PCD logo

Disparities in Patterns of Health Care Travel Among Inpatients Diagnosed With Congestive Heart Failure, Florida, 2011

Peng Jia, PhD; Imam M. Xierali, PhD

Suggested citation for this article: Jia P, Xierali IM. Disparities in Patterns of Health Care Travel Among Inpatients Diagnosed With Congestive Heart Failure, Florida, 2011. Prev Chronic Dis 2015;12:150079. DOI: http://dx.doi.org/10.5888/pcd12.150079external icon.

PEER REVIEWED

PEER REVIEWED

Abstract

Introduction

Congestive heart failure (CHF) is a major public health problem in the United States and is a leading cause of hospitalization in the elderly population. Understanding the health care travel patterns of CHF patients and their underlying cause is important to balance the supply and demand for local hospital resources. This article explores the nonclinical factors that prompt CHF patients to seek distant instead of local hospitalization.

Methods

Local hospitalization was defined as inpatients staying within hospital service areas, and distant hospitalization was defined as inpatients traveling outside hospital service areas, based on individual hospital discharge data in 2011 generated by a Dartmouth–Swiss hybrid approach. Multiple logistic and linear regression models were used to compare the travel patterns of different groups of inpatients in Florida.

Results

Black patients, no-charge patients, patients living in large metropolitan areas, and patients with a low socioeconomic status were more likely to seek local hospitalization than were white patients, those who were privately insured, those who lived in rural areas, and those with a high socioeconomic status, respectively.

Conclusion

Findings indicate that different populations diagnosed with CHF had different travel patterns for hospitalization. Changes or disruptions in local hospital supply could differentially affect different groups in a population. Policy makers could target efforts to CHF patients who are less likely to travel to seek treatment.

Top

Introduction

Congestive heart failure (CHF) is a major public health problem in the United States. In 2010, it was the leading cause of hospitalization in the population older than 85 years and the second leading cause of hospitalization for people aged 65 to 84 years (1). To provide all CHF patients high-quality and timely services, hospital resources must be made equally accessible for the entire population (2). However, regardless of accessibility, patients do not always go to their nearest hospitals; this fact confounds the local supply–demand relationships. Therefore, it is critical to understand the travel patterns of CHF patients and the factors that influence those patterns.

Research on the travel patterns of hospital patients has increased during the last 2 decades. Long travel distance and travel time to hospitals and other medical facilities, in addition to depriving local hospitals of revenue and deteriorating the patient–doctor relationship (3–5), are associated with decreased health-related quality of life and increased mortality risk, especially with regard to the use of emergency services (6,7). For example, long travel time to a dialysis unit is negatively associated with patients’ health-related quality of life (6). Likewise, increased travel time to the nearest hospitals providing surgery, chemotherapy, or radiotherapy for cancer patients made patients less likely to receive those services (8). A review article of determinants of delivery-service use found that distance to health services was both a disincentive to seeking care and an obstacle to receiving care (9). Compared with its role in developed countries, travel distance affects the use of health care services more in low- and middle-income countries, especially in rural areas (10).

Many factors affect patients’ decisions to seek medical services within or outside of their residence counties. In one study, patients aged 75 or older were less likely to travel across county boundaries to seek treatment (4). Racial/ethnic disparities in travel patterns for care seeking were reported by several studies, and it was consistently found that, compared with whites, nonwhites were less likely to travel long distances for hospitalization for referral-sensitive surgeries or ambulatory care-sensitive admissions, even when they were severely ill (11–13). Lack of health insurance is a crucial determinant of patients’ choosing to stay in their residence county for hospitalization (13). In addition to age, race/ethnicity, and health insurance status (13–16), other factors that influence travel patterns are sex, severity of illness (13), patient location (15), and socioeconomic status (SES) (11,17).

Traveling to hospitals outside a patient’s county of residence is often classified as a longer-than-normal trip (18). However, some patients live closer to hospitals outside than inside their county of residence (3). Therefore, administrative unit boundaries may not represent underlying local patterns of hospital travel as well as do hospital service areas (HSAs) (19), a series of functional areas in which most patients live and go to a hospital or group of hospitals (20). In this study, being hospitalized in a patient’s HSA is defined as local hospitalization, and traveling outside a patients’ HSA is defined as distant hospitalization.

Distinct from most empirical studies, which have focused on minority groups that had less accessibility to hospitals and other medical resources, the objective of this study was to explore the nonclinical characteristics of CHF patients attributable to distant instead of local hospitalization. We integrated all factors that influence the travel patterns of CHF patients and examined them to determine whether disparities in patterns exist; in addition to demographic characteristics, we considered the presence of comorbidities. Conclusions will aid in identifying the factors associated with patients’ travel patterns and informing policy makers of populations that are most affected by the changes in local hospital resources, such as reduction in the number of beds or hospital closure.

Top

Methods

Data from the Agency for Healthcare Research and Quality’s (AHRQ’s) State Inpatient Database (SID), part of the Healthcare Cost and Utilization Project (HCUP), which includes individual discharge records from all hospitals in Florida during the year 2011, was used in this study (21). Florida is considered an ideal region for examining the travel patterns of inpatients (3). Each record includes a range of demographic and socioeconomic characteristics. Using the zip code of residence of inpatients, individual discharge records can be geocoded at the zip code level. “Patient” and “inpatient” are interchangeably used in this study.

Clinical Classification Software developed by AHRQ was used to identify all hospital discharges diagnosed with CHF (coded as 108, nonhypertensive), which ranked second by the number of discharges among all diagnosis groups in Florida in 2011. A total of 62,451 discharge records from 221 general hospitals were used in this study. The primary and secondary road network with speed limit information in Florida was obtained from the Florida Department of Transportation, manually corrected in ArcGIS version 10.2 (ESRI), and used for calculating the travel time from the population-weighted centroid of postal zone to hospital (22).

Florida was divided into 78 HSAs on the basis of all individual discharges from 221 hospitals in Florida during 2011, using a Dartmouth–Swiss hybrid method (3). A discharge from one HSA to the same HSA was defined as local hospitalization, and a discharge from one HSA to a different HSA was defined as distant hospitalization. Multiple logistic regression models were used to estimate the association of local hospitalization with race/ethnicity, with local/distant hospitalization assigned as the dependent variable (1 for local hospitalization and 0 for distant hospitalization). Six exclusive racial/ethnic categories were used: white, black, Hispanic, Asian, Native American, and other.

Potential confounding factors were adjusted to remove their effects on the disparities among races/ethnicities, including age, sex, payer, patient location (large metropolitan area [≥1 million residents], small metropolitan area [<1 million residents], micropolitan area, or rural area), SES (measured by the median household income for patient’s zip code), severity of illness (indirectly determined by surgery received or not received and death as an outcome), length of stay, and presence of comorbidities. Race/ethnicity was controlled for while examining the associations of local hospitalization with other factors. All categories of each factor were subsequently used as reference categories, to which the odds ratios (ORs) of all the other categories were compared.

In addition to the dichotomous proxy for local or distant hospitalization, candidate measures of time from the population-weighted centroid of each postal zone to each hospital were actual and excess travel time. On the basis of the primary and secondary road network with speed limits, actual travel time for a given discharge record was calculated along the shortest driving path from the population-weighted centroid of the postal zone to which that record was discharged to the hospital from which that record was discharged. Second, excess travel time for a given discharge record was computed by subtracting time spent from population-weighted centroid of that postal zone to the nearest hospital from the actual travel time.

Two measures alternated as a continuous dependent variable in linear regression models, which were used to study the association of travel patterns with the same set of factors included in multiple logistic regression models. All values in 4 primary categories (race/ethnicity, payer, patient location, and SES) were converted and used as “dummy” variables in linear regression models. Results from both multiple logistic and linear regression models were all tested at the 90%, 95%, and 99% confidence levels.

Top

Results

Of all CHF discharges, 18.3% were black, and 14.4% were Hispanic; 0.49% were Asian, and 0.1% were Native American (Table 1). Approximately 78.8% (49,234) of the CHF hospitalizations occurred in the inpatients’ local HSAs during 2011.

When logistic models controlled for all known predictors for travel patterns (Table 1), female inpatients were more likely to stay within their HSAs for hospitalization than were male patients. Linear models consistently indicated that female patients spent 1.7% less travel time and 1.8% less excess travel time than male patients. Odds of local hospitalization increased with age, and local patients tended to have a shorter stay in hospital. Distant inpatients were more likely to receive surgery than their local counterparts. However, no significant differences in death rate at the time of discharge were found between local and distant inpatients. The significant comparisons on the age continuum and between the inpatients receiving and not receiving surgery were validated at the 99% confidence level in both linear models.

Blacks were more likely to seek local hospitalization than whites (OR = 1.24); the findings for other races/ethnicities did not differ significantly from findings for whites in logistic models (Table 1). Although the findings for Asians were significant at only the 90% confidence level (OR = 1.31), Asians were more likely to be locally hospitalized than whites. Hispanics, despite traveling 2.7% less time than whites to hospitals, spent approximately the same amount of excess travel time as whites. Other significant findings were found after changing the reference category for each factor while examining the odds of local hospitalization (Table 2) and excess travel time (Table 3). When blacks were used as the reference group in the logistic model, Hispanics were less likely to choose local hospitalization (OR = 0.83), and in the linear model they were more likely to spend 1.9% more excess travel time to hospitals.

Variations in patients’ travel patterns were found by patient insurance coverage and by source of health insurance payment. The odds of local hospitalization for Medicaid, self-pay, and no-charge patients were all higher than those for Medicare patients, and privately insured patients were more likely to travel outside the HSAs (Table 1); the number of no-charge patients was only 1.4% of Medicare patients. Alternating the reference group confirmed that privately insured patients were most likely to travel outside the HSAs than any other payer group, followed by Medicare patients (Table 2). In addition to confirming that privately insured patients spent the most excess travel time, the linear model indicated that no-charge patients spent the least amount of excess travel time to hospitals compared with Medicaid and self-pay patients (Table 3), a difference that was indistinguishable in logistic models.

Patients living in large metropolitan areas were most likely to seek hospitalization within their HSAs and also spent the shortest excess travel time to hospitals (Table 1). Rural patients spent 22.4% more travel time and 18.4% more excess travel time to hospitals than large-metropolitan patients (Table 1) and 17.9% and 12.5% more excess time to hospitals than small-metropolitan or micropolitan patients, respectively (Table 3).

The differences in travel patterns of patients living in the postal zones with different median household incomes were similarly apparent. As median household income in a postal zone increased, patients were more likely to travel outside their HSA for hospitalization and spend more excess travel time to hospitals. Despite a general tendency toward distant hospitalization as median household income increased, significant differences were not found between the 2 wealthier groups and the 2 poorer groups in logistic models (Table 2). Nevertheless, linear models showed that patients in the 4th quartile of median household income spent 1.1% more excess travel time than the patients in the 3rd quartile, and 2nd-quartile patients spent 1.9% more excess travel time to hospitals than 1st-quartile patients (Table 3).

In logistic models and linear regression models controlling for all factors, 16 comorbidities were significantly associated with travel patterns. Most comorbidities were more likely to be diagnosed in local patients, whereas 5 specific comorbidities were more likely to be diagnosed in distant patients (Table 1).

Top

Discussion

We examined influential demographic, geographic, and socioeconomic factors associated with disparities in the travel patterns of CHF patients. To overcome the biases of a onetime decision made by patients, discharge-level data instead of patient-level data were used. More than 20% of the hospitalizations occurred outside of patients’ HSAs in 2011, and significant disparities in travel patterns among different groups of inpatients were found, which were confirmed by the significant relationships of those influential factors to excess travel time.

Choosing a hospital can be a difficult decision, especially in large cities where many choices are available to most residents that are within an acceptable distance or travel time. Unlike many traditional studies, we did not focus on which groups of patients lacked access to health care resources. Instead, assuming that most patients had access to local hospital resources and that HSAs were delineated on the basis of acceptable distances for most patients, we defined local hospitalization as a preference of going to the closest hospital rather than being forced to go. Given that patients’ accurate addresses are often not available because of privacy protection, examining the tendency to choose close hospitals is more meaningful than scrutinizing whether patients go to the physically closest hospital (16).

In addition to using a dichotomous variable and traditional continuous travel time, the concept of local hospitalization was also used as a dependent variable in linear regression models (excess travel time) to supplement the results from logistic models. Excess time removed the effects of varying closest hospitals and, compared with travel time, better reflected the tendency of the patients to travel. For example, although spending as much travel time as blacks, Hispanics spent 1.9% more excess travel time, which implies that Hispanics may live closer to hospitals but bypass their closer choices to a larger extent than blacks do.

According to the results from logistic models, the subgroups most (least) likely to stay within the HSAs were blacks (whites); Medicaid, self-pay, and no-charge patients (privately insured patients); large metropolitan patients (rural patients); and patients in the 1st and 2nd income quartiles (3rd- and 4th-quartile patients). The juxtaposed subgroups were statistically indistinguishable in logistic models, but they were significantly different in the linear models, producing 3 new findings: 1) no-charge patients spent less time on travel than did Medicaid and self-pay patients, 2) patients in the 1st income quartile patients spent less time than those in the 2nd quartile, and 3) patients in the 3rd income quartile patients spent less time than the those in the 4th quartile. Therefore, the 2 approaches complement each another while providing consistent evidence, and the combination of logistic and linear regression, in conjunction with using dummy variables converted from categorical variables, could be applied to future research.

Our results indicate that patients’ SES plays a prominent role in their travel behavior, possibly by providing them more choices or a stronger tendency to travel. Blacks and Hispanics normally have an apparent disadvantage in SES relative to other races/ethnicities, and they are more likely to live in the inner city and rely on hospitals around them, which may explain their shorter excess travel time. Furthermore, because Medicare and Medicaid patients do not have the burden of payment, they often have more choices. However, being eligible for Medicaid is an indicator of low SES, which accounts for these patients being less likely to travel farther than their Medicare counterparts. No charge for hospitalization also indicates low SES, so SES may underlie both geographic and payer factors. Another possible explanation is the interplay between the insured and uninsured. No-charge patients may prefer to go to local hospitals they are more familiar with and save the costs of traveling, and self-pay patients may prefer local hospitals for a discount received by paying cash.

A major limitation of this study is that patients’ residential location can only be determined by zip code where they lived at the time of discharge, because of data confidentiality laws. We assumed that the zip codes inpatients claimed as residential zip codes are those of their own permanent addresses or that influenced their choices of travel distance or time (such as those of extended family). The small sample size in some subpopulations may affect the conclusions, especially the comparisons with other subpopulations under the same category. For example, the higher tendency of Asians to be locally hospitalized might be discounted by a small sample size (ie, only 0.74% of whites). Also, our focus was the tendency of patients to seek hospitalization with travel time, insurance, and SES considered, regardless of whether those inpatient visits were transferred to current hospitals. Therefore, we assume that those transferred to current hospitals do not significantly affect our conclusions.

Other limitations are lack of consideration for hospital quality and capacity and insurance network within the HSAs. For example, renowned hospitals and those with sufficient number of beds within the HSAs influence patients to choose local hospitalization. Some types of insurance, such as Medicare Advantage plans, dictate a network in which patients may receive services, making some hospitals unavailable to nearby populations. Nevertheless, we emphasized the concept of local hospitalization instead of the closest hospital, which reduces this bias. Compared with metropolitan areas, rural areas may be disproportionately affected because of fewer choices within the HSAs. The delineation of HSAs is also subject to the modifiable areal unit problem (MAUP) (23), which should be further explored in future studies. The results related to Native Americans and Asians should be interpreted with caution because of small numbers and percentages over the entire population. Patients’ travel patterns may vary across diagnoses and diagnostic procedures (4,24). Even if the severity of illness is controlled, the pattern may vary geographically. Consequently, results of this study should be interpreted with caution when applied to patients diagnosed with other symptoms or those in other states or regions.

Study results imply that changes or disruptions in local hospital supply, such as hospital closures or changes in hospital resource allocation and transportation infrastructures, could differentially affect different population groups, which may require policy makers to pay extra attention to the disadvantaged populations who are less likely to travel. Furthermore, the HSA has re-emerged as an important unit of analysis, especially after the 2013 report by the Institute of Medicine (25). Future research should explore the value of HSAs in maximizing the efficiency of health care systems while reducing costs.

Top

Acknowledgments

Peng Jia acknowledges the support of the 2015 Dissertation Year Fellowship at the Louisiana State University. We also thank the reviewers for their great comments and suggestions, which have tremendously improved this manuscript.

Top

Author Information

Corresponding Author: Peng Jia, PhD, Department of Epidemiology and Environmental Health, University at Buffalo, Buffalo, NY 14214. Telephone: 716-829-5354. Email: jiapengff@hotmail.com.

Author Affiliation: Imam M. Xierali, Louisiana State University, Baton Rouge, Louisiana, and Association of American Medical Colleges, Washington, DC.

Top

References

  1. Pfuntner A, Wier LM, Stocks C. Most frequent conditions in US hospitals, 2010. In: Statistical brief no. 148. Rockville (MD): Agency for Healthcare Research and Quality; 2013.
  2. Wang F. Measurement, optimization, and impact of health care accessibility: a methodological review. Ann Assoc Am Geogr 2012;102(5):1104–12. CrossRefexternal icon PubMedexternal icon
  3. Jia P, Xierali I, Wang F. Evaluating and re-demarcating the hospital service areas in Florida. Appl Geogr 2014;60:248–53. CrossRefexternal icon
  4. Hogan C. Patterns of travel for rural individuals hospitalized in New York State: relationships between distance, destination, and case mix. J Rural Health 1988;4(2):29–41. CrossRefexternal icon PubMedexternal icon
  5. Wilbush J. The local hospital: functions, advantages and difficulties. Can Fam Physician 1974;20(7):54–6. PubMedexternal icon
  6. Moist LM, Bragg-Gresham JL, Pisoni RL, Saran R, Akiba T, Jacobson SH, et al. Travel time to dialysis as a predictor of health-related quality of life, adherence, and mortality: the Dialysis Outcomes and Practice Patterns Study (DOPPS). Am J Kidney Dis 2008;51(4):641–50. CrossRefexternal icon PubMedexternal icon
  7. Nicholl J, West J, Goodacre S, Turner J. The relationship between distance to hospital and patient mortality in emergencies: an observational study. Emerg Med J 2007;24(9):665–8. CrossRefexternal icon PubMedexternal icon
  8. Jones AP, Haynes R, Sauerzapf V, Crawford SM, Zhao H, Forman D. Travel time to hospital and treatment for breast, colon, rectum, lung, ovary and prostate cancer. Eur J Cancer 2008;44(7):992–9. CrossRefexternal icon PubMedexternal icon
  9. Gabrysch S, Campbell OM. Still too far to walk: literature review of the determinants of delivery service use. BMC Pregnancy Childbirth 2009;9(1):34. CrossRefexternal icon PubMedexternal icon
  10. Masters SH, Burstein R, Amofah G, Abaogye P, Kumar S, Hanlon M. Travel time to maternity care and its effect on utilization in rural Ghana: a multilevel analysis. Soc Sci Med 2013;93:147–54. CrossRefexternal icon PubMedexternal icon
  11. Basu J, Friedman B. A re-examination of distance as a proxy for severity of illness and the implications for differences in utilization by race/ethnicity. Health Econ 2007;16(7):687–701. CrossRefexternal icon PubMedexternal icon
  12. Basu J. Severity of illness, race, and choice of local versus distant hospitals among the elderly. J Health Care Poor Underserved 2005;16(2):391–405. CrossRefexternal icon PubMedexternal icon
  13. Basu J, Cooper J. Out-of-area travel from rural and urban counties: a study of ambulatory care sensitive hospitalizations for New York State residents. J Rural Health 2000;16(2):129–38. CrossRefexternal icon PubMedexternal icon
  14. Biello KB, Rawlings J, Carroll-Scott A, Browne R, Ickovics JR. Racial disparities in age at preventable hospitalization among U.S. Adults. Am J Prev Med 2010;38(1):54–60. CrossRefexternal icon PubMedexternal icon
  15. O’Hare AM, Johansen KL, Rodriguez RA. Dialysis and kidney transplantation among patients living in rural areas of the United States. Kidney Int 2006;69(2):343–9. CrossRefexternal icon PubMedexternal icon
  16. Radcliff TA, Brasure M, Moscovice IS, Stensland JT. Understanding rural hospital bypass behavior. J Rural Health 2003;19(3):252–9. CrossRefexternal icon PubMedexternal icon
  17. Delmelle EM, Cassell CH, Dony C, Radcliff E, Tanner JP, Siffel C, et al. Modeling travel impedance to medical care for children with birth defects using Geographic Information Systems. Clin Molec Teratology 2013;97(10):673–84. CrossRefexternal icon
  18. Basu J, Mobley LR. Illness severity and propensity to travel along the urban-rural continuum. Health Place 2007;13(2):381–99. CrossRefexternal icon PubMedexternal icon
  19. Lembcke PA. Measuring the quality of medical care through vital statistics based on hospital service areas; I. Comparative study of appendectomy rates. Am J Public Health Nations Health 1952;42(3):276–86. CrossRefexternal icon PubMedexternal icon
  20. Klauss G, Staub L, Widmer M, Busato A. Hospital service areas — a new tool for health care planning in Switzerland. BMC Health Serv Res 2005;5(1):33. CrossRefexternal icon PubMedexternal icon
  21. Healthcare Cost and Utilization Project. Overview of the State Inpatient Databaes. Agency for Healthcare Research and Quality; 2011. http://www.hcup-us.ahrq.gov/sidoverview.jsp. Accessed August 11, 2015.
  22. Luo W, Wang F. Measures of spatial accessibility to health care in a GIS environment: synthesis and a case study in the Chicago region. Environ Plan B 2003;30(6):865–84. CrossRefexternal icon
  23. Fotheringham AS, Wong DW. The modifiable areal unit problem in multivariate statistical analysis. Environ Plan A 1991;23(7):1025–44. CrossRefexternal icon
  24. Mayer JD. The distance behavior of hospital patients: a disaggregated analysis. Soc Sci Med 1983;17(12):819–27. CrossRefexternal icon PubMedexternal icon
  25. Newhouse JP, Garber AM, Graham RP, McCoy MA, Mancher M, Kibria A. Variation in health care spending: target decision making, not geography. Washington (DC): Institute of Medicine, National Academies Press; 2013.

Top

Tables

Return to your place in the textTable 1. Descriptive Statistics, Odds of Local Hospitalization, and Predictors of Travel Time for Patients Diagnosed With Congestive Heart Failure (N = 62,451), Florida, United States, 2011
Predictor Total Discharge, n Crude Rate, % OR (95% CI) Standard Coefficient, Travel Time Standard Coefficient, Excess Time
Sex
Male 32,634 77.6 1.00 1 1
Female 29,817 80.2 1.10 (1.06–1.14) -0.017 -0.018
Age 1.014 (1.012–1.016) -0.096 -0.090
Length of stay 0.99 (0.987–0.994)
Race/ethnicity
White 41,008 78.5 1.00 1 1
Black 11,402 79.9 1.24 (1.17–1.32) -0.031 -0.019
Hispanic 9,010 79.2 1.03 (0.97–1.10) -0.027 0.001
Asian 305 81.0 1.31 (0.98–1.76) -0.009 -0.007
Native American 75 81.3 1.29 (0.72–2.31) 0.003 0.004
Other 651 77.1 0.99 (0.82–1.20) 0.006 0.008
Payer
Medicare 49,799 79.7 1.00 1 1
Medicaid 4,865 78.0 1.15 (1.06–1.25) -0.013 -0.011
Private 4,074 70.0 0.77 (0.71–0.83) 0.042 0.046
Self-pay 1,735 78.5 1.24 (1.09–1.40) -0.004 -0.003
No charge 681 79.7 1.27 (1.04–1.54) -0.016 -0.013
Other 1,297 76.2 0.92 (0.80–1.05) 0.007 0.006
Location/areaa
Large metropolitan 37,446 79.7 1.00 1 1
Small metropolitan 20,035 78.7 0.94 (0.90–0.99) 0.076 0.015
Micropolitan 3,324 76.4 0.81 (0.74–0.88) 0.141 0.084
Rural 1,646 66.7 0.50 (0.45–0.56) 0.224 0.184
Income quartile
1st 23,563 79.0 1.00 1 1
2nd 19,156 79.3 0.99 (0.95–1.04) 0.043 0.019
3rd 15,232 78.3 0.92 (0.87–0.97) 0.078 0.047
4th 4,500 77.9 0.90 (0.83–0.98) 0.064 0.039
Severity
Not surgery 56,208 79.8 1.00 1 1
Surgery 6,243 70.5 0.66 (0.62–0.71) 0.057 0.059
Not died 60,764 78.8 1.00 1 1
Died 1,687 79.5 0.92 (0.81–1.04) -0.006 -0.004
Not AIDS 62,202 78.8 1.00
AIDS 249 83.9 1.66 (1.18–2.34)
Not chronic pulmonary disease 36,903 78.0 1.00 1 1
Chronic pulmonary disease 25,548 80.0 1.14 (1.09–1.18) -0.030 -0.030
Not hypertension 13,448 77.5 1.00 1 1
Hypertension 49,003 79.2 1.04 (0.99–1.09) -0.011 -0.015
Not liver disease 60,750 78.9 1.00
Liver disease 1,701 75.3 0.91 (0.81–1.02)
Not neurological disorders 58,030 78.7 1.00 1 1
Neurological disorders 4,421 80.8 1.09 (1.01–1.18) -0.010 -0.008
Not obesity 51,069 78.9 1.00 1 1
Obesity 11,382 78.4 1.08 (1.03–1.14) -0.010 -0.013
Not weight loss 60,381 79.0 1.00 1 1
Weight loss 2,070 74.0 0.79 (0.72–0.88) 0.008 0.010
Not solid tumor without metastasis 61,446 78.8 1.00 1 1
Solid tumor without metastasis 1,005 81.1 1.15 (0.98–1.35) -0.010 -0.008
Not coagulopathy 58,429 78.9 1.00 1 1
Coagulopathy 4,022 77.5 1.13 (1.02–1.26) 0.010 0.011
Not deficiency anemias 40,734 78.7 1 1
Deficiency anemias 21,717 79.1 -0.008 -0.008
Not diabetes with chronic complications 56,549 78.9 1 1
Diabetes with chronic complications 5,902 77.8 -0.014 -0.014
Not hypothyroidism 51,447 78.7 1 1
Hypothyroidism 11,004 79.3 0.010 0.010
Not fluid and electrolyte disorders 43,706 79.1 1 1
Fluid and electrolyte disorders 18,745 78.1 0.016 0.016
Not psychoses 60,666 78.9 1
Psychoses 1,785 77.8 -0.009
Not renal failure 37,176 78.9 1 1
Renal failure 25,275 78.8 0.015 0.012
Not valvular disease 62,164 78.9 1 1
Valvular disease 287 74.9 -0.010 -0.012

Abbreviations: — , not applicable; AIDS, acquired immune deficiency syndrome; CI, confidence interval; OR, odds ratio.
a A large metropolitan area was 1 million or more residents, and a small metropolitan area was fewer than 1 million residents.

 

Return to your place in the textTable 2. Odds of Local Hospitalization Rates for Patients Diagnosed With Congestive Heart Failure (N = 62,451), by Alternating Reference Group, Florida, United States, 2011
Factor Reference Group
Race/ethnicity White Black Hispanic Asian Native American Other
White 1.00 0.80 (0.76–0.85) 0.97 (0.91–1.03) 0.76 (0.57–1.02) 0.79 (0.44–1.41) 1.01 (0.83–1.21)
Black 1.24 (1.17–1.32) 1.00 1.21 (1.12–1.30) 0.95 (0.71–1.27) 0.98 (0.55–1.76) 1.25 (1.03–1.52)
Hispanic 1.03 (0.97–1.10) 0.83 (0.77–0.89) 1.00 0.78 (0.58–1.05) 0.81 (0.45–1.46) 1.04 (0.86–1.26)
Asian 1.31 (0.98–1.76) 1.06 (0.79–1.42) 1.28 (0.95–1.71) 1.00 1.04 (0.54–1.99) 1.32 (0.94–1.86)
Native American 1.29 (0.72–2.31) 1.02 (0.57–1.84) 1.23 (0.69–2.22) 0.97 (0.50–1.85) 1.00 1.28 (0.69–2.36)
Other 0.99 (0.82–1.20) 0.80 (0.66–0.97) 0.97 (0.80–1.17) 0.76 (0.54–1.07) 0.78 (0.42–1.44) 1.00
Insurance Medicare Medicaid Private Self-pay No charge Others
Medicare 1.00 0.87 (0.80–0.95) 1.30 (1.20–1.40) 0.81 (0.71–0.92) 0.79 (0.65–0.96) 1.09 (0.96–1.25)
Medicaid 1.15 (1.06–1.25) 1.00 1.49 (1.35–1.64) 0.93 (0.81–1.06) 0.91 (0.74–1.11) 1.26 (1.08–1.46)
Private 0.77 (0.71–0.83) 0.67 (0.61–0.74) 1.00 0.62 (0.54–0.71) 0.61 (0.50–0.74) 0.84 (0.73–0.98)
Self-pay 1.24 (1.09–1.40) 1.08 (0.94–1.24) 1.61 (1.41–1.84) 1.00 0.98 (0.78–1.22) 1.36 (1.14–1.62)
No charge 1.27 (1.04–1.54) 1.10 (0.90–1.35) 1.65 (1.35–2.01) 1.02 (0.82–1.28) 1.00 1.39 (1.10–1.74)
Other 0.92 (0.80–1.05) 0.80 (0.69–0.92) 1.19 (1.03–1.38) 0.74 (0.62–0.88) 0.72 (0.57–0.91) 1.00
Location/areaa Large Metropolitan Small Metropolitan Micropolitan Rural
Large metropolitan 1.00 1.06 (1.01–1.10) 1.24 (1.13–1.35) 1.98 (1.78–2.21)
Small metropolitan 0.94 (0.90–0.99) 1.00 1.17 (1.07–1.28) 1.87 (1.68–2.09)
Micropolitan 0.81 (0.74–0.88) 0.86 (0.78–0.94) 1.00 1.60 (1.41–1.83)
Rural 0.50 (0.45–0.56) 0.53 (0.48–0.60) 0.62 (0.55–0.71) 1.00
Household income quartile 1st 2nd 3rd 4th
1st 1.00 1.01 (0.96–1.06) 1.09 (1.03–1.15) 1.11 (1.02–1.20)
2nd 0.99 (0.95–1.04) 1.00 1.08 (1.03–1.14) 1.10 (1.02–1.20)
3rd 0.92 (0.87–0.97) 0.92 (0.88–0.97) 1.00 1.02 (0.94–1.10)
4th 0.90 (0.83–0.98) 0.91 (0.84–0.99) 0.98 (0.91–1.07) 1.00

a A large metropolitan area was 1 million or more residents, and a small metropolitan area was fewer than 1 million residents.

 

Return to your place in the textTable 3. Standardized Coefficients of the Factors Influencing Excess Travel Time, by Patients Diagnosed With Congestive Heart Failure (N = 62,451), by Alternating Reference Group, Florida, United States, 2011
Factor Reference Group
Race/ethnicity White Black Hispanic Asian Native American Other
White 1 0.023 -0.002 0.049 -0.055 -0.036
Black -0.019 1 -0.021 0.021 -0.064 -0.048
Hispanic 0.001 0.019 1 0.038 -0.039 -0.025
Asian -0.007 -0.004 -0.007 1 -0.015 -0.012
Native American 0.004 0.006 0.004 0.008 1 0.001
Other 0.008 0.013 0.007 0.018 -0.004 1
Insurance Medicare Medicaid Private Self-pay No charge Other
Medicare 1 0.017 -0.075 0.008 0.051 -0.017
Medicaid -0.011 1 -0.061 -0.006 0.023 -0.023
Private 0.046 0.056 1 0.051 0.078 0.035
Self-pay -0.003 0.004 -0.034 1 0.018 -0.010
No charge -0.013 -0.009 -0.033 -0.011 1 -0.018
Other 0.006 0.012 -0.020 0.009 0.024 1
Location/areaa Large Metropolitan Small Metropolitan Micropolitan Rural
Large metropolitan 1 -0.016 -0.183 -0.563
Small metorpolitan 0.015 1 -0.159 -0.522
Micropolitan 0.084 0.076 1 -0.175
Rural 0.184 0.179 0.125 1
Household income quartile 1st 2nd 3rd 4th
1st 1 -0.020 -0.053 -0.073
2nd 0.019 1 -0.031 -0.050
3rd 0.047 0.029 1 -0.018
4th 0.039 0.028 0.011 1

a A large metropolitan area was 1 million or more residents, and a small metropolitan area was fewer than 1 million residents.

Top

View Page In:pdf icon

The opinions expressed by authors contributing to this journal do not necessarily reflect the opinions of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors’ affiliated institutions.

Page last reviewed: September 17, 2015