Abstract
We determined the associations of follow-up blood pressure (BP) after stroke as a time-dependent covariate with the risk of subsequent ischemic stroke, as well as those of BP levels with the difference in the impact of long-term clopidogrel or aspirin monotherapy versus additional cilostazol medication on secondary stroke prevention. In a sub-analysis of a randomized controlled trial (CSPS.com), patients between 8 and 180 days after stroke onset were randomly assigned to receive aspirin or clopidogrel alone, or a combination of cilostazol with aspirin or clopidogrel. The percent changes, differences, and raw values of follow-up BP were examined. The primary efficacy outcome was the first recurrence of ischemic stroke. In a total of 1657 patients (69.5 ± 9.3 years, female 29.1%) with median 1.5-year follow-up, ischemic stroke recurred in 74 patients. The adjusted hazard ratio for ischemic stroke of a 10% systolic BP (SBP) increase from baseline was 1.19 (95% CI 1.03–1.36), that of a 10 mmHg SBP increase was 1.14 (1.03–1.28), and that of SBP as the raw value with the baseline SBP as a fixed (time-independent) covariate was 1.14 (1.00–1.31). Such significant associations were not observed in diastolic BP-derived variables. The estimated adjusted hazard ratio curves for the outcome showed the benefit of dual therapy over a wide SBP range between ≈120 and ≈165 mmHg uniformly. Lower long-term SBP levels after ischemic stroke were associated with a lower risk of subsequent ischemic events. The efficacy of dual antiplatelet therapy including cilostazol for secondary stroke prevention was evident over a wide SBP range.
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Introduction
Long-term treatment with cilostazol, a phosphodiesterase 3 inhibitor, coupled with aspirin or clopidogrel was shown to halve the risk of recurrent ischemic stroke and have a similar risk of severe or life-threatening bleeding compared to aspirin or clopidogrel alone in patients at high risk for recurrent noncardioembolic ischemic stroke in a randomized, controlled trial, the Cilostazol Stroke Prevention Study for Antiplatelet Combination (CSPS.com) [1]. Cilostazol is known to have a lower risk of bleeding than the other antiplatelet agents [2, 3], and the result of the safety outcome was within the expectations of the trial investigators. In contrast, the strong efficacy of the dual antiplatelet therapy (DAPT) with half the risk of recurrent ischemic stroke exceeded our assumptions to some extent. The possible clinical conditions causing such clear efficacy need clarification.
The post-stroke blood pressure (BP) level is predictive of recurrent stroke risk [4,5,6,7]. Several guidelines recommend intensive BP lowering for chronic stroke to prevent recurrent stroke [8,9,10]. Appropriate risk-factor modification would strengthen the preventive power of antithrombotic pharmacotherapy. Thus, BP control might have affected the main results of CSPS.com.
The primary research objective of the present sub-study was to determine the associations of long-term BP after stroke as a time-dependent covariate with the risk of subsequent ischemic events, including recurrent ischemic stroke, in the CSPS.com cohort. The secondary objective was to clarify the associations of follow-up BP level with the therapeutic superiority of cilostazol-based DAPT to monotherapy
Methods
Study design and setting
CSPS.com was a multicenter, randomized, open-label, parallel-group trial, involving participants from 292 sites across Japan registered from December 2013 through March 2017. The trial protocol, statistical analysis plan, design, and main and major post hoc results of CSPS.com have been reported previously [1, 11,12,13,14,15]. CSPS.com was registered in ClinicalTrials.gov NCT01995370 and the University Hospital Medical Information Network clinical trial registry in Japan UMIN 000012180 and approved by the ethics committee at each participating site. All patients gave written, informed consent before randomization. This study followed the Consolidated Standards of Reporting Trials (CONSORT) reporting guidelines.
Participants
Eligible patients were between 20 and 85 years of age who had a non-cardioembolic ischemic stroke identified on magnetic resonance imaging between 8 and 180 days before the start of the protocol treatment and were taking either aspirin or clopidogrel alone as antiplatelet therapy when providing informed consent. The patients were required to meet at least one of the following three criteria indicating a high risk for stroke recurrence: (a) ≥ 50% stenosis of a major intracranial artery; (b) ≥ 50% stenosis of an extracranial artery; and (c) two or more of the following risk factors (age ≥ 65 years, hypertension, diabetes mellitus, chronic kidney disease, peripheral arterial disease, history of ischemic stroke other than the qualifying one for this trial, history of ischemic heart disease, and current smoking). Additional information regarding the inclusion and exclusion criteria is provided elsewhere [1, 11]. For example, patients with emboligenic heart disease were excluded from the study. In this sub-study, patients with consistent BP data at baseline and at least once during the follow-up period were included.
Patients were randomly assigned in a 1:1 ratio to receive either monotherapy with aspirin (81 or 100 mg) or clopidogrel (50 or 75 mg) once daily or dual therapy with cilostazol (100 mg, twice daily, the recommended dose for stroke prevention in Japan) and either aspirin (81 or 100 mg) or clopidogrel (50 or 75 mg), once daily. Trial medication was continued for half a year or longer, for a maximum of 3.5 years. Changes in these three antiplatelet medications were not permitted after informed consent was obtained. Systolic and diastolic BPs (SBP, DBP) were measured in a sitting position at follow-up visits 1, 3, and 6 months later and every 6 months thereafter.
Outcomes
The primary efficacy outcome was the first recurrence of ischemic stroke. The secondary efficacy outcome was the first occurrence of a composite of stroke, myocardial infarction, and vascular death. The safety outcome was the first occurrence of severe or life-threatening bleeding as defined in the Global Utilization of Streptokinase and Tissue Plasminogen Activator for Occluded Coronary Arteries classification [16]. These events have been defined elsewhere [1, 11].
Statistical analysis
Continuous data are reported as medians (interquartile range) or means ± standard deviation, and categorical data are presented as numbers (%). In principle, all BP data were treated as time-dependent covariates. The variables “percent change” and “difference” were derived as the ratio of BP values to baseline BP value and the difference from baseline at each time point, respectively. Note that these variables are still time-dependent covariates.
For example, consider a patient with a baseline BP value of 140 mmHg and follow-up BP values of 150, 140, and 130 mmHg. In the “raw value” analysis, the follow-up values of 150, 140, and 130 mmHg are directly used, with the baseline value of 140 mmHg serving as a fixed (time-independent) adjustment variable. In the “difference” analysis, the changes from the baseline are calculated as 10, 0, and −10 mmHg, respectively. For the “percent change” analysis, the converted values are computed as follows: (150/140)*100, (140/140)*100 and (130/140)*100, yielding percentages of 107%, 100%, and 93% respectively.
A Cox proportional hazards model was used to calculate adjusted hazard ratios (aHRs) and 95% confidence intervals (CIs) of the percent changes, differences, and raw values of BP. For the analysis of raw values, follow-up BP values were treated as time-dependent covariates, while baseline BP value was included as time-independent covariate. HRs are represented as per 10% for percent change and per 10 mmHg for difference and raw value. Multivariable adjustment was performed using sex, age, and variables that were proven to affect the outcomes of CSPS.com, including assigned treatment, antiplatelet agents at randomization, intracranial artery stenosis, and the timing of starting trial treatment [11,12,13,14]. The preventive effect of dual therapy relative to monotherapy on outcomes considering its interaction with BP levels was visualized using a generalized additive model. In brief, the hazard function was estimated through a generalized additive model of Poisson regression, which allows for flexible modeling of complex nonlinear relationships, and calculated aHR and 95% CI values were plotted against BP. All statistical analyses were performed using R version 4.2.0 (R Core Team 2022). Fitting the generalized additive model was done with pammtools and mgcv R packages.
Results
Of the total 1879 randomized patients, 222 were excluded from the present study due to lack of sufficient and consistent data on BP (or unclear description between the timing of events onset and that of follow-up BP measurement), and 1657 were finally studied; 790 were assigned to dual therapy and 867 to monotherapy (Fig. 1). Table 1 shows the patients’ baseline characteristics. Overall, average BP was 139.0 ± 19.7/79.0 ± 13.4 mmHg at baseline and 136.1 ± 12.6/77.0 ± 9.2 mmHg at mean follow-up. The median duration of follow-up was 1.5 years overall (interquartile range 1.0–2.3 years), resulting in 2700.9 person-years of follow-up. Ischemic stroke occurred in 74 patients, the composite of stroke, myocardial infarction, and vascular death occurred in 92 patients, and severe or life-threatening bleeding occurred in 18 patients. All severe or life-threatening bleeding events were symptomatic intracranial hemorrhages. Figure 2 shows BP levels at each visit. The median number of BP measurements per patient was 5 (interquartile range: 4–7).
Primary outcome of ischemic stroke
Table 2 shows the associations of BP-derived variables with recurrent ischemic stroke. When BP was treated as a time-dependent covariate, the aHR of a 10% SBP increase from baseline was 1.19 (95% CI: 1.03–1.36), and that of a 10 mmHg SBP increase from baseline was 1.14 (1.03–1.28). With the baseline SBP as a fixed (time-independent) covariate, the aHR of SBP was 1.14 (1.00–1.31) per 10 mmHg. On the other hand, no DBP-derived variables showed significant associations with the outcome.
Table 3 shows the associations of SBP-derived variables with recurrent ischemic stroke in subgroups by assigned antiplatelet therapy and those by the antiplatelet agent at randomization. Similar numerical data with those in the overall patients were obtained in all subgroups, with significant associations of the percent change and the difference in SBP in the monotherapy subgroup and the clopidogrel subgroup. Note that the event rate was somewhat higher in patients taking clopidogrel (50/973) than those taking aspirin (24/684). The difference was probably because the physicians preferred clopidogrel to aspirin for patients with history of ischemic stroke and those with intra-/extracranial artery stenosis, that showed clearly higher risk of recurrent ischemic stroke [1, 12].
Fig. 3A shows the aHR of dual therapy relative to monotherapy plotted against SBP. The estimated aHR curve for the outcome showed the benefit of dual therapy over a wide SBP range from ≈120 mmHg to ≈165 mmHg uniformly, with the greatest risk reduction when SBP was ≈150 mmHg.
Other outcomes
The aHR for the secondary outcome of composite events of a 10% and a 10 mmHg SBP increase from baseline was 1.18 (1.04–1.34) and 1.15 (1.04–1.26), respectively (Table 2). With the baseline SBP as a fixed covariate, the aHR of SBP was 1.15 (1.01–1.30). No DBP-derived variables showed significant associations with the outcome. The estimated aHR curve for the outcome showed the benefit of dual therapy relative to monotherapy over a wide SBP range from ≈120 mmHg to ≈160 mmHg uniformly (Fig. 3B).
No SBP-derived or DBP-derived variables showed significant associations with the safety outcome of severe or life-threatening bleeding (Table 2).
Discussion
This was a sub-analysis of the randomized CSPS.com trial to determine the effects of follow-up BP parameters as a time-dependent covariate on recurrent stroke risk. The first major finding of this study was that both ischemic stroke and composite cardiovascular events increased significantly as the variables derived from SBP increased, but not as the DBP-derived variables increased. The second major finding was that the benefit of dual therapy was uniformly observed over a wide SBP range, with the greatest risk reduction when SBP was ≈150 mmHg.
Cilostazol inhibits phosphodiesterase activity and suppresses cyclic adenosine monophosphate (cAMP) degradation, increases intracellular cAMP concentrations, activates the cAMP-dependent protein kinase A, and inhibits platelet aggregation [2, 3, 17]. Both cilostazol monotherapy and cilostazol-based long-term DAPT were recommended as the first-line antiplatelet agents for secondary stroke prevention in Japan [10] and several Asian countries based on the results of CSPS2 and CSPS.com [1, 18]. Cilostazol monotherapy was weakly recommended for stroke or transient ischemic attack attributable to moderate to severe intracranial artery stenosis in the United States of America [19]. Cilostazol has pleiotropic effects other than inhibiting platelet aggregation, such as a vasodilatory effect on smooth muscle cells via the increase in intracellular cAMP concentrations [20]. The vasodilation may cause mild BP lowering; a 2 to 4 mmHg lower SBP level was observed during cilostazol-based DAPT than during monotherapy throughout the follow-up period in the overall CSPS.com cohort [1].
Lower percent changes, differences, and raw values of SBP were associated with lower risks of ischemic stroke. This “the lower, the better” phenomenon in stroke survivors was common to the results of the Perindopril Protection Against Recurrent Stroke Study (PROGRESS) [4, 7], but different from those of the Prevention Regimen for Effectively Avoiding Second Strokes (PRoFESS) study, where the risk was higher for patients with SBP < 120 mmHg [21]. Since patients within 120 days after stroke were enrolled in PRoFESS and those within 5 years were enrolled in PROGRESS, failure of cerebral autoregulation during subacute stroke might have affected the results more in PRoFESS. In addition, the Secondary Prevention of Small Subcortical Strokes (SPS3) and Recurrent Stroke Prevention Clinical Outcome (RESPECT) trials showed a significant risk reduction of intracerebral hemorrhage in patients with a target SBP < 130 mm Hg or < 120 mmHg compared with a higher target but did not show the significant reduction of ischemic stroke [22,23,24]. A reason for the differences in results between these trials and ours is that in our study, SBP was treated as a time-dependent covariate, and our findings were not confined to a specific SBP range, such as around 130 mmHg. Additionally, the discrepancies may be due to the fact that patients’ SBP data were treated consecutively in our study, without grouping patients based on a specific SBP value. Another possible explanation was the higher percentage of patients assigned to dual therapy in the lower mean SBP population, since dual therapy excessively lowered SBP by 2 to 4 mmHg.
In contrast, the DBP-derived variables were not associated with the outcome. The J-shaped relationship between DBP and adverse cardiovascular outcomes including stroke with DBP nadir around 70–80 mmHg has been repeatedly reported [25,26,27,28,29,30]. The J-shaped curve might be due to the positive association of low DBP and evident or subclinical myocardial damage [31] and due to the high frequency of isolated systolic hypertension with an increased pulse pressure in the low DBP cohort [30, 32]. However, the presence of a J-shaped relationship between DBP and the risk of stroke alone was somewhat unclear [25, 26, 31], presumably partly due to differences in mechanisms between cerebral and coronary autoregulation [33].
The benefit of dual therapy was observed over a wide SBP range. This suggests a simple message: the positive results of promising trial treatments can be more clearly identified when the vascular risk factors of the participants are appropriately controlled. Patients with good BP management might also be mindful of their general health condition and modify risk factors other than hypertension, and thus the impact of dual therapy might be clearer in such patients.
Visit-to-visit SBP variability was reported to be firmly associated with stroke outcomes and subsequent events [34,35,36]. Since the number of visits in the present patients was small (median 5), the association between BP variability and outcomes was not examined.
The strength of this study was that BP was treated as a time-dependent covariate and evaluated over time. For example, summarizing a patient’s BP values into a single statistic, e.g., mean BP, and treating it as a time-independent covariate would be equivalent to assuming that the patient’s BP is constant at the mean BP level throughout the follow-up period. However, this may miss the more detailed relationship between BP and events. The present method takes into account the fact that a patient’s BP is not constant and can change during the follow-up period, allowing for a more detailed and relevant assessment.
The limitations of the present study include the post hoc nature of the analysis, meaning that the associations identified might not necessarily imply causality. Severe stroke could cause both subsequent events and higher BP values. Second, visits for BP measurement were not frequent for patients developing events early after enrollment. Third, the present sample size seemed to be small for appropriate subgroup analyses, although numerical results indicated a tendency for a positive association between SBP and subsequent ischemic stroke regardless of assigned antiplatelet therapy and the antiplatelet agent at randomization. Fourth, the number of severe or life-threatening bleeding events (intracranial hemorrhage) was too small to perform meaningful statistical analysis. Hemorrhagic stroke generally shows a stronger association with follow-up BP than ischemic stroke [7, 37, 38].
Perspective of Asia
In Asia, cilostazol is widely used for secondary stroke prevention. DAPT including cilostazol decreased the risk of recurrent ischemic stroke compared to aspirin or clopidogrel monotherapy in patients with lacunar stroke and those with intracranial arterial stenosis [15, 39]; both of these pathologies are common to Asian population. BP lowering after stroke is an optimal strategy to strengthen the power of cilostazol-based DAPT in Asian stroke patients.
Conclusion
The present sub-study renewed our understanding of the importance of intensive BP lowering for secondary stroke prevention and also suggested the necessity of appropriate BP control for success in stroke clinical trials.
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for the CSPS.com Trial Investigators
Study sponsor Takenori Yamaguchi10
Principal Investigator Takenori Yamaguchi11
Steering Committee Kazunori Toyoda11, Shinichiro Uchiyama12, Haruhiko Hoshino13, Kazumi Kimura14, Yasushi Okada15, Nobuyuki Sakai16, Kotaro Tanaka17
Protocol Authoring Committee Kazunori Toyoda11, Haruhiko Hoshino13, Kazumi Kimura14
Independent Data Monitoring Committee Hiroaki Naritomi18, Shinya Goto19, Tatsuya Isomura20
Event Evaluation Committee Kazuo Minematsu21, Kiyohiro Houkin22, Masayasu Matsumoto23, Yasuo Terayama24, Hidekazu Tomimoto25, Teiji Tominaga26, Satoshi Yasuda11
Statistical Analysis Committee Hideki Orikasa17, Naoko Kumagai17
Publication Committee Takenori Yamaguchi11, Haruhiko Hoshino13, Kazumi Kimura14, Hideki Orikasa17, Kazunori Toyoda11, Shinichiro Uchiyama12
Clinical Sites and Site Investigators, by Enrolment Akihiro Miyasaki27, Masanori Isobe28, Yoshitaka Suda29, Kazuo Kitagawa30, Kazuyuki Nagatsuka11, Shuta Toru31, Makoto Katsuno32, Nobuyuki Sakai16, Kenichi Murao33, Norio Ikeda34, Kazuya Nakashima35, Shinichi Okabe36, Masanori Kurimoto37, Ikuo Ihara38, Hideki Matsuoka39, Shoji Mabuchi40, Hideo Hara41, Teruyuki Yoshimoto42, Takeshi Matsuoka43, Yoshikazu Arai44, Yasuyuki Iwasaki45, Manabu Hattori46, Kazuya Takahashi47, Yoshihisa Fukushima48, Masayuki Ezura49, Yasuaki Takeda50, Kimihiro Nakahara51, Masahiro Okada52, Shingo Mitaki53, Kosuke Yoshida54, Kenji Kamiyama55, Takahiro Kuwashiro56, Takeshi Iwanaga57, Akira Takahashi58, Junichi Maruyama59, Teiji Yamamoto60, Michiyuki Maruyama61, Yoshiharu Taguchi62, Kazuhiro Hashidume63, Katsumi Takizawa64, Yasuyuki Iguchi65, Kazuhito Kitajima66, Shinichi Yoshimura67, Syuji Arakawa68, Takeshi Inoue69, Hiroyuki Yamaguchi70, Susumu Suzuki71, Yasuo Terayama24, Youichi Watanabe72, Daisuke Yasutomi73, Ryota Tanaka74, Takuji Yamamoto75, Tetsuo Ando76, Yasuhiro Ito77, Naoki Hattori78, Nobutaka Yamamoto79, Tsutomu Takahashi80, Syoji Arihiro81, Naoaki Kanda82, Hirotoshi Hamaguchi83, Junji Kasuya84, Masaru Honda85, Hiroshi Oyama86, Hidefumi Yoshida87, Satoshi Okuda88, Keita Matsuura89, Toshiaki Ieda90, Takao Kanzawa91, Makio Takahashi92, Hirokazu Sadahiro93, Takahiro Miyahara94, Masahiko Yamada95, Takeshi Aoki96, Taizen Nakase97, Katsuhiko Hayashi98, Toshitaka Umemura99, Yasukuni Tsugu100, Fumitaka Miya101, Ryo Otani102, Keiichi Yamada103, Yoshinaga Kajimoto104, Hiroshi Nakane105, Kiyohito Shinno106, Akio Hara107, Ryoichi Saito108, Yuzo Araki109, Toshiho Otsuki110, Koji Abe111, Shigenari Kin112, Takehisa Tsuji113, Shota Sakai114, Yoshio Tsuboi115, Atsushi Kawamorita116, Hiroaki Shimizu117, Nobuo Araki118, Takashi Hata119, Hiroshi Ryu120, Kazumasa Yamatani121, Shinji Minami122, Takahiro Maruta123, Masaki Eto124, Katsutoshi Takayama125, Kazuo Hashikawa126, Eiichiro Mabuchi127, Yoshio Sakagami128, Syoji Tsuchimoto129, Jiro Kitayama130, Kiyoshi Shirakawa131, Haruki Takahashi132, Syunro Uchinokura133, Naohiro Osaka134, Ichiro Imafuku135, Toshiro Otsuka136, Ryo Itabashi137, Yuji Kujiraoka138, Naohisa Miura139, Koichi Nomura140, Masahiro Kobari141, Keizo Yasui142, Susumu Kashino143, Hiroto Murata144, Kazuhiko Nozaki145, Kosuke Yamashita92, Katsumi Matsumoto146, Yuji Shibata147, Atsuo Aoyama148, Yoshimasa Watanabe149, Toru Eto150, Susumu Mekaru151, Tsuneo Honda152, Masato Seike153, Masahiro Kurisaka154, Toshio Imaizumi155, Kojiro Wada156, Norihiro Suzuki157, Atsuo Yoshino158, Yukiko Hara159, Shunya Takizawa160, Kaoru Kamimoto161, Hiroshi Iizuka162, Yasuo Toma163, Taro Komuro164, Atsushi Sueyoshi165, Yoshikazu Nakajima23, Takayuki Sakaki166, Hiroji Miyake167, Masaru Idei168, Tsutomu Hitotsumatsu169, Shigehiro Nakahara170, Masahiko Kawanishi171, Takuji Kitaoka172, Naoyuki Isobe173, Masanobu Hokama174, Toshihide Shibata175, Kazuhito Tsuruta176, Akihito Moriki177, Masahiro Makino178, Masafumi Otaki179, Minoru Ajiki180, Takaaki Yamazaki181, Kiyohiro Houkin182, Nobuyuki Yasui183, Koichi Hirata184, Hiroyuki Kato185, Ichiro Suzuki186, Takakazu Kawamata30, Yoshikazu Uesaka187, Kohei Yamashita188, Yukiko Enomoto189, Osamu Onodera190, Masato Ikeda191, Susumu Miyamoto192, Manabu Sakaguchi193, Hiroyuki Nakase194, Yoshiki Yagita195, Tetsuhiro Kitahara196, Katsumi Irie197, Tomohiko Kusuhara198, Kazumasa Kawazoe199, Shinji Nagahiro200, Norikazu Kawada201, Akiko Adachi202, Toshihiro Fukusako203, Wataro Tsuruta204, Naoko Fujimura205, Takayuki Koizumi206, Hiroyuki Tomimitsu207, Shigeru Fujimoto208, Tsukasa Tsuchiya209, Hitoshi Aizawa210, Nobutaka Ishizu211, Shigeru Nogawa212, Hideharu Furumoto213, Toshihiro Ueda214, Syogo Imae215, Teiji Nakayama216, Hiroki Namba217, Jun Ochiai218, Tomoko Yamana219, Mitsuhito Mase220, Noriyuki Matsukawa220, Hisayoshi Niwa221, Masatoshi Muramatsu222, Yoshio Nakashima223, Fuminori Iwamoto224, Syunichi Yoneda225, Kenji Hashimoto226, Tatsuo 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Ryoichi Takahashi274, Sotaro Higashi275, Cheho Park276, Mitsutoshi Nakada277, Makoto Matsui278, Yoshinari Nagakane279, Akira Yoshioka280, Masahiro Makino281, Kazuyoshi Yamaguchi282, Yasushi Hagihara283, Tomonori Yamada284, Kenji Hashimoto285, Toshiaki Fujita286, Tetsuya Kumagai287, Masayuki Sumida288, Motohiro Morioka289, Hiroaki Oboshi290, Takanari Kitazono291, Yukio Ando292, Seiichiro Minato293, Masahito Agawa294, Takeshi Kono295, Tomohiko Izumidani295, Tetsuya Ueba296, Hiroaki Takeuchi297, Syuji Monden298, Syoji Shiraishi299, Hidehiko Syoji300, Tatsuya Nakamura300, Naoki Ikawa301, Hiroshi Sugihara302, Shinichi Toyonaga303, Hiroyuki Kon304, Yuji Kanamori305, Hiroaki Tanaka306
Funding
Grants covering the research: Supported by the Japan Agency for Medical Research and Development (AMED: JP24lk0221186, JP24lk0221171) and JSPS KAKENHI (JP23H02831). CSPS.com was conducted under a trial contract between the consignee, Japan Cardiovascular Research Foundation, and the consignor, Otsuka Pharmaceutical Co., Ltd. The Japan Cardiovascular Research Foundation received funding for trial implementation and management from Otsuka. Otsuka did not directly contribute to trial design, data management, or statistical analysis of CSPS.com and did not contribute to any components in this sub-study.
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All of the following are outside the submitted work. Toyoda reports honoraria from Otsuka Pharmaceutical, Daiichi-Sankyo, Bristol-Myers-Squibb, Bayer Yakuhin, and Janssen. Koga reports honoraria from Bayer Yakuhin, Daiichi-Sankyo, Mitsubishi Tanabe Pharma Corporation, and research support from, Daiichi-Sankyo, Nippon Boehringer Ingelheim. Hoshino reports honoraria from Otsuka Pharmaceutical, Bristol-Myers-Squibb and Pfizer. Okada reports honoraria from Daiichi-Sankyo and Pfizer. Sakai reports a research grant from Biomedical Solutions, Medtronic, Terumo and TG Medical; lecturer’s fees from Asahi-Intec, Biomedical Solutions, Daiichi Sankyo, Kaneka, Medtronic, Stryker and Terumo; and membership on the advisory boards for Johnson & Johnson, Medtronic and Terumo. Minematsu reports honoraria from Bayer Yakuhin and Pfizer. None of the other authors have any conflicts of interest to declare.
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Toyoda, K., Koga, M., Tanaka, K. et al. Blood pressure during long-term cilostazol-based dual antiplatelet therapy after stroke: a post hoc analysis of the CSPS.com trial. Hypertens Res 47, 2238–2249 (2024). https://doi.org/10.1038/s41440-024-01742-3
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DOI: https://doi.org/10.1038/s41440-024-01742-3
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