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Research ArticleFamily Medicine - World Perspective

Effect of Continuity of Care on Emergency Department Visits in Elderly Patients with Asthma in Taiwan

Yu-Hsiang Kao and Shiao-Chi Wu
The Journal of the American Board of Family Medicine May 2017, 30 (3) 384-395; DOI: https://doi.org/10.3122/jabfm.2017.03.160285
Yu-Hsiang Kao
From the Institute of Health and Welfare Policy, National Yang-Ming University, Taipei, Taiwan.
PhD
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Shiao-Chi Wu
From the Institute of Health and Welfare Policy, National Yang-Ming University, Taipei, Taiwan.
PhD
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Abstract

Background: Continuity of care (COC) is positively associated with health care outcomes. However, the effect of COC on the reduction of asthma-related emergency department (ED) visits among older asthmatic patients is not clearly understood.

Methods: We conducted a retrospective cohort study using the Taiwan nationwide health insurance claims database between 2004 and 2013. Patients aged 65 years with asthma during 2005 to 2011 were selected. The COC index (COCI) is used to measure the number of individual physicians a patient sees in the first year and we identified asthma-related ED visit in the subsequent year. Cox model was used to examine the hazard ratio (HR) between COC and an ED visit for asthma.

Results: Among a total of 3395 subjects, the overall mean COC was 0.73, and 48.5% of subjects had perfect COC (COCI = 1). After controlling for covariables, in the group of patients with low COC, the risk of having an asthma-related ED visit was higher compared with those with perfect COC (Adjusted HR, 2.11; 95% CI, 1.37−3.25).

Conclusions: Elderly asthmatic patients with lower COC had a significantly higher likelihood of having asthma-related ED visits.

  • Ambulatory Care
  • Asthma
  • Continuity of Care
  • Emergency Departments
  • Retrospective Studies
  • Taiwan

Asthma is a chronic inflammatory respiratory disease and is associated with various morbidities1 and high medical costs.2 A common misconception is that asthma occurs only in childhood. A considerable number of studies focus on children with asthma; however, few studies have examined asthma in adults.3 Asthma also occurs in people aged >40 years.4 The prevalence of asthma among people aged ≥65 years is approximately 7% in Taiwan,5 which is similar to that in the United States.6,7 The average annual rate of outpatient visits for older patients with asthma in Taiwan is 6.3 per 100 persons,8 and this rate is also similar to that in the United States (5.6 per 100 persons).7 The mortality rate among older people with asthma is higher than that among adults or children with asthma.7,9,10 In addition, health care utilization is higher among older people with asthma than their healthy peers.11 Therefore, an investigation of elderly patients with asthma is necessary because of societal aging.

The Global Initiative for Asthma has indicated that the symptoms and frequency of exacerbations can be controlled and patients' quality of life improved if patients receive regular and continuous medication and appropriate disease management.12 To ensure that health care providers are aware of the treatment goals of providing better care for patients with asthma,13 Taiwan's government published the Taiwan Asthma Guidelines in 2000, following the Global Initiative for Asthma guidelines.

Poor asthma management on the part of health care providers and patients often increases asthma-related health care utilization and expenditures.14 Hence, asthma is an ambulatory care–sensitive condition (ACSC).15 ACSCs are conditions characterized by episodes that may have been avoided if the condition had been more effectively managed.16⇓–18 According to the concept of ACSC, asthma is classified as a condition that is urgent but treatable with primary care during emergency department (ED) visits.19,20 Continuity of care (COC) is a process in which a patient and a medical team are cooperatively involved in ongoing health care management. Although studies have linked high COC to less hospitalization,21,22 the relationship between COC and ED visits among aging adults remains unclear. Studies have ascribed better health care outcomes in chronic diseases, such as asthma, to high COC.23⇓⇓–26 However, the effect of COC on aging populations with asthma has not yet been well explored.

Taiwan implemented a single-payer National Health Insurance (NHI) program in 1995, and approximately 99% of Taiwan's 23 million residents are enrolled in this program. The NHI program provides universal and compulsory health insurance to reduce financial barriers and strengthen the accessibility of health services.27 Furthermore, 70% of primary care is provided in clinics, and 30% of outpatient care is provided in hospitals. Under the NHI program, patients can freely visit any health care provider in a clinic or in a hospital, without a referral. This study investigated whether high continuity of ambulatory asthma care reduces asthma-related ED visits among the aging population with asthma under a national insurance system without referral arrangements.

Methods

Study Data and Design

A population-based, retrospective cohort study was conducted using the 2004 to 2013 NHI Research Database and was organized by the National Health Research Institutes. This study used the Longitudinal Health Insurance Database 2010, which contains data from 1 million beneficiaries randomly selected from all insured beneficiaries in 2010 and covers approximately 1/23 of the NHI enrollee population. This data set contains all administration claims data for these beneficiaries for the period from 2004 to 2013.8 To protect patients' privacy, identifying information is encrypted and can be linked by an encrypted but unique number. These data files also provide longitudinal medical records and the International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM) codes of each patient. The accuracy of the data and diagnoses retrieved from the database has been validated.28 This study protocol was reviewed and approved by the Institutional Review Board of National Yang-Ming University, Taiwan (approval no. YM103047E).

Study Population

The study population comprised patients aged ≥65 years who either had at least 2 ambulatory visits or had 1 inpatient visit for asthma29 as a major diagnosis (ICD-9-CM code 493.xx) during the period from 2005 to 2011 (n = 8173). Patients who were not continuously enrolled in the NHI program (n = 326) or had no outpatient visits (n = 269) during the study period were excluded. Furthermore, patients with <4 outpatient visits during the COC period were excluded (n = 4183).25,26,30,31 In total, 3395 patients were included (Figure 1).

Figure 1.
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Figure 1.

Diagrammatic representation of the patient populations. *The results of analysis among those patients are demonstrated in Appendix Table 1. COC, continuity of care.

The index date was set as the earliest date for patients who had >1 record during this period. To avoid time-dependent bias and incorrect conclusions, we examined COC and health outcomes independently, and each patient was followed for 2 years after the index date. The first year was the COC period, and the subsequent year was the outcome period (Figure 2).

Figure 2.
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Figure 2.

The schematic diagram of the time frame. CCI, Charlson comorbidity index; COC, continuity of care; COCI, continuity of care index; COPD, chronic obstructive pulmonary disease; ED, emergency department.

Variables

Dependent Variable

According to the prevention quality indicator of the US Agency for Healthcare Research and Quality, ED visits for asthma were identified by the main ICD-9-CM diagnostic code 493.xx.32 An ED visit was defined as an event that occurred during the outcome period. The follow-up duration was defined as the number of days from the date of the end of the COC period to the date of an ED visit for asthma. If a patient had no ED visit for asthma, then that patient was censored at the end of the outcome period.

Independent Variable

The score of the continuity of care index (COCI), ranging from 0 to 1, reflects the dispersion of contact between a patient and a physician.33 A higher value represents better COC. A COCI of 1 indicates that all outpatient visits were to the same physician; in other words, patients had a continuous connection with 1 physician. This index has been widely adopted in studies using claim data sets30,31,34,35 because the index is less sensitive to the number of physician visits and more suitable for a higher number of outpatient visits.33 The general formula for COCI is as follows: Embedded Image where N is the total number of outpatient asthma care visits, ni is the number of outpatient asthma care visits to ith physician, and j is the total number of physicians. The total number of physician visits (N) and the number of visits to a given physician (ni) include ambulatory claims (including clinic or hospital physician visits) in the principal diagnosis (ICD-9-CM code 493.xx). We calculated COCI during the COC period and then categorized COCI into 3 groups according to the first and third quartiles: low (COCI <0.47), moderate (0.47 ≤ COCI < 1), and perfect (COCI = 1).36

Covariables

Several covariables were considered in this study. Patient characteristics at baseline were age, sex, and insurance premiums (low [<US$667], medium [US$667-1333], and high [≥US$1333]). One US dollar was equal to 30 New Taiwan dollars in 2012.37 Patients' educational level or household income may affect health care outcomes6,23,38; the NHI claims data set does not provide this information. Hence, insurance premiums were used as a proxy for socioeconomic status.39 Enrollment in the asthma pay-for-performance (P4P) program during the COC period was considered because the P4P program has been proven to improve both COC and health care outcomes among patients with chronic diseases.35,40⇓–42 In addition, health status and disease severity may affect the measurement of health outcomes; therefore, we considered medical conditions in the previous year and in the COC period to identify patients' health status and disease severity. Furthermore, the Charlson Comorbidity Index (CCI) and a history of chronic obstructive pulmonary disease (COPD; ICD-9-CM codes 491, 492, or 496)22 were included and identified in the previous year. The CCI, which was calculated for each patient according to outpatient or inpatient care, was divided into 3 groups: 0, 1 to 2, and ≥3.43 The number of ambulatory visits for asthma (4–12, 13–24, and ≥25 times),25,26,30 whether a patient was hospitalized for asthma,24 and whether a patient had an ED visit for asthma22,24,25—all during the COC period—were used as proxies for disease severity.

Statistical Analysis

The association of patients' characteristics with COC was examined using the χ2 test for categorical variables and 1-way analysis of variance for continuous variables. The Cochran-Armitage trend test was used to evaluate the association of asthma-related ED visits with the level of COC. In addition, with the valid proportional hazard assumption (P = .927),44 Cox regression models were used to examine the association between COC levels and the risk of ED visit for asthma in elderly patients with asthma. In the adjusted model, we calculated the adjusted hazard ratio (aHR) after adjusting for sex, age, insurance premium, P4P participation status, CCI, COPD, number of ambulatory visits for asthma, hospitalization for asthma, and ED visits for asthma. All variables had no multicollinearity in our model. In addition to these models, we conducted a supplementary analysis including patients with <4 annual visits.

All analyses were performed using SAS version 9.4 (SAS Institute, Cary, NC). All tests were 2-sided, and a P value <.05 was defined as statistically significant for all tests.

Results

Table 1 lists the characteristics of the patients with asthma (n = 3395). The average COCI of elderly patients with asthma was 0.73 (standard deviation = 0.3; data not shown). Furthermore, 1663 (49.0%), 906 (26.7%), and 826 (24.3%) patients were included in the perfect (COCI = 1), moderate (COCI = 0.47–0.99), and low (COCI <0.47) COC groups, respectively. Across the entire sample, the mean age was 74.0 years and men comprised 50.5% of the patients. Furthermore, 56.3% of the patients had a low insurance premium, and 89.7% of the patients did not participate in the asthma P4P program. Regarding medical conditions during the COC period, 80.5% of the patients had 4 to 12 ambulatory visits. The proportion of patients with a history of COPD (77.7%), the number of asthma-related outpatient visits (83.8%), and the number of asthma-related hospitalizations (98.5%) and ED visits (96.8%) during the COC period were lower in the perfect COC group than in the low and moderate COC groups.

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Table 1.

Characteristics of Subjects (N = 3395) by Continuity of Care Index Group

The incidence of asthma-related ED visits is shown in Table 2. The overall rate was 3.45%, and it increased significantly with a decrease in the level of COCI (perfect: 2.22%, moderate: 3.31%, and low: 6.05%; P for trend <.01). Of the patients' characteristics at baseline, a significant dose-response association was identified for sex, a low insurance premium, and no participation in the asthma P4P program (P for trend <.01). An increased rate of ED visits was found to correlate with a decreased level of COC among the patients with a CCI of ≥3 and patients with a history of COPD (P for trend <.01). The incidence of asthma- related ED visits across the 3 COCI levels tended to increase significantly among the patients with 4 to 12 or 13 to 24 ambulatory visits, those not requiring hospitalization, and those having ED visits during the COC period (P for trend <.01).

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Table 2.

Incidence of Emergency Department Visits Across Continuity of Care Index Groups (n = 3395)

The risk of ED visits for asthma is demonstrated in Table 3. The patients in the low COC group had a significantly higher risk of asthma-related ED visits than did the patients in the perfect COC group (aHR, 2.11; 95% confidence interval [CI], 1.37–3.25). However, the patients in the moderate COC group exhibited a tendency to visit the ED because of asthma (aHR, 1.15; 95% CI, 0.70–1.87). Furthermore, patients with COPD were more likely to have asthma-related ED visits (aHR, 2.20; 95% CI, 1.46–3.30). Compared with the patients having 4 to 12 ambulatory visits, the patients having 13 to 24 or ≥25 ambulatory visits during the COC period were 124% (aHR, 2.24; 95% CI, 1.49–3.36) or 203% (aHR, 3.03; 95% CI, 1.44-6.39) more likely to have more ED visits for asthma, respectively. Moreover, experience of asthma-related ED visits during the COC period was associated with a higher risk of asthma-related ED visits (aHR, 6.69; 95% CI, 4.40–10.17). No significant interactions were observed between the COC groups and other variables in the regression model. The results of the supplementary analysis including the patients with <4 annual visits were consistent with those obtained from the original models (Appendix Table 1).

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Table 3.

Factors Associated with Emergency Department Visits for Asthma Using Cox Models (n = 3395)

Discussion

Taiwanese nationwide claims data were used in this study to examine the association between COC and asthma-related ED visits among older patients with asthma. The results of this study revealed that half of the elderly patients with asthma in Taiwan received ambulatory asthma care from a single physician during the first observational year, and the average COCI was 0.73 among the study population. We also observed that internists and family physicians were the principal outpatient care providers for patients in our study population; only 9% of the health care providers for our subjects were pulmonologists. A high COC score for the elderly patients with asthma might be attributable to the asthma P4P program. The Taiwan government launched the asthma P4P program in 2001 to encourage clinics and hospitals to provide patient-centered care and focus on disease management. This program provides a financial incentive to health care providers if their patients have a high follow-up rate and a low rate of hospitalization and ED visits for asthma. In addition, a previous study reported that children with asthma in Taiwan have a higher average COC score41 than do those in America and Canada.24,30

The continuous treatment of patients with asthma through inhaled medicine provides safe and effective long-term disease management.45 Studies have suggested an association of superior COC with fewer ED visits in different populations with asthma.23,26,30,41,46 Our findings are consistent with those reported in a previous study focusing on children.41 That study indicated that 42.3% of children with asthma had high COC (COCI = 1), and those with medium or low COC had a higher risk of asthma-related ED visits (odds ratio, 1.21 and 1.38, respectively). In addition, a study investigating the effects of COC on older patients in South Korea25 supported our finding of an inverse association between COC and the risk of asthma-related ED visits in elderly patients with asthma. In that study, the COCI was determined using medical institution units. Moreover, the study suggested that improved COC is associated with a lower risk of ED visits in elderly patients with asthma. Although the effect of COC may vary between different populations, our findings support the association of low COC with a high risk of ED visits for asthma in elderly populations with asthma.

The data suggest that COC plays a much more crucial role for older patients with asthma who have a low insurance premium, have providers who do not participate in the P4P program, and have a high CCI score (CCI ≥3). In studies focusing on adults or older people, low-income status was found to be adversely associated with health outcomes.22,23 Despite the insignificance of enrollment in the P4P program, the program seemed to be one of the factors reducing the risk of asthma-related ED visits in older patients with asthma (aHR, 0.78). A study reported that P4P programs benefit patients with diabetes and improve COC as well as health outcomes.35 In addition, a randomized clinical study demonstrated that offering financial incentives to both physicians and patients can lead to superior care outcomes for patients.47 Therefore, we suggest that governments should consider designing financial incentives for patients and physicians in order to increase their motivation, thereby improving patients' COC. Furthermore, elderly patients with asthma with higher levels of comorbidity might have poor health status. Upon suffering an asthma attack, older patients with asthma should contact the physician who is their main health care provider. As a result, these patients may benefit from improving their own COC.

Older patients with asthma and COPD should be more diligent regarding follow-up care. The results of this study revealed that these patients might have an approximately 2 times higher risk of asthma-related ED visits, even after considering COC and other covariables. An increased trend in the rates of asthma-related ED visits was observed to correlate with decreased COC levels in these patients (P for trend <.01). An inverse association was reported between COC and health outcomes, such as hospitalization and ED visits, among patients with COPD.22,25 In addition, asthma–COPD overlap syndrome has been increasingly discussed recently because of the similar clinical features of asthma and COPD.48 Therefore, our results support the theory that older patients with asthma and COPD have a higher risk of ED visits. Thus, future studies should further investigate this issue to gather more evidence.

Studies evaluating COC for all diseases have reported that patients with superior COC had a lower risk of ED visits and avoidable hospitalizations.23,49 However, the effect of COC on health outcomes can be confounded if a study includes several diseases.26 Therefore, focusing on a single disease can clarify the association between COC and health outcomes. For instance, Lin et al22 indicated that high COC was associated with a low risk of avoidable COPD-related hospitalization among adults with COPD. Our study focused on elderly patients with asthma and found a significantly inverse relationship between COC levels and the risk of ED visits for asthma. Thus, we suggest that these patients with low COC should attempt to develop a continuing relationship with a single physician in order to reduce the risk of ED visits for asthma. Our study demonstrates that COC plays a vital role in the reduction of ED visits for asthma among elderly patients with asthma. The findings also suggest that improving COC can be favorable for both patients and the health care system.36

This study has some limitations. First, it excluded patients with <4 outpatient visits during the COC period, which might limit the generalizability for these patients.50 Second, the claims data did not include the results of clinical data, such as peak expiratory flow or forced expiratory volume, to define disease severity and health status.38,51 Therefore, we referred to previous studies to adopt the frequency of ambulatory visits for asthma,25,26,30 hospitalization,24 and ED visits22,24,25 as a proxy for asthma severity, and we used CCI as a proxy indicator to present each patient's health status.21,22,52 Third, we could not obtain patients' educational level or household income, and this may affect the measurement of COC and outcomes.23 Hence, we used insurance premiums as an indicator to represent patients' socioeconomic status.39 In addition, despite measuring COC before health care outcomes, as suggested by a previous study,53 the problem of temporal ambiguity between COC and health care outcomes might not be completely avoided. We recommend that this issue should be further investigated in the future.

This study has several advantages. First, 99% of Taiwanese residents are enrolled in the NHI program; therefore, the findings are highly representative of the entire population. Second, the nationwide administrative databases include all information on clinical practices and reduce the effect of recall bias, thereby delivering results that are superior to those from hospital-based data sets54 or national surveys.55 Third, this study applied a longitudinal design in order to avoid the problem of a cross-sectional design and present stronger evidence of an association between COC and ED visits for asthma. Fourth, previous studies have explored the effect of COC on health care outcomes in children and adolescents with asthma.24,30,41 Our study provided empirical evidence of an adverse association between COC and the risk of ED visits among older patients with asthma. Fifth, we focused on a specific disease (asthma) and used critical criteria to identify patients; these criteria could be used more precisely to reflect the actual asthma care received and examine the association between COC and asthma-related ED visits. Previous research has reported that using a specific disease to calculate the COCI is more helpful for interpreting the relationship between COC and health outcomes.41,56 Finally, we measured the COCI at the physician level, which may provide information about the association between COC and asthma-related ED visits among elderly patients with asthma that is superior to that obtained from measurements at the institutional level.

Conclusions

This study demonstrates that an adverse association exists between COC and the risk of ED visits among elderly asthmatics, and that a long-term continuous relationship with the same physician is favorable for elderly patients with asthma in order to improve health care outcomes. We recommend that policymakers create effective policies for elderly patients with asthma to enhance the ongoing physician-patient relationship and improve disease control.

Appendix

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Appendix Table 1.

Factors Associated with Emergency Department Visits for Asthma Using Cox Models (N = 7578)

Notes

  • This article was externally peer reviewed.

  • Funding: This study was supported by grants from the Ministry of Science and Technology (103–2410-H-010–011-MY2 and 105-2410-H-010–011-MY2) in Taiwan.

  • Conflict of interest: none declared.

  • To see this article online, please go to: http://jabfm.org/content/30/3/384.full.

  • Received for publication September 12, 2016.
  • Revision received January 9, 2017.
  • Accepted for publication January 9, 2017.

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The Journal of the American Board of Family     Medicine: 30 (3)
The Journal of the American Board of Family Medicine
Vol. 30, Issue 3
May-June 2017
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Effect of Continuity of Care on Emergency Department Visits in Elderly Patients with Asthma in Taiwan
Yu-Hsiang Kao, Shiao-Chi Wu
The Journal of the American Board of Family Medicine May 2017, 30 (3) 384-395; DOI: 10.3122/jabfm.2017.03.160285

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Effect of Continuity of Care on Emergency Department Visits in Elderly Patients with Asthma in Taiwan
Yu-Hsiang Kao, Shiao-Chi Wu
The Journal of the American Board of Family Medicine May 2017, 30 (3) 384-395; DOI: 10.3122/jabfm.2017.03.160285
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