Residual Risk and Its Risk Factors for Ischemic Stroke with Adherence to Guideline-Based Secondary Stroke Prevention

Article information

J Stroke. 2021;23(1):51-60
Publication date (electronic) : 2021 January 31
doi : https://doi.org/10.5853/jos.2020.03391
aDepartment of Neurology, Beijing Tiantan Hospital, Capital Medical University, Beijing, China
bChina National Clinical Research Center for Neurological Diseases, Beijing, China
Correspondence: Yongjun Wang Department of Neurology, Beijing Tiantan Hospital, Capital Medical University, No.119, South 4th Ring West Road, Fengtai District, Beijing 100070, China Tel: +86-10-59975807 Fax: +86-10-59975807 E-mail: yongjunwang@ncrcnd.org.cn
Received 2020 August 12; Revised 2020 October 17; Accepted 2020 October 22.

Abstract

Background and Purpose

Despite administration of evidence-based therapies, residual risk of stroke recurrence persists. This study aimed to evaluate the residual risk of recurrent stroke in acute ischemic stroke or transient ischemic attack (TIA) with adherence to guideline-based secondary stroke prevention and identify the risk factors of the residual risk.

Methods

Patients with acute ischemic stroke or TIA within 7 hours were enrolled from 169 hospitals in Third China National Stroke Registry (CNSR-III) in China. Adherence to guideline-based secondary stroke prevention was defined as persistently receiving all of the five secondary prevention medications (antithrombotic, antidiabetic and antihypertensive agents, statin and anticoagulants) during hospitalization, at discharge, at 3, 6, and 12 months if eligible. The primary outcome was a new stroke at 12 months.

Results

Among 9,022 included patients (median age 63.0 years and 31.7% female), 3,146 (34.9%) were identified as adherence to guideline-based secondary prevention. Of all, 864 (9.6%) patients had recurrent stroke at 12 months, and the residual risk in patients with adherence to guidelinebased secondary prevention was 8.3%. Compared with those without adherence, patients with adherence to guideline-based secondary prevention had lower rate of recurrent stroke (hazard ratio, 0.85; 95% confidence interval, 0.74 to 0.99; P=0.04) at 12 months. Female, history of stroke, interleukin-6 ≥5.63 ng/L, and relevant intracranial artery stenosis were independent risk factors of the residual risk.

Conclusions

There was still a substantial residual risk of 12-month recurrent stroke even in patients with persistent adherence to guideline-based secondary stroke prevention. Future research should focus on efforts to reduce the residual risk.

Introduction

Patients with acute ischemic stroke or transient ischemic attack (TIA) suffer from approximately 10% to 17% risk of recurrent stroke during the first year after symptom onset [1,2]. Intensive quality improvement in adherence to performance measures was showed to improve the prognosis of stroke [3]. In recent years, there has been substantial decrease in the risk of stroke recurrence [4,5], mainly due to improvement of ischemic stroke and TIA management, especially increased adherence to guideline-based secondary prevention medications (e.g., antithrombotic, antihypertensive, antidiabetic, lipid-lowing and anticoagulant treatment) [6]. However, the residual risk of stroke recurrence in patients with persistent adherence to guideline-based secondary stroke prevention is not yet estimated. Furthermore, it is noted that despite administration of these evidence-based therapies, substantial residual risk of stroke recurrence persists [7], indicating that the current guideline-based interventions do not adequately account for all the pathways that lead to stroke recurrence. Besides traditional vascular risk factors, there may be other risk factors (e.g., chronic inflammation) that contribute to the residual risk of stroke recurrence [8,9] which might indicate the direction of efforts for stroke management in the future.

We therefore evaluated the residual risk of recurrent stroke in acute ischemic stroke or TIA with persistent adherence to guideline-based secondary stroke prevention, and identify the risk factors of the residual risk, using data from a nationwide prospective registry of patients with acute ischemic stroke and TIA in China.

Methods

Study design and participants

Data were derived from the Third China National Stroke Registry (CNSR-III), a large scale nationwide prospective registry of acute ischemic cerebrovascular events in China [10]. The CNSR-III enrolled 15,166 consecutive patients with ischemic stroke and TIA from 201 hospitals in China between August 2015 and March 2018 [10]. The primary objectives of the CNSR-III were to establish Chinese ischemic cerebrovascular disease etiology classification based on standard diagnosis procedures and identify imaging and biological markers for prognosis of ischemic stroke. Patients with acute ischemic stroke or TIA within 7 days from symptoms onset and age older than 18 were enrolled in this study. Acute ischemic stroke was diagnosed according to the World Health Organization criteria [11] with confirmation by brain magnetic resonance imaging (MRI) or computed tomography (CT). The protocol of CNSR-III was approved by the ethics committee of Beijing Tiantan Hospital (KY2015-001-01) and each participating site. Written informed consent was obtained from each participant or his/her representative before data collection. Data are available to researchers on request for purposes of reproducing the results by directly contacting the corresponding author.

Among all the participating sites, 169 sites had prior experience in collecting blood samples and imaging data, and agreed to participate in both the pre-specified biomarker substudy and imaging substudy. We only included patients from these 169 sites in this analysis. Patients with missing data for low-density lipoprotein cholesterol (LDL-C), high-sensitive C-reactive protein (hsCRP), interleukin-6 (IL-6) or serum creatinine were excluded from this analysis.

Baseline data collection

Trained investigators (neurologists from participating hospitals) collected baseline data through face-to-face interviews with standard operating protocol. Baseline data included demographics, medical history (prior stroke, coronary heart disease, hypertension, diabetes mellitus, dyslipidemia, and atrial fibrillation), smoking and drinking status, prestroke modified Rankin Scale, National Institutes of Health Stroke Scale (NIHSS) score at admission, and medication use.

Blood sample collection and laboratory tests

Blood samples were collected within 24 hours of admission (median time of 55 hours after index event onset). Plasma specimens were extracted, aliquoted and transported through cold chain to the central laboratory in Beijing Tiantan Hospital and stored at –80℃ refrigerator until tests were performed centrally and blindly.

Total cholesterol (TC), triglycerides, high-density lipoprotein cholesterol (HDL-C), LDL-C, IL-6, lipoprotein-associated phospolipase A2 (Lp-PLA2), Lp-PLA2 activity (Lp-PLA2-A), hsCRP, monocyte chemoattractant protein-1, and serum creatinine were measured centrally. Then, non-HDL-C was calculated as TC-(HDL-C), and remnant lipoprotein cholesterol, corresponding to all cholesterol not found in LDL-C and HDL-C, was calculated as TC-(HDL-C)-(LDL-C) [12]. Estimated glomerular filtration rate (eGFR) were calculated using the Chinese modified equations from Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) with adjusted coefficient of 1.1 for the Asian population [13]. An eGFR of <60 mL/min/1.73 m2 indicated a reduced renal dysfunction [14].

Imaging data collection

Brain imaging (MRI or CT), at least one vascular assessment for intracranial and extracranial arteries, and heart examination were performed at baseline following standard protocols [10]. Sequences of brain MRI examinations included T1 weighted, T2 weighted, fluid-attenuated inversion recovery, diffusion-weighted imaging (DWI) with apparent diffusion coefficient maps, and magnetic resonance angiography. Imaging data were collected in Digital Imaging and Communications in Medicine (DICOM) format on discs and sent to the image research center in Beijing Tiantan Hospital. All MRI images were read centrally by two readers (Z.L. and J.J.) who were blinded to each other and patients’ clinical information. Disagreement was further reviewed by a third reader (X.M.) and resolved by consensus.

Acute infarction was diagnosed according to the presence of hyperintense on the DWI and further classified to single acute infarction (uninterrupted lesions visible in contiguous territories) and multiple acute infarctions (more than one lesion that was topographically distinct) [4]. The presence of relevant intracranial artery stenosis (ICAS) was defined as 50% to 99% stenosis or occlusion of at least one of major intracranial artery segments relevant to the index event according to the Warfarin-Aspirin Symptomatic Intracranial Disease Trial (WASID) criteria [15]. Based on patient’s features combined with the results of 1 or more of aforementioned diagnostic tests, all patients were classified according to the Trial of Org 10172 in Acute Stroke Treatment (TOAST) criteria [16]: large-artery atherosclerosis (LAA), cardioembolism (CE), small-artery occlusion, other determined cause and undetermined cause.

Patients follow-up and outcomes

Patients were followed up by face-to-face interview at 3 months and by telephone interview at 6 and 12 months by trained research coordinators based on a standardized interview protocol. Information collected at each follow-up included cardio-/cerebrovascular events, all causes of death and medications use. Vascular events were confirmed from the treating hospital and death was either confirmed on a death certificate from the attended hospital or the local citizen registry.

The primary outcome was a new stroke defined as an aggravated primary neurologic deficit (NIHSS score increased by 4 points or above), a new neurological deficit lasting more than 24 hours or re-hospitalization with a diagnosis of ischemic stroke, intracerebral hemorrhage, or subarachnoid hemorrhage [11]. The secondary outcomes included composite vascular event (stroke, myocardial infarction, or vascular death) and all cause death.

Secondary prevention care

Medications use during hospitalization, at discharge and 3-, 6-, and 12-month follow-up were also recorded. Data regarding medications during hospitalization and at discharge were collected through medical records and data regarding medications during follow-up visits were collected by interviews between site investigators (neurologists) and patients. We used five evidence-based interventions [17] to document the performance of secondary prevention care of ischemic cerebrovascular event for each patient. It includes (1) antithrombotic treatment for patients who had no contraindications; (2) statins use for patients with dyslipidemia or LDL-C ≥100 mg/dL who had no contraindications; (3) antihypertensive agents use for patients with hypertension who had no contraindications; (4) antidiabetic agents use for patients with diabetes mellitus who had no contraindications; and (5) anticoagulant agents use for atrial fibrillation who had no contraindications. Adherence to guideline-based secondary stroke prevention was expressed as an all-or-none measure and defined as proportion of patients who persistently received all of the five-performance measures at all visits (during hospitalization, at discharge, at 3, 6, and 12 months) for which the patient was eligible [3].

Statistical analysis

Administration of each and total secondary prevention care performance measures at each visit were calculated and presented as proportion. Baseline variables were presented as median with interquartile range (IQR) for continuous variables and percentages for categorical variables. Baseline variables between patients included in and excluded from this analysis, and those with and without recurrent stroke were compared by using Wilcoxon rank sum test for continuous variables, and chi-square test for categorical variables, respectively. Balance of baseline characteristics between patients with and without adherence to guideline-based secondary stroke prevention was checked using the absolute standardized difference. An absolute standardized difference greater than 0.10 is approximately equivalent to P<0.05 and indicates significant imbalance of a baseline covariate between groups [18].

The associations between adherence to guideline-based secondary stroke prevention and outcomes were assessed using usual univariable and multivariable Cox proportional hazards model for outcomes of stroke, composite vascular event and death. Age, sex, and all the covariates with an absolute standardized difference greater than 0.10 in the univariable analyses were adjusted in the multivariable models, including hypertension, diabetes, atrial fibrillation, TC, LDL-C, non-HDL-C, and stroke etiology. The proportional hazards assumption for the Cox model was tested by adding a time-dependent covariate with interaction of group and a logarithmic function of survival time in the model. We further used the Fine and Gray regression model for a subdistribution function treating non-stroke/non-vascular death as a competing event [19]. In sensitivity analysis, the associations were further assessed using a propensity score approach with inverse probability of treatment weighted estimation. The propensity score for adherence to guideline-based secondary prevention was generated for each patient regardless of the outcome by using a nonparsimonious multivariable logistic regression model with all covariates in Table 1 included in the model. Inverse probability of treatment weighted estimation was then defined as the inverse of the estimated propensity score for patients with adherence to guideline-based secondary stroke prevention and the inverse of one minus the estimated propensity score for those without adherence to guidelinebased secondary stroke prevention [20]. Hazard ratios (HRs) with their 95% confidence intervals (CIs) were calculated.

Baseline characteristics of study population

Risks of recurrent stroke at 12 months were calculated in total population (indicating risk under current clinical practice) and those with adherence to guideline-based secondary stroke prevention (indicating residual risk under adherence to guideline-based secondary stroke prevention) in all patients and each etiological subtype, respectively. Receiver operating characteristic (ROC) cure analysis was used to identify the cut-off point of IL-6 for recurrent stroke. Independent risk factors of residual risk for 12-month recurrent stroke were determined using multivariable Cox regression in patients with adherence to guideline-based standard secondary prevention. All the covariates with P<0.05 in the univariable analysis were included in the model and selected with stepwise method. Based on the results of multivariable regression, residual risk of recurrent stroke was further estimated in a hypothetical scenario with anti-inflammatory therapy and treatment for ICAS in population with adherence to guideline-based secondary stroke prevention using the data of population without these two risk factors. We presented the time to first new stroke in different scenarios by the Kaplan-Meier curves.

To assess the contribution of each risk factor to the residual risk of new stroke, attributable risk percent (ARP) (1) and population attributable risk percent (PARP) (2) were calculated as follows [21]:

ARP = (Ie – I0)/Ie × 100%, (1)

PARP = (It – I0)/It × 100%, (2)

It denotes rate of new stroke in the total population; I0 is rate of new stroke in population without the risk factor; Ie is rate of new stroke in population with the risk factor.

All analyses were conducted with SAS software version 9.4 (SAS Institute Inc, Cary, NC, USA). P-values less than 0.05 were considered statistically significant and all tests were 2-sided.

Results

Study participants and characteristics

A total of 9,733 patients with ischemic stroke or TIA in 169 sites participated in both the biomarker and imaging substudies. After further exclusion of 711 patients with missing data of laboratory tests or lost to follow-up at 12 months, a total of 9,022 patients with ischemic stroke or TIA were included in this analysis (Figure 1). Patients included in and those excluded from this analysis were largely comparable (Supplementary Table 1). Among these patients, 2,862 (31.7%) were female and the median age was 63.0 years (IQR, 55.0 to 70.0); 8,424 (93.4%) patients had an index event of ischemic stroke and 598 (6.6%) patients had TIA (Table 1). The median of NIHSS score at admission was 3 (IQR, 1 to 6).

Figure 1.

Flow chart of study population. TIA, transient ischemic attack; CNSR-III, Third China National Stroke Registry; MRI, magnetic resonance imaging; LDL-C, low-density lipoprotein cholesterol; hsCRP, high-sensitive C-reactive protein; IL-6, interleukin-6.

Administration of secondary prevention medication

Among all the eligible patients, there were 97.4%, 96.8%, 80.4%, 60.4%, and 28.6% patients received the antithrombotic treatment, statin, antidiabetic, antihypertensive, and anticoagulant agents during hospitalization, respectively (Supplementary Figure 1). Administration of these secondary prevention medications at discharge and at 3, 6, and 12 months were almost similar to that during hospitalization, but a little lower for antithrombotic treatment, statin, and antidiabetic treatment and a little higher for antihypertensive and anticoagulant treatment (Supplementary Figure 1). There were 61.0%, 62.3%, 59.3%, 58.1%, and 54.4% patients adherent to all the five performance measures at each visit (during hospitalization, at discharge, at 3, 6, and 12 months), respectively.

Among all patients, there were 3,146 (34.9%) patients with adherence to guideline-based secondary stroke prevention (received all the five performance measures at all visits). Compared with those without adherence, patients with adherence to guideline-based secondary stroke prevention were younger, less likely to have medical histories (hypertension, diabetes, atrial fibrillation) and CE etiological subtype, had lower level of TC, LDL-C, and non-HDL-C (Table 1).

Residual risk of recurrent stroke and risk factors

Among all the 9,022 patients, 864 (9.6%) and 912 (10.1%) patients had recurrent stroke and composite vascular event at 12 months, respectively. Compared with those without adherence, patients with adherence to guideline-based secondary stroke prevention had lower rate of new stroke (8.3% vs. 10.2%; adjusted hazard ratio [aHR], 0.85; 95% CI, 0.74 to 0.99; P=0.04) and composite vascular event (8.7% vs. 10.9%; aHR, 0.85; 95% CI, 0.74 to 0.98; P=0.03) at 12 months (Table 2 and Figure 2). All of the proportional hazard assumptions were met (P=0.16 for new stroke and P=0.10 for composite vascular event). Similar results were observed using competing-risks models and propensity score approaches with inverse probability of treatment weighted estimation (Table 2). Further analysis showed that adherence to guideline-based secondary prevention care mainly reduced the residual risks in LAA subtype (Supplementary Table 2).

Outcomes at 12 months in patients with or without adherence to guideline-based secondary prevention

Figure 2.

Residual risk of recurrent stroke in different scenarios. IL-6, interleukin-6; ICAS, intracranial artery stenosis.

Among patients with adherence to guideline-based secondary stroke prevention, those with recurrent stroke at 12 months were more likely to be female, have history of stroke and diabetes, multiple infarctions, relevant ICAS and LAA etiological subtype, higher level of hsCRP and IL-6, but less likely to be current smoking (Supplementary Table 3). In the multivariable regression model, female, history of stroke, higher IL-6 level, and relevant ICAS were independent risk factors of residual risk of 12-month new stroke (Table 3).

Independent risk factors of residual risk of 12-month recurrent stroke

Higher IL-6 level (defined by cut-off values of ≥5.63 ng/L derived from the ROC analysis) and relevant ICAS attributed to 11.2% and 14.6% of the total population residual risk respectively, and together contributed to 17.6%. Residual risk of 12-month recurrent stroke was estimated to be 6.9% in hypothetical scenario with further anti-inflammatory therapy and treatment for ICAS estimated using data of subgroup patients without these two risk factors in population with adherence to guideline-based secondary stroke prevention (Figure 2 and Supplementary Table 2).

Discussion

In the nationwide, multicenter, prospective registry in China, we found that although substantially reduced by secondary prevention treatment, there was still 8.3% residual risk of 12-month recurrent stroke even in patients with persistent adherence to guideline-based secondary stroke prevention. Female, history of stroke, higher IL-6 level, and relevant ICAS were independent risk factors of the residual risk. Hypothetical anti-inflammatory therapy and treatment for ICAS may be associated with further reduction of approximately 17% of the residual risk in population with adherence to guideline-based secondary stroke prevention.

The residual risk of recurrent stroke in patients under guideline-based secondary prevention management has not been well-estimated and varied ranging from approximately 6% to 14% at 12 months [7,22,23]. Differences in patient characteristics, severity of stroke, intensity of secondary prevention management, different ethnicities, and setting of studies may contribute to the heterogeneity of these estimates. Our study observed 8.3% residual risk of 12-month recurrent stroke despite administration of these evidence-based therapies in a nationwide, prospective registry in China. Future research may focus on identification of non-traditional risk factors and specific effective strategies to further reduce the residual risk in patents under guideline-based secondary prevention management.

Recent studies demonstrated that chronic inflammation was an independent predictor of vascular events both in primary and secondary prevention setting [24-27]. In population-based studies, elevated IL-6 was found to be associated with subclinical atherosclerosis and incident stroke [24,25]. Other previous studies demonstrated that patients with elevated hsCRP had an increased risk of recurrent stroke [26,27]. Although anti-inflammatory therapy with canakinumab can reduce the rate of recurrent cardiovascular events in patients with myocardial infarction in the Canakinumab Anti-inflammatory Thrombosis Outcome Study (CANTOS) trial [28], well-designed randomized trial of anti-inflammatory therapy in patients with ischemic stroke has not yet been performed. Our study showed that inflammation was an independent risk factor of recurrent stroke even in patients under guideline-based secondary prevention medications, emphasizing that anti-inflammatory therapy might be considered in secondary prevention clinical practice. Therefore, randomized trials estimating the effect of anti-inflammatory therapy in patients with ischemic stroke should be performed in future.

A previous study showed a high prevalence (46.6%; relevant or not) of ICAS in patients with cerebrovascular disease and it was an independent predictor for recurrent stroke [29]. Despite its heavy burden, there is no specific treatment for ICAS. The Stenting and Aggressive Medical Management for Preventing Recurrent stroke in Intracranial Stenosis (SAMMPRIS) trial demonstrated benefit of aggressive medical management over stenting in high-risk patients with ICAS [30]. Our study showed that even with persistent adherence to guideline-based secondary prevention medications, relevant ICAS was still an important independent risk factor of the residual risk, indicating that more aggressive intervention should be developed to treat this risk factor.

This study has several limitations. First, although secondary prevention medications were administrated in each visit, whether secondary prevention goals (blood pressure, glucose, and lipoprotein lowing, etc.) were achieved was not assessed, thus leading to a potential misclassification of patients. Insufficient control of the risk factors in the real world may lead to overestimate the residual risk. Second, patients with adherence to guideline-based secondary stroke prevention had less vascular risk factors than those without adherence, which may cause underestimate the residual risk. Third, residual risk in hypothetical scenario with treatment for inflammation and ICAS was estimated using the data of population without these two risk factors. This may be different from the real effect of the treatments. Fourth, high level of inflammatory markers like hsCRP and IL-6 may increase due to stress response to the acute events and not reflect chronic inflammation. Fifth, medications during follow-up visits were collected by interviews between neurologists and patients. Patients’ false recall and their little understanding of the medication may attenuate recorded information’s validity. Finally, the external generalizability of our findings is limited as participants were restricted to Chinese patients. Selection bias may also exist as the low proportion of atrial fibrillation (7.0% in CNSR-III vs. 9.6% in CNSR-II [31]) and rate of death (3.2% in CNSR-III vs. 8.4% in CNSR-II [31]) were observed in this population. Further validation was required in other populations or settings.

Conclusions

In patients with ischemic stroke or TIA and persistent adherence to guideline-based secondary stroke prevention, there was still a substantial residual risk of 12-month recurrent stroke. Female, history of stroke, inflammation, and relevant ICAS were independent risk factors of the residual risk. Future research should focus on efforts to reduce the residual risk targeting these non-traditional risk factors.

Supplementary materials

Supplementary materials related to this article can be found online at https://doi.org/10.5853/jos.2020.03391.

Supplementary Table 1.

Baseline characteristics of patients included in and excluded from this analysis

jos-2020-03391-suppl1.pdf
Supplementary Table 2.

Risk for 12-month recurrent stroke according to etiological subtypes

jos-2020-03391-suppl1.pdf
Supplementary Table 3.

Baseline characteristics of patients with adherence to guideline-based secondary stroke prevention according to 12-month recurrent stroke or not

jos-2020-03391-suppl2.pdf
Supplementary Figure 1.

Administration of secondary prevention medications for ischemic stroke and transient ischemic attack.

jos-2020-03391-suppl3.pdf

Notes

Disclosure

The authors have no financial conflicts of interest.

Acknowledgements

This study is supported by grants from the National Science and Technology Major Project (2017ZX09304018), National Key R&D Program of China (2018YFC1312903, 2017YFC1310902, 2018YFC1311700 and 2018YFC1311706), National Natural Science Foundation of China (81971091), Beijing Hospitals Authority Youth Programme (QML20190501), Beijing Municipal Science & Technology Commission (D171100003017002, Z18110000 1818001).

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Article information Continued

Figure 1.

Flow chart of study population. TIA, transient ischemic attack; CNSR-III, Third China National Stroke Registry; MRI, magnetic resonance imaging; LDL-C, low-density lipoprotein cholesterol; hsCRP, high-sensitive C-reactive protein; IL-6, interleukin-6.

Figure 2.

Residual risk of recurrent stroke in different scenarios. IL-6, interleukin-6; ICAS, intracranial artery stenosis.

Table 1.

Baseline characteristics of study population

Characteristic Unadjusted
Inverse probability of treatment weighted
Total (n=9,022) Without adherence to guideline-based secondary prevention (n=5,876) With adherence to guideline-based secondary prevention (n=3,146) ASD Without adherence to guideline-based secondary prevention (n=8,904) With adherence to guideline-based secondary prevention (n=8,914) ASD
Age (yr) 63.0 (55.0–70.0) 63.0 (55.0–71.0) 62.0 (54.0–69.0) 0.116 63.0 (55.0–70.0) 63.0 (54.0–70.0) 0.005
Female sex 2,862 (31.7) 1,874 (31.9) 988 (31.4) 0.011 2,833 (31.8) 2,830 (31.8) 0.000
Body mass index (kg/m2) 24.5 (22.6–26.6) 24.5 (22.6–26.6) 24.5 (22.5–26.7) 0.000 24.5 (22.6–26.6) 24.5 (22.5–26.6) 0.006
Current smoking 2,831 (31.4) 1,857 (31.6) 974 (31.0) 0.013 2,789 (31.3) 2,817 (31.6) 0.006
Regular drinking 1,271 (14.1) 877 (14.9) 394 (12.5) 0.070 1,254 (14.1) 1,254 (14.1) 0.000
Medical history
Prior stroke 2,035 (22.6) 1,391 (23.7) 644 (20.5) 0.077 2,004 (22.5) 1,974 (22.1) 0.010
Coronary artery disease 932 (10.3) 640 (10.9) 292 (9.3) 0.053 914 (10.3) 882 (9.9) 0.013
Hypertension 5,673 (62.9) 3,974 (67.6) 1,699 (54.0) 0.281 5,599 (62.9) 5,613 (63.0) 0.002
Diabetes 2,136 (23.7) 1,503 (25.6) 633 (20.1) 0.131 2,111 (23.7) 2,111 (23.7) 0.000
Dyslipidemia 753 (8.3) 504 (8.6) 249 (7.9) 0.025 744 (8.4) 740 (8.3) 0.004
Atrial fibrillation 629 (7.0) 556 (9.5) 73 (2.3) 0.309 625 (7.0) 612 (6.9) 0.004
Prestroke mRS 2–5 788 (8.7) 552 (9.4) 236 (7.5) 0.068 770 (8.6) 737 (8.3) 0.011
Index event 0.008 0.000
TIA 598 (6.6) 385 (6.6) 213 (6.8) 592 (6.6) 591 (6.6)
Ischemic stroke 8,424 (93.4) 5,491 (93.4) 2,933 (93.2) 8,312 (93.4) 8,323 (93.4)
NIHSS at admission 3 (1–6) 3 (1–6) 3 (1–6) 0.072 3 (1–6) 3 (1–6) 0.002
Laboratory tests
TG (mmol/L) 1.37 (1.03–1.87) 1.37 (1.03–1.88) 1.37 (1.03–1.86) 0.021 1.37 (1.03–1.87) 1.38 (1.04–1.88) 0.015
TC (mmol/L) 3.99 (3.32–4.76) 4.05 (3.36–4.83) 3.87 (3.27–4.63) 0.107 4.03 (3.34–4.78) 3.96 (3.31–4.73) 0.018
LDL-C (mmol/L) 2.34 (1.74–3.01) 2.39 (1.78–3.07) 2.24 (1.69–2.88) 0.123 2.37 (1.75–3.03) 2.32 (1.74–2.99) 0.014
HDL-C (mmol/L) 1.08 (0.91–1.29) 1.08 (0.91–1.29) 1.08 (0.91–1.28) 0.033 1.08 (0.91–1.29) 1.09 (0.92–1.29) 0.000
Non-HDL-C (mmol/L) 2.88 (2.25–3.59) 2.94 (2.29–3.66) 2.80 (2.19–3.46) 0.103 2.91 (2.28–3.61) 2.86 (2.24–3.57) 0.018
RemnantC (mmol/L) 0.47 (0.21–0.77) 0.47 (0.20–0.77) 0.48 (0.23–0.77) 0.017 0.47 (0.21–0.77) 0.46 (0.22–0.76) 0.012
hsCRP (mg/L) 1.74 (0.81–4.54) 1.80 (0.83–4.78) 1.64 (0.77–4.12) 0.025 1.74 (0.82–4.65) 1.73 (0.79–4.37) 0.005
IL-6 (ng/L) 2.66 (1.61–5.01) 2.71 (1.63–5.11) 2.56 (1.56–4.78) 0.042 2.66 (1.61–4.98) 2.63 (1.60–4.82) 0.009
MCP-1 (ng/L) 258.2 (200.8–335.8) 258.8 (200.2–336.2) 257.4 (201.4–334.8) 0.009 258.8 (200.2–335.4) 257.6 (202.1–336.1) 0.004
Lp-PLA2-A (nmol/min/mL) 162.0 (128.0–194.4) 162.9 (128.1–194.8) 160.8 (127.9–193.7) 0.032 162.1 (127.8–194.2) 161.9 (129.3–195.0) 0.001
Lp-PLA2-Mass (ng/mL) 173.4 (126.0–224.0) 175.0 (126.7–226.8) 170.6 (125.3–219.0) 0.069 174.2 (126.5–225.3) 173.9 (127.5–223.8) 0.003
eGFR <60 mL/min/1.73 m2 689 (7.6) 484 (8.2) 205 (6.5) 0.065 681 (7.7) 709 (8.0) 0.011
Infarction pattern
No infarction 1,299 (14.4) 858 (14.6) 441 (14.0) 0.009 1,284 (14.4) 1,271 (14.3) 0.003
Single infarction 3,867 (42.9) 2,433 (41.4) 1,434 (45.6) 0.085 3,828 (43.0) 3,854 (43.2) 0.004
Multiple infarctions 3,856 (42.7) 2,585 (44.0) 1,271 (40.4) 0.073 3,792 (42.6) 3,789 (42.5) 0.002
Relevant ICAS 2,596 (28.8) 1,727 (29.4) 869 (27.6) 0.040 2,555 (28.7) 2,526 (28.3) 0.009
Stroke etiology
Large-artery atherosclerosis 2,333 (25.9) 1,503 (25.6) 830 (26.4) 0.018 2,297 (25.8) 2,306 (25.9) 0.002
Cardioembolism 561 (6.2) 448 (7.6) 113 (3.6) 0.175 555 (6.2) 559 (6.3) 0.004
Small-artery occlusion 2,063 (22.9) 1,284 (21.9) 779 (24.8) 0.069 2,046 (23.0) 2,065 (23.2) 0.005
Others 4,065 (45.1) 2,641 (44.9) 1,424 (45.3) 0.008 4,007 (45.0) 3,985 (44.7) 0.006

Values are presented as median (interquartile range) or number (%).

ASD, absolute standardized difference; mRS, modified Rankin Scale; TIA, transient ischemic attack; NIHSS, National Institutes of Health Stroke Scale; TG, triglyceride; TC, total cholesterol; LDL-C, low-density lipoprotein cholesterol; HDL-C, high-density lipoprotein cholesterol; RemnantC, remnant lipoprotein cholesterol; hsCRP, high-sensitive C-reactive protein; IL-6, interleukin-6; MCP-1, monocyte chemoattractant protein-1; Lp-PLA2-A, lipoprotein-associated phospolipase A2 activity; Lp-PLA2, lipoprotein-associated phospolipase A2; eGFR, estimated glomerular filtration rate; ICAS, intracranial artery stenosis.

Table 2.

Outcomes at 12 months in patients with or without adherence to guideline-based secondary prevention

Outcomes at 3 months Model Without adherence to guideline-based secondary prevention With adherence to guideline-based secondary prevention HR (95% CI) P
Stroke Univariable Cox regression 602 (10.2) 262 (8.3) 0.81 (0.70–0.93) 0.003
Multivariable Cox regression* 0.85 (0.74–0.99) 0.037
IPTW Cox regression 0.84 (0.76–0.92) <0.001
Univariable competing-risks model 0.80 (0.68–0.93) 0.004
Multivariable competing-risks model* 0.85 (0.72–0.99) 0.036
IPTW competing-risks model 0.80 (0.68–0.93) 0.004
Composite vascular event Univariable Cox regression 639 (10.9) 273 (8.7) 0.79 (0.69–0.91) 0.001
Multivariable Cox regression* 0.85 (0.74–0.98) 0.027
IPTW Cox regression 0.83 (0.75–0.91) <0.001
Univariable competing-risks model 0.76 (0.66–0.88) <0.001
Multivariable competing-risks model* 0.82 (0.71–0.95) 0.010
IPTW competing-risks model 0.76 (0.66–0.89) <0.001
Death Univariable Cox regression 224 (3.8) 68 (2.2) 0.56 (0.43–0.74) <0.001
Multivariable Cox regression 0.69 (0.52–0.91) 0.009
IPTW Cox regression 0.66 (0.55–0.78) <0.001

Values are presented as number (%).

HR, hazard ratio; CI, confidence interval; IPTW, inverse probability of treatment weighted.

*

Adjusted for age, sex, hypertension, diabetes, atrial fibrillation, triglyceride, low-density lipoprotein cholesterol, non-high-density lipoprotein cholesterol, and stroke etiology;

Composite vascular event was defined as a new stroke, myocardial infarction or vascular death.

Table 3.

Independent risk factors of residual risk of 12-month recurrent stroke

Characteristic aHR (95% CI) P It (%) I0 (n0/N0) Ie (ne/Ne) ARP (%) PARP (%)
Female sex 1.46 (1.14–1.87) 0.003 8.33 7.32 (158/2,158) 10.53 (104/988) 30.5 12.1
History of stroke 1.39 (1.06–1.83) 0.019 8.33 7.71 (193/2,502) 10.71 (69/644) 28.0 7.4
IL-6 ≥5.63 ng/L 1.65 (1.26–2.16) <0.001 8.33 7.40 (186/2,515) 12.04 (76/631) 38.5 11.2
Relevant ICAS 1.57 (1.22–2.02) <0.001 8.33 7.11 (162/2,277) 11.51 (100/869) 38.2 14.6

aHR, adjusted hazard ratio; CI, confidence interval; It, rate of new stroke in the total population; I0, rate of new stroke in population without the risk factor; Ie, rate of new stroke in population with the risk factor; ARP, attributable risk percent; PARP, population attributable risk percent; IL-6, interleukin-6; ICAS, intracranial artery stenosis.