological deterioration (eg, through the use of rapid response teams).1517 Most of these studies have been single‐center studies and/or studies reporting only an ICU denominator. While useful in some respects, such studies are less helpful to hospitalists, who would benefit from better understanding of the types of patients transferred and the total impact that transfers to a higher level of care make on general medical‐surgical wards. In addition, entities such as the Institute for Healthcare Improvement recommend the manual review of records of patients who were transferred from the ward to the ICU18 to identify performance improvement opportunities. While laudable, such approaches do not lend themselves to automated reporting strategies.
We recently described a new risk adjustment methodology for inpatient mortality based entirely on automated data preceding hospital admission and not restricted to ICU patients. This methodology, which has been externally validated in Ottawa, Canada, after development in the Kaiser Permanente Medical Care Program (KPMCP), permits quantification of a patient's pre‐existing comorbidity burden, physiologic derangement at the time of admission, and overall inpatient mortality risk.19, 20 The primary purpose of this study was to combine this methodology with bed history analysis to quantify the in‐hospital mortality and length of stay (LOS) of patients who experienced intra‐hospital transfers in a large, multihospital system. As a secondary goal, we also wanted to assess the degree to which these transfers could be predicted based on information available prior to a patient's admission.
ABBREVIATIONS AND TERMS USED IN TEXT
COPS: COmorbidity Point Score. Point score based on a patient's health care utilization diagnoses (during the year preceding admission to the hospital. Analogous to POA (present on admission) coding. Scores can range from 0 to a theoretical maximum of 701 but scores >200 are rare. With respect to a patient's pre‐existing comorbidity burden, the unadjusted relationship of COPS and inpatient mortality is as follows: a COPS <50 is associated with a mortality risk of <1%, <100 with a mortality risk of <5%, 100 to 145 with a mortality risk of 5% to 10%, and >145 with a mortality risk of 10% or more.
ICU: Intensive Care Unit. In this study, all ICUs have a minimum registered nurse to patient ratio of 1:2.
LAPS: Laboratory Acute Physiology Score. Point score based on 14 laboratory test results obtained in the 72 hours preceding hospitalization. With respect to a patient's physiologic derangement, the unadjusted relationship of LAPS and inpatient mortality is as follows: a LAPS <7 is associated with a mortality risk of <1%, <7 to 30 with a mortality risk of <5%, 30 to 60 with a mortality risk of 5% to 9%, and >60 with a mortality risk of 10% or more.
LOS: Exact hospital Length Of Stay. LOS is calculated from admission until first discharge home (i.e., it may span more than one hospital stay if a patient experienced inter‐hospital transport).
Predicted (expected) mortality risk: the % risk of death for a given patient based on his/her age, sex, admission diagnosis, COPS, and LAPS.
OEMR: Observed to Expected Mortality Ratio. For a given patient subset, the ratio of the actual mortality experienced by the subset to the expected (predicted) mortality for the subset. Predicted mortality is based on patients' age, sex, admission diagnosis, COPS, and LAPS.
OMELOS: Observed Minus Expected LOS. For a given patient subset, the difference between the actual number of hospital days experienced by the subset and the expected (predicted) number of hospital days for the subset. Predicted LOS is based on patients' age, sex, admission diagnosis, COPS, and LAPS.
TCU: Transitional Care Unit (also called intermediate care unit or stepdown unit). In this study, TCUs have variable nurse to patient ratios ranging from 1:2.5 to 1:3 and did not provide assisted ventilation, continuous pressor infusions, or invasive monitoring.
Materials and Methods
This project was approved by the Northern California KPMCP Institutional Review Board for the Protection of Human Subjects.
The Northern California KPMCP serves a total population of approximately 3.3 million members. Under a mutual exclusivity arrangement, physicians of The Permanente Medical Group, Inc., care for Kaiser Foundation Health Plan, Inc. members at facilities owned by Kaiser Foundation Hospitals, Inc. All Northern California KPMCP hospitals and clinics employ the same information systems with a common medical record number and can track care covered by the plan but delivered elsewhere. Databases maintained by the KPMCP capture admission and discharge times, admission and discharge diagnoses and procedures (assigned by professional coders), bed histories, inter‐hospital transfers, as well as the results of all inpatient and outpatient laboratory tests. The use of these databases for research has been described in multiple reports.2124
Our setting consisted of all 19 hospitals owned and operated by the KPMCP, whose characteristics are summarized in the Supporting Information Appendix available to interested readers. These include the 17 described in our previous report19 as well as 2 new hospitals (Antioch and Manteca) which are similar in size and type of population served. Our study population consisted of all patients admitted to these 19 hospitals who met these criteria: 1) hospitalization began from November 1st, 2006 through January 31st, 2008; 2) initial hospitalization occurred at a Northern California KPMCP hospital (ie, for inter‐hospital transfers, the first hospital stay occurred within the KPMCP); 3) age 15 years; and 4) hospitalization was not for childbirth.
We defined a linked hospitalization as the time period that began with a patient's admission to the hospital and ended with the patient's discharge (home, to a nursing home, or death). Linked hospitalizations can thus involve more than 1 hospital stay and could include a patient transfer from one hospital to another prior to definitive discharge. For linked hospitalizations, mortality was attributed to the admitting KPMCP hospital (ie, if a patient was admitted to hospital A, transferred to B, and died at hospital B, mortality was attributed to hospital A). We defined total LOS as the exact time in hours from when a patient was first admitted to the hospital until death or final discharge home or to a nursing home, while total ICU or transitional care unit (TCU, referred to as stepdown unit in some hospitals) LOS was calculated for all individual ICU or TCU stays during the hospital stay.
Intra‐Hospital Transfers
We grouped all possible hospital units into four types: general medical‐surgical ward (henceforth, ward); operating room (OR)/post‐anesthesia recovery (PAR); TCU; and ICU. In 2003, the KPMCP implemented a mandatory minimum staffing ratio of one registered nurse for every four patients in all its hospital units; in addition, staffing levels for designated ICUs adhered to the previously mandated minimum of one nurse for every 2 patients. So long as they adhere to these minimum ratios, individual hospitals have considerable autonomy with respect to how they staff or designate individual hospital units. Registered nurse‐to‐patient ratios during the time of this study were as follows: ward patients, 1:3.5 to 1:4; TCU patients, 1:2.5 to 1:3; and ICU patients, 1:1 to 1:2. Staffing ratios for the OR and PAR are more variable, depending on the surgical procedures involved. Current KPMCP databases do not permit accurate quantification of physician staffing. All 19 study hospitals had designated ICUs, 6 were teaching hospitals, and 11 had designated TCUs. None of the study hospitals had closed ICUs (units where only intensivists admit patients) and none had continuous coverage of the ICU by intensivists. While we were not able to employ electronic data to determine who made the decision to transfer, we did find considerable variation with respect to how intensivists covered the ICUs and how they interfaced with hospitalists. Staffing levels for specialized coronary care units and non‐ICU monitored beds were not standardized. All study hospitals had rapid response teams as well as code blue teams during the time period covered by this report. Respiratory care practitioners were available to patients in all hospital units, but considerable variation existed with respect to other services available (eg, cardiac catheterization units, provision of noninvasive positive pressure ventilation outside the ICU, etc.).
This report focuses on intra‐hospital transfers to the ICU and TCU, with special emphasis on nonsurgical transfers (due to space limitations, we are not reporting on the outcomes of patients whose first hospital unit was the OR; additional details on these patients are provided in the Supporting Information Appendix). For the purposes of this report, we defined the following admission types: direct admits (patients admitted to the ICU or TCU whose first hospital unit on admission was the ICU or TCU); and nonsurgical transfers to a higher level of care. These latter transfers could be of 3 types: ward to ICU, ward to TCU, and TCU to ICU. We also quantified the effect of inter‐hospital transfers.
Independent Variables
In addition to patients' age and sex, we employed the following independent variables to predict transfer to a higher level of care. These variables are part of the risk adjustment model described in greater detail in our previous report19 and were available electronically for all patients in the cohort. We grouped admission diagnoses into 44 broad diagnostic categories (Primary Conditions), and admission types into 4 groups (emergency medical, emergency surgical, elective medical, and elective surgical). We quantified patients' degree of physiologic derangement using a Laboratory‐based Acute Physiology Score (LAPS) using laboratory test results prior to hospitalization. We quantified patients' comorbid illness burden using a Comorbidity Point Score (COPS) based on patients' pre‐existing diagnoses over the 12‐month period preceding hospitalization. Lastly, we assigned each patient a predicted mortality risk (%) and LOS based on the above predictors,19 permitting calculation of observed to expected mortality ratios (OEMRs) and observed minus expected LOS (OMELOS).
Statistical Methods
All analyses were performed in SAS.25 We calculated standard descriptive statistics (medians, means, standard deviations) and compared different patient groupings using t and chi‐square tests. We employed a similar approach to that reported by Render et al.7 to calculate OEMR and OMELOS.
To determine the degree to which transfers to a higher level of care from the ward or TCU would be predictable using information available at the time of admission, we performed 4 sets of logistic regression analyses using the above‐mentioned predictors in which the outcome variables were as follows: 1) transfer occurring in the first 48 hours after admission (time frame by which point approximately half of the transferred patients experienced a transfer) among ward or TCU patients and 2) transfer occurring after 48 hours among ward or TCU patients. We evaluated the discrimination and calibration of these models using the same methods described in our original report (measuring the area under the receiver operator characteristic curve, or c statistic, and visually examining observed and expected mortality rates among predicted risk bands as well as risk deciles) as well as additional statistical tests recommended by Cook.19, 26
Results
During the study period, a total of 249,129 individual hospital stays involving 170,151 patients occurred at these 19 hospitals. After concatenation of inter‐hospital transfers, we were left with 237,208 linked hospitalizations. We excluded 26,738 linked hospitalizations that began at a non‐KPMCP hospital (ie, they were transported in), leaving a total of 210,470 linked hospitalizations involving 150,495 patients. The overall linked hospitalization mortality rate was 3.30%.
Table 1 summarizes cohort characteristics based on initial hospital location. On admission, ICU patients had the highest degree of physiologic derangement as well as the highest predicted mortality. Considerable inter‐hospital variation was present in both predictors and outcomes; details on these variations are provided in the Supporting Information Appendix.
| Ward | TCU | ICU | All* | |
|---|---|---|---|---|
| ||||
| n | 121,237 | 20,556 | 16,001 | 210,470 |
| Admitted via emergency department, n (%) | 99,909 (82.4) | 18,612 (90.5) | 13,847 (86.5) | 139,036 (66.1) |
| % range across hospitals | 55.0‐94.2 | 64.7‐97.6 | 49.5‐97.4 | 53.6‐76.9 |
| Male, n (%) | 53,744 (44.3) | 10,362 (50.4) | 8,378 (52.4) | 94,451 (44.9) |
| Age in years (mean SD) | 64.5 19.2 | 69.0 15.6 | 63.7 17.8 | 63.2 18.6 |
| LAPS (mean SD) | 19.2 18.0 | 23.3 19.5 | 31.7 25.7 | 16.7 19.0 |
| COPS (mean SD) | 90.4 64.0 | 99.2 65.9 | 94.5 67.5 | 84.7 61.8 |
| % predicted mortality (mean SD) | 4.0 7.1 | 4.6 7.3 | 8.7 12.8 | 3.6 7.3 |
| Observed in‐hospital deaths (n, %) | 3,793 (3.1) | 907 (4.4) | 1,995 (12.5) | 6,952 (3.3) |
| Observed to expected mortality ratio | 0.79 (0.77‐0.82) | 0.95 (0.89‐1.02) | 1.43 (1.36‐1.49) | 0.92 (0.89‐0.94) |
| Total hospital LOS, days (mean SD) | 4.6 7.5 | 5.3 10.0 | 7.8 14.0 | 4.6 8.1 |
Table 2 summarizes data from 3 groups of patients: patients initially admitted to the ward, or TCU, who did not experience a transfer to a higher level of care and patients admitted to these 2 units who did experience such a transfer. Patients who experienced a transfer constituted 5.3% (6,484/121,237) of ward patients and 6.7% (1,384/20,556) of TCU patients. Transferred patients tended to be older, have more acute physiologic derangement (higher LAPS), a greater pre‐existing illness burden (higher COPS), and a higher predicted mortality risk. Among ward patients, those with the following admission diagnoses were most likely to experience a transfer to a higher level of care: gastrointestinal bleeding (10.8% of all transfers), pneumonia (8.7%), and other infections (8.2%). The diagnoses most likely to be associated with death following transfer were cancer (death rate among transferred patients, 48%), renal disease (death rate, 36%), and liver disease (33%). Similar distributions were observed for TCU patients.
| Patients Initially Admitted to Ward, Remained There | Patients Initially Admitted to TCU, Remained There | Patients Transferred to Higher Level of Care | All | |
|---|---|---|---|---|
| ||||
| n | 114,753 | 19,172 | 7,868 | 141,793 |
| Male, n (%) | 50,586 (44.1) | 9,626 (50.2) | 3,894 (49.5) | 64,106 (45.2) |
| Age (mean SD) | 64.3 19.4 | 69.0 15.7 | 68.1 16.1 | 65.2 18.8 |
| LAPS (mean SD) | 18.9 17.8 | 22.7 19.1 | 26.7 21.0 | 19.8 18.3 |
| COPS (mean SD) | 89.4 63.7 | 98.3 65.5 | 107.9 67.6 | 91.7 64.4 |
| % predicted mortality risk (mean SD) | 3.8 7.0 | 4.4 7.0 | 6.5 8.8 | 4.1 7.1 |
| Admission diagnosis of pneumonia, n (%) | 5,624 (4.9) | 865 (4.5) | 684 (8.7) | 7,173 (5.1) |
| Admission diagnosis of sepsis, n (%) | 1,181 (1.0) | 227 (1.2) | 168 (2.1) | 1,576 (1.1) |
| Admission diagnosis of GI bleed, n (%) | 13,615 (11.9) | 1,448 (7.6) | 851 (10.8) | 15,914 (11.2) |
| Admission diagnosis of cancer, n (%) | 2,406 (2.1) | 80 (0.4) | 186 (2.4) | 2,672 (1.9) |
Table 3 compares outcomes among ward and TCU patients who did and did not experience a transfer to a higher level of care. The table shows that transferred patients were almost 3 times as likely to die, even after controlling for severity of illness, and that their hospital LOS was 9 days higher than expected. This increased risk was seen in all hospitals and among all transfer types (ward to ICU, ward to TCU, and TCU to ICU).
| Patients Initially Admitted to Ward, Remained There | Patients Initially Admitted to TCU, Remained There | Patients Transferred to Higher Level of Care | |
|---|---|---|---|
| |||
| n | 114,753 | 19,172 | 7,868 |
| Admitted to ICU, n (%) | 0 (0.0) | 0 (0.0) | 5,245 (66.7) |
| Ventilated, n (%) | 0 (0.0) | 0 (0.0) | 1,346 (17.1) |
| Died in the hospital, n (%) | 2,619 (2.3) | 572 (3.0) | 1,509 (19.2) |
| Length of stay, in days, at time of death (mean SD) | 7.0 11.9 | 8.3 12.4 | 16.2 23.7 |
| Observed to expected mortality ratio (95% CI) | 0.60 (0.57‐0.62) | 0.68 (0.63‐0.74) | 2.93 (2.79‐3.09) |
| Total hospital length of stay, days (mean SD) | 4.0 5.7 | 4.4 6.9 | 14.3 21.3 |
| Observed minus expected length of stay (95% CI) | 0.4 (0.3‐0.4) | 0.8 (0.7‐0.9) | 9.1 (8.6‐9.5) |
| Length of stay, in hours, at time of transfer (mean SD) | 80.8 167.2 | ||
Table 3 also shows that, among decedent patients, those who never left the ward or TCU died much sooner than those who died following transfer. Among direct admits to the ICU, the median LOS at time of death was 3.9 days, with a mean of 9.4 standard deviation of 19.9 days, while the corresponding times for TCU direct admits were a median and mean LOS of 6.5 and 11.7 19.5 days.
Table 4 summarizes outcomes among different patient subgroups that did and did not experience a transfer to a higher level of care. Based on location, patients who experienced a transfer from the TCU to the ICU had the highest crude death rate, but patients transferred from the ward to the ICU had the highest OEMR. On the other hand, if one divides patients by the degree of physiologic derangement, patients with low LAPS who experienced a transfer had the highest OEMR. With respect to LOS, patients transferred from the TCU to the ICU had the highest OMELOS (13.4 extra days).
| n (%)* | Death Rate (%) | OEMR | LOS (mean SD) | OMELOS | |
|---|---|---|---|---|---|
| |||||
| Never admitted to TCU or ICU | 157,632 (74.9) | 1.6 | 0.55 (0.53‐0.57) | 3.6 4.6 | 0.04 (0.02‐0.07) |
| Direct admit to TCU | 18,464 (8.8) | 2.9 | 0.66 (0.61‐0.72) | 4.2 5.8 | 0.60 (0.52‐0.68) |
| Direct admit to ICU | 14,655 (7.0) | 11.9 | 1.38 (1.32‐1.45) | 6.4 9.4 | 2.28 (2.14‐2.43) |
| Transferred from ward to ICU | 5,145 (2.4) | 21.5 | 3.23 (3.04‐3.42) | 15.7 21.6 | 10.33 (9.70‐10.96) |
| Transferred from ward to TCU | 3,144 (1.5) | 11.9 | 1.99 (1.79‐2.20) | 13.6 23.2 | 8.02 (7.23‐8.82) |
| Transferred from TCU to ICU | 1,107 (0.5) | 25.7 | 2.94 (2.61‐3.31) | 18.0 28.2 | 13.35 (11.49‐15.21) |
| Admitted to ward, COPS 80, no transfer to ICU or TCU | 55,405 (26.3) | 3.4 | 0.59 (0.56‐0.62) | 4.5 5.9 | 0.29 (0.24‐0.34) |
| Admitted to ward, COPS 80, did experience transfer to ICU or TCU | 4,851 (2.3) | 19.3 | 2.72 (2.55‐2.90) | 14.2 20.0 | 8.14 (7.56‐8.71) |
| Admitted to ward, COPS <80, no transfer to ICU or TCU | 57,421 (27.3) | 1.1 | 0.55 (0.51‐0.59) | 3.4 4.2 | 0.23 (0.19‐0.26) |
| Admitted to ward, COPS <80, did experience transfer to ICU or TCU | 3,560 (1.7) | 9.8 | 2.93 (2.63‐3.26) | 12.0 19.0 | 7.52 (6.89‐8.15) |
| Admitted to ward, LAPS 20, no transfer to ICU or TCU | 46,492 (22.1) | 4.2 | 0.59 (0.56‐0.61) | 4.6 5.4 | 0.16 (0.12‐0.21) |
| Admitted to ward, LAPS 20, did experience transfer to ICU or TCU | 4,070 (1.9) | 21.4 | 2.37 (2.22‐2.54) | 14.8 21.0 | 8.76 (8.06‐9.47) |
| Admitted to ward, LAPS <20, no transfer to ICU or TCU | 66,334 (31.5) | 0.9 | 0.55 (0.51‐0.60) | 3.5 4.9 | 0.32 (0.28‐0.36) |
| Admitted to ward, LAPS <20, did experience transfer to ICU or TCU | 4,341 (2.1) | 9.5 | 4.31 (3.90‐4.74) | 11.8 18.1 | 7.12 (6.61‐7.64) |
Transfers to a higher level of care at a different hospital, which in the KPMCP are usually planned, experienced lower mortality than transfers within the same hospital. For ward to TCU transfers, intra‐hospital transfers had a mortality of 12.1% while inter‐hospital transfers had a mortality of 5.7%. Corresponding rates for ward to ICU transfers were 21.7% and 11.2%, and for TCU to ICU transfers the rates were 25.9% and 12.5%, respectively.
Among patients initially admitted to the ward, a model to predict the occurrence of a transfer to a higher level of care (within 48 hours after admission) that included age, sex, admission type, primary condition, LAPS, COPS, and interaction terms had poor discrimination, with an area under the receiver operator characteristic (c statistic) of only 0.64. The c statistic for a model to predict transfer after 48 hours was 0.66. The corresponding models for TCU admits had c statistics of 0.67 and 0.68. All four models had poor calibration.
Discussion
Using automated bed history data permits characterizing a patient population with disproportionate mortality and LOS: intra‐hospital transfers to special care units (ICUs or TCUs). Indeed, the largest subset of these patients (those initially admitted to the ward or TCU) constituted only 3.7% of all admissions, but accounted for 24.2% of all ICU admissions, 21.7% of all hospital deaths, and 13.2% of all hospital days. These patients also had very elevated OEMRs and OMELOS. Models based on age, sex, preadmission laboratory test results, and comorbidities did not predict the occurrence of these transfers.
We performed multivariate analyses to explore the degree to which electronically assigned preadmission severity scores could predict these transfers. These analyses found that, compared to our ability to predict inpatient or 30‐day mortality at the time of admission, which is excellent, our ability to predict the occurrence of transfer after admission is much more limited. These results highlight the limitations of severity scores that rely on automated data, which may not have adequate discrimination when it comes to determining the risk of an adverse outcome within a narrow time frame. For example, among the 121,237 patients initially admitted to the ward who did not experience an intra‐hospital transfer, the mean LAPS was 18.9, while the mean LAPS among the 6,484 ward patients who did experience a transfer was 25.5. Differences between the mean and median LAPS, COPS, and predicted mortality risk among transferred and non‐transferred patients were significant (P < 0.0001 for all comparisons). However, examination of the distribution of LAPS, COPS, and predicted mortality risk between these two groups of patients showed considerable overlap.
Our methodology resembles Silber et al.'s27, 28 concept of failure to rescue in that it focuses on events occurring after hospitalization. Silber et al. argue that a hospital's quality can be measured by quantifying the degree to which patients who experience new problems are successfully rescued. Furthermore, quantification of those situations where rescue attempts are unsuccessful is felt to be superior to simply comparing raw or adjusted mortality rates because these are primarily determined by underlying case mix. The primary difference between Silber et al.'s approach and ours is at the level of detailthey specified a specific set of complications, whereas our measure is more generic and would include patients with many of the complications specified by Silber et al.27, 28
Most of the patients transferred to a higher level of care in our cohort survived (ie, were rescued), indicating that intensive care is beneficial. However, the fact that these patients had elevated OEMRs and OMELOS indicates that the real challenge facing hospitalists involves the timing of provision of a beneficial intervention. In theory, improved timing could result from earlier detection of problems, which is the underlying rationale for employing rapid response teams. However, the fact that our electronic tools (LAPS, COPS) cannot predict patient deteriorations within a narrow time frame suggests that early detection will remain a major challenge. Manually assigned vital signs scores designed for this purpose do not have good discrimination either.29, 30 This raises the possibility that, though patient groups may differ in terms of overall illness severity and mortality risk, differences at the individual patient level may be too subtle for clinicians to detect. Future research may thus need to focus on scores that combine laboratory data, vital signs, trends in data,31, 32 and newer proteomic markers (eg, procalcitonin).33 We also found that most transfers occurred early (within <72 hours), raising the possibility that at least some of these transfers may involve issues around triage rather than sudden deterioration.
Our study has important limitations. Due to resource constraints and limited data availability, we could not characterize the patients as well as might be desirable; in particular, we could not make full determinations of the actual reasons for patients' transfer for all patients. Broadly speaking, transfer to a higher level of care could be due to inappropriate triage, appropriate (preventive) transfer (which could include transfer to a more richly staffed unit for a specific procedure), relentless progression of disease despite maximal therapy, the occurrence of management errors, patient and family uncertainty about goals of care or inadequate understanding of treatment options and prognoses, or a combination of these factors. We could not make these distinctions with currently available electronic data. This is also true of postsurgical patients, in whom it is difficult to determine which transfers to intensive care might be planned (eg, in the case of surgical procedures where ICU care is anticipated) as opposed to the occurrence of a deterioration during or following surgery. Another major limitation of this study is our inability to identify code or no code status electronically. The elapsed LOS at time of death among patients who experienced a transfer to a higher level of care (as compared to patients who died in the ward without ever experiencing intra‐hospital transfer) suggests, but does not prove, that prolonged efforts were being made to keep them alive. We were also limited in terms of having access to other process data (eg, physician staffing levels, provision and timing of palliative care). Having ICU severity of illness scores would have permitted us to compare our cohort to those of other recent studies showing elevated mortality rates among transfer patients,911 but we have not yet developed that capability.
Consideration of our study findings suggests a possible research agenda that could be implemented by hospitalist researchers. This agenda should emphasize three areas: detection, intervention, and reflection.
With respect to detection, attention needs to be paid to better tools for quantifying patient risk at the time a decision to admit to the ward is made. It is likely that such tools will need to combine the attributes of our severity score (LAPS) with those of the manually assigned scores.30, 34 In some cases, use of these tools could lead a physician to change the locus of admission from the ward to the TCU or ICU, which could improve outcomes by ensuring more timely provision of intensive care. Since problems with initial triage could be due to factors other than the failure to suspect or anticipate impending instability, future research should also include a cognitive component (eg, quantifying what proportion of subsequent patient deteriorations could be ascribed to missed diagnoses35). Additional work also needs to be done on developing mathematical models that can inform electronic monitoring of ward (not just ICU) patients.
Research on interventions that hospitalists can use to prevent the need for intensive care or to improve the rescue rate should take two routes. The first is a disease‐specific route, which builds on the fact that a relatively small set of conditions (pneumonia, sepsis, gastrointestinal bleeding) account for most transfers to a higher level of care. Condition‐specific protocols, checklists, and bundles36 tailored to a ward environment (as opposed to the ICU or to the entire hospital) might prevent deteriorations in these patients, as has been reported for sepsis.37 The second route is to improve the overall capabilities of rapid response and code blue teams. Such research would need to include a more careful assessment of what commonalities exist among patients who were and were not successfully rescued by these teams. This approach would probably yield more insights than the current literature, which focuses on whether rapid response teams are a good thing or not.
Finally, research also needs to be performed on how hospitalists reflect on adverse outcomes among ward patients. Greater emphasis needs to be placed on moving beyond trigger tool approaches that rely on manual chart review. In an era of expanding use of electronic medical record systems, more work needs to be done on how to harness these to provide hospitalists with better quantitative and risk‐adjusted information. This information should not be limited to simply reporting rates of transfers and deaths. Rather, finer distinctions must be provided with respect of the type of patients (ie, more diagnostic detail), the clinical status of patients (ie, more physiologic detail), as well as the effects of including or excluding patients in whom therapeutic options may be limited (ie, do not resuscitate and comfort care patients) on reported rates. Ideally, researchers should develop better process and outcomes measures that could be tested in collaborative networks that include multiple nonacademic general medical‐surgical wards.
Acknowledgements
The authors thank Drs. Paul Feigenbaum, Alan Whippy, Joseph V. Selby, and Philip Madvig for reviewing the manuscript and Ms. Jennifer Calhoun for formatting the manuscript.
Considerable research and public attention is being paid to the quantification, risk adjustment, and reporting of inpatient mortality.15 Inpatient mortality is reported as aggregate mortality (for all hospitalized patients or those with a specific diagnosis3, 6) or intensive care unit (ICU) mortality.7, 8 While reporting aggregate hospital or aggregate ICU mortality rates is useful, it is also important to develop reporting strategies that go beyond simply using data elements found in administrative databases (eg, diagnosis and procedure codes) to quantify practice variation. Ideally, such strategies would permit delineating processes of careparticularly those potentially under the control of hospitalists, not only intensiviststo identify improvement opportunities. One such process, which can be tracked using the bed history component of a patient's electronic medical record, is the transfer of patients between different units within the same hospital.
Several studies have documented that risk of ICU death is highest among patients transferred from general medical‐surgical wards, intermediate among direct admissions from the emergency department, and lowest among surgical admissions.911 Opportunities to reduce subsequent ICU mortality have been studied among ward patients who develop sepsis and are then transferred to the ICU,12 among patients who experience cardiac arrest,13, 14 as well as among patients with any physiological deterioration (eg, through the use of rapid response teams).1517 Most of these studies have been single‐center studies and/or studies reporting only an ICU denominator. While useful in some respects, such studies are less helpful to hospitalists, who would benefit from better understanding of the types of patients transferred and the total impact that transfers to a higher level of care make on general medical‐surgical wards. In addition, entities such as the Institute for Healthcare Improvement recommend the manual review of records of patients who were transferred from the ward to the ICU18 to identify performance improvement opportunities. While laudable, such approaches do not lend themselves to automated reporting strategies.
We recently described a new risk adjustment methodology for inpatient mortality based entirely on automated data preceding hospital admission and not restricted to ICU patients. This methodology, which has been externally validated in Ottawa, Canada, after development in the Kaiser Permanente Medical Care Program (KPMCP), permits quantification of a patient's pre‐existing comorbidity burden, physiologic derangement at the time of admission, and overall inpatient mortality risk.19, 20 The primary purpose of this study was to combine this methodology with bed history analysis to quantify the in‐hospital mortality and length of stay (LOS) of patients who experienced intra‐hospital transfers in a large, multihospital system. As a secondary goal, we also wanted to assess the degree to which these transfers could be predicted based on information available prior to a patient's admission.
ABBREVIATIONS AND TERMS USED IN TEXT
COPS: COmorbidity Point Score. Point score based on a patient's health care utilization diagnoses (during the year preceding admission to the hospital. Analogous to POA (present on admission) coding. Scores can range from 0 to a theoretical maximum of 701 but scores >200 are rare. With respect to a patient's pre‐existing comorbidity burden, the unadjusted relationship of COPS and inpatient mortality is as follows: a COPS <50 is associated with a mortality risk of <1%, <100 with a mortality risk of <5%, 100 to 145 with a mortality risk of 5% to 10%, and >145 with a mortality risk of 10% or more.
ICU: Intensive Care Unit. In this study, all ICUs have a minimum registered nurse to patient ratio of 1:2.
LAPS: Laboratory Acute Physiology Score. Point score based on 14 laboratory test results obtained in the 72 hours preceding hospitalization. With respect to a patient's physiologic derangement, the unadjusted relationship of LAPS and inpatient mortality is as follows: a LAPS <7 is associated with a mortality risk of <1%, <7 to 30 with a mortality risk of <5%, 30 to 60 with a mortality risk of 5% to 9%, and >60 with a mortality risk of 10% or more.
LOS: Exact hospital Length Of Stay. LOS is calculated from admission until first discharge home (i.e., it may span more than one hospital stay if a patient experienced inter‐hospital transport).
Predicted (expected) mortality risk: the % risk of death for a given patient based on his/her age, sex, admission diagnosis, COPS, and LAPS.
OEMR: Observed to Expected Mortality Ratio. For a given patient subset, the ratio of the actual mortality experienced by the subset to the expected (predicted) mortality for the subset. Predicted mortality is based on patients' age, sex, admission diagnosis, COPS, and LAPS.
OMELOS: Observed Minus Expected LOS. For a given patient subset, the difference between the actual number of hospital days experienced by the subset and the expected (predicted) number of hospital days for the subset. Predicted LOS is based on patients' age, sex, admission diagnosis, COPS, and LAPS.
TCU: Transitional Care Unit (also called intermediate care unit or stepdown unit). In this study, TCUs have variable nurse to patient ratios ranging from 1:2.5 to 1:3 and did not provide assisted ventilation, continuous pressor infusions, or invasive monitoring.
Materials and Methods
This project was approved by the Northern California KPMCP Institutional Review Board for the Protection of Human Subjects.
The Northern California KPMCP serves a total population of approximately 3.3 million members. Under a mutual exclusivity arrangement, physicians of The Permanente Medical Group, Inc., care for Kaiser Foundation Health Plan, Inc. members at facilities owned by Kaiser Foundation Hospitals, Inc. All Northern California KPMCP hospitals and clinics employ the same information systems with a common medical record number and can track care covered by the plan but delivered elsewhere. Databases maintained by the KPMCP capture admission and discharge times, admission and discharge diagnoses and procedures (assigned by professional coders), bed histories, inter‐hospital transfers, as well as the results of all inpatient and outpatient laboratory tests. The use of these databases for research has been described in multiple reports.2124
Our setting consisted of all 19 hospitals owned and operated by the KPMCP, whose characteristics are summarized in the Supporting Information Appendix available to interested readers. These include the 17 described in our previous report19 as well as 2 new hospitals (Antioch and Manteca) which are similar in size and type of population served. Our study population consisted of all patients admitted to these 19 hospitals who met these criteria: 1) hospitalization began from November 1st, 2006 through January 31st, 2008; 2) initial hospitalization occurred at a Northern California KPMCP hospital (ie, for inter‐hospital transfers, the first hospital stay occurred within the KPMCP); 3) age 15 years; and 4) hospitalization was not for childbirth.
We defined a linked hospitalization as the time period that began with a patient's admission to the hospital and ended with the patient's discharge (home, to a nursing home, or death). Linked hospitalizations can thus involve more than 1 hospital stay and could include a patient transfer from one hospital to another prior to definitive discharge. For linked hospitalizations, mortality was attributed to the admitting KPMCP hospital (ie, if a patient was admitted to hospital A, transferred to B, and died at hospital B, mortality was attributed to hospital A). We defined total LOS as the exact time in hours from when a patient was first admitted to the hospital until death or final discharge home or to a nursing home, while total ICU or transitional care unit (TCU, referred to as stepdown unit in some hospitals) LOS was calculated for all individual ICU or TCU stays during the hospital stay.
Intra‐Hospital Transfers
We grouped all possible hospital units into four types: general medical‐surgical ward (henceforth, ward); operating room (OR)/post‐anesthesia recovery (PAR); TCU; and ICU. In 2003, the KPMCP implemented a mandatory minimum staffing ratio of one registered nurse for every four patients in all its hospital units; in addition, staffing levels for designated ICUs adhered to the previously mandated minimum of one nurse for every 2 patients. So long as they adhere to these minimum ratios, individual hospitals have considerable autonomy with respect to how they staff or designate individual hospital units. Registered nurse‐to‐patient ratios during the time of this study were as follows: ward patients, 1:3.5 to 1:4; TCU patients, 1:2.5 to 1:3; and ICU patients, 1:1 to 1:2. Staffing ratios for the OR and PAR are more variable, depending on the surgical procedures involved. Current KPMCP databases do not permit accurate quantification of physician staffing. All 19 study hospitals had designated ICUs, 6 were teaching hospitals, and 11 had designated TCUs. None of the study hospitals had closed ICUs (units where only intensivists admit patients) and none had continuous coverage of the ICU by intensivists. While we were not able to employ electronic data to determine who made the decision to transfer, we did find considerable variation with respect to how intensivists covered the ICUs and how they interfaced with hospitalists. Staffing levels for specialized coronary care units and non‐ICU monitored beds were not standardized. All study hospitals had rapid response teams as well as code blue teams during the time period covered by this report. Respiratory care practitioners were available to patients in all hospital units, but considerable variation existed with respect to other services available (eg, cardiac catheterization units, provision of noninvasive positive pressure ventilation outside the ICU, etc.).
This report focuses on intra‐hospital transfers to the ICU and TCU, with special emphasis on nonsurgical transfers (due to space limitations, we are not reporting on the outcomes of patients whose first hospital unit was the OR; additional details on these patients are provided in the Supporting Information Appendix). For the purposes of this report, we defined the following admission types: direct admits (patients admitted to the ICU or TCU whose first hospital unit on admission was the ICU or TCU); and nonsurgical transfers to a higher level of care. These latter transfers could be of 3 types: ward to ICU, ward to TCU, and TCU to ICU. We also quantified the effect of inter‐hospital transfers.
Independent Variables
In addition to patients' age and sex, we employed the following independent variables to predict transfer to a higher level of care. These variables are part of the risk adjustment model described in greater detail in our previous report19 and were available electronically for all patients in the cohort. We grouped admission diagnoses into 44 broad diagnostic categories (Primary Conditions), and admission types into 4 groups (emergency medical, emergency surgical, elective medical, and elective surgical). We quantified patients' degree of physiologic derangement using a Laboratory‐based Acute Physiology Score (LAPS) using laboratory test results prior to hospitalization. We quantified patients' comorbid illness burden using a Comorbidity Point Score (COPS) based on patients' pre‐existing diagnoses over the 12‐month period preceding hospitalization. Lastly, we assigned each patient a predicted mortality risk (%) and LOS based on the above predictors,19 permitting calculation of observed to expected mortality ratios (OEMRs) and observed minus expected LOS (OMELOS).
Statistical Methods
All analyses were performed in SAS.25 We calculated standard descriptive statistics (medians, means, standard deviations) and compared different patient groupings using t and chi‐square tests. We employed a similar approach to that reported by Render et al.7 to calculate OEMR and OMELOS.
To determine the degree to which transfers to a higher level of care from the ward or TCU would be predictable using information available at the time of admission, we performed 4 sets of logistic regression analyses using the above‐mentioned predictors in which the outcome variables were as follows: 1) transfer occurring in the first 48 hours after admission (time frame by which point approximately half of the transferred patients experienced a transfer) among ward or TCU patients and 2) transfer occurring after 48 hours among ward or TCU patients. We evaluated the discrimination and calibration of these models using the same methods described in our original report (measuring the area under the receiver operator characteristic curve, or c statistic, and visually examining observed and expected mortality rates among predicted risk bands as well as risk deciles) as well as additional statistical tests recommended by Cook.19, 26
Results
During the study period, a total of 249,129 individual hospital stays involving 170,151 patients occurred at these 19 hospitals. After concatenation of inter‐hospital transfers, we were left with 237,208 linked hospitalizations. We excluded 26,738 linked hospitalizations that began at a non‐KPMCP hospital (ie, they were transported in), leaving a total of 210,470 linked hospitalizations involving 150,495 patients. The overall linked hospitalization mortality rate was 3.30%.
Table 1 summarizes cohort characteristics based on initial hospital location. On admission, ICU patients had the highest degree of physiologic derangement as well as the highest predicted mortality. Considerable inter‐hospital variation was present in both predictors and outcomes; details on these variations are provided in the Supporting Information Appendix.
| Ward | TCU | ICU | All* | |
|---|---|---|---|---|
| ||||
| n | 121,237 | 20,556 | 16,001 | 210,470 |
| Admitted via emergency department, n (%) | 99,909 (82.4) | 18,612 (90.5) | 13,847 (86.5) | 139,036 (66.1) |
| % range across hospitals | 55.0‐94.2 | 64.7‐97.6 | 49.5‐97.4 | 53.6‐76.9 |
| Male, n (%) | 53,744 (44.3) | 10,362 (50.4) | 8,378 (52.4) | 94,451 (44.9) |
| Age in years (mean SD) | 64.5 19.2 | 69.0 15.6 | 63.7 17.8 | 63.2 18.6 |
| LAPS (mean SD) | 19.2 18.0 | 23.3 19.5 | 31.7 25.7 | 16.7 19.0 |
| COPS (mean SD) | 90.4 64.0 | 99.2 65.9 | 94.5 67.5 | 84.7 61.8 |
| % predicted mortality (mean SD) | 4.0 7.1 | 4.6 7.3 | 8.7 12.8 | 3.6 7.3 |
| Observed in‐hospital deaths (n, %) | 3,793 (3.1) | 907 (4.4) | 1,995 (12.5) | 6,952 (3.3) |
| Observed to expected mortality ratio | 0.79 (0.77‐0.82) | 0.95 (0.89‐1.02) | 1.43 (1.36‐1.49) | 0.92 (0.89‐0.94) |
| Total hospital LOS, days (mean SD) | 4.6 7.5 | 5.3 10.0 | 7.8 14.0 | 4.6 8.1 |
Table 2 summarizes data from 3 groups of patients: patients initially admitted to the ward, or TCU, who did not experience a transfer to a higher level of care and patients admitted to these 2 units who did experience such a transfer. Patients who experienced a transfer constituted 5.3% (6,484/121,237) of ward patients and 6.7% (1,384/20,556) of TCU patients. Transferred patients tended to be older, have more acute physiologic derangement (higher LAPS), a greater pre‐existing illness burden (higher COPS), and a higher predicted mortality risk. Among ward patients, those with the following admission diagnoses were most likely to experience a transfer to a higher level of care: gastrointestinal bleeding (10.8% of all transfers), pneumonia (8.7%), and other infections (8.2%). The diagnoses most likely to be associated with death following transfer were cancer (death rate among transferred patients, 48%), renal disease (death rate, 36%), and liver disease (33%). Similar distributions were observed for TCU patients.
| Patients Initially Admitted to Ward, Remained There | Patients Initially Admitted to TCU, Remained There | Patients Transferred to Higher Level of Care | All | |
|---|---|---|---|---|
| ||||
| n | 114,753 | 19,172 | 7,868 | 141,793 |
| Male, n (%) | 50,586 (44.1) | 9,626 (50.2) | 3,894 (49.5) | 64,106 (45.2) |
| Age (mean SD) | 64.3 19.4 | 69.0 15.7 | 68.1 16.1 | 65.2 18.8 |
| LAPS (mean SD) | 18.9 17.8 | 22.7 19.1 | 26.7 21.0 | 19.8 18.3 |
| COPS (mean SD) | 89.4 63.7 | 98.3 65.5 | 107.9 67.6 | 91.7 64.4 |
| % predicted mortality risk (mean SD) | 3.8 7.0 | 4.4 7.0 | 6.5 8.8 | 4.1 7.1 |
| Admission diagnosis of pneumonia, n (%) | 5,624 (4.9) | 865 (4.5) | 684 (8.7) | 7,173 (5.1) |
| Admission diagnosis of sepsis, n (%) | 1,181 (1.0) | 227 (1.2) | 168 (2.1) | 1,576 (1.1) |
| Admission diagnosis of GI bleed, n (%) | 13,615 (11.9) | 1,448 (7.6) | 851 (10.8) | 15,914 (11.2) |
| Admission diagnosis of cancer, n (%) | 2,406 (2.1) | 80 (0.4) | 186 (2.4) | 2,672 (1.9) |
Table 3 compares outcomes among ward and TCU patients who did and did not experience a transfer to a higher level of care. The table shows that transferred patients were almost 3 times as likely to die, even after controlling for severity of illness, and that their hospital LOS was 9 days higher than expected. This increased risk was seen in all hospitals and among all transfer types (ward to ICU, ward to TCU, and TCU to ICU).
| Patients Initially Admitted to Ward, Remained There | Patients Initially Admitted to TCU, Remained There | Patients Transferred to Higher Level of Care | |
|---|---|---|---|
| |||
| n | 114,753 | 19,172 | 7,868 |
| Admitted to ICU, n (%) | 0 (0.0) | 0 (0.0) | 5,245 (66.7) |
| Ventilated, n (%) | 0 (0.0) | 0 (0.0) | 1,346 (17.1) |
| Died in the hospital, n (%) | 2,619 (2.3) | 572 (3.0) | 1,509 (19.2) |
| Length of stay, in days, at time of death (mean SD) | 7.0 11.9 | 8.3 12.4 | 16.2 23.7 |
| Observed to expected mortality ratio (95% CI) | 0.60 (0.57‐0.62) | 0.68 (0.63‐0.74) | 2.93 (2.79‐3.09) |
| Total hospital length of stay, days (mean SD) | 4.0 5.7 | 4.4 6.9 | 14.3 21.3 |
| Observed minus expected length of stay (95% CI) | 0.4 (0.3‐0.4) | 0.8 (0.7‐0.9) | 9.1 (8.6‐9.5) |
| Length of stay, in hours, at time of transfer (mean SD) | 80.8 167.2 | ||
Table 3 also shows that, among decedent patients, those who never left the ward or TCU died much sooner than those who died following transfer. Among direct admits to the ICU, the median LOS at time of death was 3.9 days, with a mean of 9.4 standard deviation of 19.9 days, while the corresponding times for TCU direct admits were a median and mean LOS of 6.5 and 11.7 19.5 days.
Table 4 summarizes outcomes among different patient subgroups that did and did not experience a transfer to a higher level of care. Based on location, patients who experienced a transfer from the TCU to the ICU had the highest crude death rate, but patients transferred from the ward to the ICU had the highest OEMR. On the other hand, if one divides patients by the degree of physiologic derangement, patients with low LAPS who experienced a transfer had the highest OEMR. With respect to LOS, patients transferred from the TCU to the ICU had the highest OMELOS (13.4 extra days).
| n (%)* | Death Rate (%) | OEMR | LOS (mean SD) | OMELOS | |
|---|---|---|---|---|---|
| |||||
| Never admitted to TCU or ICU | 157,632 (74.9) | 1.6 | 0.55 (0.53‐0.57) | 3.6 4.6 | 0.04 (0.02‐0.07) |
| Direct admit to TCU | 18,464 (8.8) | 2.9 | 0.66 (0.61‐0.72) | 4.2 5.8 | 0.60 (0.52‐0.68) |
| Direct admit to ICU | 14,655 (7.0) | 11.9 | 1.38 (1.32‐1.45) | 6.4 9.4 | 2.28 (2.14‐2.43) |
| Transferred from ward to ICU | 5,145 (2.4) | 21.5 | 3.23 (3.04‐3.42) | 15.7 21.6 | 10.33 (9.70‐10.96) |
| Transferred from ward to TCU | 3,144 (1.5) | 11.9 | 1.99 (1.79‐2.20) | 13.6 23.2 | 8.02 (7.23‐8.82) |
| Transferred from TCU to ICU | 1,107 (0.5) | 25.7 | 2.94 (2.61‐3.31) | 18.0 28.2 | 13.35 (11.49‐15.21) |
| Admitted to ward, COPS 80, no transfer to ICU or TCU | 55,405 (26.3) | 3.4 | 0.59 (0.56‐0.62) | 4.5 5.9 | 0.29 (0.24‐0.34) |
| Admitted to ward, COPS 80, did experience transfer to ICU or TCU | 4,851 (2.3) | 19.3 | 2.72 (2.55‐2.90) | 14.2 20.0 | 8.14 (7.56‐8.71) |
| Admitted to ward, COPS <80, no transfer to ICU or TCU | 57,421 (27.3) | 1.1 | 0.55 (0.51‐0.59) | 3.4 4.2 | 0.23 (0.19‐0.26) |
| Admitted to ward, COPS <80, did experience transfer to ICU or TCU | 3,560 (1.7) | 9.8 | 2.93 (2.63‐3.26) | 12.0 19.0 | 7.52 (6.89‐8.15) |
| Admitted to ward, LAPS 20, no transfer to ICU or TCU | 46,492 (22.1) | 4.2 | 0.59 (0.56‐0.61) | 4.6 5.4 | 0.16 (0.12‐0.21) |
| Admitted to ward, LAPS 20, did experience transfer to ICU or TCU | 4,070 (1.9) | 21.4 | 2.37 (2.22‐2.54) | 14.8 21.0 | 8.76 (8.06‐9.47) |
| Admitted to ward, LAPS <20, no transfer to ICU or TCU | 66,334 (31.5) | 0.9 | 0.55 (0.51‐0.60) | 3.5 4.9 | 0.32 (0.28‐0.36) |
| Admitted to ward, LAPS <20, did experience transfer to ICU or TCU | 4,341 (2.1) | 9.5 | 4.31 (3.90‐4.74) | 11.8 18.1 | 7.12 (6.61‐7.64) |
Transfers to a higher level of care at a different hospital, which in the KPMCP are usually planned, experienced lower mortality than transfers within the same hospital. For ward to TCU transfers, intra‐hospital transfers had a mortality of 12.1% while inter‐hospital transfers had a mortality of 5.7%. Corresponding rates for ward to ICU transfers were 21.7% and 11.2%, and for TCU to ICU transfers the rates were 25.9% and 12.5%, respectively.
Among patients initially admitted to the ward, a model to predict the occurrence of a transfer to a higher level of care (within 48 hours after admission) that included age, sex, admission type, primary condition, LAPS, COPS, and interaction terms had poor discrimination, with an area under the receiver operator characteristic (c statistic) of only 0.64. The c statistic for a model to predict transfer after 48 hours was 0.66. The corresponding models for TCU admits had c statistics of 0.67 and 0.68. All four models had poor calibration.
Discussion
Using automated bed history data permits characterizing a patient population with disproportionate mortality and LOS: intra‐hospital transfers to special care units (ICUs or TCUs). Indeed, the largest subset of these patients (those initially admitted to the ward or TCU) constituted only 3.7% of all admissions, but accounted for 24.2% of all ICU admissions, 21.7% of all hospital deaths, and 13.2% of all hospital days. These patients also had very elevated OEMRs and OMELOS. Models based on age, sex, preadmission laboratory test results, and comorbidities did not predict the occurrence of these transfers.
We performed multivariate analyses to explore the degree to which electronically assigned preadmission severity scores could predict these transfers. These analyses found that, compared to our ability to predict inpatient or 30‐day mortality at the time of admission, which is excellent, our ability to predict the occurrence of transfer after admission is much more limited. These results highlight the limitations of severity scores that rely on automated data, which may not have adequate discrimination when it comes to determining the risk of an adverse outcome within a narrow time frame. For example, among the 121,237 patients initially admitted to the ward who did not experience an intra‐hospital transfer, the mean LAPS was 18.9, while the mean LAPS among the 6,484 ward patients who did experience a transfer was 25.5. Differences between the mean and median LAPS, COPS, and predicted mortality risk among transferred and non‐transferred patients were significant (P < 0.0001 for all comparisons). However, examination of the distribution of LAPS, COPS, and predicted mortality risk between these two groups of patients showed considerable overlap.
Our methodology resembles Silber et al.'s27, 28 concept of failure to rescue in that it focuses on events occurring after hospitalization. Silber et al. argue that a hospital's quality can be measured by quantifying the degree to which patients who experience new problems are successfully rescued. Furthermore, quantification of those situations where rescue attempts are unsuccessful is felt to be superior to simply comparing raw or adjusted mortality rates because these are primarily determined by underlying case mix. The primary difference between Silber et al.'s approach and ours is at the level of detailthey specified a specific set of complications, whereas our measure is more generic and would include patients with many of the complications specified by Silber et al.27, 28
Most of the patients transferred to a higher level of care in our cohort survived (ie, were rescued), indicating that intensive care is beneficial. However, the fact that these patients had elevated OEMRs and OMELOS indicates that the real challenge facing hospitalists involves the timing of provision of a beneficial intervention. In theory, improved timing could result from earlier detection of problems, which is the underlying rationale for employing rapid response teams. However, the fact that our electronic tools (LAPS, COPS) cannot predict patient deteriorations within a narrow time frame suggests that early detection will remain a major challenge. Manually assigned vital signs scores designed for this purpose do not have good discrimination either.29, 30 This raises the possibility that, though patient groups may differ in terms of overall illness severity and mortality risk, differences at the individual patient level may be too subtle for clinicians to detect. Future research may thus need to focus on scores that combine laboratory data, vital signs, trends in data,31, 32 and newer proteomic markers (eg, procalcitonin).33 We also found that most transfers occurred early (within <72 hours), raising the possibility that at least some of these transfers may involve issues around triage rather than sudden deterioration.
Our study has important limitations. Due to resource constraints and limited data availability, we could not characterize the patients as well as might be desirable; in particular, we could not make full determinations of the actual reasons for patients' transfer for all patients. Broadly speaking, transfer to a higher level of care could be due to inappropriate triage, appropriate (preventive) transfer (which could include transfer to a more richly staffed unit for a specific procedure), relentless progression of disease despite maximal therapy, the occurrence of management errors, patient and family uncertainty about goals of care or inadequate understanding of treatment options and prognoses, or a combination of these factors. We could not make these distinctions with currently available electronic data. This is also true of postsurgical patients, in whom it is difficult to determine which transfers to intensive care might be planned (eg, in the case of surgical procedures where ICU care is anticipated) as opposed to the occurrence of a deterioration during or following surgery. Another major limitation of this study is our inability to identify code or no code status electronically. The elapsed LOS at time of death among patients who experienced a transfer to a higher level of care (as compared to patients who died in the ward without ever experiencing intra‐hospital transfer) suggests, but does not prove, that prolonged efforts were being made to keep them alive. We were also limited in terms of having access to other process data (eg, physician staffing levels, provision and timing of palliative care). Having ICU severity of illness scores would have permitted us to compare our cohort to those of other recent studies showing elevated mortality rates among transfer patients,911 but we have not yet developed that capability.
Consideration of our study findings suggests a possible research agenda that could be implemented by hospitalist researchers. This agenda should emphasize three areas: detection, intervention, and reflection.
With respect to detection, attention needs to be paid to better tools for quantifying patient risk at the time a decision to admit to the ward is made. It is likely that such tools will need to combine the attributes of our severity score (LAPS) with those of the manually assigned scores.30, 34 In some cases, use of these tools could lead a physician to change the locus of admission from the ward to the TCU or ICU, which could improve outcomes by ensuring more timely provision of intensive care. Since problems with initial triage could be due to factors other than the failure to suspect or anticipate impending instability, future research should also include a cognitive component (eg, quantifying what proportion of subsequent patient deteriorations could be ascribed to missed diagnoses35). Additional work also needs to be done on developing mathematical models that can inform electronic monitoring of ward (not just ICU) patients.
Research on interventions that hospitalists can use to prevent the need for intensive care or to improve the rescue rate should take two routes. The first is a disease‐specific route, which builds on the fact that a relatively small set of conditions (pneumonia, sepsis, gastrointestinal bleeding) account for most transfers to a higher level of care. Condition‐specific protocols, checklists, and bundles36 tailored to a ward environment (as opposed to the ICU or to the entire hospital) might prevent deteriorations in these patients, as has been reported for sepsis.37 The second route is to improve the overall capabilities of rapid response and code blue teams. Such research would need to include a more careful assessment of what commonalities exist among patients who were and were not successfully rescued by these teams. This approach would probably yield more insights than the current literature, which focuses on whether rapid response teams are a good thing or not.
Finally, research also needs to be performed on how hospitalists reflect on adverse outcomes among ward patients. Greater emphasis needs to be placed on moving beyond trigger tool approaches that rely on manual chart review. In an era of expanding use of electronic medical record systems, more work needs to be done on how to harness these to provide hospitalists with better quantitative and risk‐adjusted information. This information should not be limited to simply reporting rates of transfers and deaths. Rather, finer distinctions must be provided with respect of the type of patients (ie, more diagnostic detail), the clinical status of patients (ie, more physiologic detail), as well as the effects of including or excluding patients in whom therapeutic options may be limited (ie, do not resuscitate and comfort care patients) on reported rates. Ideally, researchers should develop better process and outcomes measures that could be tested in collaborative networks that include multiple nonacademic general medical‐surgical wards.
Acknowledgements
The authors thank Drs. Paul Feigenbaum, Alan Whippy, Joseph V. Selby, and Philip Madvig for reviewing the manuscript and Ms. Jennifer Calhoun for formatting the manuscript.
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- ,.Identifying poor‐quality hospitals. Can hospital mortality rates detect quality problems for medical diagnoses?Med Care.1996;34(8):737–753.
- ,,.Surgical mortality as an indicator of hospital quality: the problem with small sample size.JAMA.2004;292(7):847–851.
- State of California Office of Statewide Health Planning and Development. AHRQ ‐ Inpatient quality indicators (IQIs) hospital inpatient mortality indicators for California. Available at: http://www.oshpd.ca.gov/HID/Products/PatDischargeData/AHRQ/iqi‐imi_overview.html. Accessed June2010.
- ,,, et al.Enhancement of claims data to improve risk adjustment of hospital mortality.JAMA.2007;297(1):71–76.
- ,,, et al.Variation in outcomes in Veterans Affairs intensive care units with a computerized severity measure.Crit Care Med.2005;33(5):930–939.
- ,,,.Acute Physiology and Chronic Health Evaluation (APACHE) IV: hospital mortality assessment for today's critically ill patients.Crit Care Med.2006;34(5):1297–1310.
- ,,,.Day of the week of intensive care admission and patient outcomes: a multisite regional evaluation.Med Care.2002;40(6):530–539.
- ,,, et al.The hospital mortality of patients admitted to the ICU on weekends.Chest.2004;126(4):1292–1298.
- ,,, et al.Mortality among patients admitted to intensive care units during weekday day shifts compared with “off” hours.Crit Care Med.2007;35(1):3–11.
- ,,, et al.Septic shock: an analysis of outcomes for patients with onset on hospital wards versus intensive care units.Crit Care Med.1998;26(6):1020–1024.
- ,,,,.Clinical antecedents to in‐hospital cardiopulmonary arrest.Chest.1990;98(6):1388–1392.
- ,.Developing strategies to prevent inhospital cardiac arrest: analyzing responses of physicians and nurses in the hours before the event.Crit Care Med.1994;22(2):244–247.
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