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Factors associated with VHA costs of care for first 12 months after first stroke.


Stroke is the second most frequent cause of death and the most common cause of invalidity in adults worldwide [1], as well as the leading cause of long-term disability in the United States [2]. More than 700,000 Americans experience a new or recurrent stroke each year [3]. The estimated direct costs exceeded $31 billion in 2003 [4].

Stroke-related diseases cost the Veterans Health Administration (VHA) at least $1 billion each year [5]. This figure is expected to increase significantly in the next 20 years as more veterans reach an age at which stroke is more likely to occur [6-7]. This article examined the use patterns and costs of care of a validated VHA stroke cohort (n = 172) over a 1-year period. Decision Support System (DSS) cost and use data (inpatient and outpatient) were profiled for the cohort. From a policy perspective, it is important to differentiate the costs associated with inpatient and outpatient care and to consider the relationship between the type of setting (inpatient vs outpatient), characteristics of the stroke, and patient functional outcomes. Accurate, detailed assessments of the costs of stroke care are needed to help policy makers allocate scarce healthcare resources. We analyzed the relationship between cost of stroke care to the VHA, location of service (inpatient and outpatient), stroke characteristics, and patient functional outcomes by using the Modified Rankin Scale (MRS), a global disability measure [8-12], and the Functional Independence Measure (FIM) [13].


Several studies report the cost of poststroke care. Matchar and Duncan examined Medicare claims data to gain insight into the costs of stroke care 90 days poststroke [14]. A little more than half (57%) of the costs of stroke were represented by direct medical costs (e.g., hospitalization, nursing home care, physicians' fees, and medical equipment). The remaining 43 percent consisted of indirect costs from lost wages. The average cost of stroke care during the first 90 days after stroke was $15,000 (1991 dollars). Lee et al. used a 20 percent sample of the 1991 national Medicare claims data to examine stroke costs during the initial 6 months poststroke [15]. The researchers found that the average total per patient cost of care for the first 6 months poststroke was $18,626, with 60 percent of the poststroke expense incurred in acute care settings. Freburger explored the costs of poststroke care by using the 1996 University Health System Consortium Clinical Database [16]. The mean total direct cost associated with stroke care was $9,146 per patient, and the mean direct physical therapy charge for acute care was $527 per patient. Further, physical therapy use was significantly associated with the cost of poststroke care.

Within the Department of Veterans Affairs (VA) system, however, little is known about the costs incurred for stroke care. Various methods of examining the costs of stroke care in the VHA have been discussed, including the advantages, disadvantages, and assumptions associated with each of five methods: direct assessment of costs, list costing, estimations using regression analysis, average cost data based on Health Economics Resource Center data, and DSS National Data Extracts (NDE) data [17]. DSS costs are based on actual resource consumption (not charges or payments) in both direct patient care cost centers (e.g., inpatient wards) and indirect cost centers (e.g., housekeeping). DSS uses a system of intermediate product accounts to allocate costs incurred in indirect work centers to direct patient care cost centers where attribution to individual patients is possible. This allocation is based on a number of mechanisms, including physical measurements (e.g., square footage) and relative value units specific to DSS. Recently, DSS costs have become the basis for development of the VHA budget and have gained increasing credibility as the DSS cost accounting system has been developed and refined.

Validation of VHA DSS-NDE data is still necessary, however, for at least two reasons: (1) DSS remains a relatively new tool available to researchers and (2) incomplete reporting can pose serious challenges to the validity of extracts [17-18]. Also, one should note that DSS only captures VA-specific cost and use and does not include any non-VA healthcare consumed by our sample. This limitation of our study was unavoidable and limited the perspective of our analyses to the VA as opposed to total societal costs and use.



The subjects for this research were recruited as part of a larger clinical survey designed to compare telephone versus mail administration of the Stroke Impact Scale (SIS), a 59-item instrument assessing eight dimensions of patient health and the overall burden of stroke [19]. Thirteen VA medical centers participated in this retrospective/ prospective study. Potential stroke patients were identified by International Classification of Diseases-9th Revision diagnosis codes that have been shown to be highly sensitive to stroke capture [20]. The larger clinical study was approved by human subject committees at all participating VA sites of care.

Patient Selection and Variable Definitions

A trained research coordinator reviewed electronic medical records (VHA VISTA [Veterans Health Information Systems and Technology Architecture]) to validate the stroke diagnosis either by clinical or imaging diagnosis. Stroke patients who survived their index hospitalization were randomly assigned to one of two survey methods for SIS administration: mail or telephone. A letter of introduction and a consent form were mailed to each survey recipient. Following informed consent, patients were surveyed (by either mail or telephone) with the SIS at 12 weeks poststroke. At 16 weeks poststroke, all patients were resurveyed (by telephone only) with the FIM [13] and the 36-item Short Form Health Survey for Veterans (SF-36V) [21]. The following information was abstracted from the medical record: age, sex, race, marital status, next of kin, provider specialty, stroke diagnosis source, stroke type and location, functional status at discharge, history of prior stroke, prior functional status, prior neurological symptoms, cognitive impairment on discharge, and pre- and poststroke MRSs.

Modified Rankin Scale--Derived Functional Measure

The MRS is scored along a continuum ranging from 0 to 6, with 0 representing "no symptoms at all" and 6 indicating "death" [22]. A person whose score is a 1 may have symptoms but no significant disability and be able to carry out all usual duties and activities. Similarly, a score of 2 indicates "slight disability" and the person is usually unable to carry out all previous activities but can look after his or her own affairs without assistance. A score of 3 indicates "moderate disability" and the person requires some help but is able to walk without assistance.

A score of 4 indicates "moderately severe disability" and the person is unable to walk without assistance and cannot attend to his or her own bodily needs without assistance. A score of 5 indicates "severe disability" and the person is usually bedridden and incontinent and requires constant nursing care and attention.

Study Subgroup Variables

The FIM, an 18-item instrument with two domains, motor (13 items) and cognition (5 items), is the most widely used instrument in the United States to measure activities of daily living function in all rehabilitation populations [13]. The FIM has been adopted by the VHA as the standard for functional measurement; has been mandated for use in VA patients with stroke, amputation, and traumatic brain injury; and forms the basis for the VA-wide Functional Status Outcomes Database that is integrated nationally within the Computerized Patient Record System and housed at the Austin Information Technology Center (AITC). The SF-36V is a veterans-pecific adaptation of the 36-item Short Form, developed as part of the Medical Outcomes Study, and is perhaps the most commonly used measure of health-related quality of life [21]. The instrument has 36 items in eight domains and has a physical and mental summary scale.

From the DSS-NDE cost files located at the AITC, VA cost data were obtained for VHA use and costs only (i.e., no out-of-system use was measured). All inpatient and outpatient cost data associated with each unique patient identifier were collected from the index stroke admission through 12 months (based on the hospital admission date for the index stroke). Patients who died during the 12-month period were excluded from the descriptive analyses. Descriptive statistics were generated using SAS, version 8.2 (SAS Institute Inc; Cary, North Carolina). Statistical tests (t-tests and F-tests) were run on all cost comparisons for continuous and categorical variables thought to be associated with costs. Costs were aggregated for two time periods: (1) a 3-month period from stroke onset to SIS evaluation and (2) from 3 months poststroke (SIS evaluation) to 12 months poststroke. Costs for total, inpatient, and outpatient services were aggregated as well. Small sample sizes in some categories limit our ability to draw conclusions and require that results be interpreted with caution.


Screening of medical records yielded 458 patients with a valid diagnosis of stroke. Two-hundred thirty-five of the patients (51%) completed the SIS evaluation by telephone or mail. Forty-nine participating patients were dropped from the study according to institutional review board rules because consent forms were not returned or were incomplete (no witness signature). The study sample consisted of 186 validated stroke patients, representing 41 percent of the surveyed sample. All patients received treatment for stroke from May 2001 through September 2002 in 13 VA medical centers with an average bed capacity of 275 (standard deviation [SD] = 175) and a range of 60-688 beds. Table 1 is a comparison of the 186 complete responders and the 272 validated stroke patients who either did not respond to the survey or were dropped because of invalid consents. A t-test was used to compare responders and nonresponders on continuous variables (age) and the chi-square statistic was used for categorical variables (all remaining comparisons). Two baseline characteristics were statistically different between the groups: the responders were more often married (60% vs 42%, respectively) and had fewer cognitive deficits at acute care discharge (16% vs 30%, respectively) than nonresponders. These two characteristic differences are likely causal in relationship to survey response and should be expected in survey studies of older and potentially more impaired populations.

Prior studies on the stroke cohort used in this study focused on the effect of SIS administration mode and on the construct validity of the SIS [23-24]. Findings from the article on SIS administration mode included (1) mail nonresponders were more likely to have had severe strokes, have cognitive deficits, and be unmarried; (2) telephone responders and nonresponders were not different; (3) mail and telephone responders were not different, and the SIS score distribution did not indicate the presence of mode effects; (4) telephone mode of administration yielded a higher response rate; (5) test-retest reliability was good to excellent for seven SIS domains in the mail group (0.77-0.99), except social participation (0.62); and (6) test-retest reliability was excellent in the telephone group (0.90-0.99), except emotion (0.68) [23]. For additional details on the study methodology and results, see Duncan and colleagues [23] and Kwon and colleagues [24]. In general, these findings support both the broad consistency of the SIS across modes of administration and the use of these data for the current exploratory research.

Tables 2-5 contain the 186 validated stroke patients in the original sample less the 14 patients who died during the follow-up period, resulting in an analytic sample of 172 for all cost and use analyses. Table 2 provides aggregate cost data and use by admission period (time 0- 3 months poststroke and time 4-12 months poststroke) and delivery setting (inpatient and outpatient). Nearly 66 percent of the mean total inpatient and outpatient costs were accrued for patients in time 0-3 months ($15,375). While the majority of stroke costs were associated with inpatient care occurring 0-3 months poststroke ($12,547), about 33 percent of the mean total costs resulted from care received on an outpatient basis ($2,829 in time 0- 3 months plus $5,710 for time 4-12 months). Finally, the study sample distributions were skewed right, as noted by the higher mean costs than median costs, as expected when studying healthcare costs.

Median costs in Table 3 are broken down into clinical categories such as stroke type and location, comorbidities, stroke severity (MRS), and bed section at discharge.

Variation is observed across all inpatient, outpatient, and total cost categories as well as by stroke type and location.

Most notable among the cost variations are the graduated increases in costs with each incremental increase in the number of comorbidities and stroke disability increases (MRS), especially the MRS unit increase from 2 to 3. A general linear model (GLM) (univariate Proc GLM) indicated that outpatient costs in time 4-12 months were significantly greater for stroke patients who had more comorbid health conditions (p = 0.04). Similarly, the MRS at discharge was related to inpatient costs in time 0-3 months (p < 0.001), all costs in time 0-3 months (p < 0.001), and total inpatient and outpatient costs (p < 0.001). Higher MRS at discharge corresponded to higher inpatient costs.

Table 4 lists median costs broken down by the Veterans Integrated Service Network (VISN) structure and site(s) within each VISN, patient discharge location, and facility characteristics. Median costs varied considerably across VISNs, with sites in VISNs 12, 17, and 23 ranging about 55 percent higher than the lowest total cost category (VISN 8), although these comparisons are limited by the small sample sizes in these VISNs. A GLM (univariate Proc GLM) indicated that the cost of care associated with inpatient days and total patient costs was significantly greater for patients who discharged to an acute care hospital or nursing home as opposed to remaining in the community (e.g., at home) (p < 0.001). Further, the number of outpatient visits in time 4-12 months was significantly higher for stroke patients in facilities with more than 200 beds (p = 0.04). The results only address VHA use and costs, and out-of-system use is not measured.

Table 5 displays median costs by patient age group and patient function as measured by the SF-36V and FIM. A GLM (univariate Proc GLM) revealed that age appears to be related to greater costs associated with inpatient days (p = 0.03). Median costs for the entire 12-month period may exhibit this trend best. The cost of stroke care is the greatest for patients who are in the youngest (35-44 years) and the oldest (85+ years) age categories. However, the small sample sizes for these age categories limit our ability to draw conclusions and suggest the need for further investigation. Median FIM motor scores measured at 3 months poststroke appear to have the strongest association with stroke costs. Increased median costs are graduated across the quartiles of motor function and appear monotonic. Median inpatient costs at time 0-3 months are 2.4 times higher among patients with FIM motor scores in the lowest quartile than among patients with FIM motor scores in the highest quartile.

Median costs across the quartiles of the SF-36V follow a similar but not identical pattern. Results of a GLM (univariate Proc GLM) indicated significantly higher inpatient costs (time 0-3 months and total costs time 0-3 months; both p < 0.001), outpatient costs (time 4-12 months; p = 0.03), and total costs (p < 0.001) for stroke patients with greater functional limitations as measured by the FIM (p < 0.001). Stroke patients who had lower scores on the SF-36V physical functioning subscale had significantly greater costs associated with inpatient days (p = 0.01). Increased stroke costs may be associated with increasing stroke impact in later years, increased comorbidities as seen in Table 3, or a combination of the two.

The Figure displays the median costs for inpatient care (time 0-3 months), outpatient care (time 4- 12 months), and total care (time 0-12 months) across deciles of the SIS physical dimension at 3 months poststroke. Higher SIS scores reflect improved patient health and lower stroke burden. We inserted trend (regression) lines for each variable using Microsoft Excel software (Microsoft Corporation; Redmond, Washington). For 171 valid physical dimension scores, the mean score was 59, median 62, SD 26, minimum 1.3, and maximum 100 (higher SIS scores indicate better functioning). Each regression line has a substantial negative slope, although the outpatient slope is difficult to see as a result of the larger scale needed for inpatient care. The actual decrease for outpatient median costs from the first decile to the last decile was from $5,251 to $2,581, representing a 51 percent reduction. Inpatient median costs decreased from $9,196 to $3,670 (60% reduction) across the deciles, and total median costs decreased from $23,706 to $15,676 (34% reduction).


The present article reports several important findings. First, since stroke can manifest along a continuum of severity, one would expect to identify variation in median costs across these categories. DSS costs do indeed vary with function (as indicated by the FIM), health and disability status (assessed using the SF-36V and MRS, respectively), and the number of comorbidities. Second, variation in median costs by discharge location was also observed in the expected direction. The patients discharged to both nursing homes and other acute settings were typically the most severely affected patients with the highest costs. Third, although the majority of stroke costs are still accrued from inpatient admissions in time 0-3 months poststroke, about 33 percent of the total annual costs occur on an outpatient basis. Fourth, there appears to be substantial variation in median patient-specific costs by facility. Such variation is likely caused by differences in factors such as case-mix, severity, teaching status, quality of care, geographic wage differences, scale economies, and efficiency. Future work is necessary to measure the relative contributions of such factors to the observed differences.


Documenting the costs associated with patient care in all care settings and considering the relationship with patient functional outcomes are important. Future research should examine the relationship between costs and functional outcomes by using a larger cohort and multivariate modeling techniques to better estimate the relationship between rehabilitation unit type, costs, and functional outcomes and health status, while controlling for covariates such as patient characteristics, baseline functional and health status, and facility characteristics (e.g., facility size, bed capacity).


This study relied on a limited sample of VHA stroke patients from a previous study investigating the effects of the mode of SIS administration. As such, the sample was not selected specifically for the study of costs and some systematic differences (marital status and cognition) between the analytic and overall samples were noted. Moreover, this descriptive study did not control for the myriad of factors that influence costs, and hence, the results presented here should be viewed as preliminary. In addition, the results only address VHA use and costs; out-of-system use was not measured. This out-of-system use is likely to be significant for veterans with other sources of care and coverage (e.g., veterans enrolled in Medicare). Finally, the small sample size in some stratified categories should be noted and the results interpreted with caution.


Several conclusions can be drawn from the present article. Our examination of inpatient- and outpatient-use figures found in the data suggest that DSS costs correlate well with expected use patterns 3 and 12 months poststroke. For example, higher costs were reported for patients who had greater impairments, had longer inpatient stays, had more outpatient visits, and were discharged to nursing homes. Thus, our results are clinically intuitive and consistent with other studies examining the costs of stroke care among VA (and non-VA) patients, lending credence to the use of DSS in cost studies. A significant variation in median patient costs by facility was documented, suggesting that the factors driving such variations need to be identified and their relative contributions measured. Finally, examination of a validated stroke cohort for a full 12-months indicates that about a third of the costs of care in the VHA over a 12-month period occur on an outpatient basis. These data provide a first look at VHA costs for stroke care. Future studies could extend these results with a sample that is larger and national in scope.

Abbreviations: AITC = Austin Information Technology Center, DSS = Decision Support System, FIM = Functional Independence Measure, GLM = general linear model, MRS = Modified Rankin Scale, NDE = National Data Extracts, SD = standard deviation, SF-36V = 36-item Short Form Health Survey for Veterans, SIS = Stroke Impact Scale, VA = Department of Veterans Affairs, VHA = Veterans Health Administration, VISN = Veterans Integrated Service Network.


Dr. Reker is now with the VA Information and Resource Center, Center for the Management of Complex Chronic Care, Edward Hines Jr VA Hospital, Hines, Illinois.

This material was based on work supported by the VA Office of Research and Development, Health Services Research and Development Service (project STI20029-1).

The authors have declared that no competing interests exist.

Submitted for publication September 25, 2007. Accepted in revised form May 28, 2008.


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Jeanne Hayes, PhD; (1) * Bruce Vogel, PhD; (2-3) Dean M. Reker, PhD (1)

(1) Kansas City Department of Veterans Affairs (VA) Medical Center, Kansas City, MO; (2) North Florida/South Georgia VA Medical Center, Gainesville, FL; (3) Department of Epidemiology and Health Policy Research, College of Medicine, University of Florida, Gainesville, FL

* Address all correspondence to Jeanne Hayes, PhD; Kansas City VA Medical Center, Research Service, 4801 Linwood Blvd, Kansas City, MO 64128; 816-861-4700, ext 57694; fax: 816-861-1110. Email:

Table 1.
Baseline characteristics of survey responders and nonresponders. Data
shown as No. (%), unless otherwise indicated.

 Variable (n = 186)

Age (mean [+ or -] standard deviation) 68.4 [+ or -] 11.0
Female 1 (0.5)
 White 128 (69)
 Black 24 (13)
 Hispanic 1 (0.5)
 Asian 8 (4)
 Other 1 (0.4)
 Missing 24 (13)
Marital Status
 Married 107 (60)
 Divorced/Separated 23 (13)
 Widowed 15 (8)
 Never Married 11 (6)
 Missing 22 (12)
Ischemic Stroke (%) 93.5
Prestroke Modified Rankin Scale Score
 0 = No symptoms at all 94 (51)
 1 = Symptoms, no significant
 disability 37 (20)
 2 = Slight disability 23 (12)
 3 = Moderate disability 9 (5)
 4 = Moderately severe disability 6 (3)
 5 = Severe disability 1 (1)
 Missing 16 (9)
Previously Resided in Community 180 (97)
Prior Stroke 69 (26)
Prior Neurological Symptoms 30 (11)
Poststroke Modified Rankin Scale Score
 0 = No symptoms at all 8 (4)
 1 = Symptoms, no significant
 disability 37 (20)
 2 = Slight disability 40 (22)
 3 = Moderate disability 51 (27)
 4 = Moderately severe disability 37 (20)
 5 = Severe disability 7 (4)
 Missing 6 (3)
Cognitive Deficit at Discharge 30 (16)
Aphasia 34 (18)

 Variable (n = 272) p-Value

Age (mean [+ or -] standard deviation) 67.8 [+ or -] 12.0 0.74
Female 7 (1.5) 0.10
Race/Ethnicity 0.12
 White 167 (61)
 Black 51 (19)
 Hispanic 5 (2)
 Asian 2 (1)
 Other 12 (4)
 Missing 35 (13)
Marital Status 0.00
 Married 109 (42)
 Divorced/Separated 67 (26)
 Widowed 34 (13)
 Never Married 16 (6)
 Missing 35 (13)
Ischemic Stroke (%) 94.1 0.65
Prestroke Modified Rankin Scale Score 0.87
 0 = No symptoms at all 138 (51)
 1 = Symptoms, no significant
 disability 47 (17)
 2 = Slight disability 33 (12)
 3 = Moderate disability 21 (8)
 4 = Moderately severe disability 12 (4)
 5 = Severe disability 1 (0)
 Missing 20 (7)
Previously Resided in Community 249 (92) 0.07
Prior Stroke 77 (35) 0.61
Prior Neurological Symptoms 42 (18) 0.13
Poststroke Modified Rankin Scale Score 0.36
 0 = No symptoms at all 14 (5)
 1 = Symptoms, no significant
 disability 50 (18)
 2 = Slight disability 40 (15)
 3 = Moderate disability 73 (27)
 4 = Moderately severe disability 63 (23)
 5 = Severe disability 20 (7)
 Missing 12 (4)
Cognitive Deficit at Discharge 82 (30) 0.002
Aphasia 52 (19) 0.34

Source: Data extracted from Department of Veterans Affairs (VA)
Decision Support System as merged with VA medical SAS data sets.

Table 2.
Mean and median inpatient and outpatient costs and use 012 mo after
first stroke.

 Variable n Sum Mean

 Cost ($)
 Time 0-3 mo 172 2,158,072 12,547
 Time 4-12 mo 172 737,239 4,286
 Days (No.)
 Time 0-3 mo 172 2,492 14
 Time 4-12 mo 172 769 4
 Cost ($)
 Time 0-3 mo 172 486,505 2,829
 Time 4-12 mo 172 982,173 5,710
 Day Visits ([dagger])(No.)
 Time 0-3 mo 172 1,309 8
 Time 4-12 mo 172 3,013 18
 Clinic Stops([double dagger]) (No.) 169 2,482 14
 Time 0-3 mo 169 4,882 29
 Time 4-12 mo
Inpatient & Outpatient Costs ($)
 Total Time 0-3 mo 172 2,644,577 15,375
 Total Time 4-12 mo 172 1,719,412 9,997
 Grand Total 1-2 mo 172 4,363,989 25,372

 Variable Median Deviation

 Cost ($)
 Time 0-3 mo 7,085 15,253
 Time 4-12 mo 0 * 11,883
 Days (No.)
 Time 0-3 mo 7 25
 Time 4-12 mo 0 * 15
 Cost ($)
 Time 0-3 mo 2,159 2,414
 Time 4-12 mo 4,049 5,268
 Day Visits ([dagger])(No.)
 Time 0-3 mo 7 5
 Time 4-12 mo 14 18
 Clinic Stops([double dagger]) (No.) 12 10
 Time 0-3 mo 21 27
 Time 4-12 mo
Inpatient & Outpatient Costs ($)
 Total Time 0-3 mo 10,063 15,273
 Total Time 4-12 mo 5,101 13,840
 Grand Total 1-2 mo 18,374 22,450

Source: Data extracted from Department of Veterans Affairs (VA)
Decision Support System as merged with VA medical SAS data sets.

* Value of zero indicates that more than half our sample had no
hospitalizations in months 412.

([dagger]) Veterans Health Administration defines "day visits" as
visit to VA facility on any given day.

([double dagger]) During a "Day Visit," the patient may visit one or
more outpatient department(s). Visits to one or more outpatient
clinics during a "Day Visit" are defined as "Clinic Stops."

Table 3.
Median inpatient and outpatient costs by clinical characteristics,
discharge bed section, and survival status.

 Time 0-3 Mo Costs ($)
 Variable n
 Inpatient Total

Stroke Type
 Ischemic 163 7,236 10,527
 Hemorrhagic 9 4,437 8,603
Stroke Location
 Right Hemisphere 57 7,922 10,010
 Left Hemisphere 68 6,389 9,268
 Brain stem 26 7,404 10,696
 Cerebellar 7 7,852 16,215
 Bilateral 3 21,555 21,889
No. Elixhauser Comorbidities
 0 25 4,988 7,290
 1 59 7,247 11,439
 2 48 7,082 10,513
 3 30 8,571 12,001
 4 9 9,017 11,265
 5 1 32,095 36,287
Poststroke Modified Rankin Scale
 0 = No symptoms at all 8 5,014 7,044
 1 = Symptoms, no significant 35 4,025 6,159
 2 = Slight disability 39 5,767 7,885
 3 = Moderate disability 48 8,249 11,723
 4 = Moderately severe disability 34 19,197 22,156
 5 = Severe disability 2 17,097 18,670
Discharge Bed section
 Neurology 65 6,145 9,633
 General Medicine 77 7,922 11,955
 Intermediate Medicine (subacute 20 6,839 8,430
 hospital bed)

 Time 4-12 Mo
 Costs ($)
 Variable Grand Total
 Outpatient Total Costs ($)

Stroke Type
 Ischemic 4,220 5,138 18,349
 Hemorrhagic 3,529 3,578 18,399
Stroke Location
 Right Hemisphere 4,082 5,727 19,218
 Left Hemisphere 4,332 5,915 19,113
 Brain stem 3,136 4,150 15,824
 Cerebellar 4,253 4,253 25,244
 Bilateral 1,355 1,355 23,244
No. Elixhauser Comorbidities
 0 3,084 4,471 14,174
 1 4,122 5,344 16,497
 2 4,049 4,269 19,044
 3 4,619 5,446 23,218
 4 5,602 6,243 21,475
 5 8,812 14,543 50,830
Poststroke Modified Rankin Scale
 0 = No symptoms at all 4,108 4,321 14,901
 1 = Symptoms, no significant 3,433 5,727 12,637
 2 = Slight disability 3,414 3,994 12,751
 3 = Moderate disability 5,329 6,811 23,218
 4 = Moderately severe disability 4,231 5,154 30,971
 5 = Severe disability 5,795 9,958 28,628
Discharge Bed section
 Neurology 4,325 6,044 17,220
 General Medicine 3,656 4,471 18,399
 Intermediate Medicine (subacute 4,162 4,790 14,097
 hospital bed)

Source: Data extracted from Department of Veterans Affairs (VA)
Decision Support System as merged with VA medical SAS data sets.

Table 4.
Median costs by Veterans Integrated Service Network (VISN), patient
discharge location, and facility characteristics.

 Time 0-3 Mo Costs ($)
 Variable n
 Inpatient Total
 VISN 1 (1 site) 7 5,471 13,917
 VISN 4 (1 site) 4 6,850 9,684
 VISN 8 (1 site) 12 5,790 7,414
 VISN 9 (1 site) 2 11,480 14,723
 VISN 10 (1 site) 10 4,485 7,391
 VISN 12 (1 site) 15 10,497 16,080
 VISN 15 (3 sites) 64 7,074 9,562
 VISN 16 (1 site) 12 6,245 7,874
 VISN 17 (1 site) 31 11,011 13,259
 VISN 18 (1 site) 3 6,358 9,061
 VISN 23 (1 site) 12 5,956 9,979
Discharge Location
 Community/AMA 146 6,162 9,073
 Other Acute Care Hospital 4 23,736 25,201
 Nursing Home 22 20,358 24,144
Facility Size
 <200 Beds 81 5,620 8,233
 >200 Beds 91 8,369 11,955

 Time 0-3 Mo
 Inpatient Days

Use by Facility Size
 Days/Visits (Median)
 <200 Beds 81 7
 >200 Beds 91 8
 Cost/Day/Visit ($)
 <200 Beds 81 1,022
 >200 Beds 91 990

 Time 4-12 Mo
 Costs ($)
 Variable Grand Total
 Outpatient Total Costs ($)
 VISN 1 (1 site) 4,286 4,286 16,497
 VISN 4 (1 site) 3,242 3,242 14,097
 VISN 8 (1 site) 2,368 2,368 10,356
 VISN 9 (1 site) 7,404 8,847 23,570
 VISN 10 (1 site) 3,772 3,772 11,169
 VISN 12 (1 site) 6,950 10,649 23,598
 VISN 15 (3 sites) 3,105 3,641 15,272
 VISN 16 (1 site) 4,141 6,024 17,490
 VISN 17 (1 site) 4,250 5,862 23,244
 VISN 18 (1 site) 2,807 2,807 14,126
 VISN 23 (1 site) 12,858 13,531 23,598
Discharge Location
 Community/AMA 4,049 5,194 15,958
 Other Acute Care Hospital 4,585 7,574 30,614
 Nursing Home 3,955 4,541 30,130
Facility Size
 <200 Beds 3,625 4,253 14,174
 >200 Beds 4,250 6,044 20,229

 Time 4-12 Mo
 Outpatient Visits
Use by Facility Size
 Days/Visits (Median)
 <200 Beds 11 --
 >200 Beds 17 --
 Cost/Day/Visit ($)
 <200 Beds 326 --
 >200 Beds 309 --

Source: Data extracted from Department of Veterans Affairs (VA)
Decision Support System as merged with VA medical SAS data sets. AMA =
against medical advice.

Table 5.
Median costs by patient age and function.

 Time 0-3 Mo Costs ($)
 Variable n
 Inpatient Total
Age Group
 35-44 2 26,084 28,143
 45-54 23 6,803 8,417
 55-64 35 6,358 9,335
 65-74 53 7,047 10,209
 75-84 56 9,017 11,784
 85+ 3 21,384 22,042
Most and Least Impaired
 FIM Motor
 Lowest Two Quartiles 71 11,885 13,462
 Highest Two Quartiles 76 5,018 7,500
 SF-36V Physical Dimension
 Lowest Two Quartiles 69 9,017 11,265
 Highest Two Quartiles 79 5,476 8,233

 Time 4-12 Mo
 Costs ($) Grand
 Variable Total
 Outpatient Total Costs ($)
Age Group
 35-44 2,052 2,052 30,196
 45-54 4,122 5,805 14,442
 55-64 4,253 4,471 18,349
 65-74 3,701 5,178 18,112
 75-84 4,082 5,576 19,385
 85+ 828 828 22,042
Most and Least Impaired
 FIM Motor
 Lowest Two Quartiles 5,315 6,962 24,446
 Highest Two Quartiles 3,254 3,602 13,265
 SF-36V Physical Dimension
 Lowest Two Quartiles 4,325 5,344 19,385
 Highest Two Quartiles 3,887 4,286 15,676

Source: Data extracted from Department of Veterans Affairs (VA)
Decision Support System as merged with VA medical SAS data sets. FIM =
Functional Independence Measure, SF-36V= 36-item Short Form Health
Survey for Veterans.
COPYRIGHT 2008 Department of Veterans Affairs
No portion of this article can be reproduced without the express written permission from the copyright holder.
Copyright 2008 Gale, Cengage Learning. All rights reserved.

Article Details
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Author:Hayes, Jeanne; Vogel, Bruce; Reker, Dean M.
Publication:Journal of Rehabilitation Research & Development
Article Type:Report
Date:Nov 1, 2008
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