This analysis of Medicare data examines the relationships between fragmented readmission, health information exchange, and repeat imaging in older adults with and without Alzheimer disease.
ABSTRACT
Objectives: We examined the association between electronic health information sharing and repeat imaging in readmissions among older adults with and without Alzheimer disease (AD).
Study Design: Cohort study using national Medicare data.
Methods: Among Medicare beneficiaries with 30-day readmissions in 2018, we examined repeat imaging on the same body system during the readmission. This was evaluated between fragmented and nonfragmented (same-hospital) readmissions and across categories of electronic information sharing via health information exchanges (HIEs) in fragmented readmissions: admission and readmission hospitals share the same HIE, admission and readmission hospitals participate in different HIEs, one or both do not participate in HIE, or HIE data missing. This relationship was evaluated using unadjusted and adjusted logistic regression.
Results: Overall, 14.3% of beneficiaries experienced repeat imaging during their readmission. Compared with nonfragmented readmissions, fragmented readmissions were associated with 5% higher odds of repeat imaging on the same body system in older adults without AD. This was not mitigated by the presence of electronic information sharing: Fragmented readmissions to hospitals that shared an HIE had 6% higher odds of repeat imaging (adjusted OR, 1.06; 95% CI, 1.00-1.13). There was no difference seen in the odds of repeat imaging for older adults with AD.
Conclusions: Despite substantial investment, HIEs as currently deployed and used are not associated with decreased odds of repeat imaging in readmissions.
Am J Manag Care. 2024;30(2):66-72. https://doi.org/10.37765/ajmc.2024.89493
Takeaway Points
We examined the association between repeat imaging and health information exchange (HIE) during fragmented readmissions in older adults with and without Alzheimer disease (AD).
As US health care costs continue to rise,1 efforts to decrease low-value care remain at the forefront for policy makers, payers, clinicians, and patients. Repeat imaging is a common type of low-value care; in 2007, 20% of surveyed patients reported undergoing duplicate imaging procedures.2 As of 2009, radiology procedures were estimated to cost $100 billion per year in the US,3 and 20% to 25% of these tests represent inappropriate or low-value care.4,5
One factor that may increase the potential for repeat imaging is lack of access to a patient’s previous imaging studies,6 such as during a fragmented readmission, which is when a patient has a readmission to a different hospital than the one from which they were previously discharged. Fragmented readmissions occur in up to 25% of readmissions and are associated with higher rates of health care use, including longer lengths of stay and more readmissions.7
Health information exchanges (HIEs)—electronic systems for accessing health data across settings of care—have been proposed as a solution to decrease duplicate imaging.8 HIEs have been widely adopted,9 but previous investigations regarding the association between electronic health information sharing and repeat imaging have shown mixed results. A 2012 study found 40% to 70% greater odds of imaging orders by physicians with access to previous imaging results,10 whereas another study examining HIE and repeat imaging found nearly the opposite: that HIE use was associated with a 25% reduction in repeat imaging.11
Older adults and particularly individuals with diseases such as Alzheimer disease (AD) that may affect their ability to relay critical points in their prior medical history may be at higher risk of low-value care, including repeat imaging during fragmented readmissions. Because most imaging procedures are performed in older patients2 and the rate of imaging use increased by approximately 5% per year between 2014 and 2016 among older adults,12 it is crucial to understand the contexts in which duplicative imaging occurs in this population.
In this study, we examined Medicare data from 2018 to investigate the association between fragmented readmissions as well as types of information shared in fragmented 30-day readmissions and the odds of duplicate radiology exams among beneficiaries with and without AD.
METHODS
Data Sources
Hospital admissions and imaging studies were identified in the 2018 Medicare Provider Analysis and Review (MedPAR) file for fee-for-service beneficiaries. Additional imaging studies were obtained from the 2018 Medicare Carrier File. Patient demographics and clinical characteristics were found in the Medicare Master Beneficiary Summary File and its Chronic Conditions segment. Hospital information was obtained from the 2018 American Hospital Association (AHA) Annual Survey and the 2017-2018 AHA Annual Survey Information Technology Supplement (henceforth, IT Supplement; completed in 2018-2019). The AHA Annual Survey is a voluntary survey of hospitals and health care systems.13 The IT Supplement is a supplemental survey conducted with the AHA Annual Survey.14
Patients
This analysis included Medicare beneficiaries who had a hospital admission for select Hospital Readmissions Reduction Program diagnoses (acute myocardial infarction, congestive heart failure, chronic obstructive pulmonary disease, pneumonia)15 or common causes of hospitalization among older adults, particularly those with AD (dehydration, syncope, urinary tract infection, behavioral issues) (International Statistical Classification of Diseases, Tenth Revision [ICD-10] codes in eAppendix A [eAppendices available at ajmc.com]).16 All index admissions in the analytic sample were for one of these reasons, but readmissions could be for any reason. Beneficiaries with and without AD were included in the analysis.
Beneficiaries were excluded if they did not have any readmissions within 30 days of their index admission, if their beneficiary identifier was missing, or if the admissions/readmissions represented hospital-to-hospital transfers. Admissions and 30-day readmissions were transformed into admission-readmission pairs; a beneficiary could have multiple admission-readmission pairs if they had more than 2 admissions in the data set. The final sample included only admission-readmission pairs in which an imaging study was performed during the index admission.
Main Exposure: Level of Health Information Sharing Between Admission and Readmission Hospitals
Fragmented readmissions were defined as an admission and subsequent readmission to different hospitals. Information sharing was defined as the category of health care information sharing at the hospital level based on the data available in the AHA Annual Survey and IT Supplement. The reference category was nonfragmented/same-hospital readmissions, which is when the index admission and readmission were to the same hospital. All fragmented readmissions were divided into 4 subcategories based on hospital-level HIE participation: same HIE pairs, where both the admission and readmission hospital participated in the same HIE; different HIE pairs, where both hospitals participated in HIE, but the HIEs were different; no HIE, where 1 or both hospitals indicated that they do not participate in HIE; or HIE missing, where HIE status was missing due to nonresponse to the IT Supplement or the HIE question.
HIE participation was determined by the response to the question: “Please indicate your level of participation in a state, regional, and/or local [HIE] or health information organization [HIO]” on the IT Supplement. Answers could be “do not know,” “HIE/HIO is not operational in my area,” “HIE/HIO is operational…we are not participating,” or “HIE/HIO is operational…we are participating.” If the hospital answered that it was participating in HIE on an IT Supplement in 2017 or 2018, it was classified as having HIE in this analysis. If a hospital had different or missing answers across years of data, we used the answer reflecting its highest level of information sharing. To determine which HIE a hospital participated in, we examined answers to the questions: “Which of the following national health information networks does your hospital participate in?” Potential responses included “your [electronic health record (EHR)] vendor’s network” and “other,” which offered free-text response options. If a hospital responded “your EHR vendor’s network,” we examined potential free-text response options as well as its answer to the survey question regarding the primary inpatient EHR. Because a beneficiary could have multiple admission-readmission pairs in this analysis, they could have pairs in more than 1 category of information sharing.
Main Outcome: Repeat Imaging of the Same Body System
The main outcome for this study was repeat imaging of the same body system performed during the 30-day readmission. Imaging was identified via ICD-10 procedure codes in the MedPAR file and by Berenson-Eggers Type of Service (BETOS) codes in the Carrier file.17 Each hospitalization could have up to 25 ICD-10 procedure codes listed. The anatomical region examined by the imaging procedure is identified by the second character of the ICD-10 procedure code; 31 potential anatomic regions are delineated within ICD-10.18 The mapping of BETOS codes to ICD-10 anatomic regions can be found in eAppendix B.
Repeat imaging on the same body system occurred if an imaging procedure/BETOS code in the readmission had the same body system as an imaging procedure/BETOS code in the index admission. All outcomes were agnostic to imaging modality used; for example, a chest CT and chest x-ray would be considered repeat imaging on the same body system. Additionally, we did not include the number of repeat imaging studies performed as part of the primary outcome.
Analytic Approach
Univariate statistics were used to compare characteristics of beneficiaries with admission-readmission pairs across the categories of information sharing (nonfragmented/same hospital [reference], same HIE, different HIE, no HIE, missing HIE). The demographic characteristics examined were beneficiary age, sex, and race. The clinical characteristics were the Charlson Comorbidity Index (CCI) score19 and the diagnosis related group (DRG) code of the readmission. The readmission hospital characteristics included were urban/rural status (metropolitan, micropolitan, and rural), number of hospital beds (< 200, 200-399, ≥ 400), hospital ownership (public, for-profit, government, and church), teaching status, and type of hospital. Urban/rural status was identified via the rural-urban commuting area code of the hospital.20 Hospitals were labeled teaching hospitals if they reported programs accredited by the Accreditation Council for Graduate Medical Education, the American Osteopathic Association, or the Council of Teaching Hospitals, or if they were affiliated with a medical school. Hospitals were classified as either general medical/surgical or “other,” which included specialty hospitals.13
We used unadjusted and adjusted logistic regression models to evaluate the association between fragmented readmissions and repeat imaging on the same body system and then between HIE category and repeat imaging on the same body system. All models included readmission hospital fixed effects and robust SEs clustered at the hospital level; fixed effects were included to account for potential unobserved differences in hospital-level practice patterns regarding imaging studies. The reference group was nonfragmented/same-hospital readmission pairs.
Models were separately adjusted for demographic/clinical (age, sex, race, CCI, DRG) and readmission hospital characteristics. A final model that included all covariates was also created. Older adults with and without AD were included; regression results were stratified a priori by AD diagnosis. If a patient was listed as ever having AD in the Chronic Conditions segment, they were considered to have AD for this analysis.
Sensitivity Analysis
To assess the robustness of our estimates, we performed several sensitivity analyses. First, we stratified the analysis by the number of pairs present per patient (1 or ≥ 2) to determine whether HIE had a different effect on patients with multiple readmissions. We also examined the association between HIE and repeat imaging on the same body system among beneficiaries in the sample who had an MRI during their index admission. MRIs were identified by a value greater than 0 in the “MRI_CHRG” variable of the index admission. This was done to measure whether health information sharing had a differential impact on more advanced or costly radiology procedures as previously described in the literature.10 Next, we examined only admission-readmission pairs with repeat imaging on the same body system and examined whether HIE status was associated with more than 1 instance of repeat imaging during the readmission vs a single instance of repeat imaging during the readmission. This was done to assess whether HIE was associated with the volume of repeat imaging. Finally, we used advanced imaging on the same body system as the outcome, defined by the presence of an ICD-10 or BETOS code for CT, MRI, and/or ultrasound during the admission and/or readmission. This was done to assess whether there was a different association between HIE status and repeat imaging on the same body system when first-line imaging, such as x-rays, was not considered. Because of the small sample size, hospital fixed effects were not included in the final sensitivity analysis.
We conducted analyses using SAS 9.4 (SAS Institute) and Stata 17 (StataCorp LLC). This study was approved by the institutional review board of Emory University School of Medicine and funded by the National Institute on Aging at the National Institutes of Health.
RESULTS
The analytic sample included 275,860 admission-readmission pairs representing 269,348 unique patients admitted to 3436 hospitals; 13.2% of pairs had AD. Full details of the sample development can be found in Figure 1.
The majority (66.0%; n = 182,083) of pairs were nonfragmented/same-hospital readmissions (Table); 4.6% (n = 12,641) were to hospitals that shared the same HIE, 7.3%(n = 20,006) were to hospitals with different HIEs, 5.9% (n = 16,195) of admission-readmission pairs had 1 or more hospitals that did not participate in HIE, and 16.3% (n = 44,933) of pairs had missing HIE data. Same-HIE readmissions had the lowest proportion of female beneficiaries (51.4% vs 52.5%-54.6%; P < .0001) and the highest proportion of beneficiaries living in urban areas (95.0% vs 82.4%-91.1%; P < .0001). Repeat imaging was most common in same-HIE readmissions (15.9%) and least common in nonfragmented readmissions (14.0%).
Fragmented readmissions were associated with a 5% increase in the odds of repeat imaging on the same body system for beneficiaries without AD in fully adjusted models (adjusted OR [AOR], 1.05; 95% CI, 1.02-1.08). There was no difference in the odds of repeat imaging on the same body system in fragmented readmissions for beneficiaries with AD (AOR, 0.89; 95% CI, 0.89-1.08) (Figure 2 and eAppendix D).
In fully adjusted models for beneficiaries without AD, same-HIE readmissions had a 6% increase in the odds of repeat imaging on the same body system (AOR, 1.06; 95% CI, 1.00-1.13), different-HIE readmissions had an 8% increase (AOR, 1.08; 95% CI, 1.03-1.13), and no- or missing-HIE readmissions had no difference (no HIE: AOR, 1.05; 95% CI, 0.99-1.10; missing HIE: AOR, 1.03; 95% CI, 0.96-1.11) (Figure 2 and eAppendix E). Among beneficiaries with AD, there was no significant difference between any category of information sharing and the odds of repeat imaging when comparing fragmented readmissions with nonfragmented readmissions.
Results for the sensitivity analysis on beneficiaries with only 1 admission-readmission pair in the data set were similar to the primary analysis (eAppendix F). There was no difference in the odds of repeat imaging on the same body system across any category among beneficiaries with 2 or more admission-readmission pairs or among beneficiaries who had an MRI during their index admission (eAppendices F and G). Beneficiaries without AD with same-HIE readmissions had 34% higher odds of having more than 1 instance of repeat imaging on the same body system compared with those with a single repeat image (AOR, 1.34; 95% CI, 1.02-1.75); there was no difference in the odds of having more than 1 instance of repeat imaging vs only 1 instance of repeat imaging for all other HIE statuses and for beneficiaries with AD (eAppendix H). When repeat imaging on the same body system was limited to admissions and/or readmissions with advanced imaging, same-HIE readmission was associated with 58% higher odds of repeat imaging on the same body system among older adults without AD when hospitals shared an HIE (AOR, 1.58; 95% CI, 1.00-2.49). Admission-readmission pairs for which no HIE was available were associated with 76% higher odds of repeat imaging on the same body system among beneficiaries without AD (AOR, 1.76; 95% CI, 1.20-2.58) (eAppendix I).
DISCUSSION
In this study, we found an increase in the odds of repeat imaging among beneficiaries without AD during a fragmented readmission when electronic health information sharing was available. However, contrary to our hypothesis, we found no difference in the odds of repeat imaging during readmissions for beneficiaries with AD regardless of whether the readmission was fragmented or health information sharing was available.
For older adults without AD, these results suggest that the availability of information sharing between hospitals is not enough to mitigate the increased odds of repeat imaging associated with fragmented care. These findings are in line with previous work that found increased odds of repeat imaging when providers had access to a patient’s prior images.10 Possible reasons for this association could include that it is easier to order a test instead of searching through an HIE for past results10 or that the information the clinician is seeking is not available in the HIE. In previous studies, lack of necessary information was a top reason that providers did not more frequently access HIE.21,22 This reflects an important limitation of this and all studies in which “HIE presence” is substituted for “HIE use by providers.”23-26
Limitations
We were not able to detect differences in the odds of repeat imaging among older adults with AD based on fragmented readmission status or the presence of HIE. Although Medicare beneficiaries with AD represented a significantly smaller segment of the overall study population, our results may align with those of studies suggesting that low-value care is prevalent in dementia,27 leading to similar levels of repeat imaging observed across settings of care with different types of information sharing. Studies, including mixed-methods studies, could further evaluate the potential factors influencing these findings.
There are other limitations of this study. First, responses to the AHA IT Supplement may introduce differential misclassification bias into our exposure categories, as hospitals with lower health IT capabilities may be less likely to respond to this survey. We attempted to mitigate this limitation through our sensitivity analyses, which did not alter the results. In the future, studies should aim to directly measure HIE use rather than relying on the proxy of “HIE available.” Second, we did not include imaging type as part of our outcome measure, and we must acknowledge that not all repeat imaging is wasteful. If a patient arrives with stroke symptoms, they should get imaging no matter when previous imaging was done or what it showed. This may be particularly pertinent to older adults with AD, in whom many acute illnesses present with altered mental status, motivating clinicians to obtain imaging to further investigate. Third, our approach might mask appropriate repeat imaging informed by results of outside radiology procedures—for example, a chest CT ordered during a readmission to evaluate findings from a previous chest x-ray reviewed via HIE. Teasing apart appropriate vs inappropriate repeat imaging will be important in future work.
CONCLUSIONS
If reducing repeat imaging procedures is a goal to decrease low-value care, these results demonstrate that for most older adults, HIEs do not appear to be contributing to that goal. It is important to note that we do not have data on what types of radiology information (reports, imaging, or other pieces of data) are shared via these HIEs. The technology to share radiology images exists; radiology image file types are standardized,28 so images are interoperable across platforms. However, images often remain siloed within hospitals and health systems. Sharing radiology images nationwide and making them easy to access could have tangible benefits for patients and the health care system. Future work should also seek to understand how providers perceive information from outside sources. Perhaps a repeat imaging test is ordered because the provider does not trust the interpretation from another hospital. This is also a situation in which having access to the images themselves could be beneficial.29,30 Although health care systems have the tools to address this type of low-value care, they may have limited incentives to correct it when they are reimbursed on a fee-for-service basis and not penalized for repeat imaging. Other invested parties, such as the federal government, should support additional research and policy changes to increase interoperability of and access to images and radiology reports across settings of care and to reduce the rates of duplicate imaging for all patients.
Acknowledgments
The authors would like to thank Kenneth Hepburn, PhD, for his contributions to the manuscript.
Author Affiliations: Division of General Internal Medicine (SDT) and Division of Geriatrics and Gerontology (ECV), Department of Medicine, Emory University School of Medicine, Atlanta, GA; Department of Family and Preventive Medicine, Emory University School of Medicine (SDT, MKA), Atlanta, GA; Department of Health Policy and Management (SDC, MMP) and Hubert Department of Global Health (MKA), Rollins School of Public Health, Emory University, Atlanta, GA; Department of Veterans Affairs, Birmingham/Atlanta Geriatric Research Education and Clinical Center (ECV), Atlanta, GA; Nell Hodgson Woodruff School of Nursing, Emory University (CKC), Atlanta, GA; Alliant Health Group (KJR), Atlanta, GA.
Source of Funding: Research reported in this publication was supported by the National Institute on Aging of the National Institutes of Health (NIH) under award No. K23AG065505 and by the Program for Retaining, Supporting, and EleVating Early-career Researchers at Emory (PeRSEVERE) from Emory School of Medicine, by a gift from the Doris Duke Charitable Foundation, and through the Georgia Clinical and Translational Science Alliance NIH award (UL1-TR002378). This material is the result of work supported with resources and the use of facilities at the VA Atlanta Healthcare System. The content is solely the responsibility of the authors and does not necessarily represent the official views of the NIH or the Department of Veterans Affairs. The sponsors had no role in the design, methods, subject recruitment, data collection, analysis, or preparation of the manuscript.
Author Disclosures: Dr Turbow has provided expert testimony services to Hocde Dassow + Deets on topics unrelated to this research. The remaining authors report no relationship or financial interest with any entity that would pose a conflict of interest with the subject matter of this article.
Authorship Information: Concept and design (SDT, SDC, ECV, KJR, CKC, MKA); acquisition of data (SDT); analysis and interpretation of data (SDT, SDC, ECV, MMP); drafting of the manuscript (SDT, KJR, MMP, CKC); critical revision of the manuscript for important intellectual content (SDT, SDC, ECV, KJR, MMP, CKC, MKA); statistical analysis (SDT, SDC); provision of patients or study materials (SDT); obtaining funding (SDT); administrative, technical, or logistic support (CKC, MKA); and supervision (MKA).
Address Correspondence to: Sara D. Turbow, MD, MPH, Emory University School of Medicine, 49 Jesse Hill Jr Dr SE, Atlanta, GA 30303. Email: Sara.turbow@emory.edu.
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