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A retrospective cohort study on the outcomes of ischemic stroke patients with adjuvant Korean Medicine treatment

Scientific Reportsvolume 8, Article number: 1656 (2018) | Download Citation


This study aims to examine the long-term effect of adjuvant treatment in Korean Medicine (KM) clinics in ischemic stroke patients, using a national sample cohort from the National Health Insurance Service in Korea between 2010 and 2013. The National Health Insurance Service – National Sample Cohort database from 2002 to 2013 was used in this study. Ischemic stroke patients were defined and covariates were included to account for socioeconomic variables, comorbidities and disease severity. Propensity score matching was applied. Cox proportional hazards modeling and Kaplan-Meier analysis were applied to determine the differences between KM and non-KM treated groups. The results shows that KM-treated group had a higher probability of survival than non-KM group patients. No significant difference was observed between the risk of readmission between the treated and non-treated patients. Kaplan-Meier analysis showed a weak effect of KM treatments in the patients with 8 to 28 days of hospital stay for a lower risk of recurrence than in non-treated patients. In conclusion, KM treatment of mild to moderate ischemic stroke patients has a mild effect on the survival probability of stroke. Its effect for improving long-term recurrence need to be explored in the future studies.


Stroke is the second leading cause of death worldwide1,2; additionally, stroke is the leading cause of death from a single organ disease in Korea3. The recurrence rate after an ischemic stroke with an uncertain cause has been reported to be above 20% during the first 2 years after the index event4. The main priority in treating patients after the first stroke is secondary stroke prevention5,6,7; therefore, a low-cost, safe, and effective means of managing post-stroke symptoms and preventing secondary stroke is required for stroke patients. The costs of stroke to the household as well as to society indicate the importance of stroke management5.

East Asian Medicine, including Korean Medicine (KM) and Traditional Chinese Medicine (TCM), has been widely used in countries in Asia for the treatment of stroke for many centuries8. The medical effectiveness of East Asian Medicine, including acupuncture and herbal medicines, has become a subject of study in the past few decades, although experimental and clinical data have shown limited results when evaluating the efficacy of East Asian Medicine for post-stroke treatment and management9,10,11,12. A number of studies have focused on the effectiveness of acupuncture in treating stroke patients and have reported mixed results5,9,13,14,15,16,17,18,19,20,21. Many possible mechanisms of acupuncture have been suggested for both treatment and post-stroke management22,23,24,25,26. KM, including acupuncture and herbal medicines, is still widely used among ischemic stroke patients as an adjuvant therapy for the prevention of secondary stroke and mortality7.

In this study, we investigated the risk of long-term mortality and the hospital readmission rate in mildly to moderately severe ischemic stroke patients treated with KM compared to those who did not receive KM treatments based on the National Health Insurance Service - National Sample Cohort (NHIS-NSC).


Data source

Data in the NHIS-NSC from 2010 and 2011, including a total of 1,011,725 patients, were analyzed in this study. The NHIS-NSC is a population-based cohort from 2002 to 2013 that was established by the NHIS in Korea27. The NHIS-NSC data provide personal information, demographics and medical treatment data based on National Health Insurance (NHI) claims from medical institutions to the NHIS from inpatient and outpatient clinic visits for each individual patient27. Specific information contained in the NHI claims data include principal and additional diagnoses, as well as hospitalization and outpatient treatment, dates of examinations, medical fees, details of medical services, prescribed medications, hospital codes, and patients’ sex and age; all information is accumulated and categorized based on the examination documented in the claims from the medical institutions28. The Korean Classification of Diseases, sixth revision (KCD-6), was used to code the diagnoses in the NHIS-NSC database and is based on the International Classification of Diseases, Tenth Revision, Clinical Modification (ICD-10-CM). For confidentiality and ethical considerations, the identification numbers of the individuals in the cohort were encrypted and transformed using a random number string. Written consent was not obtained from the study participants because the retrospective data used encrypted identification of the individuals. This study was given a formal waiver for the need for consent by the Institutional Review Board of Kyung Hee University.

Study population

In this nationwide retrospective cohort study, the claims data of a cohort of 1,011,725 patients was used to define a study population of ischemic stroke patients who were diagnosed from January 2010 to December 2011. In the dual-medical license system of Korea, doctors of Western medicine and doctors of Korean medicine separately diagnose and treat patients in different clinics and hospitals. In addition, the two groups of doctors consult and in diagnosis and treatment of patients, allowing for collaboration. Both of the medical treatments are reimbursed by NHIS, which allows for cross-identification of patients who used only the Western Medicine and those who used both Western and Korean Medicine. Therefore, our dataset includes patients who visited KM clinics in addition to the standard care in the WM clinics, and those who only visited WM clinics, of which both clinics include qualified clinicians with certified license by the state and with qualified diagnosis skills. Subjects included patients above the age of 18 years, with an inpatient claims record and admission of one day or more under the main disease diagnosis of the KCD-6 code I63 (ischemic stroke). The admission day of each newly diagnosed patient was defined as the index date for data analysis. To exclude patients who had medical histories of stroke and to remove the possibility of immortal time bias, all records of reported symptoms from 2002 to 2009 were examined for any form of stroke (Supplementary data 1). To ensure the validity of the diagnosis of ischemic stroke in our study cohort, only patients with a neuroimaging record of computerized tomography (CT) scans, magnetic resonance imaging (MRI), or magnetic resonance angiogram (MRA) when they were diagnosed with ischemic stroke were included. In addition, only patients with a medication record of antithrombotic, anticoagulant, or antiplatelet therapy (Supplementary data 2) between one day before and after the index date were included in the final study cohort.


The NHIS claims record was examined using reimbursement records of treatment in KM clinics after the index date of the ischemic stroke. Only the patients with treatment records in KM clinics after the discharge from the medical institution in which they were initially diagnosed with ischemic stroke and hospitalized were included in the cohort. The patients in the treated group received at least 3 treatment sessions, and the treatments included acupuncture, electroacupuncture, moxibustion, cupping therapies, and herbal complexes. Table 1 outlines the types of treatments and medical care that the KM-treated patients received. Only KM doctors with certified medical licenses are qualified to file NHIS claims for acupuncture treatment reimbursement; thus, the quality of acupuncture treatment in the medical institutions was indirectly controlled. Patients with and without treatments from KM clinics were followed from the index event until the end of 2013 to determine mortality as well as hospital readmission due to secondary stroke.

Table 1 Types of treatments received by KM-treated patients (n = 194) among ischemic stroke study cohort.


The long-term outcomes in this study included all-cause mortality and readmission due to any type of secondary stroke for more than 1 day, and with a neuroimaging record of computerized tomography (CT) scans, magnetic resonance imaging (MRI), or magnetic resonance angiogram (MRA). The NHIS-NSC cohort provided data on mortality as well as the admission records of all the patients included in the study.

Stroke severity

To assess the stroke severity of the ischemic stroke patients in the study cohort, surgery records (Supplementary data 3), Charles Comorbidity Index (CCI), bacterial sensitivity test, nasogastric intubation, urinary catheterization, intensive care unit (ICU) stay, and manual ventilation on the first diagnosis of the ischemic stroke were collected. To assess the underlying comorbidities of ischemic stroke, diseases including hypertension, diabetes, hyperlipidemia, myocardial infarction, and renal failure were identified as the key stroke risk factors that might contribute to stroke recurrence and compound the effectiveness of the acupuncture treatment1,2,4,29,30. Furthermore, anticoagulation therapy and antiplatelet therapy, as well as the types of medical institutions in which the patient was hospitalized were also assessed3,7. The length of stay upon the first admission was assessed by division into three categories: 7 days or less, between 8 and 28 days, and 29 days or longer. In further data analysis, we only included patients with a length of stay for 28 days or less to include patients with mild to moderately severe stroke symptoms and exclude patients who had limited access to KM treatments as a result of lower functional independence31,32.

Statistical analysis

A propensity score was calculated for each patient based on key baseline covariates with a known association with KM treatments or the outcomes in the study, including age, sex, economic status, disease severity according to the types of medical institutions, length of stay, and types of medication were also included in PSM calculation using the “nearest” method. We tested for difference-in-means of the variables between KM and non-KM groups before finalizing the selection of cohorts. We also did a correlation analysis on the corresponding set of scaled Schoenfeld residuals with time to test for independence between residuals and time. The resulted cohort which did not show differences in means of the variables was selected for further analysis.

Chi-square tests were used to compare the distributions of age, sex, economic status, comorbidities, types of medical institutions, length of stay, CCI, types of medications, and medical interventions between the groups with and without KM treatment. To eliminate the risk of immortal time bias, the KM treatment group’s observation period was adjusted to the time when the patient first visited the KM clinic. The Cox proportional hazards ratio was applied to calculate the hazard ratios (HRs) of mortality and readmission with 95% confidence intervals (CIs). Kaplan-Meier curve analysis was used to measure mortality over time, and the cumulative hazard curve was applied to measure readmission over time. In the Kaplan-Meier curve analysis of both mortality and readmission, patients were divided into subgroups by the length of hospital stay and medication to control for stroke severity. All statistical analyses were conducted using “MedicalRisk”, “ICD”, “survival” and “survsim” package in R software (version 3.2.3 “Wooden Christmas-Tree”,, with p < 0.05 representing statistical significance.


Baseline statistics

The final population of mild to moderately severe ischemic stroke patients from 2010 and 2011 (n = 448) was divided into two groups including those with (n = 108) or without (n = 340) adjuvant treatment from KM clinics according to the claims data. The cohort for survival analysis was developed with mild cases of ischemic stroke consisted of patients who stayed in the hospital for 8 to 28 days. Furthermore, as the non-KM treated group of mild ischemic stroke did not receive anticoagulant therapies, we also excluded this medication from the inclusion criteria of KM-treated group of patients. The resulted cohort (n = 194) was created from ischemic stroke patients between 2010 and 2011 with and without adjuvant treatment in KM clinics, from the index date to the last day of 2013. After the matching analysis by propensity scoring, no significant difference was found in socio-demographic factors, underlying comorbidities, length of stay, CCI, manual ventilation, nasogastric intubation, bacterial antibiotic sensitivity test, urinary catheterization, ICU stay, and the types of medication during hospitalized care during the first ischemic stroke, or the type of hospitalized medical institutions between the ischemic stroke patients with and without acupuncture treatment (Table 2).

Table 2 Baseline characteristics of propensity score-matched ischemic stroke study cohort with and without KM treatments.


During a mean follow-up time of 36.2 weeks (range: 0–200 weeks), a total of 35 patients (18%, 17 patients in KM cohort and 18 patients in non-KM cohort) died, and 148 patients (76.3%) were readmitted to the hospital for more than one day. The mortality rate was 68.04 per 1,000 population per year in KM cohort, and 47.27 per 1,000 population per year in non-KM cohort. The crude and adjusted propensity score-matched HRs for post-stroke all-cause mortality and readmissions due to secondary stroke are shown in Table 3. Patients who received KM treatment had a lower long-term risk of all-cause mortality with an adjusted propensity score-matched HR of 0.44 (95% CI, 0.21–0.93). The long-term risk of readmission did not differ significantly between patients with and without KM treatment (adjusted HR, 1.02; 95% CI, 0.73–1.43 and adjusted HR, 1.01; 95% CI, 0.30–3.38, respectively).

Table 3 Hazard ratios of all-cause mortality and readmission in propensity score-matched ischemic stroke study cohort with and without KM treatments.

Kaplan-Meier analysis showed that among the patients who stayed in the hospital for less than 8 days, patients in the non-KM treated group had higher mortality (log rank test, p = 0.02; Fig. 1A). Among the patients who stayed in the hospital for 8 to 28 days, KM and non-KM treated groups did not show any differences (Fig. 1B). In the case of readmission, KM and non-KM treated groups of the patients who stayed in the hospital for less than 8 days had no difference in the risk of readmission (Fig. 2A). Readmission of the patients who stayed in the hospital for 8 to 28 days also did not show any significant difference (Fig. 2B).

Figure 1
Figure 1

Estimated all-cause survival probability (%) for ischemic stroke patient cohort with and without treatments in Korean Medical clinics. Figure 1A: Survival probability of the patient cohort with length of stay for less than 8 days. (Log tank test, p = 0.02). Figure 1B: Survival probability of the patient cohort with length of stay for 8 to 28 days. (p = 0.70). X-axis: time of survival in weeks; Y-axis: estimated survival probability (%). Red line: patients who received KM treatments; Black line: patients who did not receive KM treatments.

Figure 2
Figure 2

Cumulative risk of readmission (%) for ischemic stroke patient cohort with and without treatments in Korean Medical clinics Fig. 2A: Readmission risk of the patient cohort who stayed in the hospital for less than 8 days (p = 0.60). Figure 2B: Readmission risk of the patient cohort who stayed in the hospital for 8 to 28 days (p < 0.001). X-axis: time of survival in weeks; Y-axis: cumulative risk of readmission (%). Red line: patients who received KM treatments; Black line: patients who did not receive KM treatments.


This study assessed the propensity score-matched risk of the long-term outcomes of all-cause mortality and recurrence, in mild to moderately severe ischemic stroke patients using the NHIS-NSC. The results of the Cox proportional hazards model showed a higher survival probability among patients treated in KM clinics than in non-treated patients, and no significant difference in the risk of hospital readmission was found among the treated and non-treated patients. Among the patients who did not stay for longer than one week after the onset of ischemic stroke, the KM-treated patients showed higher probability of survival. On the other hand, there were no significant differences of survival between KM and non-KM treated patients in the patient cohort who stayed for 8 to 28 days in the hospital. The analysis has been thoroughly controlled for the possibility of selection bias, and thus might imply the effect of Korean Medicine in the long-term survival of mild ischemic stroke patients. However, the cases of more severe patients who stayed for shorter period of time in the hospital have also been observed in previous studies33,34, and therefore, caution is required in the interpretation of this result. On the other hand, weak but consistent tendencies of KM treatment effects were observed in both mortality and recurrence of ischemic stroke, and the statistical significance may have been limited due to the conservative analytical approach taken in our study in creating the cohort and proportional hazards modeling.

This observational study took a large effort in minimizing selection bias and may further explain the heterogeneous results from previous studies. First, unlike previous studies that only employed the disease codes to define stroke20, this study defined newly diagnosed ischemic stroke patients in 2010 and 2011 through their neuroimaging records, the length of stay for the first ischemic stroke, and the medical prescriptions of antiplatelet and antithrombotic therapies in the claims data from one day before to one day after the index date. In addition, the medical histories from 2002 to the day before the index date were thoroughly examined for any record of cerebral disease. Second, while the severity of the stroke, in addition to socioeconomic variables, was not sufficiently accounted for in the previous studies, the severity of the patients was taken into account through their Charlson comorbidity index and underlying comorbidities such as hypertension, diabetes, and hypercholesterolemia, the risk factors of stroke3, the length of stay during their first stroke32, and the type of medical institution in which they were hospitalized29,30,31. We also analyzed the stroke severity through the records of medical interventions including length of stay, ICU stay, bacterial antibiotics sensitivity test, urinary catheterization, nasogastric intubation, and manual ventilation. Our study analyzed only mild to moderately severe ischemic stroke patients to include patients with sufficient functional independence to access adjuvant KM treatments35,36.

The observed effects of KM treatments, including acupuncture, in all sessions in this study are consistent with two recent randomized trials with long-term follow-up periods9,37. While a limited improvement of leg function37 and a tendency of reduced mortality and functional dependency was observed in acupuncture-treated patients9, limited evidence and a remaining demand for a larger randomized trial with long-term observation of the effectiveness of acupuncture after stroke still exist. However, the exact mechanisms responsible for the possible lower risk of mortality of after KM treatment remain to be clarified21. Previous studies have suggested that the salutary actions of acupuncture affect vascular function in ischemic stroke patients22,23,24,25. Pretreatment using electroacupuncture may reduce the size of an infarct through regulation of the endocannabinoid system and improve the neurological outcome26. Therapeutic aid by acupuncture in some stroke patients may increase physical activity and reduce stroke recurrence risk, in addition to improving the rehabilitation outcome38,39. Despite the insufficient explanation of the mechanism of acupuncture in stroke patients and the lack of solid evidence regarding its clinical utility13, several recent studies have shown some improvement in stroke outcome through acupuncture treatment9,13. On the other hand, herbal complexes have been suggested as useful agents for various issues such as recovery of motor function40,41,42, sensory disturbances43, emotional problems44, cognitive dysfunction45, aphasia46 and prevention of recurrence47. The assumed mechanism of herbal medicines in stroke is an anti-inflammatory effect on neuro-inflammation48. Furthermore, previous studies suggest that herbal medicines have antihypertensive49 and antilipidemic effects.

This study has several limitations. First, the retrospective cohort did not include detailed information on the biochemical measures, including clinical features of stroke such as the location of specific lesions and factors related to lifestyles. The types of different medications and their possible implications in the post-stroke quality of life need to be assessed in the future as well. In addition, the combination of treatments received in the KM clinics vary among patients, which only allows to estimate a general effect of KM treatments. We also cannot exclude that the results from this study are influenced by confounding factors due to the observational nature of our study design; furthermore, the risk of selection bias as well as the limits of propensity score matching can’t be overlooked50. However, the selection of eligible patients with a length of stay of 29 days or less, as well as patients among this group who received treatments in KM clinics, was performed from a cohort of 1,011,725 patients which reduces the risk of selection bias. In addition, covariates based on previous were included in setting the propensity score; and the difference-in-means were tested for each covariate between groups with and without KM treatments to minimize the risk of confounding factors through a combination of restriction, propensity score matching, and multivariable regression50,51.

In conclusion, this study assessed the efficacy of KM treatments including acupuncture and herbal medicines that were used as an adjunct to standard care in post-stroke management. While the results need to be interpreted with caution, KM-treated patients showed higher survival probability of stroke, and although insignificant, a weak tendency of reduced long-term recurrence risk was observed. Although the result does not fully support the utilization of KM to prevent readmission or recurrence of secondary stroke, it may have an effect on the overall survival of ischemic stroke patients. Large-scale clinical trials with long-term observations are needed to confirm the potential benefit of KM treatments and acupuncture for post-stroke management and rehabilitation.


The funders had no role in the study design, data collection and analysis, or the decision to publish the paper.

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This research was supported by a grant from Kyung Hee University in 2014 (KHU-20140692) and by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, ICT & Future Planning (NRF-2014R1A1A1038082). This study used NHIS-NSC data (NHIS-2014-2-011) from the National Health Insurance Service (NHIS). The author(s) declare no conflicts of interest with the NHIS.

Author information


  1. Acupuncture and Meridian Science Research Center, College of Korean Medicine, Kyung Hee University, Seoul, 02447, Republic of Korea

    • Ye-Seul Lee
    •  & Younbyoung Chae
  2. Department of Cardiology and Neurology, College of Korean Medicine, Kyung Hee University, Seoul, 02447, Republic of Korea

    • Seungwon Kwon
  3. Department of Preventive Medicine, College of Korean Medicine, Kyung Hee University, Seoul, 02447, Republic of Korea

    • Bo-Hyoung Jang
    •  & Seong-Gyu Ko


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Y.S.L. and B.H.J. planned the study design and the sample cohort. S.K. and Y.C. revised the experiment design and made stroke severity adjustments. S.G.K. prepared the figures. Y.S.L. analyzed the data and wrote the manuscript. B.H.J. and S.K. reviewed the data analysis and interpretations. Y.S.L. and Y.C. revised the manuscript.

Competing Interests

The authors declare that they have no competing interests.

Corresponding author

Correspondence to Bo-Hyoung Jang.

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