Affiliations
Harvard Medical School
Department of Pathology and Division of Clinical Informatics, Department of Medicine, Beth Israel Deaconess Medical Center, Boston, Massachusetts
Given name(s)
Melissa L. P.
Family name
Mattison
Degrees
MD

Research Agenda for Older Patient Care

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A patient‐centered research agenda for the care of the acutely Ill older patient

Older adults with high levels of medical complexity occupy an increasing fraction of beds in acute‐care hospitals in the United States.[1, 2] By 2007, patients age 65 years and older accounted for nearly half of adult inpatient days of care.[1] These patients are commonly cared for by hospitalists who number more than 40,000.[3] Although hospitalists are most often trained in internal medicine, they have typically received limited formal geriatrics training. Increasingly, access to experts in geriatric medicine is limited.[4] Further, hospitalists and others who practice in acute care are limited by the lack of research to address the needs of the older adult population, specifically in the diagnosis and management of conditions encountered during acute illness.

To better support hospitalists in providing acute inpatient geriatric care, the Society of Hospital Medicine (SHM) partnered with the Association of Specialty Professors to develop a research agenda to bridge this gap. Using methodology from the James Lind Alliance (JLA) and the Patient Centered Outcomes Research Institute (PCORI), the SHM joined with older adult advocacy groups, professional societies of providers, and funders to create a geriatric‐focused acute‐care research agenda, highlighting 10 key research questions.[5, 6, 7] The goal of this approach was to produce and promote high integrity, evidence‐based information that comes from research guided by patients, caregivers, and the broader healthcare community.[8] In this article, we describe the methodology and results of this agenda‐setting process, referred to as the Acute Care of Older Patients (ACOP) Priority Setting Partnership.

METHODS

Overview

This project focused on topic generation, the first step in the PCORI framework for identification and prioritization of research areas.[5] We employed a specific and defined methodology to elicit and prioritize potential research topics incorporating input from representatives of older patients, family caregivers, and healthcare providers.[6]

To elicit this input, we chose a collaborative and consultative approach to stakeholder engagement, drawing heavily from the published work of the JLA, an initiative promoting patient‐clinician partnerships in health research developed in the United Kingdom.[6] We previously described the approach elsewhere.[7]

The ACOP process for determining the research agenda consisted of 4 steps: (1) convene, (2) consult, (3) collate, and (4) prioritize.[6] Through these steps, detailed below, we were able to obtain input from a broad group of stakeholders and engage the stakeholders in a process of reducing and refining our research questions.

Convene

The steering committee (the article's authors) convened a stakeholder partnership group that included stakeholders representing patients and caregivers, advocacy organizations for the elderly, organizations that address diseases and conditions common among hospitalized older patients, provider professional societies (eg, hospitalists, subspecialists, and nurses and social workers), payers, and funders. Patient, caregiver, and advocacy organizations were identified based on their engagement in aging and health policy advocacy by SHM staff and 1 author who had completed a Health and Aging Policy Fellowship (H.L.W.).

The steering committee issued e‐mail invitations to stakeholder organizations, making initial inquiries through professional staff and relevant committee chairs. Second inquiries were made via e‐mail to each organization's volunteer leadership. We developed a webinar that outlined the overall research agenda setting process and distributed the webinar to all stakeholders. The stakeholder organizations were asked to commit to (1) surveying their memberships and (2) participating actively in prioritization by e‐mail and at a 1‐day meeting in Washington DC.

Consult

Each stakeholder organization conducted a survey of its membership via an Internet‐based survey in the summer of 2013 (see Supporting Information, Appendix A, in the online version of this article). Stakeholder organizations were asked to provide up to 75 survey responses each. Though a standard survey was used, the steering committee was not prescriptive in the methodology of survey distribution to accommodate the structure and communication methods of the individual stakeholder organizations. Survey respondents were asked to identify up to 5 unanswered questions relevant to the acute care of older persons and also provide demographic information.

Collate

In the collating process, we clarified and categorized the unanswered questions submitted in the individual surveys. Each question was initially reviewed by a member of the steering committee, using explicit criteria (see Supporting Information, Appendix B, in the online version of this article). Questions that did not meet all 4 criteria were removed. For questions that met all criteria, we clarified language, combined similar questions, and categorized each question. Categories were created in a grounded process, in which individual reviewers assigned categories based on the content of the questions. Each question could be assigned to up to 2 categories. Each question was then reviewed by a second member of the steering committee using the same 4 criteria. As part of this review, similar questions were consolidated, and when possible, questions were rewritten in a standard format.[6]

Finally, the steering committee reviewed previously published research agendas looking for additional relevant unanswered questions, specifically the New Frontiers Research Agenda created by the American Geriatrics Society in conjunction with participating subspecialty societies,[9] the Cochrane Library, and other systematic reviews identified in the literature via PubMed search.[10, 11, 12, 13, 14, 15]

Prioritize

The resulting list of unanswered questions was prioritized in 2 phases. First, the list was e‐mailed to all stakeholder organizations. The organizations were asked to vote on their top 10 priorities from this list using an online ballot, assigning 10 points to their highest priority down to 1 point for their lowest priority. In so doing, they were asked to consider explicit criteria (see Supporting Information, Appendix B, in the online version of this article). Each organization had only 1 ballot and could arrive at their top 10 list in any manner they wished. The balloting from this phase was used to develop a list of unanswered questions for the second round of in‐person prioritization. Each priority's scores were totaled across all voting organizations. The 29 priorities with the highest point totals were brought to the final prioritization round because of a natural cut point at priority number 29, rather than number 30.

For the final prioritization round, the steering committee facilitated an in‐person meeting in Washington, DC in October 2013 using nominal group technique (NGT) methodologies to arrive at consensus.[16] During this process stakeholders were asked to consider additional criteria (see Supporting Information, Appendix B, in the online version of this article).

RESULTS

Table 1 lists the organizations who engaged in 1 or more parts of the topic generation process. Eighteen stakeholder organizations agreed to participate in the convening process. Ten organizations did not respond to our solicitation and 1 declined to participate.

Stakeholder Organizations Participating in the Acute Care of Older Persons Priority Setting Partnership
Organization (N=18) Consultation % of Survey Responses (N=580) Prioritization Round 1 Prioritization Round 2
Alzheimer's Association 7.0% Yes Yes
American Academy of Neurology 3.4% Yes Yes
American Association of Retired Persons 0.8% No No
American College of Cardiology 11.4% Yes Yes
American College of Emergency Physicians 1.3% No No
American College of Surgeons 1.0% Yes Yes
American Geriatrics Society 7.6% Yes Yes
American Hospital Association 1.7% Yes No
Centers for Medicare & Medicaid Services 0.8% Yes Yes
Gerontological Society of America 18.9% Yes Yes
National Alliance for Caregiving 1.0% Yes Yes
National Association of Social Workers 5.9% Yes Yes
National Coalition for Healthcare 0.6% No No
National Institute on Aging 2.1% Yes Yes
National Partnership for Women and Families 0.0% Yes Yes
Nursing Improving Care for Healthsystem Elders 28.6% Yes No
Society of Critical Care Medicine 12.0% Yes Yes
Society of Hospital Medicine 4.6% Yes Yes

Seventeen stakeholder organizations obtained survey responses from a total of 580 individuals (range, 3150 per organization), who were asked to identify important unanswered questions in the acute care of older persons. Survey respondents were typically female (77%), white (85%), aged 45 to 65 years (65%), and identified themselves as health professionals (90%). Twenty‐six percent of respondents also identified as patients or family caregivers. Their surveys included 1299 individual questions.

Figure 1 summarizes our collation and prioritization process and reports the numbers of questions resulting at each stage. Nine hundred nineteen questions were removed during the first review conducted by steering committee members, and 31 question categories were identified. An additional 305 questions were removed in the second review, with 75 questions remaining. As the final step of the collating process, literature review identified 39 relevant questions not already suggested or moved forward through our consultation and collation process. These questions were added to the list of unanswered questions.

Figure 1
Flow diagram to develop top 10 unanswered questions from stakeholder survey results. The 1299 unanswered questions were reduced to a final list of 10 high‐priority research topics through a 2‐step collation process and a 2‐step prioritization process as depicted in the flow diagram.

In the first round of prioritization, this list of 114 questions was emailed to each stakeholder organization (Table 1). After the stakeholder voting process was completed, 29 unanswered questions remained (see Supporting Information, Appendix C, in the online version of this article). These questions were refined and prioritized in the in‐person meeting to create the final list of 10 questions. The stakeholders present in the meeting represented 13 organizations (Table 1). Using the NGT with several rounds of small group breakouts and large group deliberation, 9 of the top 10 questions were selected from the list of 29. One additional highly relevant question that had been removed earlier in the collation process regarding workforce was added back by the stakeholder group.

This prioritized research agenda appears in Table 2 and below, organized alphabetically by topic.

  1. Advanced care planning: What approaches for determining and communicating goals of care across and within healthcare settings are most effective in promoting goal‐concordant care for hospitalized older patients?
  2. Care transitions: What is the comparative effectiveness of transitional care models on patient‐centered outcomes for hospitalized older adults?
  3. Delirium: What practices are most effective for consistent recognition, prevention, and treatment of delirium subtypes among hospitalized older adults?
  4. Dementia: Does universal assessment of hospitalized older adults for cognitive impairment (eg, at presentation and/or discharge) lead to more appropriate application of geriatric care principles and improve patient‐centered outcomes?
  5. Depression: Does identifying depressive symptoms during a hospital stay and initiating a therapeutic plan prior to discharge improve patient‐centered and/or disease‐specific outcomes?
  6. Medications: What systems interventions improve medication management for older adults (ie, appropriateness of medication choices and dosing, compliance, cost) in the hospital and postacute care?
  7. Models of care: For which populations of hospitalized older adults does systematic implementation of geriatric care principles/processes improve patient‐centered outcomes?
  8. Physical function: What is the comparative effectiveness of interventions that promote in‐hospital mobility, improve and preserve physical function, and reduce falls among older hospitalized patients?
  9. Surgery: What perioperative strategies can be used to optimize care processes and improve outcomes in older surgical patients?
  10. Training: What is the most effective approach to training hospital‐based providers in geriatric and palliative care competencies?
Top Ten Unanswered Questions in the Acute Care of Older Persons
Topic Scope of Problem What Is known Unanswered Question Proposed Dimensions
  • NOTE: Abbreviations: ADL, activities of daily living; AGESP, Advancement of Geriatrics Education Scholars Program; CHAMP, Curriculum for the Hospitalized Aging Medical Patient; ICU, intensive care unit; NICHE, Nurses Improving the Care of Health System Elders; PAGE, Program for Advancing Geriatrics Education; POLST, physician orders for life sustaining treatment; RCT, randomized controlled trial; STOPP, Screening Tool of Older People's Potentially Inappropriate Prescriptions.

  • Patient‐centered outcomes might include quality of life, symptoms, cognition, and functional status.

Advanced‐care planning Older persons who lack decision‐making capacity often do not have surrogates or clear goals of care documented.[19] Advanced‐care directives are associated with an increase in patient autonomy and empowerment, and although 15% to 25% of adults completed the documentation in 2004,[20] a recent study found completion rates have increased to 72%.[21] Nursing home residents with advanced directives are less likely to be hospitalized.[22, 23] Advanced directive tools, such as POLST, work to translate patient preferences to medical order.[24] standardized patient transfer tools may help to improve transitions between nursing homes and hospitals.[25] However, advanced care planning fails to integrate into courses of care if providers are unwilling or unskilled in using advanced care documentation.[26] What approaches for determining and communicating goals of care across and within healthcare settings are most effective in promoting goal‐concordant care for hospitalized older patients? Potential interventions:
Decision aids
Standard interdisciplinary advanced care planning approach
Patient advocates
Potential outcomes might include:
Completion of advanced directives and healthcare power of attorney
Patient‐centered outcomesa
Care transitions Hospital readmission from home and skilled nursing facilities occurs within 30 days in up to a quarter of patients.[27, 28] The discharge of complex older hospitalized patients is fraught with challenges. The quality of the hospital discharge process can influence outcomes for vulnerable older patients.[29, 30, 31, 32] Studies measuring the quality of hospital discharge frequently find deficits in documentation of assessment of geriatric syndromes,[33] poor patient/caregiver understanding,[34, 35] and poor communication and follow‐up with postacute providers.[35, 36, 37, 38] As many as 10 separate domains may influence the success of a discharge.[39] There is limited evidence, regarding quality‐of‐care transitions for hospitalized older patients. The Coordinated‐Transitional Care Program found that follow‐up with telecommunication decreased readmission rates and improved transitional care for a high‐risk condition veteran population.[40] There is modest evidence for single interventions,[41] whereas the most effective hospital‐to‐community care interventions address multiple processes in nongeriatric populations.[39, 42, 43] What is the comparative effectiveness of the transitional care models on patient‐centered outcomes for hospitalized older adults? Possible models:
Established vs novel care‐transition models
Disease‐specific vs general approaches
Accountable care models
Caregiver and family engagement
Community engagement
Populations of interest:
Patients with dementia
Patients with multimorbidity
Patients with geriatric syndromes
Patients with psychiatric disease
Racially and ethnically diverse patients
Outcomes:
Readmission
Other adverse events
Cost and healthcare utilization
Patient‐centered outcomesa
Delirium Among older inpatients, the prevalence of delirium varies with severity of illness. Among general medical patients, in‐hospital prevalence ranges from 10% to 25 %.[44, 45] In the ICU, prevalence estimates are higher, ranging from 25% to as high as 80%.[46, 47] Delirium independently predicts increased length of stay,[48, 49] long‐term cognitive impairment,[50, 51] functional decline,[51] institutionalization,[52] and short‐ and long‐term mortality.[52, 53, 54] Multicomponent strategies have been shown to be effective in preventing delirium. A systematic review of 19 such interventions identified the most commonly included such as[55]: early mobilization, nutrition supplements, medication review, pain management, sleep enhancement, vision/hearing protocols, and specialized geriatric care. Studies have included general medical patients, postoperative patients, and patients in the ICU. The majority of these studies found reductions in either delirium incidence (including postoperative), delirium prevalence, or delirium duration. Although medications have not been effective in treating delirium in general medical patients,[48] the choice and dose of sedative agents has been shown to impact delirium in the ICU.[56, 57, 58] What practices are most effective for consistent recognition, prevention, and treatment of delirium subtypes (hypoactive, hyperactive, and mixed) among hospitalized older adults? Outcomes to examine:
Delirium incidence (including postoperative)
Delirium duration
Delirium‐/coma‐free days
Delirium prevalence at discharge
Subsyndromal delirium
Potential prevention and treatment modalities:
Family education or psychosocial interventions
Pharmacologic interventions
Environmental modifications
Possible areas of focus:
Special populations
Patients with varying stages of dementia
Patients with multimorbidity
Patients with geriatric syndromes
Observation patients
Diverse settings
Emergency department
Perioperative
Skilled nursing/rehab/long‐term acute‐care facilities
Dementia 13% to 63% of older persons in the hospital have dementia.[59] Dementia is often unrecognized among hospitalized patients.[60] The presence of dementia is associated with a more rapid functional decline during admission and delayed hospital discharge.[59] Patients with dementia require more nursing hours, and are more likely to have complications[61] or die in care homes rather than in their preferred site.[59] Several tools have been validated to screen for dementia in the hospital setting.[62] Studies have assessed approaches to diagnosing delirium in hospitalized patients with dementia.[63] Cognitive and functional stimulation interventions may have a positive impact on reducing behavioral issues.[64, 65] Does universal assessment of hospitalized older adults for cognitive impairment (eg, at presentation and/or discharge) lead to more appropriate application of geriatric care principles and improve patient centered outcomes? Potential interventions:
Dementia or delirium care
Patient/family communication and engagement strategies
Maintenance/recovery of independent functional status
Potential outcomes:
Patient‐centered outcomesa
Length of stay, cost, and healthcare utilization (including palliative care)
Immediate invasive vs early conservative treatments pursued
Depression Depression is a common geriatric syndrome among acutely ill older patients, occurring in up to 45% of patients.[66, 67] Rates of depression are similar among patients discharged following a critical illness, with somatic, rather than cognitive‐affective complaints being the most prevalent.[68] Depression among inpatients or immediately following hospitalization independently predicts worse functional outcomes,[69] cognitive decline,[70] hospital readmission,[71, 72] and long‐term mortality.[69, 73] Finally, geriatric patients are known to respond differently to medical treatment.[74, 75] Although highly prevalent, depression is poorly recognized and managed in the inpatient setting. Depression is recognized in only 50% of patients, with previously undiagnosed or untreated depression being at highest risk for being missed.[76] The role of treatment of depression in the inpatient setting is poorly understood, particularly for those with newly recognized depression or depressive symptoms. Some novel collaborative care and telephone outreach programs have led to increases in depression treatment in patients with specific medical and surgical conditions, resulting in early promising mental health and comorbid outcomes.[77, 78] The efficacy of such programs for older patients is unknown. Does identifying depressive symptoms during a hospital stay and initiating a therapeutic plan prior to discharge improve patient‐centered and/or disease‐specific outcomes? Possible areas of focus:
Comprehensive geriatric and psychosocial assessment;
Inpatient vs outpatient initiation of pharmacological therapy
Integration of confusion assessment method into therapeutic approaches
Linkages with outpatient mental health resources
Medications Medication exposure, particularly potentially inappropriate medications, is common in hospitalized elders.[79] Medication errorsof dosage, type, and discrepancy between what a patient takes at home and what is known to his/her prescribing physicianare common and adversely affects patient safety.[80] Geriatric populations are disproportionately affected, especially those taking more than 5 prescription medications per day.[81] Numerous strategies including electronic alerts, screening protocols, and potentially inappropriate medication lists (Beers list, STOPP) exist, though the optimal strategies to limit the use of potentially inappropriate medications is not yet known.[82, 83, 84] What systems interventions improve medication management for older adults (ie, appropriateness of medication choices and dosing, compliance, cost) in hospital and post‐acute care? Possible areas of focus:
Use of healthcare information technology
Communication across sites of care
Reducing medication‐related adverse events
Engagement of family caregivers
Patient‐centered strategies to simplify regimens
Models of care Hospitalization marks a time of high risk for older patients. Up to half die during hospitalization or within the year following the hospitalization. There is high risk of nosocomial events, and more than a third experience a decline in health resulting in longer hospitalizations and/or placement in extended‐care facilities.[73, 85, 86] Comprehensive inpatient care for older adults (acute care for elders units, geriatric evaluation and management units, geriatric consultation services) were studied in 2 meta‐analyses, 5 RCTs, and 1 quasiexperimental study and summarized in a systematic review.[87] The studies reported improved quality of care (1 of 1 article), quality of life (3 of 4), functional autonomy (5 of 6), survival (3 of 6), and equal or lower healthcare utilization (7 of 8). For which populations of hospitalized older adults does systematic implementation of geriatric care principles/processes improve patient‐centered outcomes? Potential populations:
Patients of the emergency department, critical care, perioperative, and targeted medical/surgical units
Examples of care principles:
Geriatric assessment, early mobility, medication management, delirium prevention, advanced‐care planning, risk‐factor modification, caregiver engagement
Potential outcomes:
Patient‐centered outcomesa
Cost
Physical function Half of older patients will lose functional capacity during hospitalization.[88] Loss of physical function, particularly of lower extremities, is a risk factor for nursing home placement.[89, 90] Older hospitalized patients spend the majority (up to 80%) of their time lying in bed, even when they are capable of walking independently.[91] Loss of independences with ADL capabilities is associated with longer hospital stays, higher readmission rates, and higher mortality risk.[92] Excessive time in bed during a hospital stay is also associated with falls.[93] Often, hospital nursing protocols and physician orders increase in‐hospital immobility in patients.[91, 94] However, nursing‐driven mobility protocols can improve functional outcomes of older hospitalized patients.[95, 96] What is the comparative effectiveness of interventions that promote in‐hospital mobility, improve and preserve physical function, and reduce falls among older hospitalized patients? Potential interventions:
Intensive physical therapy
Incidental functional training
Restraint reduction
Medication management
Potential outcomes:
Discharge location
Delirium, pressure ulcers, and falls
Surgery An increasing number of persons over age 65 years are undergoing surgical procedures.[97] These persons are at increased risk for developing delirium/cogitative dysfunction,[98] loss of functional status,[99] and exacerbations of chronic illness.[97] Additionally, pain management may be harder to address in this population.[100] Current outcomes may not reflect the clinical needs of elder surgical patients.[101] Tailored drug selection and nursing protocols may prevent delirium.[98] Postoperative cognitive dysfunction may require weeks for resolution. Identifying frail patients preoperatively may lead to more appropriate risk stratification and improved surgical outcomes.[99] Pain management strategies focused on mitigating cognitive impact and other effects may also be beneficial.[100] Development of risk‐adjustment tools specific to older populations, as well as measures of frailty and patient‐centered care, have been proposed.[101] What perioperative strategies can be used to optimize care processes and improve outcomes in older surgical patients? Potential strategies:
Preoperative risk assessment and optimization for frail or multimorbid older patients
Perioperative management protocols for frail or multimorbid older patients
Potential outcomes:
Postoperative patient centered outcomesa
Perioperative cost, healthcare utilization
Training Adults over age 65 years comprise 13.2 % of the US population, but account for >30% of hospital discharges and 50% of hospital days.[86, 102, 103] By 2030, there will only be 1 geriatrician for every 3798 Americans >75 years.[4] Between 1997 and 2006, the odds that a hospitalist would treat a hospitalized Medicare patient rose 29% per year.[3] Train the trainer programs for physicians include the CHAMP, the AGESP, and the PAGE. Education for nurses include the NICHE. Outcomes include improved self‐confidence, attitudes, teaching skills, and geriatric care environment.[104, 105, 106] What is the most effective approach to training hospital‐based providers in geriatric and palliative care competencies? Potential interventions:
Mentored implementation
Train the trainer
Technical support

Table 2 also contains a capsule summary of the scope of the problem addressed by each research priority, a capsule summary of related work in the content area (what is known) not intended as a systematic review, and proposed dimensions or subquestions suggested by the stakeholders at the final prioritization meeting

DISCUSSION

Older hospitalized patients account for an increasing number and proportion of hospitalized patients,[1, 2] and hospitalists increasingly are responsible for inpatient care for this population.[3] The knowledge required for hospitalists to deliver optimal care and improve outcomes has not kept pace with the rapid growth of either hospitalists or hospitalized elders. Through a rigorous prioritization process, we identified 10 areas that deserve the highest priority in directing future research efforts to improve care for the older hospitalized patient. Assessment, prevention, and treatment of geriatric syndromes in the hospital account for almost half of the priority areas. Additional research is needed to improve advanced care planning, develop new care models, and develop training models for future hospitalists competent in geriatric and palliative care competencies.

A decade ago, the American Geriatric Society and the John A. Hartford Foundation embarked upon a research agenda aimed at improving the care of hospitalized elders cared for by specialists (ie, New Frontiers in Geriatrics Research: An Agenda for Surgical and Related Medical Specialties).[9] This effort differed in many important ways from the current priortization process. First, the New Frontiers agenda focused upon specific diseases, whereas the ACOP agenda addresses geriatric syndromes that cut across multiple diseases. Second, the New Frontiers agenda was made by researchers and based upon published literature, whereas the ACOP agenda involved the input of multiple stakeholders. Finally, the New Frontiers prioritized a research agenda across a number of surgical specialties, emergency medicine, and geriatric rehabilitation. Hospital medicine, however, was still early in its development and was not considered a unique specialty. Since that time, hospital medicine has matured into a unique specialty, with increased numbers of hospitalists,[3] increased research in hospital medicine,[17] and a separate recertification pathway for internal medicine licensure.[18] To date, there has not been a similar effort performed to direct geriatric research efforts for hospital medicine.

For researchers working in the field of hospital medicine, this list of topics has several implications. First, as hospitalists are commonly generalists, hospitalist researchers may be particularly well‐suited to study syndromes that cut across specialties. However, this does raise concerns about funding sources, as most National Institutes of Health institutes are disease‐focused. Funders that are not disease‐focused such as PCORI, National Institute on Aging, National Institute of Nursing Research, and Agency for Healthcare Research and Quality, and private foundations (Hartford, Robert Wood Johnson, and Commonwealth) may be more fruitful sources of funding for this work, but funding may be challenging. Nonetheless, the increased focus on patient‐centered work may increase funders' interest in such work. Second, the topics on this list would suggest that interventions will not be pharmacologic, but will focus on nonpharmacologic, behavioral, and social interventions. Similarly, outcomes of interest must expand beyond utilization metrics such as length of stay and mortality, to include functional status and symptom management, and goal‐concordant care. Therefore, research in geriatric acute care will necessarily be multidisciplinary.

Although these 10 high‐priority areas have been selected, this prioritized list is inherently limited by our methodology. First, our survey question was not focused on a disease state, and this wording may have resulted in the list favoring geriatric syndromes rather than common disease processes. Additionally, the resulting questions encompass large research areas and not specific questions about discrete interventions. Our results may also have been skewed by the types of engaged respondents who participated in the consultation, collating, and prioritization phases. In particular, we had a large response from geriatric medicine nurses, whereas some stakeholder groups provided no survey responses. Thus, these respondents were not representative of all possible stakeholders, nor were the survey respondents necessarily representative of each of their organizations. Nonetheless, the participants self‐identified as representative of diverse viewpoints that included patients, caregivers, and advocacy groups, with the majority of stakeholder organizations remaining engaged through the completion of the process. Thus, the general nature of this agenda helps us focus upon larger areas of importance, leaving researchers the flexibility to choose to narrow the focus on a specific research question that may include potential interventions and unique outcomes. Finally, our methodology may have inadvertently limited the number of patient and family caregiver voices in the process given our approach to large advocacy groups, our desire to be inclusive of healthcare professional organizations, and our survey methodology. Other methodologies may have reached more patients and caregivers, yet many healthcare professionals have served as family caregivers to frail elders requiring hospitalization and may have been in an ideal position to answer the survey.

In conclusion, several forces are shaping the future of acute inpatient care. These include the changing demographics of the hospitalized patient population, a rapid increase in the proportion of multimorbid hospitalized older adults, an inpatient workforce (hospitalists, generalists, and subspecialists) with potentially limited geriatrics training, and gaps in evidence‐based guidance to inform diagnostic and therapeutic decision making for acutely ill older patients. Training programs in hospital medicine should be aware of and could benefit from the resulting list of unanswered questions. Our findings also have implications for training to enrich education in geriatrics. Moreover, there is growing recognition that patients and other stakeholders deserve a greater voice in determining the direction of research. In addition to efforts to improve patient‐centeredness of research, these areas have been uniquely identified by stakeholders as important, and therefore are in line with newer priorities of PCORI. This project followed a road map resulting in a patient‐centered research agenda at the intersection of hospital medicine and geriatric medicine.[7] In creating this agenda, we relied heavily on the framework proposed by PCORI. We propose to pursue a dissemination and evaluation strategy for this research agenda as well as additional prioritization steps. We believe the adoption of this methodology will create a knowledge base that is rigorously derived and most relevant to the care of hospitalized older adults and their families. Its application will ultimately result in improved outcomes for hospitalized older adults.

Acknowledgements

The authors acknowledge Claudia Stahl, Society of Hospital Medicine; Cynthia Drake, University of Colorado; and the ACOP stakeholder organizations.

Disclosures: This work was supported by the Association of Specialty Professors/American Society of Internal Medicine and the John A. Hartford Foundation. Dr. Vasilevskis was supported by the National Institute on Aging of the National Institutes of Health under award number K23AG040157 and the Veterans Affairs Clinical Research Center of Excellence, and the Geriatric Research, Education and Clinical Center (GRECC). Dr. Vasilevskis' institution receives grant funding for an aspect of submitted work. Dr. Meltzer is a PCORI Methodology Committee member. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health or the Department of Veterans' Affairs. The authors report no conflicts of interest.

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References
  1. Hall MJ, DeFrances CJ, Williams SN, Golosinskiy A, Schwartzman A. National Hospital Discharge Survey: 2007 summary. Natl Health Stat Report. 2010(29):120, 24.
  2. Centers for Medicare 2012. Available at: http://www.cms.gov/Research‐Statistics‐Data‐and‐Systems/Statistics‐Trends‐and‐Reports/Chronic‐Conditions/Downloads/2012Chartbook.pdf. Accessed December 12, 2014.
  3. Kuo YF, Sharma G, Freeman JL, Goodwin JS. Growth in the care of older patients by hospitalists in the United States. N Engl J Med. 2009;360(11):11021112.
  4. Bragg E, Hansen JC. A revelation of numbers: will America's eldercare workforce be ready to care for an aging America? Generations. 2010;34(4):1119.
  5. Patient‐Centered Outcomes Research Institute Methodology Committee. The PCORI methodology report. Available at: http://www.pcori.org/assets/2013/11/PCORI‐Methodology‐Report.pdf. Published November 2013. Accessed December 19, 2013.
  6. The James Lind Alliance. JLA method. Available at: http://www.lindalliance.org/JLA_Method.asp. Accessed December 19, 2013.
  7. Wald HL, Leykum LK, Mattison ML, Vasilevskis EE, Meltzer DO. Road map to a patient‐centered research agenda at the intersection of hospital medicine and geriatric medicine. J Gen Intern Med. 2014;29(6):926931.
  8. Patient‐Centered Outcomes Research Institute. About us. Available at: http://www.pcori.org/about‐us. Accessed February 23, 2015.
  9. Solomon D, LoCicero J, Rosenthal R. New Frontiers of Geriatrics Research: An Agenda for Surgical and Related Medical Specialties. New York, NY: American Geriatrics Society; 2004.
  10. Raveis VH, Gardner DS, Berkman B, Harootyan L. Linking the NIH strategic plan to the research agenda for social workers in health and aging. J Gerontol Soc Work. 2010;53(1):7793.
  11. Lai JM, Karlawish J. Assessing the capacity to make everyday decisions: a guide for clinicians and an agenda for future research. Am J Geriatr Psychiatry. 2007;15(2):101111.
  12. Pillemer K, Breckman R, Sweeney CD, et al. Practitioners' views on elder mistreatment research priorities: recommendations from a Research‐to‐Practice Consensus conference. J Elder Abuse Negl. 2011;23(2):115126.
  13. Goldstein NE, Morrison RS. The intersection between geriatrics and palliative care: a call for a new research agenda. J Am Geriatr Soc. 2005;53(9):15931598.
  14. Cohen HJ. The cancer aging interface: a research agenda. J Clin Oncol. 2007;25(14):19451948.
  15. Clevenger CK, Chu TA, Yang Z, Hepburn KW. Clinical care of persons with dementia in the emergency department: a review of the literature and agenda for research. J Am Geriatr Soc. 2012;60(9):17421748.
  16. Delbecq AL, Ven AH. A group process model for problem identification and program planning. J Appl Behav Sci. 1971;7(4):466492.
  17. Dang Do AN, Munchhof AM, Terry C, Emmett T, Kara A. Research and publication trends in hospital medicine. J Hosp Med. 2014;9(3):148154.
  18. Ireland J. ABFM and ABIM to jointly participate in recognition of focused practice (rfp) in hospital medicine pilot approved by abms. Ann Fam Med. 2010;8(1):87.
  19. Weiss BD, Berman EA, Howe CL, Fleming RB. Medical decision‐making for older adults without family. J Am Geriatr Soc. 2012;60(11):21442150.
  20. Wissow LS, Belote A, Kramer W, Compton‐Phillips A, Kritzler R, Weiner JP. Promoting advance directives among elderly primary care patients. J Gen Intern Med. 2004;19(9):944951.
  21. Silveira MJ, Wiitala W, Piette J. Advance directive completion by elderly Americans: a decade of change. J Am Geriatr Soc. 2014;62(4):706710.
  22. Murray LM, Laditka SB. Care transitions by older adults from nursing homes to hospitals: implications for long‐term care practice, geriatrics education, and research. J Am Med Dir Assoc. 2010;11(4):231238.
  23. Lamberg JL, Person CJ, Kiely DK, Mitchell SL. Decisions to hospitalize nursing home residents dying with advanced dementia. J Am Geriatr Soc. 2005;53(8):13961401.
  24. Hickman SE, Nelson CA, Perrin NA, Moss AH, Hammes BJ, Tolle SW. A comparison of methods to communicate treatment preferences in nursing facilities: traditional practices versus the physician orders for life‐sustaining treatment program. J Am Geriatr Soc. 2010;58(7):12411248.
  25. LaMantia MA, Scheunemann LP, Viera AJ, Busby‐Whitehead J, Hanson LC. Interventions to improve transitional care between nursing homes and hospitals: a systematic review. J Am Geriatr Soc. 2010;58(4):777782.
  26. Zadeh S, Pao M, Wiener L. Opening end‐of‐life discussions: how to introduce Voicing My CHOiCES, an advance care planning guide for adolescents and young adults [published online ahead of print March 13, 2014]. Palliat Support Care. doi: 10.1017/S1478951514000054.
  27. Mor V, Intrator O, Feng Z, Grabowski DC. The revolving door of rehospitalization from skilled nursing facilities. Health Aff (Millwood). 2010;29(1):5764.
  28. Jencks SF, Williams MV, Coleman EA. Rehospitalizations among patients in the Medicare fee‐for‐service program. N Engl J Med. 2009;360(14):14181428.
  29. Morandi A, Bellelli G, Vasilevskis EE, et al. Predictors of rehospitalization among elderly patients admitted to a rehabilitation hospital: the role of polypharmacy, functional status, and length of stay. J Am Med Dir Assoc. 2013;14(10):761767.
  30. Fisher SR, Kuo YF, Sharma G, et al. Mobility after hospital discharge as a marker for 30‐day readmission. J Gerontol A Biol Sci Med Sci. 2013;68(7):805810.
  31. Ashton CM, Del Junco DJ, Souchek J, Wray NP, Mansyur CL. The association between the quality of inpatient care and early readmission: a meta‐analysis of the evidence. Med Care. 1997;35(10):10441059.
  32. Hoyer EH, Needham DM, Atanelov L, Knox B, Friedman M, Brotman DJ. Association of impaired functional status at hospital discharge and subsequent rehospitalization. J Hosp Med. May 2014;9(5):277282.
  33. Lakhan P, Jones M, Wilson A, Courtney M, Hirdes J, Gray LC. A prospective cohort study of geriatric syndromes among older medical patients admitted to acute care hospitals. J Am Geriatr Soc. 2011;59(11):20012008.
  34. Albrecht JS, Gruber‐Baldini AL, Hirshon JM, et al. Hospital discharge instructions: comprehension and compliance among older adults. J Gen Intern Med. 2014;29(11):14911498.
  35. Arora VM, Prochaska ML, Farnan JM, et al. Problems after discharge and understanding of communication with their primary care physicians among hospitalized seniors: a mixed methods study. J Hosp Med. 2010;5(7):385391.
  36. Gandara E, Moniz T, Ungar J, et al. Communication and information deficits in patients discharged to rehabilitation facilities: an evaluation of five acute care hospitals. J Hosp Med. 2009;4(8):E28E33.
  37. King BJ, Gilmore‐Bykovskyi AL, Roiland RA, Polnaszek BE, Bowers BJ, Kind AJ. The consequences of poor communication during transitions from hospital to skilled nursing facility: a qualitative study. J Am Geriatr Soc. 2013;61(7):10951102.
  38. Kripalani S, LeFevre F, Phillips CO, Williams MV, Basaviah P, Baker DW. Deficits in communication and information transfer between hospital‐based and primary care physicians: implications for patient safety and continuity of care. JAMA. 2007;297(8):831841.
  39. Burke RE, Kripalani S, Vasilevskis EE, Schnipper JL. Moving beyond readmission penalties: creating an ideal process to improve transitional care. J Hosp Med. 2013;8(2):102109.
  40. Kind AJ, Jensen L, Barczi S, et al. Low‐cost transitional care with nurse managers making mostly phone contact with patients cut rehospitalization at a VA hospital. Health Aff (Millwood). 2012;31(12):26592668.
  41. Feltner C, Jones CD, Cene CW, et al. Transitional care interventions to prevent readmissions for persons with heart failure: a systematic review and meta‐analysis. Ann Intern Med. 2014;160(11):774784.
  42. Hansen LO, Young RS, Hinami K, Leung A, Williams MV. Interventions to reduce 30‐day rehospitalization: a systematic review. Ann Intern Med. 2011;155(8):520528.
  43. Rennke S, Nguyen OK, Shoeb MH, Magan Y, Wachter RM, Ranji SR. Hospital‐initiated transitional care interventions as a patient safety strategy: a systematic review. Ann Intern Med. 2013;158(5 pt 2):433440.
  44. Vasilevskis EE, Han JH, Hughes CG, Ely EW. Epidemiology and risk factors for delirium across hospital settings. Best Pract Res Clin Anaesthesiol. 2012;26(3):277287.
  45. Inouye SK, Rushing JT, Foreman MD, Palmer RM, Pompei P. Does delirium contribute to poor hospital outcomes? A three‐site epidemiologic study. J Gen Intern Med. 1998;13(4):234242.
  46. Ouimet S, Kavanagh BP, Gottfried SB, Skrobik Y. Incidence, risk factors and consequences of ICU delirium. Intensive Care Med. 2007;33(1):6673.
  47. Ely EW, Inouye SK, Bernard GR, et al. Delirium in mechanically ventilated patients: validity and reliability of the confusion assessment method for the intensive care unit (CAM‐ICU). JAMA. 2001;286(21):27032710.
  48. Boustani M, Baker MS, Campbell N, et al. Impact and recognition of cognitive impairment among hospitalized elders. J Hosp Med. 2010;5(2):6975.
  49. Ely EW, Gautam S, Margolin R, et al. The impact of delirium in the intensive care unit on hospital length of stay. Intensive Care Med. 2001;27(12):18921900.
  50. Pandharipande PP, Girard TD, Ely EW. Long‐term cognitive impairment after critical illness. N Engl J Med. 2014;370(2):185186.
  51. Brummel NE, Jackson JC, Pandharipande PP, et al. Delirium in the ICU and subsequent long‐term disability among survivors of mechanical ventilation. Crit Care Med. 2014;42(2):369377.
  52. Witlox J, Eurelings LS, Jonghe JF, Kalisvaart KJ, Eikelenboom P, Gool WA. Delirium in elderly patients and the risk of postdischarge mortality, institutionalization, and dementia: a meta‐analysis. JAMA. 2010;304(4):443451.
  53. Ely EW, Shintani A, Truman B, et al. Delirium as a predictor of mortality in mechanically ventilated patients in the intensive care unit. JAMA. 2004;291(14):17531762.
  54. Pisani MA, Kong SY, Kasl SV, Murphy TE, Araujo KL, Ness PH. Days of delirium are associated with 1‐year mortality in an older intensive care unit population. Am J Respir Crit Care Med. 2009;180(11):10921097.
  55. Reston JT, Schoelles KM. In‐facility delirium prevention programs as a patient safety strategy: a systematic review. Ann Intern Med. 2013;158(5 pt 2):375380.
  56. Riker RR, Shehabi Y, Bokesch PM, et al. Dexmedetomidine vs midazolam for sedation of critically ill patients: a randomized trial. JAMA. 2009;301(5):489499.
  57. Pandharipande PP, Pun BT, Herr DL, et al. Effect of sedation with dexmedetomidine vs lorazepam on acute brain dysfunction in mechanically ventilated patients: the MENDS randomized controlled trial. JAMA. 2007;298(22):26442653.
  58. Skrobik Y, Ahern S, Leblanc M, Marquis F, Awissi DK, Kavanagh BP. Protocolized intensive care unit management of analgesia, sedation, and delirium improves analgesia and subsyndromal delirium rates. Anesth Analg. 2010;111(2):451463.
  59. Mukadam N, Sampson EL. A systematic review of the prevalence, associations and outcomes of dementia in older general hospital inpatients. Int Psychogeriatr. 2011;23(3):344355.
  60. Torisson G, Minthon L, Stavenow L, Londos E. Cognitive impairment is undetected in medical inpatients: a study of mortality and recognition amongst healthcare professionals. BMC Geriatr. 2012;12:47.
  61. George J, Long S, Vincent C. How can we keep patients with dementia safe in our acute hospitals? A review of challenges and solutions. J R Soc Med. 2013;106(9):355361.
  62. Jackson TA, Naqvi SH, Sheehan B. Screening for dementia in general hospital inpatients: a systematic review and meta‐analysis of available instruments. Age Ageing. 2013;42(6):689695.
  63. Morandi A, McCurley J, Vasilevskis EE, et al. Tools to detect delirium superimposed on dementia: a systematic review. J Am Geriatr Soc. 2012;60(11):20052013.
  64. Moniz Cook ED, Swift K, James I, Malouf R, Vugt M, Verhey F. Functional analysis‐based interventions for challenging behaviour in dementia. Cochrane Database Syst Rev. 2012;2:CD006929.
  65. Woods B, Aguirre E, Spector AE, Orrell M. Cognitive stimulation to improve cognitive functioning in people with dementia. Cochrane Database Syst Rev. 2012;2:CD005562.
  66. McCusker J, Cole M, Dufouil C, et al. The prevalence and correlates of major and minor depression in older medical inpatients. J Am Geriatr Soc. 2005;53(8):13441353.
  67. Koenig HG, Meador KG, Shelp F, Goli V, Cohen HJ, Blazer DG. Major depressive disorder in hospitalized medically ill patients: an examination of young and elderly male veterans. J Am Geriatr Soc. 1991;39(9):881890.
  68. Jackson JC, Pandharipande PP, Girard TD, et al. Depression, post‐traumatic stress disorder, and functional disability in survivors of critical illness in the BRAIN‐ICU study: a longitudinal cohort study. Lancet Respir Med. 2014;2(5):369379.
  69. Pierluissi E, Mehta KM, Kirby KA, et al. Depressive symptoms after hospitalization in older adults: function and mortality outcomes. J Am Geriatr Soc. 2012;60(12):22542262.
  70. Han L, McCusker J, Cole M, Abrahamowicz M, Capek R. 12‐month cognitive outcomes of major and minor depression in older medical patients. Am J Geriatr Psychiatry. 2008;16(9):742751.
  71. Kartha A, Anthony D, Manasseh CS, et al. Depression is a risk factor for rehospitalization in medical inpatients. Prim Care Companion J Clin Psychiatry. 2007;9(4):256262.
  72. Cancino RS, Culpepper L, Sadikova E, Martin J, Jack BW, Mitchell SE. Dose‐response relationship between depressive symptoms and hospital readmission. J Hosp Med. 2014;9(6):358364.
  73. Covinsky KE, Kahana E, Chin MH, Palmer RM, Fortinsky RH, Landefeld CS. Depressive symptoms and 3‐year mortality in older hospitalized medical patients. Ann Intern Med. 1999;130(7):563569.
  74. Sheline YI, Pieper CF, Barch DM, et al. Support for the vascular depression hypothesis in late‐life depression: results of a 2‐site, prospective, antidepressant treatment trial. Arch Gen Psychiatry. 2010;67(3):277285.
  75. Alexopoulos GS, Kiosses DN, Heo M, Murphy CF, Shanmugham B, Gunning‐Dixon F. Executive dysfunction and the course of geriatric depression. Biol Psychiatry. 2005;58(3):204210.
  76. Cepoiu M, McCusker J, Cole MG, Sewitch M, Ciampi A. Recognition of depression in older medical inpatients. J Gen Intern Med. 2007;22(5):559564.
  77. Huffman JC, Mastromauro CA, Sowden GL, Wittmann C, Rodman R, Januzzi JL. A collaborative care depression management program for cardiac inpatients: depression characteristics and in‐hospital outcomes. Psychosomatics. 2011;52(1):2633.
  78. Huffman JC, Mastromauro CA, Sowden G, Fricchione GL, Healy BC, Januzzi JL. Impact of a depression care management program for hospitalized cardiac patients. Circ Cardiovasc Qual Outcomes. 2011;4(2):198205.
  79. Rothberg MB, Pekow PS, Liu F, et al. Potentially inappropriate medication use in hospitalized elders. J Hosp Med. 2008;3(2):91102.
  80. Lewis PJ, Dornan T, Taylor D, Tully MP, Wass V, Ashcroft DM. Prevalence, incidence and nature of prescribing errors in hospital inpatients: a systematic review. Drug Saf. 2009;32(5):379389.
  81. Pham CB, Dickman RL. Minimizing adverse drug events in older patients. Am Fam Physician. 2007;76(12):18371844.
  82. Gallagher P, Ryan C, Byrne S, Kennedy J, O'Mahony D. STOPP (Screening Tool of Older Person's Prescriptions) and START (Screening Tool to Alert doctors to Right Treatment). Consensus validation. Int J Clin Pharmacol Ther. 2008;46(2):7283.
  83. American Geriatrics Society 2012 Beers Criteria Update Expert Panel. American Geriatrics Society updated Beers Criteria for potentially inappropriate medication use in older adults. J Am Geriatr Soc. 2012;60(4):616631.
  84. Mattison ML, Afonso KA, Ngo LH, Mukamal KJ. Preventing potentially inappropriate medication use in hospitalized older patients with a computerized provider order entry warning system. Arch Intern Med. 2010;170(15):13311336.
  85. Creditor MC. Hazards of Hospitalization of the Elderly. Ann Intern Med. 1993;118(3):219223.
  86. Landefeld CS. Improving health care for older persons. Ann Intern Med. 2003;139(5 part 2):421424.
  87. Boult C, Green AF, Boult LB, Pacala JT, Snyder C, Leff B. Successful models of comprehensive care for older adults with chronic conditions: evidence for the Institute of Medicine's "retooling for an aging America" report. J Am Geriatr Soc. 2009;57(12):23282337.
  88. Boyd CM, Landefeld CS, Counsell SR, et al. Recovery of activities of daily living in older adults after hospitalization for acute medical illness. J Am Geriatr Soc. 2008;56(12):21712179.
  89. Wolinsky FD, Callahan CM, Fitzgerald JF, Johnson RJ. Changes in functional status and the risks of subsequent nursing home placement and death. J Gerontol. 1993;48(3):S94S101.
  90. Smith GE, Kokmen E, O'Brien PC. Risk factors for nursing home placement in a population‐based dementia cohort. J Am Geriatr Soc. 2000;48(5):519525.
  91. Brown CJ, Redden DT, Flood KL, Allman RM. The underrecognized epidemic of low mobility during hospitalization of older adults. J Am Geriatr Soc. 2009;57(9):16601665.
  92. Hoogerduijn JG, Schuurmans MJ, Duijnstee MS, Rooij SE, Grypdonck MF. A systematic review of predictors and screening instruments to identify older hospitalized patients at risk for functional decline. J Clin Nurs. 2007;16(1):4657.
  93. Mahoney JE. Immobility and falls. Clin Geriatr Med. 1998;14(4):699726.
  94. Brown CJ, Friedkin RJ, Inouye SK. Prevalence and outcomes of low mobility in hospitalized older patients. J Am Geriatr Soc. 2004;52(8):12631270.
  95. Padula CA, Hughes C, Baumhover L. Impact of a nurse‐driven mobility protocol on functional decline in hospitalized older adults. J Nurs Care Qual. 2009;24(4):325331.
  96. Pashikanti L, Ah D. Impact of early mobilization protocol on the medical‐surgical inpatient population: an integrated review of literature. Clin Nurse Spec. 2012;26(2):8794.
  97. Etzioni DA, Liu JH, Maggard MA, Ko CY. The aging population and its impact on the surgery workforce. Ann Surg. 2003;238(2):170177.
  98. Palmer RM. Perioperative care of the elderly patient: an update. Cleve Clin J Med. 2009;76(suppl 4):S16S21.
  99. Partridge JS, Harari D, Dhesi JK. Frailty in the older surgical patient: a review. Age Ageing. 2012;41(2):142147.
  100. Schofield PA. The assessment and management of peri‐operative pain in older adults. Anaesthesia. 2014;69(suppl 1):5460.
  101. Peden CJ, Grocott MP. National Research Strategies: what outcomes are important in peri‐operative elderly care? Anaesthesia. 2014;69(suppl 1):6169.
  102. DeFrances CJ, Hall MJ. 2002 National Hospital Discharge Survey. Adv Data. 2004;342:130.
  103. Merrill CT, Elixhauser A. Hospitalization in the United States, 2002. Rockville, MD: Agency for Healthcare Research and Quality; 2005.
  104. Podrazik PM, Levine S, Smith S, et al. The Curriculum for the Hospitalized Aging Medical Patient program: a collaborative faculty development program for hospitalists, general internists, and geriatricians. J Hosp Med. 2008;3(5):384393.
  105. Mattison ML, Li JMW. Advancement of geriatrics education. J Hosp Med. 2011;6(6):370.
  106. Mazotti L, Moylan A, Murphy E, Harper GM, Johnston CB, Hauer KE. Advancing geriatrics education: an efficient faculty development program for academic hospitalists increases geriatric teaching. J Hosp Med. 2010;5(9):541546.
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Older adults with high levels of medical complexity occupy an increasing fraction of beds in acute‐care hospitals in the United States.[1, 2] By 2007, patients age 65 years and older accounted for nearly half of adult inpatient days of care.[1] These patients are commonly cared for by hospitalists who number more than 40,000.[3] Although hospitalists are most often trained in internal medicine, they have typically received limited formal geriatrics training. Increasingly, access to experts in geriatric medicine is limited.[4] Further, hospitalists and others who practice in acute care are limited by the lack of research to address the needs of the older adult population, specifically in the diagnosis and management of conditions encountered during acute illness.

To better support hospitalists in providing acute inpatient geriatric care, the Society of Hospital Medicine (SHM) partnered with the Association of Specialty Professors to develop a research agenda to bridge this gap. Using methodology from the James Lind Alliance (JLA) and the Patient Centered Outcomes Research Institute (PCORI), the SHM joined with older adult advocacy groups, professional societies of providers, and funders to create a geriatric‐focused acute‐care research agenda, highlighting 10 key research questions.[5, 6, 7] The goal of this approach was to produce and promote high integrity, evidence‐based information that comes from research guided by patients, caregivers, and the broader healthcare community.[8] In this article, we describe the methodology and results of this agenda‐setting process, referred to as the Acute Care of Older Patients (ACOP) Priority Setting Partnership.

METHODS

Overview

This project focused on topic generation, the first step in the PCORI framework for identification and prioritization of research areas.[5] We employed a specific and defined methodology to elicit and prioritize potential research topics incorporating input from representatives of older patients, family caregivers, and healthcare providers.[6]

To elicit this input, we chose a collaborative and consultative approach to stakeholder engagement, drawing heavily from the published work of the JLA, an initiative promoting patient‐clinician partnerships in health research developed in the United Kingdom.[6] We previously described the approach elsewhere.[7]

The ACOP process for determining the research agenda consisted of 4 steps: (1) convene, (2) consult, (3) collate, and (4) prioritize.[6] Through these steps, detailed below, we were able to obtain input from a broad group of stakeholders and engage the stakeholders in a process of reducing and refining our research questions.

Convene

The steering committee (the article's authors) convened a stakeholder partnership group that included stakeholders representing patients and caregivers, advocacy organizations for the elderly, organizations that address diseases and conditions common among hospitalized older patients, provider professional societies (eg, hospitalists, subspecialists, and nurses and social workers), payers, and funders. Patient, caregiver, and advocacy organizations were identified based on their engagement in aging and health policy advocacy by SHM staff and 1 author who had completed a Health and Aging Policy Fellowship (H.L.W.).

The steering committee issued e‐mail invitations to stakeholder organizations, making initial inquiries through professional staff and relevant committee chairs. Second inquiries were made via e‐mail to each organization's volunteer leadership. We developed a webinar that outlined the overall research agenda setting process and distributed the webinar to all stakeholders. The stakeholder organizations were asked to commit to (1) surveying their memberships and (2) participating actively in prioritization by e‐mail and at a 1‐day meeting in Washington DC.

Consult

Each stakeholder organization conducted a survey of its membership via an Internet‐based survey in the summer of 2013 (see Supporting Information, Appendix A, in the online version of this article). Stakeholder organizations were asked to provide up to 75 survey responses each. Though a standard survey was used, the steering committee was not prescriptive in the methodology of survey distribution to accommodate the structure and communication methods of the individual stakeholder organizations. Survey respondents were asked to identify up to 5 unanswered questions relevant to the acute care of older persons and also provide demographic information.

Collate

In the collating process, we clarified and categorized the unanswered questions submitted in the individual surveys. Each question was initially reviewed by a member of the steering committee, using explicit criteria (see Supporting Information, Appendix B, in the online version of this article). Questions that did not meet all 4 criteria were removed. For questions that met all criteria, we clarified language, combined similar questions, and categorized each question. Categories were created in a grounded process, in which individual reviewers assigned categories based on the content of the questions. Each question could be assigned to up to 2 categories. Each question was then reviewed by a second member of the steering committee using the same 4 criteria. As part of this review, similar questions were consolidated, and when possible, questions were rewritten in a standard format.[6]

Finally, the steering committee reviewed previously published research agendas looking for additional relevant unanswered questions, specifically the New Frontiers Research Agenda created by the American Geriatrics Society in conjunction with participating subspecialty societies,[9] the Cochrane Library, and other systematic reviews identified in the literature via PubMed search.[10, 11, 12, 13, 14, 15]

Prioritize

The resulting list of unanswered questions was prioritized in 2 phases. First, the list was e‐mailed to all stakeholder organizations. The organizations were asked to vote on their top 10 priorities from this list using an online ballot, assigning 10 points to their highest priority down to 1 point for their lowest priority. In so doing, they were asked to consider explicit criteria (see Supporting Information, Appendix B, in the online version of this article). Each organization had only 1 ballot and could arrive at their top 10 list in any manner they wished. The balloting from this phase was used to develop a list of unanswered questions for the second round of in‐person prioritization. Each priority's scores were totaled across all voting organizations. The 29 priorities with the highest point totals were brought to the final prioritization round because of a natural cut point at priority number 29, rather than number 30.

For the final prioritization round, the steering committee facilitated an in‐person meeting in Washington, DC in October 2013 using nominal group technique (NGT) methodologies to arrive at consensus.[16] During this process stakeholders were asked to consider additional criteria (see Supporting Information, Appendix B, in the online version of this article).

RESULTS

Table 1 lists the organizations who engaged in 1 or more parts of the topic generation process. Eighteen stakeholder organizations agreed to participate in the convening process. Ten organizations did not respond to our solicitation and 1 declined to participate.

Stakeholder Organizations Participating in the Acute Care of Older Persons Priority Setting Partnership
Organization (N=18) Consultation % of Survey Responses (N=580) Prioritization Round 1 Prioritization Round 2
Alzheimer's Association 7.0% Yes Yes
American Academy of Neurology 3.4% Yes Yes
American Association of Retired Persons 0.8% No No
American College of Cardiology 11.4% Yes Yes
American College of Emergency Physicians 1.3% No No
American College of Surgeons 1.0% Yes Yes
American Geriatrics Society 7.6% Yes Yes
American Hospital Association 1.7% Yes No
Centers for Medicare & Medicaid Services 0.8% Yes Yes
Gerontological Society of America 18.9% Yes Yes
National Alliance for Caregiving 1.0% Yes Yes
National Association of Social Workers 5.9% Yes Yes
National Coalition for Healthcare 0.6% No No
National Institute on Aging 2.1% Yes Yes
National Partnership for Women and Families 0.0% Yes Yes
Nursing Improving Care for Healthsystem Elders 28.6% Yes No
Society of Critical Care Medicine 12.0% Yes Yes
Society of Hospital Medicine 4.6% Yes Yes

Seventeen stakeholder organizations obtained survey responses from a total of 580 individuals (range, 3150 per organization), who were asked to identify important unanswered questions in the acute care of older persons. Survey respondents were typically female (77%), white (85%), aged 45 to 65 years (65%), and identified themselves as health professionals (90%). Twenty‐six percent of respondents also identified as patients or family caregivers. Their surveys included 1299 individual questions.

Figure 1 summarizes our collation and prioritization process and reports the numbers of questions resulting at each stage. Nine hundred nineteen questions were removed during the first review conducted by steering committee members, and 31 question categories were identified. An additional 305 questions were removed in the second review, with 75 questions remaining. As the final step of the collating process, literature review identified 39 relevant questions not already suggested or moved forward through our consultation and collation process. These questions were added to the list of unanswered questions.

Figure 1
Flow diagram to develop top 10 unanswered questions from stakeholder survey results. The 1299 unanswered questions were reduced to a final list of 10 high‐priority research topics through a 2‐step collation process and a 2‐step prioritization process as depicted in the flow diagram.

In the first round of prioritization, this list of 114 questions was emailed to each stakeholder organization (Table 1). After the stakeholder voting process was completed, 29 unanswered questions remained (see Supporting Information, Appendix C, in the online version of this article). These questions were refined and prioritized in the in‐person meeting to create the final list of 10 questions. The stakeholders present in the meeting represented 13 organizations (Table 1). Using the NGT with several rounds of small group breakouts and large group deliberation, 9 of the top 10 questions were selected from the list of 29. One additional highly relevant question that had been removed earlier in the collation process regarding workforce was added back by the stakeholder group.

This prioritized research agenda appears in Table 2 and below, organized alphabetically by topic.

  1. Advanced care planning: What approaches for determining and communicating goals of care across and within healthcare settings are most effective in promoting goal‐concordant care for hospitalized older patients?
  2. Care transitions: What is the comparative effectiveness of transitional care models on patient‐centered outcomes for hospitalized older adults?
  3. Delirium: What practices are most effective for consistent recognition, prevention, and treatment of delirium subtypes among hospitalized older adults?
  4. Dementia: Does universal assessment of hospitalized older adults for cognitive impairment (eg, at presentation and/or discharge) lead to more appropriate application of geriatric care principles and improve patient‐centered outcomes?
  5. Depression: Does identifying depressive symptoms during a hospital stay and initiating a therapeutic plan prior to discharge improve patient‐centered and/or disease‐specific outcomes?
  6. Medications: What systems interventions improve medication management for older adults (ie, appropriateness of medication choices and dosing, compliance, cost) in the hospital and postacute care?
  7. Models of care: For which populations of hospitalized older adults does systematic implementation of geriatric care principles/processes improve patient‐centered outcomes?
  8. Physical function: What is the comparative effectiveness of interventions that promote in‐hospital mobility, improve and preserve physical function, and reduce falls among older hospitalized patients?
  9. Surgery: What perioperative strategies can be used to optimize care processes and improve outcomes in older surgical patients?
  10. Training: What is the most effective approach to training hospital‐based providers in geriatric and palliative care competencies?
Top Ten Unanswered Questions in the Acute Care of Older Persons
Topic Scope of Problem What Is known Unanswered Question Proposed Dimensions
  • NOTE: Abbreviations: ADL, activities of daily living; AGESP, Advancement of Geriatrics Education Scholars Program; CHAMP, Curriculum for the Hospitalized Aging Medical Patient; ICU, intensive care unit; NICHE, Nurses Improving the Care of Health System Elders; PAGE, Program for Advancing Geriatrics Education; POLST, physician orders for life sustaining treatment; RCT, randomized controlled trial; STOPP, Screening Tool of Older People's Potentially Inappropriate Prescriptions.

  • Patient‐centered outcomes might include quality of life, symptoms, cognition, and functional status.

Advanced‐care planning Older persons who lack decision‐making capacity often do not have surrogates or clear goals of care documented.[19] Advanced‐care directives are associated with an increase in patient autonomy and empowerment, and although 15% to 25% of adults completed the documentation in 2004,[20] a recent study found completion rates have increased to 72%.[21] Nursing home residents with advanced directives are less likely to be hospitalized.[22, 23] Advanced directive tools, such as POLST, work to translate patient preferences to medical order.[24] standardized patient transfer tools may help to improve transitions between nursing homes and hospitals.[25] However, advanced care planning fails to integrate into courses of care if providers are unwilling or unskilled in using advanced care documentation.[26] What approaches for determining and communicating goals of care across and within healthcare settings are most effective in promoting goal‐concordant care for hospitalized older patients? Potential interventions:
Decision aids
Standard interdisciplinary advanced care planning approach
Patient advocates
Potential outcomes might include:
Completion of advanced directives and healthcare power of attorney
Patient‐centered outcomesa
Care transitions Hospital readmission from home and skilled nursing facilities occurs within 30 days in up to a quarter of patients.[27, 28] The discharge of complex older hospitalized patients is fraught with challenges. The quality of the hospital discharge process can influence outcomes for vulnerable older patients.[29, 30, 31, 32] Studies measuring the quality of hospital discharge frequently find deficits in documentation of assessment of geriatric syndromes,[33] poor patient/caregiver understanding,[34, 35] and poor communication and follow‐up with postacute providers.[35, 36, 37, 38] As many as 10 separate domains may influence the success of a discharge.[39] There is limited evidence, regarding quality‐of‐care transitions for hospitalized older patients. The Coordinated‐Transitional Care Program found that follow‐up with telecommunication decreased readmission rates and improved transitional care for a high‐risk condition veteran population.[40] There is modest evidence for single interventions,[41] whereas the most effective hospital‐to‐community care interventions address multiple processes in nongeriatric populations.[39, 42, 43] What is the comparative effectiveness of the transitional care models on patient‐centered outcomes for hospitalized older adults? Possible models:
Established vs novel care‐transition models
Disease‐specific vs general approaches
Accountable care models
Caregiver and family engagement
Community engagement
Populations of interest:
Patients with dementia
Patients with multimorbidity
Patients with geriatric syndromes
Patients with psychiatric disease
Racially and ethnically diverse patients
Outcomes:
Readmission
Other adverse events
Cost and healthcare utilization
Patient‐centered outcomesa
Delirium Among older inpatients, the prevalence of delirium varies with severity of illness. Among general medical patients, in‐hospital prevalence ranges from 10% to 25 %.[44, 45] In the ICU, prevalence estimates are higher, ranging from 25% to as high as 80%.[46, 47] Delirium independently predicts increased length of stay,[48, 49] long‐term cognitive impairment,[50, 51] functional decline,[51] institutionalization,[52] and short‐ and long‐term mortality.[52, 53, 54] Multicomponent strategies have been shown to be effective in preventing delirium. A systematic review of 19 such interventions identified the most commonly included such as[55]: early mobilization, nutrition supplements, medication review, pain management, sleep enhancement, vision/hearing protocols, and specialized geriatric care. Studies have included general medical patients, postoperative patients, and patients in the ICU. The majority of these studies found reductions in either delirium incidence (including postoperative), delirium prevalence, or delirium duration. Although medications have not been effective in treating delirium in general medical patients,[48] the choice and dose of sedative agents has been shown to impact delirium in the ICU.[56, 57, 58] What practices are most effective for consistent recognition, prevention, and treatment of delirium subtypes (hypoactive, hyperactive, and mixed) among hospitalized older adults? Outcomes to examine:
Delirium incidence (including postoperative)
Delirium duration
Delirium‐/coma‐free days
Delirium prevalence at discharge
Subsyndromal delirium
Potential prevention and treatment modalities:
Family education or psychosocial interventions
Pharmacologic interventions
Environmental modifications
Possible areas of focus:
Special populations
Patients with varying stages of dementia
Patients with multimorbidity
Patients with geriatric syndromes
Observation patients
Diverse settings
Emergency department
Perioperative
Skilled nursing/rehab/long‐term acute‐care facilities
Dementia 13% to 63% of older persons in the hospital have dementia.[59] Dementia is often unrecognized among hospitalized patients.[60] The presence of dementia is associated with a more rapid functional decline during admission and delayed hospital discharge.[59] Patients with dementia require more nursing hours, and are more likely to have complications[61] or die in care homes rather than in their preferred site.[59] Several tools have been validated to screen for dementia in the hospital setting.[62] Studies have assessed approaches to diagnosing delirium in hospitalized patients with dementia.[63] Cognitive and functional stimulation interventions may have a positive impact on reducing behavioral issues.[64, 65] Does universal assessment of hospitalized older adults for cognitive impairment (eg, at presentation and/or discharge) lead to more appropriate application of geriatric care principles and improve patient centered outcomes? Potential interventions:
Dementia or delirium care
Patient/family communication and engagement strategies
Maintenance/recovery of independent functional status
Potential outcomes:
Patient‐centered outcomesa
Length of stay, cost, and healthcare utilization (including palliative care)
Immediate invasive vs early conservative treatments pursued
Depression Depression is a common geriatric syndrome among acutely ill older patients, occurring in up to 45% of patients.[66, 67] Rates of depression are similar among patients discharged following a critical illness, with somatic, rather than cognitive‐affective complaints being the most prevalent.[68] Depression among inpatients or immediately following hospitalization independently predicts worse functional outcomes,[69] cognitive decline,[70] hospital readmission,[71, 72] and long‐term mortality.[69, 73] Finally, geriatric patients are known to respond differently to medical treatment.[74, 75] Although highly prevalent, depression is poorly recognized and managed in the inpatient setting. Depression is recognized in only 50% of patients, with previously undiagnosed or untreated depression being at highest risk for being missed.[76] The role of treatment of depression in the inpatient setting is poorly understood, particularly for those with newly recognized depression or depressive symptoms. Some novel collaborative care and telephone outreach programs have led to increases in depression treatment in patients with specific medical and surgical conditions, resulting in early promising mental health and comorbid outcomes.[77, 78] The efficacy of such programs for older patients is unknown. Does identifying depressive symptoms during a hospital stay and initiating a therapeutic plan prior to discharge improve patient‐centered and/or disease‐specific outcomes? Possible areas of focus:
Comprehensive geriatric and psychosocial assessment;
Inpatient vs outpatient initiation of pharmacological therapy
Integration of confusion assessment method into therapeutic approaches
Linkages with outpatient mental health resources
Medications Medication exposure, particularly potentially inappropriate medications, is common in hospitalized elders.[79] Medication errorsof dosage, type, and discrepancy between what a patient takes at home and what is known to his/her prescribing physicianare common and adversely affects patient safety.[80] Geriatric populations are disproportionately affected, especially those taking more than 5 prescription medications per day.[81] Numerous strategies including electronic alerts, screening protocols, and potentially inappropriate medication lists (Beers list, STOPP) exist, though the optimal strategies to limit the use of potentially inappropriate medications is not yet known.[82, 83, 84] What systems interventions improve medication management for older adults (ie, appropriateness of medication choices and dosing, compliance, cost) in hospital and post‐acute care? Possible areas of focus:
Use of healthcare information technology
Communication across sites of care
Reducing medication‐related adverse events
Engagement of family caregivers
Patient‐centered strategies to simplify regimens
Models of care Hospitalization marks a time of high risk for older patients. Up to half die during hospitalization or within the year following the hospitalization. There is high risk of nosocomial events, and more than a third experience a decline in health resulting in longer hospitalizations and/or placement in extended‐care facilities.[73, 85, 86] Comprehensive inpatient care for older adults (acute care for elders units, geriatric evaluation and management units, geriatric consultation services) were studied in 2 meta‐analyses, 5 RCTs, and 1 quasiexperimental study and summarized in a systematic review.[87] The studies reported improved quality of care (1 of 1 article), quality of life (3 of 4), functional autonomy (5 of 6), survival (3 of 6), and equal or lower healthcare utilization (7 of 8). For which populations of hospitalized older adults does systematic implementation of geriatric care principles/processes improve patient‐centered outcomes? Potential populations:
Patients of the emergency department, critical care, perioperative, and targeted medical/surgical units
Examples of care principles:
Geriatric assessment, early mobility, medication management, delirium prevention, advanced‐care planning, risk‐factor modification, caregiver engagement
Potential outcomes:
Patient‐centered outcomesa
Cost
Physical function Half of older patients will lose functional capacity during hospitalization.[88] Loss of physical function, particularly of lower extremities, is a risk factor for nursing home placement.[89, 90] Older hospitalized patients spend the majority (up to 80%) of their time lying in bed, even when they are capable of walking independently.[91] Loss of independences with ADL capabilities is associated with longer hospital stays, higher readmission rates, and higher mortality risk.[92] Excessive time in bed during a hospital stay is also associated with falls.[93] Often, hospital nursing protocols and physician orders increase in‐hospital immobility in patients.[91, 94] However, nursing‐driven mobility protocols can improve functional outcomes of older hospitalized patients.[95, 96] What is the comparative effectiveness of interventions that promote in‐hospital mobility, improve and preserve physical function, and reduce falls among older hospitalized patients? Potential interventions:
Intensive physical therapy
Incidental functional training
Restraint reduction
Medication management
Potential outcomes:
Discharge location
Delirium, pressure ulcers, and falls
Surgery An increasing number of persons over age 65 years are undergoing surgical procedures.[97] These persons are at increased risk for developing delirium/cogitative dysfunction,[98] loss of functional status,[99] and exacerbations of chronic illness.[97] Additionally, pain management may be harder to address in this population.[100] Current outcomes may not reflect the clinical needs of elder surgical patients.[101] Tailored drug selection and nursing protocols may prevent delirium.[98] Postoperative cognitive dysfunction may require weeks for resolution. Identifying frail patients preoperatively may lead to more appropriate risk stratification and improved surgical outcomes.[99] Pain management strategies focused on mitigating cognitive impact and other effects may also be beneficial.[100] Development of risk‐adjustment tools specific to older populations, as well as measures of frailty and patient‐centered care, have been proposed.[101] What perioperative strategies can be used to optimize care processes and improve outcomes in older surgical patients? Potential strategies:
Preoperative risk assessment and optimization for frail or multimorbid older patients
Perioperative management protocols for frail or multimorbid older patients
Potential outcomes:
Postoperative patient centered outcomesa
Perioperative cost, healthcare utilization
Training Adults over age 65 years comprise 13.2 % of the US population, but account for >30% of hospital discharges and 50% of hospital days.[86, 102, 103] By 2030, there will only be 1 geriatrician for every 3798 Americans >75 years.[4] Between 1997 and 2006, the odds that a hospitalist would treat a hospitalized Medicare patient rose 29% per year.[3] Train the trainer programs for physicians include the CHAMP, the AGESP, and the PAGE. Education for nurses include the NICHE. Outcomes include improved self‐confidence, attitudes, teaching skills, and geriatric care environment.[104, 105, 106] What is the most effective approach to training hospital‐based providers in geriatric and palliative care competencies? Potential interventions:
Mentored implementation
Train the trainer
Technical support

Table 2 also contains a capsule summary of the scope of the problem addressed by each research priority, a capsule summary of related work in the content area (what is known) not intended as a systematic review, and proposed dimensions or subquestions suggested by the stakeholders at the final prioritization meeting

DISCUSSION

Older hospitalized patients account for an increasing number and proportion of hospitalized patients,[1, 2] and hospitalists increasingly are responsible for inpatient care for this population.[3] The knowledge required for hospitalists to deliver optimal care and improve outcomes has not kept pace with the rapid growth of either hospitalists or hospitalized elders. Through a rigorous prioritization process, we identified 10 areas that deserve the highest priority in directing future research efforts to improve care for the older hospitalized patient. Assessment, prevention, and treatment of geriatric syndromes in the hospital account for almost half of the priority areas. Additional research is needed to improve advanced care planning, develop new care models, and develop training models for future hospitalists competent in geriatric and palliative care competencies.

A decade ago, the American Geriatric Society and the John A. Hartford Foundation embarked upon a research agenda aimed at improving the care of hospitalized elders cared for by specialists (ie, New Frontiers in Geriatrics Research: An Agenda for Surgical and Related Medical Specialties).[9] This effort differed in many important ways from the current priortization process. First, the New Frontiers agenda focused upon specific diseases, whereas the ACOP agenda addresses geriatric syndromes that cut across multiple diseases. Second, the New Frontiers agenda was made by researchers and based upon published literature, whereas the ACOP agenda involved the input of multiple stakeholders. Finally, the New Frontiers prioritized a research agenda across a number of surgical specialties, emergency medicine, and geriatric rehabilitation. Hospital medicine, however, was still early in its development and was not considered a unique specialty. Since that time, hospital medicine has matured into a unique specialty, with increased numbers of hospitalists,[3] increased research in hospital medicine,[17] and a separate recertification pathway for internal medicine licensure.[18] To date, there has not been a similar effort performed to direct geriatric research efforts for hospital medicine.

For researchers working in the field of hospital medicine, this list of topics has several implications. First, as hospitalists are commonly generalists, hospitalist researchers may be particularly well‐suited to study syndromes that cut across specialties. However, this does raise concerns about funding sources, as most National Institutes of Health institutes are disease‐focused. Funders that are not disease‐focused such as PCORI, National Institute on Aging, National Institute of Nursing Research, and Agency for Healthcare Research and Quality, and private foundations (Hartford, Robert Wood Johnson, and Commonwealth) may be more fruitful sources of funding for this work, but funding may be challenging. Nonetheless, the increased focus on patient‐centered work may increase funders' interest in such work. Second, the topics on this list would suggest that interventions will not be pharmacologic, but will focus on nonpharmacologic, behavioral, and social interventions. Similarly, outcomes of interest must expand beyond utilization metrics such as length of stay and mortality, to include functional status and symptom management, and goal‐concordant care. Therefore, research in geriatric acute care will necessarily be multidisciplinary.

Although these 10 high‐priority areas have been selected, this prioritized list is inherently limited by our methodology. First, our survey question was not focused on a disease state, and this wording may have resulted in the list favoring geriatric syndromes rather than common disease processes. Additionally, the resulting questions encompass large research areas and not specific questions about discrete interventions. Our results may also have been skewed by the types of engaged respondents who participated in the consultation, collating, and prioritization phases. In particular, we had a large response from geriatric medicine nurses, whereas some stakeholder groups provided no survey responses. Thus, these respondents were not representative of all possible stakeholders, nor were the survey respondents necessarily representative of each of their organizations. Nonetheless, the participants self‐identified as representative of diverse viewpoints that included patients, caregivers, and advocacy groups, with the majority of stakeholder organizations remaining engaged through the completion of the process. Thus, the general nature of this agenda helps us focus upon larger areas of importance, leaving researchers the flexibility to choose to narrow the focus on a specific research question that may include potential interventions and unique outcomes. Finally, our methodology may have inadvertently limited the number of patient and family caregiver voices in the process given our approach to large advocacy groups, our desire to be inclusive of healthcare professional organizations, and our survey methodology. Other methodologies may have reached more patients and caregivers, yet many healthcare professionals have served as family caregivers to frail elders requiring hospitalization and may have been in an ideal position to answer the survey.

In conclusion, several forces are shaping the future of acute inpatient care. These include the changing demographics of the hospitalized patient population, a rapid increase in the proportion of multimorbid hospitalized older adults, an inpatient workforce (hospitalists, generalists, and subspecialists) with potentially limited geriatrics training, and gaps in evidence‐based guidance to inform diagnostic and therapeutic decision making for acutely ill older patients. Training programs in hospital medicine should be aware of and could benefit from the resulting list of unanswered questions. Our findings also have implications for training to enrich education in geriatrics. Moreover, there is growing recognition that patients and other stakeholders deserve a greater voice in determining the direction of research. In addition to efforts to improve patient‐centeredness of research, these areas have been uniquely identified by stakeholders as important, and therefore are in line with newer priorities of PCORI. This project followed a road map resulting in a patient‐centered research agenda at the intersection of hospital medicine and geriatric medicine.[7] In creating this agenda, we relied heavily on the framework proposed by PCORI. We propose to pursue a dissemination and evaluation strategy for this research agenda as well as additional prioritization steps. We believe the adoption of this methodology will create a knowledge base that is rigorously derived and most relevant to the care of hospitalized older adults and their families. Its application will ultimately result in improved outcomes for hospitalized older adults.

Acknowledgements

The authors acknowledge Claudia Stahl, Society of Hospital Medicine; Cynthia Drake, University of Colorado; and the ACOP stakeholder organizations.

Disclosures: This work was supported by the Association of Specialty Professors/American Society of Internal Medicine and the John A. Hartford Foundation. Dr. Vasilevskis was supported by the National Institute on Aging of the National Institutes of Health under award number K23AG040157 and the Veterans Affairs Clinical Research Center of Excellence, and the Geriatric Research, Education and Clinical Center (GRECC). Dr. Vasilevskis' institution receives grant funding for an aspect of submitted work. Dr. Meltzer is a PCORI Methodology Committee member. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health or the Department of Veterans' Affairs. The authors report no conflicts of interest.

Older adults with high levels of medical complexity occupy an increasing fraction of beds in acute‐care hospitals in the United States.[1, 2] By 2007, patients age 65 years and older accounted for nearly half of adult inpatient days of care.[1] These patients are commonly cared for by hospitalists who number more than 40,000.[3] Although hospitalists are most often trained in internal medicine, they have typically received limited formal geriatrics training. Increasingly, access to experts in geriatric medicine is limited.[4] Further, hospitalists and others who practice in acute care are limited by the lack of research to address the needs of the older adult population, specifically in the diagnosis and management of conditions encountered during acute illness.

To better support hospitalists in providing acute inpatient geriatric care, the Society of Hospital Medicine (SHM) partnered with the Association of Specialty Professors to develop a research agenda to bridge this gap. Using methodology from the James Lind Alliance (JLA) and the Patient Centered Outcomes Research Institute (PCORI), the SHM joined with older adult advocacy groups, professional societies of providers, and funders to create a geriatric‐focused acute‐care research agenda, highlighting 10 key research questions.[5, 6, 7] The goal of this approach was to produce and promote high integrity, evidence‐based information that comes from research guided by patients, caregivers, and the broader healthcare community.[8] In this article, we describe the methodology and results of this agenda‐setting process, referred to as the Acute Care of Older Patients (ACOP) Priority Setting Partnership.

METHODS

Overview

This project focused on topic generation, the first step in the PCORI framework for identification and prioritization of research areas.[5] We employed a specific and defined methodology to elicit and prioritize potential research topics incorporating input from representatives of older patients, family caregivers, and healthcare providers.[6]

To elicit this input, we chose a collaborative and consultative approach to stakeholder engagement, drawing heavily from the published work of the JLA, an initiative promoting patient‐clinician partnerships in health research developed in the United Kingdom.[6] We previously described the approach elsewhere.[7]

The ACOP process for determining the research agenda consisted of 4 steps: (1) convene, (2) consult, (3) collate, and (4) prioritize.[6] Through these steps, detailed below, we were able to obtain input from a broad group of stakeholders and engage the stakeholders in a process of reducing and refining our research questions.

Convene

The steering committee (the article's authors) convened a stakeholder partnership group that included stakeholders representing patients and caregivers, advocacy organizations for the elderly, organizations that address diseases and conditions common among hospitalized older patients, provider professional societies (eg, hospitalists, subspecialists, and nurses and social workers), payers, and funders. Patient, caregiver, and advocacy organizations were identified based on their engagement in aging and health policy advocacy by SHM staff and 1 author who had completed a Health and Aging Policy Fellowship (H.L.W.).

The steering committee issued e‐mail invitations to stakeholder organizations, making initial inquiries through professional staff and relevant committee chairs. Second inquiries were made via e‐mail to each organization's volunteer leadership. We developed a webinar that outlined the overall research agenda setting process and distributed the webinar to all stakeholders. The stakeholder organizations were asked to commit to (1) surveying their memberships and (2) participating actively in prioritization by e‐mail and at a 1‐day meeting in Washington DC.

Consult

Each stakeholder organization conducted a survey of its membership via an Internet‐based survey in the summer of 2013 (see Supporting Information, Appendix A, in the online version of this article). Stakeholder organizations were asked to provide up to 75 survey responses each. Though a standard survey was used, the steering committee was not prescriptive in the methodology of survey distribution to accommodate the structure and communication methods of the individual stakeholder organizations. Survey respondents were asked to identify up to 5 unanswered questions relevant to the acute care of older persons and also provide demographic information.

Collate

In the collating process, we clarified and categorized the unanswered questions submitted in the individual surveys. Each question was initially reviewed by a member of the steering committee, using explicit criteria (see Supporting Information, Appendix B, in the online version of this article). Questions that did not meet all 4 criteria were removed. For questions that met all criteria, we clarified language, combined similar questions, and categorized each question. Categories were created in a grounded process, in which individual reviewers assigned categories based on the content of the questions. Each question could be assigned to up to 2 categories. Each question was then reviewed by a second member of the steering committee using the same 4 criteria. As part of this review, similar questions were consolidated, and when possible, questions were rewritten in a standard format.[6]

Finally, the steering committee reviewed previously published research agendas looking for additional relevant unanswered questions, specifically the New Frontiers Research Agenda created by the American Geriatrics Society in conjunction with participating subspecialty societies,[9] the Cochrane Library, and other systematic reviews identified in the literature via PubMed search.[10, 11, 12, 13, 14, 15]

Prioritize

The resulting list of unanswered questions was prioritized in 2 phases. First, the list was e‐mailed to all stakeholder organizations. The organizations were asked to vote on their top 10 priorities from this list using an online ballot, assigning 10 points to their highest priority down to 1 point for their lowest priority. In so doing, they were asked to consider explicit criteria (see Supporting Information, Appendix B, in the online version of this article). Each organization had only 1 ballot and could arrive at their top 10 list in any manner they wished. The balloting from this phase was used to develop a list of unanswered questions for the second round of in‐person prioritization. Each priority's scores were totaled across all voting organizations. The 29 priorities with the highest point totals were brought to the final prioritization round because of a natural cut point at priority number 29, rather than number 30.

For the final prioritization round, the steering committee facilitated an in‐person meeting in Washington, DC in October 2013 using nominal group technique (NGT) methodologies to arrive at consensus.[16] During this process stakeholders were asked to consider additional criteria (see Supporting Information, Appendix B, in the online version of this article).

RESULTS

Table 1 lists the organizations who engaged in 1 or more parts of the topic generation process. Eighteen stakeholder organizations agreed to participate in the convening process. Ten organizations did not respond to our solicitation and 1 declined to participate.

Stakeholder Organizations Participating in the Acute Care of Older Persons Priority Setting Partnership
Organization (N=18) Consultation % of Survey Responses (N=580) Prioritization Round 1 Prioritization Round 2
Alzheimer's Association 7.0% Yes Yes
American Academy of Neurology 3.4% Yes Yes
American Association of Retired Persons 0.8% No No
American College of Cardiology 11.4% Yes Yes
American College of Emergency Physicians 1.3% No No
American College of Surgeons 1.0% Yes Yes
American Geriatrics Society 7.6% Yes Yes
American Hospital Association 1.7% Yes No
Centers for Medicare & Medicaid Services 0.8% Yes Yes
Gerontological Society of America 18.9% Yes Yes
National Alliance for Caregiving 1.0% Yes Yes
National Association of Social Workers 5.9% Yes Yes
National Coalition for Healthcare 0.6% No No
National Institute on Aging 2.1% Yes Yes
National Partnership for Women and Families 0.0% Yes Yes
Nursing Improving Care for Healthsystem Elders 28.6% Yes No
Society of Critical Care Medicine 12.0% Yes Yes
Society of Hospital Medicine 4.6% Yes Yes

Seventeen stakeholder organizations obtained survey responses from a total of 580 individuals (range, 3150 per organization), who were asked to identify important unanswered questions in the acute care of older persons. Survey respondents were typically female (77%), white (85%), aged 45 to 65 years (65%), and identified themselves as health professionals (90%). Twenty‐six percent of respondents also identified as patients or family caregivers. Their surveys included 1299 individual questions.

Figure 1 summarizes our collation and prioritization process and reports the numbers of questions resulting at each stage. Nine hundred nineteen questions were removed during the first review conducted by steering committee members, and 31 question categories were identified. An additional 305 questions were removed in the second review, with 75 questions remaining. As the final step of the collating process, literature review identified 39 relevant questions not already suggested or moved forward through our consultation and collation process. These questions were added to the list of unanswered questions.

Figure 1
Flow diagram to develop top 10 unanswered questions from stakeholder survey results. The 1299 unanswered questions were reduced to a final list of 10 high‐priority research topics through a 2‐step collation process and a 2‐step prioritization process as depicted in the flow diagram.

In the first round of prioritization, this list of 114 questions was emailed to each stakeholder organization (Table 1). After the stakeholder voting process was completed, 29 unanswered questions remained (see Supporting Information, Appendix C, in the online version of this article). These questions were refined and prioritized in the in‐person meeting to create the final list of 10 questions. The stakeholders present in the meeting represented 13 organizations (Table 1). Using the NGT with several rounds of small group breakouts and large group deliberation, 9 of the top 10 questions were selected from the list of 29. One additional highly relevant question that had been removed earlier in the collation process regarding workforce was added back by the stakeholder group.

This prioritized research agenda appears in Table 2 and below, organized alphabetically by topic.

  1. Advanced care planning: What approaches for determining and communicating goals of care across and within healthcare settings are most effective in promoting goal‐concordant care for hospitalized older patients?
  2. Care transitions: What is the comparative effectiveness of transitional care models on patient‐centered outcomes for hospitalized older adults?
  3. Delirium: What practices are most effective for consistent recognition, prevention, and treatment of delirium subtypes among hospitalized older adults?
  4. Dementia: Does universal assessment of hospitalized older adults for cognitive impairment (eg, at presentation and/or discharge) lead to more appropriate application of geriatric care principles and improve patient‐centered outcomes?
  5. Depression: Does identifying depressive symptoms during a hospital stay and initiating a therapeutic plan prior to discharge improve patient‐centered and/or disease‐specific outcomes?
  6. Medications: What systems interventions improve medication management for older adults (ie, appropriateness of medication choices and dosing, compliance, cost) in the hospital and postacute care?
  7. Models of care: For which populations of hospitalized older adults does systematic implementation of geriatric care principles/processes improve patient‐centered outcomes?
  8. Physical function: What is the comparative effectiveness of interventions that promote in‐hospital mobility, improve and preserve physical function, and reduce falls among older hospitalized patients?
  9. Surgery: What perioperative strategies can be used to optimize care processes and improve outcomes in older surgical patients?
  10. Training: What is the most effective approach to training hospital‐based providers in geriatric and palliative care competencies?
Top Ten Unanswered Questions in the Acute Care of Older Persons
Topic Scope of Problem What Is known Unanswered Question Proposed Dimensions
  • NOTE: Abbreviations: ADL, activities of daily living; AGESP, Advancement of Geriatrics Education Scholars Program; CHAMP, Curriculum for the Hospitalized Aging Medical Patient; ICU, intensive care unit; NICHE, Nurses Improving the Care of Health System Elders; PAGE, Program for Advancing Geriatrics Education; POLST, physician orders for life sustaining treatment; RCT, randomized controlled trial; STOPP, Screening Tool of Older People's Potentially Inappropriate Prescriptions.

  • Patient‐centered outcomes might include quality of life, symptoms, cognition, and functional status.

Advanced‐care planning Older persons who lack decision‐making capacity often do not have surrogates or clear goals of care documented.[19] Advanced‐care directives are associated with an increase in patient autonomy and empowerment, and although 15% to 25% of adults completed the documentation in 2004,[20] a recent study found completion rates have increased to 72%.[21] Nursing home residents with advanced directives are less likely to be hospitalized.[22, 23] Advanced directive tools, such as POLST, work to translate patient preferences to medical order.[24] standardized patient transfer tools may help to improve transitions between nursing homes and hospitals.[25] However, advanced care planning fails to integrate into courses of care if providers are unwilling or unskilled in using advanced care documentation.[26] What approaches for determining and communicating goals of care across and within healthcare settings are most effective in promoting goal‐concordant care for hospitalized older patients? Potential interventions:
Decision aids
Standard interdisciplinary advanced care planning approach
Patient advocates
Potential outcomes might include:
Completion of advanced directives and healthcare power of attorney
Patient‐centered outcomesa
Care transitions Hospital readmission from home and skilled nursing facilities occurs within 30 days in up to a quarter of patients.[27, 28] The discharge of complex older hospitalized patients is fraught with challenges. The quality of the hospital discharge process can influence outcomes for vulnerable older patients.[29, 30, 31, 32] Studies measuring the quality of hospital discharge frequently find deficits in documentation of assessment of geriatric syndromes,[33] poor patient/caregiver understanding,[34, 35] and poor communication and follow‐up with postacute providers.[35, 36, 37, 38] As many as 10 separate domains may influence the success of a discharge.[39] There is limited evidence, regarding quality‐of‐care transitions for hospitalized older patients. The Coordinated‐Transitional Care Program found that follow‐up with telecommunication decreased readmission rates and improved transitional care for a high‐risk condition veteran population.[40] There is modest evidence for single interventions,[41] whereas the most effective hospital‐to‐community care interventions address multiple processes in nongeriatric populations.[39, 42, 43] What is the comparative effectiveness of the transitional care models on patient‐centered outcomes for hospitalized older adults? Possible models:
Established vs novel care‐transition models
Disease‐specific vs general approaches
Accountable care models
Caregiver and family engagement
Community engagement
Populations of interest:
Patients with dementia
Patients with multimorbidity
Patients with geriatric syndromes
Patients with psychiatric disease
Racially and ethnically diverse patients
Outcomes:
Readmission
Other adverse events
Cost and healthcare utilization
Patient‐centered outcomesa
Delirium Among older inpatients, the prevalence of delirium varies with severity of illness. Among general medical patients, in‐hospital prevalence ranges from 10% to 25 %.[44, 45] In the ICU, prevalence estimates are higher, ranging from 25% to as high as 80%.[46, 47] Delirium independently predicts increased length of stay,[48, 49] long‐term cognitive impairment,[50, 51] functional decline,[51] institutionalization,[52] and short‐ and long‐term mortality.[52, 53, 54] Multicomponent strategies have been shown to be effective in preventing delirium. A systematic review of 19 such interventions identified the most commonly included such as[55]: early mobilization, nutrition supplements, medication review, pain management, sleep enhancement, vision/hearing protocols, and specialized geriatric care. Studies have included general medical patients, postoperative patients, and patients in the ICU. The majority of these studies found reductions in either delirium incidence (including postoperative), delirium prevalence, or delirium duration. Although medications have not been effective in treating delirium in general medical patients,[48] the choice and dose of sedative agents has been shown to impact delirium in the ICU.[56, 57, 58] What practices are most effective for consistent recognition, prevention, and treatment of delirium subtypes (hypoactive, hyperactive, and mixed) among hospitalized older adults? Outcomes to examine:
Delirium incidence (including postoperative)
Delirium duration
Delirium‐/coma‐free days
Delirium prevalence at discharge
Subsyndromal delirium
Potential prevention and treatment modalities:
Family education or psychosocial interventions
Pharmacologic interventions
Environmental modifications
Possible areas of focus:
Special populations
Patients with varying stages of dementia
Patients with multimorbidity
Patients with geriatric syndromes
Observation patients
Diverse settings
Emergency department
Perioperative
Skilled nursing/rehab/long‐term acute‐care facilities
Dementia 13% to 63% of older persons in the hospital have dementia.[59] Dementia is often unrecognized among hospitalized patients.[60] The presence of dementia is associated with a more rapid functional decline during admission and delayed hospital discharge.[59] Patients with dementia require more nursing hours, and are more likely to have complications[61] or die in care homes rather than in their preferred site.[59] Several tools have been validated to screen for dementia in the hospital setting.[62] Studies have assessed approaches to diagnosing delirium in hospitalized patients with dementia.[63] Cognitive and functional stimulation interventions may have a positive impact on reducing behavioral issues.[64, 65] Does universal assessment of hospitalized older adults for cognitive impairment (eg, at presentation and/or discharge) lead to more appropriate application of geriatric care principles and improve patient centered outcomes? Potential interventions:
Dementia or delirium care
Patient/family communication and engagement strategies
Maintenance/recovery of independent functional status
Potential outcomes:
Patient‐centered outcomesa
Length of stay, cost, and healthcare utilization (including palliative care)
Immediate invasive vs early conservative treatments pursued
Depression Depression is a common geriatric syndrome among acutely ill older patients, occurring in up to 45% of patients.[66, 67] Rates of depression are similar among patients discharged following a critical illness, with somatic, rather than cognitive‐affective complaints being the most prevalent.[68] Depression among inpatients or immediately following hospitalization independently predicts worse functional outcomes,[69] cognitive decline,[70] hospital readmission,[71, 72] and long‐term mortality.[69, 73] Finally, geriatric patients are known to respond differently to medical treatment.[74, 75] Although highly prevalent, depression is poorly recognized and managed in the inpatient setting. Depression is recognized in only 50% of patients, with previously undiagnosed or untreated depression being at highest risk for being missed.[76] The role of treatment of depression in the inpatient setting is poorly understood, particularly for those with newly recognized depression or depressive symptoms. Some novel collaborative care and telephone outreach programs have led to increases in depression treatment in patients with specific medical and surgical conditions, resulting in early promising mental health and comorbid outcomes.[77, 78] The efficacy of such programs for older patients is unknown. Does identifying depressive symptoms during a hospital stay and initiating a therapeutic plan prior to discharge improve patient‐centered and/or disease‐specific outcomes? Possible areas of focus:
Comprehensive geriatric and psychosocial assessment;
Inpatient vs outpatient initiation of pharmacological therapy
Integration of confusion assessment method into therapeutic approaches
Linkages with outpatient mental health resources
Medications Medication exposure, particularly potentially inappropriate medications, is common in hospitalized elders.[79] Medication errorsof dosage, type, and discrepancy between what a patient takes at home and what is known to his/her prescribing physicianare common and adversely affects patient safety.[80] Geriatric populations are disproportionately affected, especially those taking more than 5 prescription medications per day.[81] Numerous strategies including electronic alerts, screening protocols, and potentially inappropriate medication lists (Beers list, STOPP) exist, though the optimal strategies to limit the use of potentially inappropriate medications is not yet known.[82, 83, 84] What systems interventions improve medication management for older adults (ie, appropriateness of medication choices and dosing, compliance, cost) in hospital and post‐acute care? Possible areas of focus:
Use of healthcare information technology
Communication across sites of care
Reducing medication‐related adverse events
Engagement of family caregivers
Patient‐centered strategies to simplify regimens
Models of care Hospitalization marks a time of high risk for older patients. Up to half die during hospitalization or within the year following the hospitalization. There is high risk of nosocomial events, and more than a third experience a decline in health resulting in longer hospitalizations and/or placement in extended‐care facilities.[73, 85, 86] Comprehensive inpatient care for older adults (acute care for elders units, geriatric evaluation and management units, geriatric consultation services) were studied in 2 meta‐analyses, 5 RCTs, and 1 quasiexperimental study and summarized in a systematic review.[87] The studies reported improved quality of care (1 of 1 article), quality of life (3 of 4), functional autonomy (5 of 6), survival (3 of 6), and equal or lower healthcare utilization (7 of 8). For which populations of hospitalized older adults does systematic implementation of geriatric care principles/processes improve patient‐centered outcomes? Potential populations:
Patients of the emergency department, critical care, perioperative, and targeted medical/surgical units
Examples of care principles:
Geriatric assessment, early mobility, medication management, delirium prevention, advanced‐care planning, risk‐factor modification, caregiver engagement
Potential outcomes:
Patient‐centered outcomesa
Cost
Physical function Half of older patients will lose functional capacity during hospitalization.[88] Loss of physical function, particularly of lower extremities, is a risk factor for nursing home placement.[89, 90] Older hospitalized patients spend the majority (up to 80%) of their time lying in bed, even when they are capable of walking independently.[91] Loss of independences with ADL capabilities is associated with longer hospital stays, higher readmission rates, and higher mortality risk.[92] Excessive time in bed during a hospital stay is also associated with falls.[93] Often, hospital nursing protocols and physician orders increase in‐hospital immobility in patients.[91, 94] However, nursing‐driven mobility protocols can improve functional outcomes of older hospitalized patients.[95, 96] What is the comparative effectiveness of interventions that promote in‐hospital mobility, improve and preserve physical function, and reduce falls among older hospitalized patients? Potential interventions:
Intensive physical therapy
Incidental functional training
Restraint reduction
Medication management
Potential outcomes:
Discharge location
Delirium, pressure ulcers, and falls
Surgery An increasing number of persons over age 65 years are undergoing surgical procedures.[97] These persons are at increased risk for developing delirium/cogitative dysfunction,[98] loss of functional status,[99] and exacerbations of chronic illness.[97] Additionally, pain management may be harder to address in this population.[100] Current outcomes may not reflect the clinical needs of elder surgical patients.[101] Tailored drug selection and nursing protocols may prevent delirium.[98] Postoperative cognitive dysfunction may require weeks for resolution. Identifying frail patients preoperatively may lead to more appropriate risk stratification and improved surgical outcomes.[99] Pain management strategies focused on mitigating cognitive impact and other effects may also be beneficial.[100] Development of risk‐adjustment tools specific to older populations, as well as measures of frailty and patient‐centered care, have been proposed.[101] What perioperative strategies can be used to optimize care processes and improve outcomes in older surgical patients? Potential strategies:
Preoperative risk assessment and optimization for frail or multimorbid older patients
Perioperative management protocols for frail or multimorbid older patients
Potential outcomes:
Postoperative patient centered outcomesa
Perioperative cost, healthcare utilization
Training Adults over age 65 years comprise 13.2 % of the US population, but account for >30% of hospital discharges and 50% of hospital days.[86, 102, 103] By 2030, there will only be 1 geriatrician for every 3798 Americans >75 years.[4] Between 1997 and 2006, the odds that a hospitalist would treat a hospitalized Medicare patient rose 29% per year.[3] Train the trainer programs for physicians include the CHAMP, the AGESP, and the PAGE. Education for nurses include the NICHE. Outcomes include improved self‐confidence, attitudes, teaching skills, and geriatric care environment.[104, 105, 106] What is the most effective approach to training hospital‐based providers in geriatric and palliative care competencies? Potential interventions:
Mentored implementation
Train the trainer
Technical support

Table 2 also contains a capsule summary of the scope of the problem addressed by each research priority, a capsule summary of related work in the content area (what is known) not intended as a systematic review, and proposed dimensions or subquestions suggested by the stakeholders at the final prioritization meeting

DISCUSSION

Older hospitalized patients account for an increasing number and proportion of hospitalized patients,[1, 2] and hospitalists increasingly are responsible for inpatient care for this population.[3] The knowledge required for hospitalists to deliver optimal care and improve outcomes has not kept pace with the rapid growth of either hospitalists or hospitalized elders. Through a rigorous prioritization process, we identified 10 areas that deserve the highest priority in directing future research efforts to improve care for the older hospitalized patient. Assessment, prevention, and treatment of geriatric syndromes in the hospital account for almost half of the priority areas. Additional research is needed to improve advanced care planning, develop new care models, and develop training models for future hospitalists competent in geriatric and palliative care competencies.

A decade ago, the American Geriatric Society and the John A. Hartford Foundation embarked upon a research agenda aimed at improving the care of hospitalized elders cared for by specialists (ie, New Frontiers in Geriatrics Research: An Agenda for Surgical and Related Medical Specialties).[9] This effort differed in many important ways from the current priortization process. First, the New Frontiers agenda focused upon specific diseases, whereas the ACOP agenda addresses geriatric syndromes that cut across multiple diseases. Second, the New Frontiers agenda was made by researchers and based upon published literature, whereas the ACOP agenda involved the input of multiple stakeholders. Finally, the New Frontiers prioritized a research agenda across a number of surgical specialties, emergency medicine, and geriatric rehabilitation. Hospital medicine, however, was still early in its development and was not considered a unique specialty. Since that time, hospital medicine has matured into a unique specialty, with increased numbers of hospitalists,[3] increased research in hospital medicine,[17] and a separate recertification pathway for internal medicine licensure.[18] To date, there has not been a similar effort performed to direct geriatric research efforts for hospital medicine.

For researchers working in the field of hospital medicine, this list of topics has several implications. First, as hospitalists are commonly generalists, hospitalist researchers may be particularly well‐suited to study syndromes that cut across specialties. However, this does raise concerns about funding sources, as most National Institutes of Health institutes are disease‐focused. Funders that are not disease‐focused such as PCORI, National Institute on Aging, National Institute of Nursing Research, and Agency for Healthcare Research and Quality, and private foundations (Hartford, Robert Wood Johnson, and Commonwealth) may be more fruitful sources of funding for this work, but funding may be challenging. Nonetheless, the increased focus on patient‐centered work may increase funders' interest in such work. Second, the topics on this list would suggest that interventions will not be pharmacologic, but will focus on nonpharmacologic, behavioral, and social interventions. Similarly, outcomes of interest must expand beyond utilization metrics such as length of stay and mortality, to include functional status and symptom management, and goal‐concordant care. Therefore, research in geriatric acute care will necessarily be multidisciplinary.

Although these 10 high‐priority areas have been selected, this prioritized list is inherently limited by our methodology. First, our survey question was not focused on a disease state, and this wording may have resulted in the list favoring geriatric syndromes rather than common disease processes. Additionally, the resulting questions encompass large research areas and not specific questions about discrete interventions. Our results may also have been skewed by the types of engaged respondents who participated in the consultation, collating, and prioritization phases. In particular, we had a large response from geriatric medicine nurses, whereas some stakeholder groups provided no survey responses. Thus, these respondents were not representative of all possible stakeholders, nor were the survey respondents necessarily representative of each of their organizations. Nonetheless, the participants self‐identified as representative of diverse viewpoints that included patients, caregivers, and advocacy groups, with the majority of stakeholder organizations remaining engaged through the completion of the process. Thus, the general nature of this agenda helps us focus upon larger areas of importance, leaving researchers the flexibility to choose to narrow the focus on a specific research question that may include potential interventions and unique outcomes. Finally, our methodology may have inadvertently limited the number of patient and family caregiver voices in the process given our approach to large advocacy groups, our desire to be inclusive of healthcare professional organizations, and our survey methodology. Other methodologies may have reached more patients and caregivers, yet many healthcare professionals have served as family caregivers to frail elders requiring hospitalization and may have been in an ideal position to answer the survey.

In conclusion, several forces are shaping the future of acute inpatient care. These include the changing demographics of the hospitalized patient population, a rapid increase in the proportion of multimorbid hospitalized older adults, an inpatient workforce (hospitalists, generalists, and subspecialists) with potentially limited geriatrics training, and gaps in evidence‐based guidance to inform diagnostic and therapeutic decision making for acutely ill older patients. Training programs in hospital medicine should be aware of and could benefit from the resulting list of unanswered questions. Our findings also have implications for training to enrich education in geriatrics. Moreover, there is growing recognition that patients and other stakeholders deserve a greater voice in determining the direction of research. In addition to efforts to improve patient‐centeredness of research, these areas have been uniquely identified by stakeholders as important, and therefore are in line with newer priorities of PCORI. This project followed a road map resulting in a patient‐centered research agenda at the intersection of hospital medicine and geriatric medicine.[7] In creating this agenda, we relied heavily on the framework proposed by PCORI. We propose to pursue a dissemination and evaluation strategy for this research agenda as well as additional prioritization steps. We believe the adoption of this methodology will create a knowledge base that is rigorously derived and most relevant to the care of hospitalized older adults and their families. Its application will ultimately result in improved outcomes for hospitalized older adults.

Acknowledgements

The authors acknowledge Claudia Stahl, Society of Hospital Medicine; Cynthia Drake, University of Colorado; and the ACOP stakeholder organizations.

Disclosures: This work was supported by the Association of Specialty Professors/American Society of Internal Medicine and the John A. Hartford Foundation. Dr. Vasilevskis was supported by the National Institute on Aging of the National Institutes of Health under award number K23AG040157 and the Veterans Affairs Clinical Research Center of Excellence, and the Geriatric Research, Education and Clinical Center (GRECC). Dr. Vasilevskis' institution receives grant funding for an aspect of submitted work. Dr. Meltzer is a PCORI Methodology Committee member. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health or the Department of Veterans' Affairs. The authors report no conflicts of interest.

References
  1. Hall MJ, DeFrances CJ, Williams SN, Golosinskiy A, Schwartzman A. National Hospital Discharge Survey: 2007 summary. Natl Health Stat Report. 2010(29):120, 24.
  2. Centers for Medicare 2012. Available at: http://www.cms.gov/Research‐Statistics‐Data‐and‐Systems/Statistics‐Trends‐and‐Reports/Chronic‐Conditions/Downloads/2012Chartbook.pdf. Accessed December 12, 2014.
  3. Kuo YF, Sharma G, Freeman JL, Goodwin JS. Growth in the care of older patients by hospitalists in the United States. N Engl J Med. 2009;360(11):11021112.
  4. Bragg E, Hansen JC. A revelation of numbers: will America's eldercare workforce be ready to care for an aging America? Generations. 2010;34(4):1119.
  5. Patient‐Centered Outcomes Research Institute Methodology Committee. The PCORI methodology report. Available at: http://www.pcori.org/assets/2013/11/PCORI‐Methodology‐Report.pdf. Published November 2013. Accessed December 19, 2013.
  6. The James Lind Alliance. JLA method. Available at: http://www.lindalliance.org/JLA_Method.asp. Accessed December 19, 2013.
  7. Wald HL, Leykum LK, Mattison ML, Vasilevskis EE, Meltzer DO. Road map to a patient‐centered research agenda at the intersection of hospital medicine and geriatric medicine. J Gen Intern Med. 2014;29(6):926931.
  8. Patient‐Centered Outcomes Research Institute. About us. Available at: http://www.pcori.org/about‐us. Accessed February 23, 2015.
  9. Solomon D, LoCicero J, Rosenthal R. New Frontiers of Geriatrics Research: An Agenda for Surgical and Related Medical Specialties. New York, NY: American Geriatrics Society; 2004.
  10. Raveis VH, Gardner DS, Berkman B, Harootyan L. Linking the NIH strategic plan to the research agenda for social workers in health and aging. J Gerontol Soc Work. 2010;53(1):7793.
  11. Lai JM, Karlawish J. Assessing the capacity to make everyday decisions: a guide for clinicians and an agenda for future research. Am J Geriatr Psychiatry. 2007;15(2):101111.
  12. Pillemer K, Breckman R, Sweeney CD, et al. Practitioners' views on elder mistreatment research priorities: recommendations from a Research‐to‐Practice Consensus conference. J Elder Abuse Negl. 2011;23(2):115126.
  13. Goldstein NE, Morrison RS. The intersection between geriatrics and palliative care: a call for a new research agenda. J Am Geriatr Soc. 2005;53(9):15931598.
  14. Cohen HJ. The cancer aging interface: a research agenda. J Clin Oncol. 2007;25(14):19451948.
  15. Clevenger CK, Chu TA, Yang Z, Hepburn KW. Clinical care of persons with dementia in the emergency department: a review of the literature and agenda for research. J Am Geriatr Soc. 2012;60(9):17421748.
  16. Delbecq AL, Ven AH. A group process model for problem identification and program planning. J Appl Behav Sci. 1971;7(4):466492.
  17. Dang Do AN, Munchhof AM, Terry C, Emmett T, Kara A. Research and publication trends in hospital medicine. J Hosp Med. 2014;9(3):148154.
  18. Ireland J. ABFM and ABIM to jointly participate in recognition of focused practice (rfp) in hospital medicine pilot approved by abms. Ann Fam Med. 2010;8(1):87.
  19. Weiss BD, Berman EA, Howe CL, Fleming RB. Medical decision‐making for older adults without family. J Am Geriatr Soc. 2012;60(11):21442150.
  20. Wissow LS, Belote A, Kramer W, Compton‐Phillips A, Kritzler R, Weiner JP. Promoting advance directives among elderly primary care patients. J Gen Intern Med. 2004;19(9):944951.
  21. Silveira MJ, Wiitala W, Piette J. Advance directive completion by elderly Americans: a decade of change. J Am Geriatr Soc. 2014;62(4):706710.
  22. Murray LM, Laditka SB. Care transitions by older adults from nursing homes to hospitals: implications for long‐term care practice, geriatrics education, and research. J Am Med Dir Assoc. 2010;11(4):231238.
  23. Lamberg JL, Person CJ, Kiely DK, Mitchell SL. Decisions to hospitalize nursing home residents dying with advanced dementia. J Am Geriatr Soc. 2005;53(8):13961401.
  24. Hickman SE, Nelson CA, Perrin NA, Moss AH, Hammes BJ, Tolle SW. A comparison of methods to communicate treatment preferences in nursing facilities: traditional practices versus the physician orders for life‐sustaining treatment program. J Am Geriatr Soc. 2010;58(7):12411248.
  25. LaMantia MA, Scheunemann LP, Viera AJ, Busby‐Whitehead J, Hanson LC. Interventions to improve transitional care between nursing homes and hospitals: a systematic review. J Am Geriatr Soc. 2010;58(4):777782.
  26. Zadeh S, Pao M, Wiener L. Opening end‐of‐life discussions: how to introduce Voicing My CHOiCES, an advance care planning guide for adolescents and young adults [published online ahead of print March 13, 2014]. Palliat Support Care. doi: 10.1017/S1478951514000054.
  27. Mor V, Intrator O, Feng Z, Grabowski DC. The revolving door of rehospitalization from skilled nursing facilities. Health Aff (Millwood). 2010;29(1):5764.
  28. Jencks SF, Williams MV, Coleman EA. Rehospitalizations among patients in the Medicare fee‐for‐service program. N Engl J Med. 2009;360(14):14181428.
  29. Morandi A, Bellelli G, Vasilevskis EE, et al. Predictors of rehospitalization among elderly patients admitted to a rehabilitation hospital: the role of polypharmacy, functional status, and length of stay. J Am Med Dir Assoc. 2013;14(10):761767.
  30. Fisher SR, Kuo YF, Sharma G, et al. Mobility after hospital discharge as a marker for 30‐day readmission. J Gerontol A Biol Sci Med Sci. 2013;68(7):805810.
  31. Ashton CM, Del Junco DJ, Souchek J, Wray NP, Mansyur CL. The association between the quality of inpatient care and early readmission: a meta‐analysis of the evidence. Med Care. 1997;35(10):10441059.
  32. Hoyer EH, Needham DM, Atanelov L, Knox B, Friedman M, Brotman DJ. Association of impaired functional status at hospital discharge and subsequent rehospitalization. J Hosp Med. May 2014;9(5):277282.
  33. Lakhan P, Jones M, Wilson A, Courtney M, Hirdes J, Gray LC. A prospective cohort study of geriatric syndromes among older medical patients admitted to acute care hospitals. J Am Geriatr Soc. 2011;59(11):20012008.
  34. Albrecht JS, Gruber‐Baldini AL, Hirshon JM, et al. Hospital discharge instructions: comprehension and compliance among older adults. J Gen Intern Med. 2014;29(11):14911498.
  35. Arora VM, Prochaska ML, Farnan JM, et al. Problems after discharge and understanding of communication with their primary care physicians among hospitalized seniors: a mixed methods study. J Hosp Med. 2010;5(7):385391.
  36. Gandara E, Moniz T, Ungar J, et al. Communication and information deficits in patients discharged to rehabilitation facilities: an evaluation of five acute care hospitals. J Hosp Med. 2009;4(8):E28E33.
  37. King BJ, Gilmore‐Bykovskyi AL, Roiland RA, Polnaszek BE, Bowers BJ, Kind AJ. The consequences of poor communication during transitions from hospital to skilled nursing facility: a qualitative study. J Am Geriatr Soc. 2013;61(7):10951102.
  38. Kripalani S, LeFevre F, Phillips CO, Williams MV, Basaviah P, Baker DW. Deficits in communication and information transfer between hospital‐based and primary care physicians: implications for patient safety and continuity of care. JAMA. 2007;297(8):831841.
  39. Burke RE, Kripalani S, Vasilevskis EE, Schnipper JL. Moving beyond readmission penalties: creating an ideal process to improve transitional care. J Hosp Med. 2013;8(2):102109.
  40. Kind AJ, Jensen L, Barczi S, et al. Low‐cost transitional care with nurse managers making mostly phone contact with patients cut rehospitalization at a VA hospital. Health Aff (Millwood). 2012;31(12):26592668.
  41. Feltner C, Jones CD, Cene CW, et al. Transitional care interventions to prevent readmissions for persons with heart failure: a systematic review and meta‐analysis. Ann Intern Med. 2014;160(11):774784.
  42. Hansen LO, Young RS, Hinami K, Leung A, Williams MV. Interventions to reduce 30‐day rehospitalization: a systematic review. Ann Intern Med. 2011;155(8):520528.
  43. Rennke S, Nguyen OK, Shoeb MH, Magan Y, Wachter RM, Ranji SR. Hospital‐initiated transitional care interventions as a patient safety strategy: a systematic review. Ann Intern Med. 2013;158(5 pt 2):433440.
  44. Vasilevskis EE, Han JH, Hughes CG, Ely EW. Epidemiology and risk factors for delirium across hospital settings. Best Pract Res Clin Anaesthesiol. 2012;26(3):277287.
  45. Inouye SK, Rushing JT, Foreman MD, Palmer RM, Pompei P. Does delirium contribute to poor hospital outcomes? A three‐site epidemiologic study. J Gen Intern Med. 1998;13(4):234242.
  46. Ouimet S, Kavanagh BP, Gottfried SB, Skrobik Y. Incidence, risk factors and consequences of ICU delirium. Intensive Care Med. 2007;33(1):6673.
  47. Ely EW, Inouye SK, Bernard GR, et al. Delirium in mechanically ventilated patients: validity and reliability of the confusion assessment method for the intensive care unit (CAM‐ICU). JAMA. 2001;286(21):27032710.
  48. Boustani M, Baker MS, Campbell N, et al. Impact and recognition of cognitive impairment among hospitalized elders. J Hosp Med. 2010;5(2):6975.
  49. Ely EW, Gautam S, Margolin R, et al. The impact of delirium in the intensive care unit on hospital length of stay. Intensive Care Med. 2001;27(12):18921900.
  50. Pandharipande PP, Girard TD, Ely EW. Long‐term cognitive impairment after critical illness. N Engl J Med. 2014;370(2):185186.
  51. Brummel NE, Jackson JC, Pandharipande PP, et al. Delirium in the ICU and subsequent long‐term disability among survivors of mechanical ventilation. Crit Care Med. 2014;42(2):369377.
  52. Witlox J, Eurelings LS, Jonghe JF, Kalisvaart KJ, Eikelenboom P, Gool WA. Delirium in elderly patients and the risk of postdischarge mortality, institutionalization, and dementia: a meta‐analysis. JAMA. 2010;304(4):443451.
  53. Ely EW, Shintani A, Truman B, et al. Delirium as a predictor of mortality in mechanically ventilated patients in the intensive care unit. JAMA. 2004;291(14):17531762.
  54. Pisani MA, Kong SY, Kasl SV, Murphy TE, Araujo KL, Ness PH. Days of delirium are associated with 1‐year mortality in an older intensive care unit population. Am J Respir Crit Care Med. 2009;180(11):10921097.
  55. Reston JT, Schoelles KM. In‐facility delirium prevention programs as a patient safety strategy: a systematic review. Ann Intern Med. 2013;158(5 pt 2):375380.
  56. Riker RR, Shehabi Y, Bokesch PM, et al. Dexmedetomidine vs midazolam for sedation of critically ill patients: a randomized trial. JAMA. 2009;301(5):489499.
  57. Pandharipande PP, Pun BT, Herr DL, et al. Effect of sedation with dexmedetomidine vs lorazepam on acute brain dysfunction in mechanically ventilated patients: the MENDS randomized controlled trial. JAMA. 2007;298(22):26442653.
  58. Skrobik Y, Ahern S, Leblanc M, Marquis F, Awissi DK, Kavanagh BP. Protocolized intensive care unit management of analgesia, sedation, and delirium improves analgesia and subsyndromal delirium rates. Anesth Analg. 2010;111(2):451463.
  59. Mukadam N, Sampson EL. A systematic review of the prevalence, associations and outcomes of dementia in older general hospital inpatients. Int Psychogeriatr. 2011;23(3):344355.
  60. Torisson G, Minthon L, Stavenow L, Londos E. Cognitive impairment is undetected in medical inpatients: a study of mortality and recognition amongst healthcare professionals. BMC Geriatr. 2012;12:47.
  61. George J, Long S, Vincent C. How can we keep patients with dementia safe in our acute hospitals? A review of challenges and solutions. J R Soc Med. 2013;106(9):355361.
  62. Jackson TA, Naqvi SH, Sheehan B. Screening for dementia in general hospital inpatients: a systematic review and meta‐analysis of available instruments. Age Ageing. 2013;42(6):689695.
  63. Morandi A, McCurley J, Vasilevskis EE, et al. Tools to detect delirium superimposed on dementia: a systematic review. J Am Geriatr Soc. 2012;60(11):20052013.
  64. Moniz Cook ED, Swift K, James I, Malouf R, Vugt M, Verhey F. Functional analysis‐based interventions for challenging behaviour in dementia. Cochrane Database Syst Rev. 2012;2:CD006929.
  65. Woods B, Aguirre E, Spector AE, Orrell M. Cognitive stimulation to improve cognitive functioning in people with dementia. Cochrane Database Syst Rev. 2012;2:CD005562.
  66. McCusker J, Cole M, Dufouil C, et al. The prevalence and correlates of major and minor depression in older medical inpatients. J Am Geriatr Soc. 2005;53(8):13441353.
  67. Koenig HG, Meador KG, Shelp F, Goli V, Cohen HJ, Blazer DG. Major depressive disorder in hospitalized medically ill patients: an examination of young and elderly male veterans. J Am Geriatr Soc. 1991;39(9):881890.
  68. Jackson JC, Pandharipande PP, Girard TD, et al. Depression, post‐traumatic stress disorder, and functional disability in survivors of critical illness in the BRAIN‐ICU study: a longitudinal cohort study. Lancet Respir Med. 2014;2(5):369379.
  69. Pierluissi E, Mehta KM, Kirby KA, et al. Depressive symptoms after hospitalization in older adults: function and mortality outcomes. J Am Geriatr Soc. 2012;60(12):22542262.
  70. Han L, McCusker J, Cole M, Abrahamowicz M, Capek R. 12‐month cognitive outcomes of major and minor depression in older medical patients. Am J Geriatr Psychiatry. 2008;16(9):742751.
  71. Kartha A, Anthony D, Manasseh CS, et al. Depression is a risk factor for rehospitalization in medical inpatients. Prim Care Companion J Clin Psychiatry. 2007;9(4):256262.
  72. Cancino RS, Culpepper L, Sadikova E, Martin J, Jack BW, Mitchell SE. Dose‐response relationship between depressive symptoms and hospital readmission. J Hosp Med. 2014;9(6):358364.
  73. Covinsky KE, Kahana E, Chin MH, Palmer RM, Fortinsky RH, Landefeld CS. Depressive symptoms and 3‐year mortality in older hospitalized medical patients. Ann Intern Med. 1999;130(7):563569.
  74. Sheline YI, Pieper CF, Barch DM, et al. Support for the vascular depression hypothesis in late‐life depression: results of a 2‐site, prospective, antidepressant treatment trial. Arch Gen Psychiatry. 2010;67(3):277285.
  75. Alexopoulos GS, Kiosses DN, Heo M, Murphy CF, Shanmugham B, Gunning‐Dixon F. Executive dysfunction and the course of geriatric depression. Biol Psychiatry. 2005;58(3):204210.
  76. Cepoiu M, McCusker J, Cole MG, Sewitch M, Ciampi A. Recognition of depression in older medical inpatients. J Gen Intern Med. 2007;22(5):559564.
  77. Huffman JC, Mastromauro CA, Sowden GL, Wittmann C, Rodman R, Januzzi JL. A collaborative care depression management program for cardiac inpatients: depression characteristics and in‐hospital outcomes. Psychosomatics. 2011;52(1):2633.
  78. Huffman JC, Mastromauro CA, Sowden G, Fricchione GL, Healy BC, Januzzi JL. Impact of a depression care management program for hospitalized cardiac patients. Circ Cardiovasc Qual Outcomes. 2011;4(2):198205.
  79. Rothberg MB, Pekow PS, Liu F, et al. Potentially inappropriate medication use in hospitalized elders. J Hosp Med. 2008;3(2):91102.
  80. Lewis PJ, Dornan T, Taylor D, Tully MP, Wass V, Ashcroft DM. Prevalence, incidence and nature of prescribing errors in hospital inpatients: a systematic review. Drug Saf. 2009;32(5):379389.
  81. Pham CB, Dickman RL. Minimizing adverse drug events in older patients. Am Fam Physician. 2007;76(12):18371844.
  82. Gallagher P, Ryan C, Byrne S, Kennedy J, O'Mahony D. STOPP (Screening Tool of Older Person's Prescriptions) and START (Screening Tool to Alert doctors to Right Treatment). Consensus validation. Int J Clin Pharmacol Ther. 2008;46(2):7283.
  83. American Geriatrics Society 2012 Beers Criteria Update Expert Panel. American Geriatrics Society updated Beers Criteria for potentially inappropriate medication use in older adults. J Am Geriatr Soc. 2012;60(4):616631.
  84. Mattison ML, Afonso KA, Ngo LH, Mukamal KJ. Preventing potentially inappropriate medication use in hospitalized older patients with a computerized provider order entry warning system. Arch Intern Med. 2010;170(15):13311336.
  85. Creditor MC. Hazards of Hospitalization of the Elderly. Ann Intern Med. 1993;118(3):219223.
  86. Landefeld CS. Improving health care for older persons. Ann Intern Med. 2003;139(5 part 2):421424.
  87. Boult C, Green AF, Boult LB, Pacala JT, Snyder C, Leff B. Successful models of comprehensive care for older adults with chronic conditions: evidence for the Institute of Medicine's "retooling for an aging America" report. J Am Geriatr Soc. 2009;57(12):23282337.
  88. Boyd CM, Landefeld CS, Counsell SR, et al. Recovery of activities of daily living in older adults after hospitalization for acute medical illness. J Am Geriatr Soc. 2008;56(12):21712179.
  89. Wolinsky FD, Callahan CM, Fitzgerald JF, Johnson RJ. Changes in functional status and the risks of subsequent nursing home placement and death. J Gerontol. 1993;48(3):S94S101.
  90. Smith GE, Kokmen E, O'Brien PC. Risk factors for nursing home placement in a population‐based dementia cohort. J Am Geriatr Soc. 2000;48(5):519525.
  91. Brown CJ, Redden DT, Flood KL, Allman RM. The underrecognized epidemic of low mobility during hospitalization of older adults. J Am Geriatr Soc. 2009;57(9):16601665.
  92. Hoogerduijn JG, Schuurmans MJ, Duijnstee MS, Rooij SE, Grypdonck MF. A systematic review of predictors and screening instruments to identify older hospitalized patients at risk for functional decline. J Clin Nurs. 2007;16(1):4657.
  93. Mahoney JE. Immobility and falls. Clin Geriatr Med. 1998;14(4):699726.
  94. Brown CJ, Friedkin RJ, Inouye SK. Prevalence and outcomes of low mobility in hospitalized older patients. J Am Geriatr Soc. 2004;52(8):12631270.
  95. Padula CA, Hughes C, Baumhover L. Impact of a nurse‐driven mobility protocol on functional decline in hospitalized older adults. J Nurs Care Qual. 2009;24(4):325331.
  96. Pashikanti L, Ah D. Impact of early mobilization protocol on the medical‐surgical inpatient population: an integrated review of literature. Clin Nurse Spec. 2012;26(2):8794.
  97. Etzioni DA, Liu JH, Maggard MA, Ko CY. The aging population and its impact on the surgery workforce. Ann Surg. 2003;238(2):170177.
  98. Palmer RM. Perioperative care of the elderly patient: an update. Cleve Clin J Med. 2009;76(suppl 4):S16S21.
  99. Partridge JS, Harari D, Dhesi JK. Frailty in the older surgical patient: a review. Age Ageing. 2012;41(2):142147.
  100. Schofield PA. The assessment and management of peri‐operative pain in older adults. Anaesthesia. 2014;69(suppl 1):5460.
  101. Peden CJ, Grocott MP. National Research Strategies: what outcomes are important in peri‐operative elderly care? Anaesthesia. 2014;69(suppl 1):6169.
  102. DeFrances CJ, Hall MJ. 2002 National Hospital Discharge Survey. Adv Data. 2004;342:130.
  103. Merrill CT, Elixhauser A. Hospitalization in the United States, 2002. Rockville, MD: Agency for Healthcare Research and Quality; 2005.
  104. Podrazik PM, Levine S, Smith S, et al. The Curriculum for the Hospitalized Aging Medical Patient program: a collaborative faculty development program for hospitalists, general internists, and geriatricians. J Hosp Med. 2008;3(5):384393.
  105. Mattison ML, Li JMW. Advancement of geriatrics education. J Hosp Med. 2011;6(6):370.
  106. Mazotti L, Moylan A, Murphy E, Harper GM, Johnston CB, Hauer KE. Advancing geriatrics education: an efficient faculty development program for academic hospitalists increases geriatric teaching. J Hosp Med. 2010;5(9):541546.
References
  1. Hall MJ, DeFrances CJ, Williams SN, Golosinskiy A, Schwartzman A. National Hospital Discharge Survey: 2007 summary. Natl Health Stat Report. 2010(29):120, 24.
  2. Centers for Medicare 2012. Available at: http://www.cms.gov/Research‐Statistics‐Data‐and‐Systems/Statistics‐Trends‐and‐Reports/Chronic‐Conditions/Downloads/2012Chartbook.pdf. Accessed December 12, 2014.
  3. Kuo YF, Sharma G, Freeman JL, Goodwin JS. Growth in the care of older patients by hospitalists in the United States. N Engl J Med. 2009;360(11):11021112.
  4. Bragg E, Hansen JC. A revelation of numbers: will America's eldercare workforce be ready to care for an aging America? Generations. 2010;34(4):1119.
  5. Patient‐Centered Outcomes Research Institute Methodology Committee. The PCORI methodology report. Available at: http://www.pcori.org/assets/2013/11/PCORI‐Methodology‐Report.pdf. Published November 2013. Accessed December 19, 2013.
  6. The James Lind Alliance. JLA method. Available at: http://www.lindalliance.org/JLA_Method.asp. Accessed December 19, 2013.
  7. Wald HL, Leykum LK, Mattison ML, Vasilevskis EE, Meltzer DO. Road map to a patient‐centered research agenda at the intersection of hospital medicine and geriatric medicine. J Gen Intern Med. 2014;29(6):926931.
  8. Patient‐Centered Outcomes Research Institute. About us. Available at: http://www.pcori.org/about‐us. Accessed February 23, 2015.
  9. Solomon D, LoCicero J, Rosenthal R. New Frontiers of Geriatrics Research: An Agenda for Surgical and Related Medical Specialties. New York, NY: American Geriatrics Society; 2004.
  10. Raveis VH, Gardner DS, Berkman B, Harootyan L. Linking the NIH strategic plan to the research agenda for social workers in health and aging. J Gerontol Soc Work. 2010;53(1):7793.
  11. Lai JM, Karlawish J. Assessing the capacity to make everyday decisions: a guide for clinicians and an agenda for future research. Am J Geriatr Psychiatry. 2007;15(2):101111.
  12. Pillemer K, Breckman R, Sweeney CD, et al. Practitioners' views on elder mistreatment research priorities: recommendations from a Research‐to‐Practice Consensus conference. J Elder Abuse Negl. 2011;23(2):115126.
  13. Goldstein NE, Morrison RS. The intersection between geriatrics and palliative care: a call for a new research agenda. J Am Geriatr Soc. 2005;53(9):15931598.
  14. Cohen HJ. The cancer aging interface: a research agenda. J Clin Oncol. 2007;25(14):19451948.
  15. Clevenger CK, Chu TA, Yang Z, Hepburn KW. Clinical care of persons with dementia in the emergency department: a review of the literature and agenda for research. J Am Geriatr Soc. 2012;60(9):17421748.
  16. Delbecq AL, Ven AH. A group process model for problem identification and program planning. J Appl Behav Sci. 1971;7(4):466492.
  17. Dang Do AN, Munchhof AM, Terry C, Emmett T, Kara A. Research and publication trends in hospital medicine. J Hosp Med. 2014;9(3):148154.
  18. Ireland J. ABFM and ABIM to jointly participate in recognition of focused practice (rfp) in hospital medicine pilot approved by abms. Ann Fam Med. 2010;8(1):87.
  19. Weiss BD, Berman EA, Howe CL, Fleming RB. Medical decision‐making for older adults without family. J Am Geriatr Soc. 2012;60(11):21442150.
  20. Wissow LS, Belote A, Kramer W, Compton‐Phillips A, Kritzler R, Weiner JP. Promoting advance directives among elderly primary care patients. J Gen Intern Med. 2004;19(9):944951.
  21. Silveira MJ, Wiitala W, Piette J. Advance directive completion by elderly Americans: a decade of change. J Am Geriatr Soc. 2014;62(4):706710.
  22. Murray LM, Laditka SB. Care transitions by older adults from nursing homes to hospitals: implications for long‐term care practice, geriatrics education, and research. J Am Med Dir Assoc. 2010;11(4):231238.
  23. Lamberg JL, Person CJ, Kiely DK, Mitchell SL. Decisions to hospitalize nursing home residents dying with advanced dementia. J Am Geriatr Soc. 2005;53(8):13961401.
  24. Hickman SE, Nelson CA, Perrin NA, Moss AH, Hammes BJ, Tolle SW. A comparison of methods to communicate treatment preferences in nursing facilities: traditional practices versus the physician orders for life‐sustaining treatment program. J Am Geriatr Soc. 2010;58(7):12411248.
  25. LaMantia MA, Scheunemann LP, Viera AJ, Busby‐Whitehead J, Hanson LC. Interventions to improve transitional care between nursing homes and hospitals: a systematic review. J Am Geriatr Soc. 2010;58(4):777782.
  26. Zadeh S, Pao M, Wiener L. Opening end‐of‐life discussions: how to introduce Voicing My CHOiCES, an advance care planning guide for adolescents and young adults [published online ahead of print March 13, 2014]. Palliat Support Care. doi: 10.1017/S1478951514000054.
  27. Mor V, Intrator O, Feng Z, Grabowski DC. The revolving door of rehospitalization from skilled nursing facilities. Health Aff (Millwood). 2010;29(1):5764.
  28. Jencks SF, Williams MV, Coleman EA. Rehospitalizations among patients in the Medicare fee‐for‐service program. N Engl J Med. 2009;360(14):14181428.
  29. Morandi A, Bellelli G, Vasilevskis EE, et al. Predictors of rehospitalization among elderly patients admitted to a rehabilitation hospital: the role of polypharmacy, functional status, and length of stay. J Am Med Dir Assoc. 2013;14(10):761767.
  30. Fisher SR, Kuo YF, Sharma G, et al. Mobility after hospital discharge as a marker for 30‐day readmission. J Gerontol A Biol Sci Med Sci. 2013;68(7):805810.
  31. Ashton CM, Del Junco DJ, Souchek J, Wray NP, Mansyur CL. The association between the quality of inpatient care and early readmission: a meta‐analysis of the evidence. Med Care. 1997;35(10):10441059.
  32. Hoyer EH, Needham DM, Atanelov L, Knox B, Friedman M, Brotman DJ. Association of impaired functional status at hospital discharge and subsequent rehospitalization. J Hosp Med. May 2014;9(5):277282.
  33. Lakhan P, Jones M, Wilson A, Courtney M, Hirdes J, Gray LC. A prospective cohort study of geriatric syndromes among older medical patients admitted to acute care hospitals. J Am Geriatr Soc. 2011;59(11):20012008.
  34. Albrecht JS, Gruber‐Baldini AL, Hirshon JM, et al. Hospital discharge instructions: comprehension and compliance among older adults. J Gen Intern Med. 2014;29(11):14911498.
  35. Arora VM, Prochaska ML, Farnan JM, et al. Problems after discharge and understanding of communication with their primary care physicians among hospitalized seniors: a mixed methods study. J Hosp Med. 2010;5(7):385391.
  36. Gandara E, Moniz T, Ungar J, et al. Communication and information deficits in patients discharged to rehabilitation facilities: an evaluation of five acute care hospitals. J Hosp Med. 2009;4(8):E28E33.
  37. King BJ, Gilmore‐Bykovskyi AL, Roiland RA, Polnaszek BE, Bowers BJ, Kind AJ. The consequences of poor communication during transitions from hospital to skilled nursing facility: a qualitative study. J Am Geriatr Soc. 2013;61(7):10951102.
  38. Kripalani S, LeFevre F, Phillips CO, Williams MV, Basaviah P, Baker DW. Deficits in communication and information transfer between hospital‐based and primary care physicians: implications for patient safety and continuity of care. JAMA. 2007;297(8):831841.
  39. Burke RE, Kripalani S, Vasilevskis EE, Schnipper JL. Moving beyond readmission penalties: creating an ideal process to improve transitional care. J Hosp Med. 2013;8(2):102109.
  40. Kind AJ, Jensen L, Barczi S, et al. Low‐cost transitional care with nurse managers making mostly phone contact with patients cut rehospitalization at a VA hospital. Health Aff (Millwood). 2012;31(12):26592668.
  41. Feltner C, Jones CD, Cene CW, et al. Transitional care interventions to prevent readmissions for persons with heart failure: a systematic review and meta‐analysis. Ann Intern Med. 2014;160(11):774784.
  42. Hansen LO, Young RS, Hinami K, Leung A, Williams MV. Interventions to reduce 30‐day rehospitalization: a systematic review. Ann Intern Med. 2011;155(8):520528.
  43. Rennke S, Nguyen OK, Shoeb MH, Magan Y, Wachter RM, Ranji SR. Hospital‐initiated transitional care interventions as a patient safety strategy: a systematic review. Ann Intern Med. 2013;158(5 pt 2):433440.
  44. Vasilevskis EE, Han JH, Hughes CG, Ely EW. Epidemiology and risk factors for delirium across hospital settings. Best Pract Res Clin Anaesthesiol. 2012;26(3):277287.
  45. Inouye SK, Rushing JT, Foreman MD, Palmer RM, Pompei P. Does delirium contribute to poor hospital outcomes? A three‐site epidemiologic study. J Gen Intern Med. 1998;13(4):234242.
  46. Ouimet S, Kavanagh BP, Gottfried SB, Skrobik Y. Incidence, risk factors and consequences of ICU delirium. Intensive Care Med. 2007;33(1):6673.
  47. Ely EW, Inouye SK, Bernard GR, et al. Delirium in mechanically ventilated patients: validity and reliability of the confusion assessment method for the intensive care unit (CAM‐ICU). JAMA. 2001;286(21):27032710.
  48. Boustani M, Baker MS, Campbell N, et al. Impact and recognition of cognitive impairment among hospitalized elders. J Hosp Med. 2010;5(2):6975.
  49. Ely EW, Gautam S, Margolin R, et al. The impact of delirium in the intensive care unit on hospital length of stay. Intensive Care Med. 2001;27(12):18921900.
  50. Pandharipande PP, Girard TD, Ely EW. Long‐term cognitive impairment after critical illness. N Engl J Med. 2014;370(2):185186.
  51. Brummel NE, Jackson JC, Pandharipande PP, et al. Delirium in the ICU and subsequent long‐term disability among survivors of mechanical ventilation. Crit Care Med. 2014;42(2):369377.
  52. Witlox J, Eurelings LS, Jonghe JF, Kalisvaart KJ, Eikelenboom P, Gool WA. Delirium in elderly patients and the risk of postdischarge mortality, institutionalization, and dementia: a meta‐analysis. JAMA. 2010;304(4):443451.
  53. Ely EW, Shintani A, Truman B, et al. Delirium as a predictor of mortality in mechanically ventilated patients in the intensive care unit. JAMA. 2004;291(14):17531762.
  54. Pisani MA, Kong SY, Kasl SV, Murphy TE, Araujo KL, Ness PH. Days of delirium are associated with 1‐year mortality in an older intensive care unit population. Am J Respir Crit Care Med. 2009;180(11):10921097.
  55. Reston JT, Schoelles KM. In‐facility delirium prevention programs as a patient safety strategy: a systematic review. Ann Intern Med. 2013;158(5 pt 2):375380.
  56. Riker RR, Shehabi Y, Bokesch PM, et al. Dexmedetomidine vs midazolam for sedation of critically ill patients: a randomized trial. JAMA. 2009;301(5):489499.
  57. Pandharipande PP, Pun BT, Herr DL, et al. Effect of sedation with dexmedetomidine vs lorazepam on acute brain dysfunction in mechanically ventilated patients: the MENDS randomized controlled trial. JAMA. 2007;298(22):26442653.
  58. Skrobik Y, Ahern S, Leblanc M, Marquis F, Awissi DK, Kavanagh BP. Protocolized intensive care unit management of analgesia, sedation, and delirium improves analgesia and subsyndromal delirium rates. Anesth Analg. 2010;111(2):451463.
  59. Mukadam N, Sampson EL. A systematic review of the prevalence, associations and outcomes of dementia in older general hospital inpatients. Int Psychogeriatr. 2011;23(3):344355.
  60. Torisson G, Minthon L, Stavenow L, Londos E. Cognitive impairment is undetected in medical inpatients: a study of mortality and recognition amongst healthcare professionals. BMC Geriatr. 2012;12:47.
  61. George J, Long S, Vincent C. How can we keep patients with dementia safe in our acute hospitals? A review of challenges and solutions. J R Soc Med. 2013;106(9):355361.
  62. Jackson TA, Naqvi SH, Sheehan B. Screening for dementia in general hospital inpatients: a systematic review and meta‐analysis of available instruments. Age Ageing. 2013;42(6):689695.
  63. Morandi A, McCurley J, Vasilevskis EE, et al. Tools to detect delirium superimposed on dementia: a systematic review. J Am Geriatr Soc. 2012;60(11):20052013.
  64. Moniz Cook ED, Swift K, James I, Malouf R, Vugt M, Verhey F. Functional analysis‐based interventions for challenging behaviour in dementia. Cochrane Database Syst Rev. 2012;2:CD006929.
  65. Woods B, Aguirre E, Spector AE, Orrell M. Cognitive stimulation to improve cognitive functioning in people with dementia. Cochrane Database Syst Rev. 2012;2:CD005562.
  66. McCusker J, Cole M, Dufouil C, et al. The prevalence and correlates of major and minor depression in older medical inpatients. J Am Geriatr Soc. 2005;53(8):13441353.
  67. Koenig HG, Meador KG, Shelp F, Goli V, Cohen HJ, Blazer DG. Major depressive disorder in hospitalized medically ill patients: an examination of young and elderly male veterans. J Am Geriatr Soc. 1991;39(9):881890.
  68. Jackson JC, Pandharipande PP, Girard TD, et al. Depression, post‐traumatic stress disorder, and functional disability in survivors of critical illness in the BRAIN‐ICU study: a longitudinal cohort study. Lancet Respir Med. 2014;2(5):369379.
  69. Pierluissi E, Mehta KM, Kirby KA, et al. Depressive symptoms after hospitalization in older adults: function and mortality outcomes. J Am Geriatr Soc. 2012;60(12):22542262.
  70. Han L, McCusker J, Cole M, Abrahamowicz M, Capek R. 12‐month cognitive outcomes of major and minor depression in older medical patients. Am J Geriatr Psychiatry. 2008;16(9):742751.
  71. Kartha A, Anthony D, Manasseh CS, et al. Depression is a risk factor for rehospitalization in medical inpatients. Prim Care Companion J Clin Psychiatry. 2007;9(4):256262.
  72. Cancino RS, Culpepper L, Sadikova E, Martin J, Jack BW, Mitchell SE. Dose‐response relationship between depressive symptoms and hospital readmission. J Hosp Med. 2014;9(6):358364.
  73. Covinsky KE, Kahana E, Chin MH, Palmer RM, Fortinsky RH, Landefeld CS. Depressive symptoms and 3‐year mortality in older hospitalized medical patients. Ann Intern Med. 1999;130(7):563569.
  74. Sheline YI, Pieper CF, Barch DM, et al. Support for the vascular depression hypothesis in late‐life depression: results of a 2‐site, prospective, antidepressant treatment trial. Arch Gen Psychiatry. 2010;67(3):277285.
  75. Alexopoulos GS, Kiosses DN, Heo M, Murphy CF, Shanmugham B, Gunning‐Dixon F. Executive dysfunction and the course of geriatric depression. Biol Psychiatry. 2005;58(3):204210.
  76. Cepoiu M, McCusker J, Cole MG, Sewitch M, Ciampi A. Recognition of depression in older medical inpatients. J Gen Intern Med. 2007;22(5):559564.
  77. Huffman JC, Mastromauro CA, Sowden GL, Wittmann C, Rodman R, Januzzi JL. A collaborative care depression management program for cardiac inpatients: depression characteristics and in‐hospital outcomes. Psychosomatics. 2011;52(1):2633.
  78. Huffman JC, Mastromauro CA, Sowden G, Fricchione GL, Healy BC, Januzzi JL. Impact of a depression care management program for hospitalized cardiac patients. Circ Cardiovasc Qual Outcomes. 2011;4(2):198205.
  79. Rothberg MB, Pekow PS, Liu F, et al. Potentially inappropriate medication use in hospitalized elders. J Hosp Med. 2008;3(2):91102.
  80. Lewis PJ, Dornan T, Taylor D, Tully MP, Wass V, Ashcroft DM. Prevalence, incidence and nature of prescribing errors in hospital inpatients: a systematic review. Drug Saf. 2009;32(5):379389.
  81. Pham CB, Dickman RL. Minimizing adverse drug events in older patients. Am Fam Physician. 2007;76(12):18371844.
  82. Gallagher P, Ryan C, Byrne S, Kennedy J, O'Mahony D. STOPP (Screening Tool of Older Person's Prescriptions) and START (Screening Tool to Alert doctors to Right Treatment). Consensus validation. Int J Clin Pharmacol Ther. 2008;46(2):7283.
  83. American Geriatrics Society 2012 Beers Criteria Update Expert Panel. American Geriatrics Society updated Beers Criteria for potentially inappropriate medication use in older adults. J Am Geriatr Soc. 2012;60(4):616631.
  84. Mattison ML, Afonso KA, Ngo LH, Mukamal KJ. Preventing potentially inappropriate medication use in hospitalized older patients with a computerized provider order entry warning system. Arch Intern Med. 2010;170(15):13311336.
  85. Creditor MC. Hazards of Hospitalization of the Elderly. Ann Intern Med. 1993;118(3):219223.
  86. Landefeld CS. Improving health care for older persons. Ann Intern Med. 2003;139(5 part 2):421424.
  87. Boult C, Green AF, Boult LB, Pacala JT, Snyder C, Leff B. Successful models of comprehensive care for older adults with chronic conditions: evidence for the Institute of Medicine's "retooling for an aging America" report. J Am Geriatr Soc. 2009;57(12):23282337.
  88. Boyd CM, Landefeld CS, Counsell SR, et al. Recovery of activities of daily living in older adults after hospitalization for acute medical illness. J Am Geriatr Soc. 2008;56(12):21712179.
  89. Wolinsky FD, Callahan CM, Fitzgerald JF, Johnson RJ. Changes in functional status and the risks of subsequent nursing home placement and death. J Gerontol. 1993;48(3):S94S101.
  90. Smith GE, Kokmen E, O'Brien PC. Risk factors for nursing home placement in a population‐based dementia cohort. J Am Geriatr Soc. 2000;48(5):519525.
  91. Brown CJ, Redden DT, Flood KL, Allman RM. The underrecognized epidemic of low mobility during hospitalization of older adults. J Am Geriatr Soc. 2009;57(9):16601665.
  92. Hoogerduijn JG, Schuurmans MJ, Duijnstee MS, Rooij SE, Grypdonck MF. A systematic review of predictors and screening instruments to identify older hospitalized patients at risk for functional decline. J Clin Nurs. 2007;16(1):4657.
  93. Mahoney JE. Immobility and falls. Clin Geriatr Med. 1998;14(4):699726.
  94. Brown CJ, Friedkin RJ, Inouye SK. Prevalence and outcomes of low mobility in hospitalized older patients. J Am Geriatr Soc. 2004;52(8):12631270.
  95. Padula CA, Hughes C, Baumhover L. Impact of a nurse‐driven mobility protocol on functional decline in hospitalized older adults. J Nurs Care Qual. 2009;24(4):325331.
  96. Pashikanti L, Ah D. Impact of early mobilization protocol on the medical‐surgical inpatient population: an integrated review of literature. Clin Nurse Spec. 2012;26(2):8794.
  97. Etzioni DA, Liu JH, Maggard MA, Ko CY. The aging population and its impact on the surgery workforce. Ann Surg. 2003;238(2):170177.
  98. Palmer RM. Perioperative care of the elderly patient: an update. Cleve Clin J Med. 2009;76(suppl 4):S16S21.
  99. Partridge JS, Harari D, Dhesi JK. Frailty in the older surgical patient: a review. Age Ageing. 2012;41(2):142147.
  100. Schofield PA. The assessment and management of peri‐operative pain in older adults. Anaesthesia. 2014;69(suppl 1):5460.
  101. Peden CJ, Grocott MP. National Research Strategies: what outcomes are important in peri‐operative elderly care? Anaesthesia. 2014;69(suppl 1):6169.
  102. DeFrances CJ, Hall MJ. 2002 National Hospital Discharge Survey. Adv Data. 2004;342:130.
  103. Merrill CT, Elixhauser A. Hospitalization in the United States, 2002. Rockville, MD: Agency for Healthcare Research and Quality; 2005.
  104. Podrazik PM, Levine S, Smith S, et al. The Curriculum for the Hospitalized Aging Medical Patient program: a collaborative faculty development program for hospitalists, general internists, and geriatricians. J Hosp Med. 2008;3(5):384393.
  105. Mattison ML, Li JMW. Advancement of geriatrics education. J Hosp Med. 2011;6(6):370.
  106. Mazotti L, Moylan A, Murphy E, Harper GM, Johnston CB, Hauer KE. Advancing geriatrics education: an efficient faculty development program for academic hospitalists increases geriatric teaching. J Hosp Med. 2010;5(9):541546.
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Head CT for the Inpatient With Delirium

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Diagnostic yield of head computed tomography for the hospitalized medical patient with delirium

Delirium is a common and costly problem in hospitalized medical patients. It is present on admission in 10% to 31% of cases and develops in up to 56% of patients during hospitalization.[1, 2] Prompt identification and treatment of the cause of delirium is important, because delirium is associated with increased morbidity and mortality, long‐term cognitive impairment, higher cost of care, increased length of stay, and more frequent discharge to an extended care facility.[3, 4, 5, 6]

Delirium can be caused or worsened by a variety of factors including adverse drug events, metabolic abnormalities, infections, immobilization, the use of tethers (eg, physical restraints, bladder catheters, telemetry), and disruption of sleepwake cycle.[7] An appropriate history, medication review, physical examination, and tailored laboratory evaluation is sufficient workup in the majority of cases.[8] However, neurologic processes, such as intracranial mass, intracranial hemorrhage, or stroke, can also present as delirium and require head imaging for diagnosis.

Because head imaging is a costly limited resource, a number of studies have aimed to determine which patients with delirium require this evaluation. The majority of research has focused on head computed tomography (CT) in patients presenting for evaluation to the emergency department (ED). In ED patients presenting with delirium, acute confusion, or altered mental status, head imaging identifies acute intracranial pathologic findings in 14% to 39% of cases.[9, 10, 11, 12, 13, 14] Only 2 studies have evaluated patients with delirium who have already been admitted to the hospital. One study involved patients admitted to a neurology unit with acute confusion and found that the yield of head imaging (head CT and magnetic resonance imaging) was 14% for acute intracranial pathology.[15] Another study reviewed patients admitted to an acute delirium unit and found a similar rate of positive findings on head CT (14.5%).[16] Neither study specified whether the head imaging occurred during initial presentation or later in the hospitalization.

Factors that increase the likelihood that delirium is caused by acute intracranial pathology include acute neurologic deficit, recent history of fall or head trauma, and significantly impaired consciousness.[9, 10, 11, 12, 13, 14, 15, 16, 17] Based on these findings, current guidelines and expert clinical statements recommend head imaging for patients with acute neurologic deficit, recent head trauma, or recent fall.[18, 19, 20]

Expert clinical statements also recommend imaging in cases where the cause is unidentified after appropriate medical testing or where delirium continues despite treatment.[8, 21] Yet the utility of head CT performed for nonresolving delirium or delirium that develops during hospitalization in the absence of recent fall, head trauma, or new neurologic deficits is not known. Our study aimed to determine the diagnostic yield of performing a head CT in this patient population. We hypothesized that the diagnostic yield of head CT in this population would be low.

METHODS

Study Design

We conducted a retrospective medical record review of hospitalized general medicine patients with head CT imaging performed for the evaluation of delirium. The study was reviewed by the internal review board and determined to be exempt.

Setting and Eligibility Criteria

The study was conducted at a large academic medical center in Boston, Massachusetts. All patients admitted to general medicine, nephrology, hepatology, cardiology, or oncology services with head CT studies performed from January 1, 2010 through November 30, 2012 were included in this retrospective, observational cohort study. Data were extracted using a defined instrument developed for this study with outcome measures predefined. Head CT imaging acquired for patients in the intensive care unit were not included in the review. The medical records were evaluated to determine indication. To be included in the study, the indication for the scan had to be delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness. In addition, the patient must have been admitted for at least 24 hours prior to the completion of the head CT scan. Scans were excluded if there was documentation in the medical record of a fall, head trauma, or new neurologic deficit within the preceding 2 weeks, or an admitting diagnosis of intracranial pathology (eg, stroke or subdural hematoma). If a patient had multiple head CT studies completed for the indication of delirium, each study was included. However, once a head CT study returned positive or equivocal for an acute intracranial process, subsequent head CT studies for the indication of delirium were not included in the analysis.

Outcome Measures

A positive head CT was defined as an intracranial process that could explain delirium (eg, intracranial hemorrhage or stroke). An equivocal head CT was defined as the presence of a finding of unclear significance in relation to delirium (eg, hypodensity of unknown etiology or clinical significance). Chronic head CT findings were noted to be intracranial pathologic findings of a chronic nature that did not meet criteria for either a positive or equivocal image (eg, chronic small vessel ischemic disease or atrophy). A normal study was without positive, equivocal, or chronic findings.

Data Collection and Statistical Analysis

Using the medical center's clinical informatics infrastructure, an experienced clinical informaticist (R.A.) compiled a list of all head CT imaging studies performed during the study period in hospitalized medical patients. An experienced hospital medicine physician (J.T.) conducted the medical record review and determined if each head CT performed met eligibility criteria. For each included study, the following information was collected: date of admission, date of head CT, date of onset of delirium, indication for obtaining head CT scan, head CT results, age, gender, race/ethnicity (patient reported), presence of dementia (if documented in the medical record), active cancer, use of anticoagulants (defined as factor Xa inhibitors, low molecular weight heparin, direct thrombin inhibitor, or vitamin K antagonist) with documentation of internationalized normalized ratio (INR), partial thromboplastin time (PTT) prothrombin time and platelet count, active infection, history of stroke, and change in clinical management. Descriptive statistics were used to analyze data. Median and interquartile range were used to describe results for age and time from admission to head CT performed due to skewed distribution of results.

RESULTS

Of 1714 head CT studies performed on hospitalized medical patients from January 1, 2010 to November 30, 2012, 398 studies were performed for an indication of delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness in patients who were admitted for >24 hours. One hundred seventy‐eight studies were excluded (137 for admitting diagnosis of intracranial process, recent fall, or head trauma, and 41 for new neurologic deficit). There were 220 scans included in the study performed on 210 patients.

Table 1 displays characteristics of the 210 patients who underwent CT head imaging. Of the 42 patients on anticoagulation, 15 were potentially supratherapeutic; 10 were on warfarin (INR range, 3.37.7) and 5 were on intravenous heparin infusion (PTT range, 101>150 seconds). None of these individuals had positive or equivocal findings on head CT.

Characteristics of Patients Undergoing Head Studies Conducted for the Indication of Delirium
CharacteristicN=210
  • NOTE: Abbreviations: CT, computed tomography; IQR, interquartile range (25th percentile75th percentile).

Age, median (IQR)70 (5980)
Male, n (%)96 (45.7)
Race/ethnicity, n (%) 
White147 (70.0)
African American44 (21.0)
Hispanic4 (1.9)
Asian3 (1.4)
Unknown9 (4.3)
Other3 (1.4)
Comorbidities, n (%) 
Dementia30 (14.3)
Active cancer49 (23.3)
Anticoagulation42 (20.0)
Active infection105 (50.0)
History of stroke41 (19.5)
Days from admission to head CT, median (IQR)4 (38)
Days from delirium onset to head CT, median (IQR)2 (14)

The main outcomes of the 220 included head CT scans and a separate analysis of the 60 head CT scans performed for indications of somnolence or unresponsiveness are shown in Table 2. The 6 (2.7%) positive and 4 (1.8%) equivocal head CT findings are listed in Table 3. Of the 3 positive results in patients on anticoagulation, 2 were on warfarin with an INR of 2.1 and 2.4, respectively, and another was on warfarin and therapeutic enoxaparin (dosed 1 mg/kg twice daily) with an INR of 1.6. The median time from admission to positive head CT was 8 days, with a range of 2 to 28 days. All of the positive head CT studies resulted in change of management. All equivocal head CT studies resulted in repeat imaging. None of these repeat head imaging studies diagnosed acute intracranial pathology. Chronic findings identified included 111 (50.5%) involution or atrophy, 95 (43.2%) small vessel ischemic disease, 31 (14.1%) prior stroke, and 18 (8.2%) other chronic abnormalities (eg, cyst or meningioma).

Results of Head Computed Tomography Studies
IndicationDelirium, N=220 (100%)*Somnolence or Unresponsiveness, N=60 (27.2%)
  • NOTE: *Delirium indication includes delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness. Positive is defined as a head computed tomography (CT) with an intracranial process that could explain delirium, equivocal finding is defined as head CT with an intracranial process of unclear significance in relation to delirium, chronic findings are head CT with findings chronic in nature that do not meet criteria for positive or equivocal findings, and normal is defined as head CT without positive, equivocal, or chronic findings.

Outcome  
Positive6 (2.7)0
Equivocal4 (1.8)1 (1.6)
Chronic162 (73.6)41 (68.3)
Normal48 (21.8)18 (30.0)
Case Review of all Positive and Equivocal Head CT Main Outcomes for the Indication of Delirium Including CT Head Findings, Age and Sex, Comorbidities, and Change in Management
 CT Head FindingsAge (Sex)Days From OnsetChange in ManagementOutcome
  • NOTE: Days to onset of 0 indicates new onset. Abbreviations: AC, anticoagulation; CT, computed tomography; F, female; M, male; MRI, magnetic resonance imaging.

Positive     
Case 1Subarachnoid hemorrhage in right frontal and temporal lobes64 (M)2Neurosurgery consult, AC reversalDischarged with outpatient follow‐up
Case 2Intraparenchymal hemorrhage with mild shift and vasogenic edema62 (M)1Neurosurgery consult, AC reversalDischarged with outpatient follow‐up
Case 3Subacute subdural hematoma62 (M)5Neurosurgery consultDischarged with outpatient follow‐up
Case 4Acute infarct or mass73 (F)2Neurology consult, palliative care consultTransitioned to comfort‐focused care, discharged
Case 54 mm focus concerning for hemorrhagic metastatic focus50 (M)3Neurosurgery consult, MRIDischarged with outpatient follow‐up
Case 6Left occipital lobe parenchymal hemorrhage81 (F)1Neurosurgery consult, neurology consultTransitioned to comfort‐focused care, died 6 days later
Equivocal     
Case 1Several white matter hypodensities of uncertain etiology70 (F)1MRIMRI with chronic small vessel ischemia
Case 2Colloid cyst likely although cannot rule out intraventricular hemorrhage59 (F)1Repeat head CTRepeat imaging with equivocal findings, no additional evaluation
Case 3Questionable hypodensity, either hemorrhagic contusion or artifact52 (M)3Repeat head CTRepeat imaging normal
Case 4Ill‐defined hypodensity in left basal ganglia, no clear acute process74 (F)0MRIMRI with chronic small vessel ischemia

DISCUSSION

In this retrospective review, we determined that there is a low diagnostic yield of head CT imaging for identifying the cause of nonresolving or new‐onset delirium in hospitalized medical patients. Only 2.7% of head CT scans resulted in identifying an acute intracranial process. Because of the low number of positive results, no risk factor associations could be made from our study.

The low diagnostic yield of head imaging in hospitalized patients with delirium is particularly important for clinicians who care for hospitalized medical patients. Prior to this study, the yield of head CT scans in hospitalized medical patients with nonresolving or new‐onset delirium was unknown. In cases with known risk factors, such as recent fall, head trauma, or acute neurologic deficit, the guidelines recommend head CT imaging.[18, 19, 20] However, in the absence of these findings, the guidelines do not make any recommendation regarding when and in whom to perform head imaging. Expert statements recommend considering head CT imaging when the cause is not identified after appropriate testing or delirium continues despite treatment.[8, 21] Given these recommendations and lack of data, there is no clear standard of care for ordering head CT imaging when hospitalized patients experience delirium in the absence of known risk factors. The low diagnostic yield in this study suggests that head CT imaging is unlikely to diagnose the cause of delirium in hospitalized patients with nonresolving or new‐onset delirium.

The diagnostic yield of head CT for diagnosis of acute intracranial process in delirium was lower in our study than prior studies, which found between 14.0 and 39.1%.[9, 10, 11, 12, 13, 14, 15, 16] This was expected, as our study excluded patients with new neurologic deficits, recent fall or trauma, or an admitting diagnosis of an intracranial process. Even with these exclusions, we still allowed for a number of findings that prior studies considered to be high risk for intracranial pathology, such as age over 73 years, use of anticoagulation, and deterioration in consciousness level or Glasgow coma score under 14.[10, 11, 16] The inclusion and exclusion criteria were designed to create a generalizable study population without a clear standard of care based on current guidelines and expert statements.

Though the rate of positive findings found in our study is low, it likely overestimates the overall yield of head CT in hospitalized patients with delirium. This is because most hospitalized patients with delirium never receive head imaging. Presumably, ordering clinicians have deemed these patients to be at higher risk for intracranial processes than the average hospitalized patient with delirium who does not receive a head CT. Thus, the true rate of positive findings in head CT imaging in delirious hospitalized medical patients is likely lower than what we identified.

Although head CT had a low diagnostic yield, the positive and equivocal studies had a high impact on clinical care. All of the positive and equivocal head CT results produced a change in management. The equivocal findings led to repeat head imaging; however, none of the repeat images identified the cause of delirium. The positive results produced a more significant change in management, ranging from a higher platelet transfusion target, reversal of anticoagulation, repeat advanced head imaging, neurosurgery consultation, and a change in goals of care to a focus on comfort. No patients in our study underwent neurosurgical intervention.

The challenge for inpatient clinicians is to weigh the low diagnostic yield of head CT with the consequences of a missed or delayed diagnosis of an acute intracranial process. The low diagnostic yield leads to unnecessary cost, resource utilization, radiation exposure, and downstream evaluation of insignificant or indeterminate results when head CT is performed. Alternatively, a missed or delayed diagnosis can lead to potentially reversible morbidity and mortality. Given this, we feel that the routine use of head CT in the evaluation of delirium in hospitalized patients is unnecessary. However, there may be a subset of patients with delirium with an increased risk of acute intracranial processes that would benefit from head imaging. Further research is needed to identify this high‐risk population.

There are a number of limitations to our study. It is a retrospective chart review, which introduces a possibility of bias and relies on proper and thorough documentation. In addition, the diagnosis of delirium was made by individual clinicians without the use of a standardized delirium assessment tool. Furthermore, it is possible there may have been CT scans that were not identified due to mischaracterization of indication, or studies may have been included in individuals with new neurologic deficit or recent fall or trauma that were not documented or clinically appreciated. Finally, the study was conducted on medicine and medical subspecialty patients at a single academic tertiary care institution, potentially limiting the generalizability to patients in other settings.

In conclusion, our study suggests that the diagnostic yield of head CT to evaluate delirium in hospitalized patients in the absence of recent fall, head trauma, or new neurologic deficit is low. The routine use of head CT in evaluation of these individuals is unnecessary. However, there may be a subset of high‐risk individuals in which head CT imaging would be indicated. Further research is needed to identify these high‐risk individuals.

Disclosures

Jesse Theisen‐Toupal, MD, has no conflicts of interest to disclose. Anthony Breu is a contributor to Practical Reviews in Hospital Medicine but has no conflicts of interest. Melissa Mattison, MD, is a contributor to UpToDate and Practical Reviews in Hospital Medicine but has no conflicts of interest. Ramy Arnaout, MD, has no conflicts of interest to disclose.

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Delirium is a common and costly problem in hospitalized medical patients. It is present on admission in 10% to 31% of cases and develops in up to 56% of patients during hospitalization.[1, 2] Prompt identification and treatment of the cause of delirium is important, because delirium is associated with increased morbidity and mortality, long‐term cognitive impairment, higher cost of care, increased length of stay, and more frequent discharge to an extended care facility.[3, 4, 5, 6]

Delirium can be caused or worsened by a variety of factors including adverse drug events, metabolic abnormalities, infections, immobilization, the use of tethers (eg, physical restraints, bladder catheters, telemetry), and disruption of sleepwake cycle.[7] An appropriate history, medication review, physical examination, and tailored laboratory evaluation is sufficient workup in the majority of cases.[8] However, neurologic processes, such as intracranial mass, intracranial hemorrhage, or stroke, can also present as delirium and require head imaging for diagnosis.

Because head imaging is a costly limited resource, a number of studies have aimed to determine which patients with delirium require this evaluation. The majority of research has focused on head computed tomography (CT) in patients presenting for evaluation to the emergency department (ED). In ED patients presenting with delirium, acute confusion, or altered mental status, head imaging identifies acute intracranial pathologic findings in 14% to 39% of cases.[9, 10, 11, 12, 13, 14] Only 2 studies have evaluated patients with delirium who have already been admitted to the hospital. One study involved patients admitted to a neurology unit with acute confusion and found that the yield of head imaging (head CT and magnetic resonance imaging) was 14% for acute intracranial pathology.[15] Another study reviewed patients admitted to an acute delirium unit and found a similar rate of positive findings on head CT (14.5%).[16] Neither study specified whether the head imaging occurred during initial presentation or later in the hospitalization.

Factors that increase the likelihood that delirium is caused by acute intracranial pathology include acute neurologic deficit, recent history of fall or head trauma, and significantly impaired consciousness.[9, 10, 11, 12, 13, 14, 15, 16, 17] Based on these findings, current guidelines and expert clinical statements recommend head imaging for patients with acute neurologic deficit, recent head trauma, or recent fall.[18, 19, 20]

Expert clinical statements also recommend imaging in cases where the cause is unidentified after appropriate medical testing or where delirium continues despite treatment.[8, 21] Yet the utility of head CT performed for nonresolving delirium or delirium that develops during hospitalization in the absence of recent fall, head trauma, or new neurologic deficits is not known. Our study aimed to determine the diagnostic yield of performing a head CT in this patient population. We hypothesized that the diagnostic yield of head CT in this population would be low.

METHODS

Study Design

We conducted a retrospective medical record review of hospitalized general medicine patients with head CT imaging performed for the evaluation of delirium. The study was reviewed by the internal review board and determined to be exempt.

Setting and Eligibility Criteria

The study was conducted at a large academic medical center in Boston, Massachusetts. All patients admitted to general medicine, nephrology, hepatology, cardiology, or oncology services with head CT studies performed from January 1, 2010 through November 30, 2012 were included in this retrospective, observational cohort study. Data were extracted using a defined instrument developed for this study with outcome measures predefined. Head CT imaging acquired for patients in the intensive care unit were not included in the review. The medical records were evaluated to determine indication. To be included in the study, the indication for the scan had to be delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness. In addition, the patient must have been admitted for at least 24 hours prior to the completion of the head CT scan. Scans were excluded if there was documentation in the medical record of a fall, head trauma, or new neurologic deficit within the preceding 2 weeks, or an admitting diagnosis of intracranial pathology (eg, stroke or subdural hematoma). If a patient had multiple head CT studies completed for the indication of delirium, each study was included. However, once a head CT study returned positive or equivocal for an acute intracranial process, subsequent head CT studies for the indication of delirium were not included in the analysis.

Outcome Measures

A positive head CT was defined as an intracranial process that could explain delirium (eg, intracranial hemorrhage or stroke). An equivocal head CT was defined as the presence of a finding of unclear significance in relation to delirium (eg, hypodensity of unknown etiology or clinical significance). Chronic head CT findings were noted to be intracranial pathologic findings of a chronic nature that did not meet criteria for either a positive or equivocal image (eg, chronic small vessel ischemic disease or atrophy). A normal study was without positive, equivocal, or chronic findings.

Data Collection and Statistical Analysis

Using the medical center's clinical informatics infrastructure, an experienced clinical informaticist (R.A.) compiled a list of all head CT imaging studies performed during the study period in hospitalized medical patients. An experienced hospital medicine physician (J.T.) conducted the medical record review and determined if each head CT performed met eligibility criteria. For each included study, the following information was collected: date of admission, date of head CT, date of onset of delirium, indication for obtaining head CT scan, head CT results, age, gender, race/ethnicity (patient reported), presence of dementia (if documented in the medical record), active cancer, use of anticoagulants (defined as factor Xa inhibitors, low molecular weight heparin, direct thrombin inhibitor, or vitamin K antagonist) with documentation of internationalized normalized ratio (INR), partial thromboplastin time (PTT) prothrombin time and platelet count, active infection, history of stroke, and change in clinical management. Descriptive statistics were used to analyze data. Median and interquartile range were used to describe results for age and time from admission to head CT performed due to skewed distribution of results.

RESULTS

Of 1714 head CT studies performed on hospitalized medical patients from January 1, 2010 to November 30, 2012, 398 studies were performed for an indication of delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness in patients who were admitted for >24 hours. One hundred seventy‐eight studies were excluded (137 for admitting diagnosis of intracranial process, recent fall, or head trauma, and 41 for new neurologic deficit). There were 220 scans included in the study performed on 210 patients.

Table 1 displays characteristics of the 210 patients who underwent CT head imaging. Of the 42 patients on anticoagulation, 15 were potentially supratherapeutic; 10 were on warfarin (INR range, 3.37.7) and 5 were on intravenous heparin infusion (PTT range, 101>150 seconds). None of these individuals had positive or equivocal findings on head CT.

Characteristics of Patients Undergoing Head Studies Conducted for the Indication of Delirium
CharacteristicN=210
  • NOTE: Abbreviations: CT, computed tomography; IQR, interquartile range (25th percentile75th percentile).

Age, median (IQR)70 (5980)
Male, n (%)96 (45.7)
Race/ethnicity, n (%) 
White147 (70.0)
African American44 (21.0)
Hispanic4 (1.9)
Asian3 (1.4)
Unknown9 (4.3)
Other3 (1.4)
Comorbidities, n (%) 
Dementia30 (14.3)
Active cancer49 (23.3)
Anticoagulation42 (20.0)
Active infection105 (50.0)
History of stroke41 (19.5)
Days from admission to head CT, median (IQR)4 (38)
Days from delirium onset to head CT, median (IQR)2 (14)

The main outcomes of the 220 included head CT scans and a separate analysis of the 60 head CT scans performed for indications of somnolence or unresponsiveness are shown in Table 2. The 6 (2.7%) positive and 4 (1.8%) equivocal head CT findings are listed in Table 3. Of the 3 positive results in patients on anticoagulation, 2 were on warfarin with an INR of 2.1 and 2.4, respectively, and another was on warfarin and therapeutic enoxaparin (dosed 1 mg/kg twice daily) with an INR of 1.6. The median time from admission to positive head CT was 8 days, with a range of 2 to 28 days. All of the positive head CT studies resulted in change of management. All equivocal head CT studies resulted in repeat imaging. None of these repeat head imaging studies diagnosed acute intracranial pathology. Chronic findings identified included 111 (50.5%) involution or atrophy, 95 (43.2%) small vessel ischemic disease, 31 (14.1%) prior stroke, and 18 (8.2%) other chronic abnormalities (eg, cyst or meningioma).

Results of Head Computed Tomography Studies
IndicationDelirium, N=220 (100%)*Somnolence or Unresponsiveness, N=60 (27.2%)
  • NOTE: *Delirium indication includes delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness. Positive is defined as a head computed tomography (CT) with an intracranial process that could explain delirium, equivocal finding is defined as head CT with an intracranial process of unclear significance in relation to delirium, chronic findings are head CT with findings chronic in nature that do not meet criteria for positive or equivocal findings, and normal is defined as head CT without positive, equivocal, or chronic findings.

Outcome  
Positive6 (2.7)0
Equivocal4 (1.8)1 (1.6)
Chronic162 (73.6)41 (68.3)
Normal48 (21.8)18 (30.0)
Case Review of all Positive and Equivocal Head CT Main Outcomes for the Indication of Delirium Including CT Head Findings, Age and Sex, Comorbidities, and Change in Management
 CT Head FindingsAge (Sex)Days From OnsetChange in ManagementOutcome
  • NOTE: Days to onset of 0 indicates new onset. Abbreviations: AC, anticoagulation; CT, computed tomography; F, female; M, male; MRI, magnetic resonance imaging.

Positive     
Case 1Subarachnoid hemorrhage in right frontal and temporal lobes64 (M)2Neurosurgery consult, AC reversalDischarged with outpatient follow‐up
Case 2Intraparenchymal hemorrhage with mild shift and vasogenic edema62 (M)1Neurosurgery consult, AC reversalDischarged with outpatient follow‐up
Case 3Subacute subdural hematoma62 (M)5Neurosurgery consultDischarged with outpatient follow‐up
Case 4Acute infarct or mass73 (F)2Neurology consult, palliative care consultTransitioned to comfort‐focused care, discharged
Case 54 mm focus concerning for hemorrhagic metastatic focus50 (M)3Neurosurgery consult, MRIDischarged with outpatient follow‐up
Case 6Left occipital lobe parenchymal hemorrhage81 (F)1Neurosurgery consult, neurology consultTransitioned to comfort‐focused care, died 6 days later
Equivocal     
Case 1Several white matter hypodensities of uncertain etiology70 (F)1MRIMRI with chronic small vessel ischemia
Case 2Colloid cyst likely although cannot rule out intraventricular hemorrhage59 (F)1Repeat head CTRepeat imaging with equivocal findings, no additional evaluation
Case 3Questionable hypodensity, either hemorrhagic contusion or artifact52 (M)3Repeat head CTRepeat imaging normal
Case 4Ill‐defined hypodensity in left basal ganglia, no clear acute process74 (F)0MRIMRI with chronic small vessel ischemia

DISCUSSION

In this retrospective review, we determined that there is a low diagnostic yield of head CT imaging for identifying the cause of nonresolving or new‐onset delirium in hospitalized medical patients. Only 2.7% of head CT scans resulted in identifying an acute intracranial process. Because of the low number of positive results, no risk factor associations could be made from our study.

The low diagnostic yield of head imaging in hospitalized patients with delirium is particularly important for clinicians who care for hospitalized medical patients. Prior to this study, the yield of head CT scans in hospitalized medical patients with nonresolving or new‐onset delirium was unknown. In cases with known risk factors, such as recent fall, head trauma, or acute neurologic deficit, the guidelines recommend head CT imaging.[18, 19, 20] However, in the absence of these findings, the guidelines do not make any recommendation regarding when and in whom to perform head imaging. Expert statements recommend considering head CT imaging when the cause is not identified after appropriate testing or delirium continues despite treatment.[8, 21] Given these recommendations and lack of data, there is no clear standard of care for ordering head CT imaging when hospitalized patients experience delirium in the absence of known risk factors. The low diagnostic yield in this study suggests that head CT imaging is unlikely to diagnose the cause of delirium in hospitalized patients with nonresolving or new‐onset delirium.

The diagnostic yield of head CT for diagnosis of acute intracranial process in delirium was lower in our study than prior studies, which found between 14.0 and 39.1%.[9, 10, 11, 12, 13, 14, 15, 16] This was expected, as our study excluded patients with new neurologic deficits, recent fall or trauma, or an admitting diagnosis of an intracranial process. Even with these exclusions, we still allowed for a number of findings that prior studies considered to be high risk for intracranial pathology, such as age over 73 years, use of anticoagulation, and deterioration in consciousness level or Glasgow coma score under 14.[10, 11, 16] The inclusion and exclusion criteria were designed to create a generalizable study population without a clear standard of care based on current guidelines and expert statements.

Though the rate of positive findings found in our study is low, it likely overestimates the overall yield of head CT in hospitalized patients with delirium. This is because most hospitalized patients with delirium never receive head imaging. Presumably, ordering clinicians have deemed these patients to be at higher risk for intracranial processes than the average hospitalized patient with delirium who does not receive a head CT. Thus, the true rate of positive findings in head CT imaging in delirious hospitalized medical patients is likely lower than what we identified.

Although head CT had a low diagnostic yield, the positive and equivocal studies had a high impact on clinical care. All of the positive and equivocal head CT results produced a change in management. The equivocal findings led to repeat head imaging; however, none of the repeat images identified the cause of delirium. The positive results produced a more significant change in management, ranging from a higher platelet transfusion target, reversal of anticoagulation, repeat advanced head imaging, neurosurgery consultation, and a change in goals of care to a focus on comfort. No patients in our study underwent neurosurgical intervention.

The challenge for inpatient clinicians is to weigh the low diagnostic yield of head CT with the consequences of a missed or delayed diagnosis of an acute intracranial process. The low diagnostic yield leads to unnecessary cost, resource utilization, radiation exposure, and downstream evaluation of insignificant or indeterminate results when head CT is performed. Alternatively, a missed or delayed diagnosis can lead to potentially reversible morbidity and mortality. Given this, we feel that the routine use of head CT in the evaluation of delirium in hospitalized patients is unnecessary. However, there may be a subset of patients with delirium with an increased risk of acute intracranial processes that would benefit from head imaging. Further research is needed to identify this high‐risk population.

There are a number of limitations to our study. It is a retrospective chart review, which introduces a possibility of bias and relies on proper and thorough documentation. In addition, the diagnosis of delirium was made by individual clinicians without the use of a standardized delirium assessment tool. Furthermore, it is possible there may have been CT scans that were not identified due to mischaracterization of indication, or studies may have been included in individuals with new neurologic deficit or recent fall or trauma that were not documented or clinically appreciated. Finally, the study was conducted on medicine and medical subspecialty patients at a single academic tertiary care institution, potentially limiting the generalizability to patients in other settings.

In conclusion, our study suggests that the diagnostic yield of head CT to evaluate delirium in hospitalized patients in the absence of recent fall, head trauma, or new neurologic deficit is low. The routine use of head CT in evaluation of these individuals is unnecessary. However, there may be a subset of high‐risk individuals in which head CT imaging would be indicated. Further research is needed to identify these high‐risk individuals.

Disclosures

Jesse Theisen‐Toupal, MD, has no conflicts of interest to disclose. Anthony Breu is a contributor to Practical Reviews in Hospital Medicine but has no conflicts of interest. Melissa Mattison, MD, is a contributor to UpToDate and Practical Reviews in Hospital Medicine but has no conflicts of interest. Ramy Arnaout, MD, has no conflicts of interest to disclose.

Delirium is a common and costly problem in hospitalized medical patients. It is present on admission in 10% to 31% of cases and develops in up to 56% of patients during hospitalization.[1, 2] Prompt identification and treatment of the cause of delirium is important, because delirium is associated with increased morbidity and mortality, long‐term cognitive impairment, higher cost of care, increased length of stay, and more frequent discharge to an extended care facility.[3, 4, 5, 6]

Delirium can be caused or worsened by a variety of factors including adverse drug events, metabolic abnormalities, infections, immobilization, the use of tethers (eg, physical restraints, bladder catheters, telemetry), and disruption of sleepwake cycle.[7] An appropriate history, medication review, physical examination, and tailored laboratory evaluation is sufficient workup in the majority of cases.[8] However, neurologic processes, such as intracranial mass, intracranial hemorrhage, or stroke, can also present as delirium and require head imaging for diagnosis.

Because head imaging is a costly limited resource, a number of studies have aimed to determine which patients with delirium require this evaluation. The majority of research has focused on head computed tomography (CT) in patients presenting for evaluation to the emergency department (ED). In ED patients presenting with delirium, acute confusion, or altered mental status, head imaging identifies acute intracranial pathologic findings in 14% to 39% of cases.[9, 10, 11, 12, 13, 14] Only 2 studies have evaluated patients with delirium who have already been admitted to the hospital. One study involved patients admitted to a neurology unit with acute confusion and found that the yield of head imaging (head CT and magnetic resonance imaging) was 14% for acute intracranial pathology.[15] Another study reviewed patients admitted to an acute delirium unit and found a similar rate of positive findings on head CT (14.5%).[16] Neither study specified whether the head imaging occurred during initial presentation or later in the hospitalization.

Factors that increase the likelihood that delirium is caused by acute intracranial pathology include acute neurologic deficit, recent history of fall or head trauma, and significantly impaired consciousness.[9, 10, 11, 12, 13, 14, 15, 16, 17] Based on these findings, current guidelines and expert clinical statements recommend head imaging for patients with acute neurologic deficit, recent head trauma, or recent fall.[18, 19, 20]

Expert clinical statements also recommend imaging in cases where the cause is unidentified after appropriate medical testing or where delirium continues despite treatment.[8, 21] Yet the utility of head CT performed for nonresolving delirium or delirium that develops during hospitalization in the absence of recent fall, head trauma, or new neurologic deficits is not known. Our study aimed to determine the diagnostic yield of performing a head CT in this patient population. We hypothesized that the diagnostic yield of head CT in this population would be low.

METHODS

Study Design

We conducted a retrospective medical record review of hospitalized general medicine patients with head CT imaging performed for the evaluation of delirium. The study was reviewed by the internal review board and determined to be exempt.

Setting and Eligibility Criteria

The study was conducted at a large academic medical center in Boston, Massachusetts. All patients admitted to general medicine, nephrology, hepatology, cardiology, or oncology services with head CT studies performed from January 1, 2010 through November 30, 2012 were included in this retrospective, observational cohort study. Data were extracted using a defined instrument developed for this study with outcome measures predefined. Head CT imaging acquired for patients in the intensive care unit were not included in the review. The medical records were evaluated to determine indication. To be included in the study, the indication for the scan had to be delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness. In addition, the patient must have been admitted for at least 24 hours prior to the completion of the head CT scan. Scans were excluded if there was documentation in the medical record of a fall, head trauma, or new neurologic deficit within the preceding 2 weeks, or an admitting diagnosis of intracranial pathology (eg, stroke or subdural hematoma). If a patient had multiple head CT studies completed for the indication of delirium, each study was included. However, once a head CT study returned positive or equivocal for an acute intracranial process, subsequent head CT studies for the indication of delirium were not included in the analysis.

Outcome Measures

A positive head CT was defined as an intracranial process that could explain delirium (eg, intracranial hemorrhage or stroke). An equivocal head CT was defined as the presence of a finding of unclear significance in relation to delirium (eg, hypodensity of unknown etiology or clinical significance). Chronic head CT findings were noted to be intracranial pathologic findings of a chronic nature that did not meet criteria for either a positive or equivocal image (eg, chronic small vessel ischemic disease or atrophy). A normal study was without positive, equivocal, or chronic findings.

Data Collection and Statistical Analysis

Using the medical center's clinical informatics infrastructure, an experienced clinical informaticist (R.A.) compiled a list of all head CT imaging studies performed during the study period in hospitalized medical patients. An experienced hospital medicine physician (J.T.) conducted the medical record review and determined if each head CT performed met eligibility criteria. For each included study, the following information was collected: date of admission, date of head CT, date of onset of delirium, indication for obtaining head CT scan, head CT results, age, gender, race/ethnicity (patient reported), presence of dementia (if documented in the medical record), active cancer, use of anticoagulants (defined as factor Xa inhibitors, low molecular weight heparin, direct thrombin inhibitor, or vitamin K antagonist) with documentation of internationalized normalized ratio (INR), partial thromboplastin time (PTT) prothrombin time and platelet count, active infection, history of stroke, and change in clinical management. Descriptive statistics were used to analyze data. Median and interquartile range were used to describe results for age and time from admission to head CT performed due to skewed distribution of results.

RESULTS

Of 1714 head CT studies performed on hospitalized medical patients from January 1, 2010 to November 30, 2012, 398 studies were performed for an indication of delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness in patients who were admitted for >24 hours. One hundred seventy‐eight studies were excluded (137 for admitting diagnosis of intracranial process, recent fall, or head trauma, and 41 for new neurologic deficit). There were 220 scans included in the study performed on 210 patients.

Table 1 displays characteristics of the 210 patients who underwent CT head imaging. Of the 42 patients on anticoagulation, 15 were potentially supratherapeutic; 10 were on warfarin (INR range, 3.37.7) and 5 were on intravenous heparin infusion (PTT range, 101>150 seconds). None of these individuals had positive or equivocal findings on head CT.

Characteristics of Patients Undergoing Head Studies Conducted for the Indication of Delirium
CharacteristicN=210
  • NOTE: Abbreviations: CT, computed tomography; IQR, interquartile range (25th percentile75th percentile).

Age, median (IQR)70 (5980)
Male, n (%)96 (45.7)
Race/ethnicity, n (%) 
White147 (70.0)
African American44 (21.0)
Hispanic4 (1.9)
Asian3 (1.4)
Unknown9 (4.3)
Other3 (1.4)
Comorbidities, n (%) 
Dementia30 (14.3)
Active cancer49 (23.3)
Anticoagulation42 (20.0)
Active infection105 (50.0)
History of stroke41 (19.5)
Days from admission to head CT, median (IQR)4 (38)
Days from delirium onset to head CT, median (IQR)2 (14)

The main outcomes of the 220 included head CT scans and a separate analysis of the 60 head CT scans performed for indications of somnolence or unresponsiveness are shown in Table 2. The 6 (2.7%) positive and 4 (1.8%) equivocal head CT findings are listed in Table 3. Of the 3 positive results in patients on anticoagulation, 2 were on warfarin with an INR of 2.1 and 2.4, respectively, and another was on warfarin and therapeutic enoxaparin (dosed 1 mg/kg twice daily) with an INR of 1.6. The median time from admission to positive head CT was 8 days, with a range of 2 to 28 days. All of the positive head CT studies resulted in change of management. All equivocal head CT studies resulted in repeat imaging. None of these repeat head imaging studies diagnosed acute intracranial pathology. Chronic findings identified included 111 (50.5%) involution or atrophy, 95 (43.2%) small vessel ischemic disease, 31 (14.1%) prior stroke, and 18 (8.2%) other chronic abnormalities (eg, cyst or meningioma).

Results of Head Computed Tomography Studies
IndicationDelirium, N=220 (100%)*Somnolence or Unresponsiveness, N=60 (27.2%)
  • NOTE: *Delirium indication includes delirium, altered mental status, confusion, encephalopathy, somnolence, or unresponsiveness. Positive is defined as a head computed tomography (CT) with an intracranial process that could explain delirium, equivocal finding is defined as head CT with an intracranial process of unclear significance in relation to delirium, chronic findings are head CT with findings chronic in nature that do not meet criteria for positive or equivocal findings, and normal is defined as head CT without positive, equivocal, or chronic findings.

Outcome  
Positive6 (2.7)0
Equivocal4 (1.8)1 (1.6)
Chronic162 (73.6)41 (68.3)
Normal48 (21.8)18 (30.0)
Case Review of all Positive and Equivocal Head CT Main Outcomes for the Indication of Delirium Including CT Head Findings, Age and Sex, Comorbidities, and Change in Management
 CT Head FindingsAge (Sex)Days From OnsetChange in ManagementOutcome
  • NOTE: Days to onset of 0 indicates new onset. Abbreviations: AC, anticoagulation; CT, computed tomography; F, female; M, male; MRI, magnetic resonance imaging.

Positive     
Case 1Subarachnoid hemorrhage in right frontal and temporal lobes64 (M)2Neurosurgery consult, AC reversalDischarged with outpatient follow‐up
Case 2Intraparenchymal hemorrhage with mild shift and vasogenic edema62 (M)1Neurosurgery consult, AC reversalDischarged with outpatient follow‐up
Case 3Subacute subdural hematoma62 (M)5Neurosurgery consultDischarged with outpatient follow‐up
Case 4Acute infarct or mass73 (F)2Neurology consult, palliative care consultTransitioned to comfort‐focused care, discharged
Case 54 mm focus concerning for hemorrhagic metastatic focus50 (M)3Neurosurgery consult, MRIDischarged with outpatient follow‐up
Case 6Left occipital lobe parenchymal hemorrhage81 (F)1Neurosurgery consult, neurology consultTransitioned to comfort‐focused care, died 6 days later
Equivocal     
Case 1Several white matter hypodensities of uncertain etiology70 (F)1MRIMRI with chronic small vessel ischemia
Case 2Colloid cyst likely although cannot rule out intraventricular hemorrhage59 (F)1Repeat head CTRepeat imaging with equivocal findings, no additional evaluation
Case 3Questionable hypodensity, either hemorrhagic contusion or artifact52 (M)3Repeat head CTRepeat imaging normal
Case 4Ill‐defined hypodensity in left basal ganglia, no clear acute process74 (F)0MRIMRI with chronic small vessel ischemia

DISCUSSION

In this retrospective review, we determined that there is a low diagnostic yield of head CT imaging for identifying the cause of nonresolving or new‐onset delirium in hospitalized medical patients. Only 2.7% of head CT scans resulted in identifying an acute intracranial process. Because of the low number of positive results, no risk factor associations could be made from our study.

The low diagnostic yield of head imaging in hospitalized patients with delirium is particularly important for clinicians who care for hospitalized medical patients. Prior to this study, the yield of head CT scans in hospitalized medical patients with nonresolving or new‐onset delirium was unknown. In cases with known risk factors, such as recent fall, head trauma, or acute neurologic deficit, the guidelines recommend head CT imaging.[18, 19, 20] However, in the absence of these findings, the guidelines do not make any recommendation regarding when and in whom to perform head imaging. Expert statements recommend considering head CT imaging when the cause is not identified after appropriate testing or delirium continues despite treatment.[8, 21] Given these recommendations and lack of data, there is no clear standard of care for ordering head CT imaging when hospitalized patients experience delirium in the absence of known risk factors. The low diagnostic yield in this study suggests that head CT imaging is unlikely to diagnose the cause of delirium in hospitalized patients with nonresolving or new‐onset delirium.

The diagnostic yield of head CT for diagnosis of acute intracranial process in delirium was lower in our study than prior studies, which found between 14.0 and 39.1%.[9, 10, 11, 12, 13, 14, 15, 16] This was expected, as our study excluded patients with new neurologic deficits, recent fall or trauma, or an admitting diagnosis of an intracranial process. Even with these exclusions, we still allowed for a number of findings that prior studies considered to be high risk for intracranial pathology, such as age over 73 years, use of anticoagulation, and deterioration in consciousness level or Glasgow coma score under 14.[10, 11, 16] The inclusion and exclusion criteria were designed to create a generalizable study population without a clear standard of care based on current guidelines and expert statements.

Though the rate of positive findings found in our study is low, it likely overestimates the overall yield of head CT in hospitalized patients with delirium. This is because most hospitalized patients with delirium never receive head imaging. Presumably, ordering clinicians have deemed these patients to be at higher risk for intracranial processes than the average hospitalized patient with delirium who does not receive a head CT. Thus, the true rate of positive findings in head CT imaging in delirious hospitalized medical patients is likely lower than what we identified.

Although head CT had a low diagnostic yield, the positive and equivocal studies had a high impact on clinical care. All of the positive and equivocal head CT results produced a change in management. The equivocal findings led to repeat head imaging; however, none of the repeat images identified the cause of delirium. The positive results produced a more significant change in management, ranging from a higher platelet transfusion target, reversal of anticoagulation, repeat advanced head imaging, neurosurgery consultation, and a change in goals of care to a focus on comfort. No patients in our study underwent neurosurgical intervention.

The challenge for inpatient clinicians is to weigh the low diagnostic yield of head CT with the consequences of a missed or delayed diagnosis of an acute intracranial process. The low diagnostic yield leads to unnecessary cost, resource utilization, radiation exposure, and downstream evaluation of insignificant or indeterminate results when head CT is performed. Alternatively, a missed or delayed diagnosis can lead to potentially reversible morbidity and mortality. Given this, we feel that the routine use of head CT in the evaluation of delirium in hospitalized patients is unnecessary. However, there may be a subset of patients with delirium with an increased risk of acute intracranial processes that would benefit from head imaging. Further research is needed to identify this high‐risk population.

There are a number of limitations to our study. It is a retrospective chart review, which introduces a possibility of bias and relies on proper and thorough documentation. In addition, the diagnosis of delirium was made by individual clinicians without the use of a standardized delirium assessment tool. Furthermore, it is possible there may have been CT scans that were not identified due to mischaracterization of indication, or studies may have been included in individuals with new neurologic deficit or recent fall or trauma that were not documented or clinically appreciated. Finally, the study was conducted on medicine and medical subspecialty patients at a single academic tertiary care institution, potentially limiting the generalizability to patients in other settings.

In conclusion, our study suggests that the diagnostic yield of head CT to evaluate delirium in hospitalized patients in the absence of recent fall, head trauma, or new neurologic deficit is low. The routine use of head CT in evaluation of these individuals is unnecessary. However, there may be a subset of high‐risk individuals in which head CT imaging would be indicated. Further research is needed to identify these high‐risk individuals.

Disclosures

Jesse Theisen‐Toupal, MD, has no conflicts of interest to disclose. Anthony Breu is a contributor to Practical Reviews in Hospital Medicine but has no conflicts of interest. Melissa Mattison, MD, is a contributor to UpToDate and Practical Reviews in Hospital Medicine but has no conflicts of interest. Ramy Arnaout, MD, has no conflicts of interest to disclose.

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Journal of Hospital Medicine - 9(8)
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Journal of Hospital Medicine - 9(8)
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497-501
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497-501
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Diagnostic yield of head computed tomography for the hospitalized medical patient with delirium
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Diagnostic yield of head computed tomography for the hospitalized medical patient with delirium
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© 2014 Society of Hospital Medicine

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Address for correspondence and reprint requests: Jesse Theisen‐Toupal, MD, 330 Brookline Avenue Span‐2, Boston, MA 02115; Telephone: 617‐754‐4677; Fax: 617‐632‐0215; E‐mail: [email protected]
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