{"paper_id":"ff44ee62-9181-4fd5-9347-0b3db2d74ab8","body_text":"Infertility is defined as the inability to achieve pregnancy after 12 months of unprotected intercourse. It affects approximately one in six people globally ( World Health Organization 2023 ,  2024 ). According to the Global Burden of Disease (GBD) data, approximately 55 million men and 110 million women were affected by infertility in 2021. Between 1990 and 2021, infertility rates have shown a steady upward trend, with women experiencing infertility at nearly twice the rate of men ( Feng  et al.  2025 ). This growing global burden of infertility has significantly increased the demand for infertility treatments.\nParallelly, there have been significant advancements in assisted reproductive technologies (ART), which encompass various interventions from medications to ART ( NICHD – Eunice Kennedy Shriver National Institute of Child Health & Human Development 2017 ). Advancements in accessibility and affordability have led to a rapid rise in the utilization of these treatments ( Gleicher 2018 ). The International Committee for Monitoring Assisted Reproductive Technologies (ICMART) reported that in 2018 alone, around 3.56 million ART cycles were conducted, resulting in an estimated 870,000 births ( Chambers  et al.  2021 ). Furthermore, a recent global estimate spanning 1978–2018 indicated that between 9.3 million and 12.4 million babies were born through ART across 101 countries – highlighting the exponential growth in ART utilization over the past four decades ( Adamson  et al.  2025 ).\nDespite the proven safety of ART interventions, concerns regarding potential adverse effects and medical complications persist. A significant concern associated with infertility treatments is the potential long-term risk of cardiovascular diseases, particularly stroke among women ( Dayan  et al.  2017 ,  Magnus  et al.  2023 ). There is a considerable body of evidence regarding the predisposition of pregnant women to various cardiovascular complications, such as venous thromboembolism, coronary ischemia, heart failure, and stroke ( Mehta  et al.  2015 ). Other medications, such as oral contraceptives and hormone therapy, have also been proven to increase the risk of cardiovascular conditions among women of reproductive age group ( Henderson & Lobo 2012 ,  Ge  et al.  2019 ).\nThe relationship between infertility treatments and stroke remains inadequately understood. There have been sporadic reports and few case studies linking infertility treatments with stroke. There have been few attempts recently to explore this association, with conflicting findings. A comprehensive evidence synthesis effort to consolidate the body of existing evidence is lacking, prompting this review. This review aims to systematically examine and integrate existing evidence to offer a more complete understanding of the potential association between infertility treatments and stroke. The objective of this review is to determine the incidence of stroke/cerebrovascular accident among women who received ART and to compare the same with women who did not receive ART.\n\nThe systematic review was conducted as per Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines ( Page  et al.  2021 ). The study protocol was registered in the PROSPERO registry (ID: CRD42023491196).\nThe review included retrospective and prospective cohort studies conducted on women aged 15–55 years who experienced cerebrovascular accident/stroke with a history of undergoing different ART in the past. Studies on women who already had cardiovascular disease before undergoing ART treatments were excluded. In addition, we excluded case reports and case series from this review.\nAll types of infertility treatments, such as  in vitro  fertilization (IVF), intrauterine insemination (IUI), follicular puncture and oocyte retrieval, intrauterine embryo transfer, and usage of drugs such as clomiphene citrate or a gonadotropin (follicle-stimulating hormone, human menopausal gonadotropin, human chorionic gonadotropin (HCG)), were considered as the exposure variables. The incidence of any stroke, including ischemic and hemorrhagic stroke, was the primary outcome of this study.\nA systematic literature search was performed in PubMed, Embase, Cochrane, Web of Science (WoS), and CINAHL (Cumulated Index to Nursing and Allied Health Literature) through Nov 2023 on studies published in the English language in academic peer-reviewed journals. Two independent authors conducted the literature search using a structured search strategy.\nThe search strategy employed to find relevant studies utilized MeSH terms such as infertility, subfertility, stroke, cerebrovascular accident (CVA), brain vascular accident, cerebrovascular stroke, cerebral stroke, acute cerebrovascular accident, and ischemic stroke (Supplement 1: detailed search strategy; see section on  Supplementary materials  given at the end of the article). Initially, keywords and their synonyms were searched using appropriate truncations, wildcards, and proximity searching techniques. Subject headings (MeSH for PubMed and Emtree for Embase) were also utilized for key concept searches across databases. The final search combined these results using Boolean operators. In addition, researchers in the field were contacted, and references of relevant articles were screened for further studies. No ethics approval or informed consent was required for this study, as it did not involve patient data collection. Gray literature and unpublished data were sought through a Google search.\nAfter de-duplicating, the studies were imported into the Rayyan.ai tool. In the first stage of screening, titles and abstracts were screened. Studies in line with the inclusion criteria were shortlisted and carried to the second stage of screening. In the second stage, all the shortlisted studies were screened for full text. The studies that were relevant to the objectives, fulfilling the inclusion criteria and outcome measures of interest, were taken ahead for data extraction. The studies that were relevant but did not satisfy a few aspects of eligibility criteria were labeled as ‘maybe’ or ‘conflict’ by the individual researcher. These contentious studies were later resolved by a third reviewer. Each stage involved two researchers (AAK and VD) who independently reviewed the level 1 and 2 screening and data extraction process, and a third reviewer settled disagreements regarding study eligibility ( Fig. 1 : PRISMA flow chart).\nThe preferred reporting items for systematic reviews and meta-analyses flowchart of the selection process of articles.\nAll the articles were carefully screened, and data were extracted using the data extraction methodology used by the same researchers: demographics, research description (first author, publication year, aims, study design, and sample size), inclusion and exclusion criteria, outcomes, period of follow-up, type of ART received, duration or cycles of treatment for infertility, incidence of stroke, mortality due to stroke, and conclusions.\nThe methodological quality of the included studies was evaluated in three domains: selection, comparability, and outcome/exposure. Assessment was independently conducted by two authors (AAK and VD) using the Newcastle–Ottawa Scale for cohort and case–control studies ( Wells  et al.  2000 ). In the comparability domain, age was the primary factor considered, with additional factors including hypertension, polycystic ovary syndrome (PCOS), body mass index, and income also evaluated. Regarding outcome assessment, a follow-up period of at least 5 years was deemed sufficient for stroke occurrences, given limited evidence on the ideal follow-up duration. Studies were scored on a maximum of nine points, categorizing study quality as high (score ≥8), moderate (score = 7), or low (score ≤6). If sufficient studies were available, funnel plots were utilized to explore reporting biases.\nWe assessed all studies for clinical and methodological heterogeneity with respect to population, intervention, outcomes, and study design. We intended to perform meta-analysis in case of the absence of clinical and methodological heterogeneity. As the included studies exhibited significant heterogeneity, we have presented the results qualitatively.\nConsidering the small number of heterogeneous studies, we could not assess the reporting bias using a funnel plot or Egger test. In addition, the power was too low to distinguish chance from real asymmetry.\n\nOut of 1,076 studies initially identified across all sources, 228 duplicates were removed, leaving 848 studies for initial screening on Rayyan.ai. These studies underwent level 1 screening based on their titles and abstracts, resulting in the exclusion of 831 studies that did not meet eligibility criteria. Seventeen studies progressed to level 2, or full-text, screening. Of these, two studies could not be accessed, and nine were subsequently excluded, three for incorrect study design, four for irrelevant outcomes, and two for incorrect study population. Finally, six studies, with a combined sample size of 406,438, were included in the qualitative synthesis and underwent data extraction (see  Fig. 1 ).\nTable 1  summarizes the characteristics of the included studies. Among the six studies, two were conducted in Canada ( Udell  et al.  2017 ,  2013 ), two in the USA ( Murugappan  et al.  2019 ,  Sachdev  et al.  2023 ), and one each in Sweden ( Westerlund  et al.  2014 ) and Taiwan ( Ge  et al.  2019 ). The publication years of the studies ranged from 2013 to 2023. Three studies were retrospective cohorts ( Ge  et al.  2019 ,  Murugappan  et al.  2019 ,  Sachdev  et al.  2023 ), and the remaining three were population-based cohorts ( Udell  et al.  2017 ,  2013 ,  Westerlund  et al.  2014 ). Participants’ mean age varied from 15 to 55 years, with sample sizes ranging from 4,710 to 287,813 and a pooled sample size of 406,438. Follow-up durations ranged from 6.2 months to 9.7 years. Exposure and outcome ascertainment methods included the Swedish IVF Register, Maternal and Birth Register, health insurance plan codes, and ICD 9, 10 codes. Exposures examined included infertility treatments such as IVF, IUI, follicular puncture, oocyte retrieval, intrauterine embryo transfer, and medications such as clomiphene citrate or gonadotropins (FSH, HMG, HCG). Outcomes examined included stroke, cerebrovascular events, cardiac ischemia, coronary heart disease, and CVD. Notably,  Sachdev  et al.  (2023)  reported separate incidence rates for ischemic and hemorrhagic stroke.\nCharacteristics of included studies.\nMean.\nMonths.\nCrude relative rate ratio and adjusted relative rate ratio.\nRCS, retrospective cohort study; PBCS, population-based cohort study; DM, diabetes mellitus; FUY, follow-up years; HF, heart failure; TE, thromboembolism; SG, study group; CG, control group; ICD, International Classification of Diseases; HR, hazard ratio; RRR, relative rate ratio; CAD, coronary artery disease; CHD, coronary heart disease; CVD, cardiovascular disease; HT, hypertension; NR, not reported.\nOf the six included studies, five studies were of high quality, and remaining one study was of moderate quality as per the Newcastle-Ottawa Scale ( Wells  et al.  2000 ). The study by  Ge  et al.  (2019)  was classified as moderate quality since it did not mention the length of the follow-up period among the women who underwent infertility treatments.\nStudies have documented varying stroke incidences, with  Udell  et al.  (2013)  reporting the lowest at 16.00 (9.80; 26.12) per 100,000 person-years ( Udell  et al.  2013 ), and Sachdev  et al.  reporting the highest at 437.01 (360.93; 529.13) per 100,000 person-years ( Sachdev  et al.  2023 ). Sachdev  et al.  compared stroke incidences between women who conceived through infertility treatment and those who conceived naturally. They found that the incidence rates of any stroke were 37 per 100,000 in the infertility treatment group versus 29 per 100,000 in the spontaneous conception group. For hemorrhagic stroke, the rates were 18 per 100,000 and 12 per 100,000, respectively. There was a difference reported in the incidence of ischemic stroke (19 per 100,000 population) between both groups ( Sachdev  et al.  2023 ). Ge  et al.  focused exclusively on ischemic stroke, reporting hazard ratios (HRs) without specifying incidence rates ( Ge  et al.  2019 ). Other studies have reported cerebrovascular and cardiovascular disease incidences alongside chronic conditions, including stroke ( Westerlund  et al.  2014 ,  Murugappan  et al.  2019 ).\nDifferent studies have shown varying HRs for the association between infertility treatment and stroke. The study by Sachdev  et al.  reported a significant positive association between infertility treatment and stroke. The reported HR was as high as 1.66 (95% CI: 1.17–2.35) ( Sachdev  et al.  2023 ). In contrast, the study by Ge  et al. , reported an HR of 0.82 (95% CI: 0.68–0.99), which indicates infertility treatments being slightly protective for the occurrence of stroke ( Ge  et al.  2019 ). Although the remaining studies also reported a positive association, their confidence intervals included a null value. Overall, substantial variability in the effect sizes reported across the studies exists.\n\nThe review aimed to address gaps in understanding ART and stroke, citing limited recent studies with inconclusive findings. Conflicting evidence was reported across the studies regarding the risk of stroke with ART. Only one study reported a significantly higher HR for stroke ( Udell  et al.  2013 ). Other studies showed marginally higher overall HRs, which were statistically insignificant ( Westerlund  et al.  2014 ,  Ge  et al.  2019 ).\nA prior meta-analysis by Liang  et al.  also found inconsistent and inconclusive evidence (HR = 1.07, 95% CI: 0.87–1.32) ( Liang  et al.  2022 ), recommending further research on different treatments and etiologies. Interestingly, Ge  et al. ’s large cohort study reported contradictory findings, suggesting infertility medications might reduce ischemic stroke risk (adjusted HR = 0.82, 95% CI: 0.68–0.99) and cardiovascular disease (adjusted HR = 0.83, 95% CI: 0.74–0.94) compared to controls ( Ge  et al.  2019 ). Similarly,  Udell  et al. ’s (2017)  Canadian study found fewer stroke and cardiovascular disease cases with fertility treatments ( Udell  et al.  2017 ). This might be due to increased health awareness among those seeking treatments and managing conditions and lifestyle factors influencing stroke risk. However, none of the studies critically evaluated the plausible biological pathways or the complex interplay of a plethora of potential risk factors.\nDrawing such conclusions oversimplifies the complex, multifactorial relationships among infertility, its causes, treatments, psychological stressors related to infertility, and cardiovascular events or stroke (see  Fig. 2 ). A comprehensive review of the existing literature unfolds valuable insights into the potential causes of stroke in women undergoing ART.\nConceptual framework of the hypothesized association of stroke among women who received infertility treatments.\nBackground health conditions that increase the risk of infertility, the causes of infertility itself, and various medications and procedures in ART might contribute to a variable extent to the incidence of stroke in these women. Conditions such as PCOS, endometriosis, premature ovarian insufficiency, and impaired glucose tolerance might contribute to the underlying pathophysiology of stroke ( Healy  et al.  1994 ,  Smith  et al.  2021 ,  Kicińska  et al.  2023 ). The increased risk of hypercoagulability induced by gonadotropins, treatments with human chorionic gonadotropin (hCG), and gonadotropin-releasing hormone (GnRH), commonly used medications in infertility treatments ( Gerotziafas  et al.  2017 ). This hypercoagulability can lead to both arterial and venous thrombosis, posing a serious health risk. Similarly, ovarian hyperstimulation syndrome (OHSS), a common side effect of infertility treatments, is often associated with an increased risk of stroke ( Aune  et al.  1991 ,  Kosteria  et al.  2015 ). Furthermore, ART, even in the absence of OHSS, can trigger complications related to hypercoagulability and potential thromboembolic events ( Dicpinigaitis  et al.  2024 ). Women undergoing certain infertility treatments, such as IVF, could be linked to acute cardiovascular changes and serious blood flow issues in the placenta, potentially leading to preeclampsia, which may further increase the risk of hemorrhagic stroke ( Miller & Leffert 2020 ,  Magnus  et al.  2023 ). The complex pathophysiology behind stroke in women of reproductive age group suggests multifaceted connections between infertility, ART, and stroke. Studies vary widely in terms of the populations, outcomes, follow-up durations, and assessment methods. These differences raise significant questions about the quality and consistency of available evidence. Diverse approaches to exposure and outcome assessment also question the reliability of combining results through meta-analysis.\nThe systematic review included studies covering a wide age range. For instance, research by  Sachdev  et al.  (2023)  and  Udell  et al.  (2017)  encompassed participants as young as 15 years old, suggesting a low likelihood of fertility treatment in this age group. Conversely, studies also involved individuals up to 55 years old, where fertility treatment rates are likely higher, but potential links with stroke could be influenced by preexisting health conditions. The choice of the most relevant age group for such studies is debatable. Heterogeneity extended beyond age groups to include variations in study and comparator groups. Some studies compared women who conceived after infertility treatment with those who conceived spontaneously, while others compared outcomes between those who achieved fertility success and those who did not after treatment. The study population included in  Murugappan  et al.  (2019)  broadly defined the infertility cohort as women who were diagnosed, tested, or treated for infertility. Despite the wide-ranging inclusion criteria, the study was able to identify an association between cerebrovascular disease and the infertile group. However, subgroup analyses based on whether women were diagnosed, tested, or treated for infertility could help eliminate potential confounding in the observed associations. The diverse nature of the evidence precluded the pooling of data for meta-analysis, necessitating qualitative synthesis only.\nAssessing exposure objectively and consistently is essential for scientifically valid conclusions on associations between risk factors and outcomes. However, this review showed significant variability in exposure assessment among studies. Three studies relied on insurance claims data, two defined exposure as any infertility treatment procedure, and one considered any infertility diagnosis as exposure ( Udell  et al.  2017 ,  2013 ,  Westerlund  et al.  2014 ,  Ge  et al.  2019 ,  Murugappan  et al.  2019 ,  Sachdev  et al.  2023 ). Furthermore, infertility treatment procedures were inconsistently categorized; for example, simple methods such as IUI were grouped with more complex ones like multiple IVF cycles. This lack of differentiation further extended to establishing dose-response relationships, such as comparing single versus multiple treatment cycles. This variability introduced substantial discrepancies in addressing the research questions and drawing conclusions across studies.\nSimilarly, the studies also varied in how they assessed outcomes. One study used a composite outcome including cardiovascular events, stroke, and other conditions, while others focused on CVD, hypertension, diabetes, and incident chronic diseases with cerebrovascular outcomes ( Westerlund  et al.  2014 ). Few studies specifically defined outcomes related to hospitalizations and stroke types (ischemic and hemorrhagic) ( Sachdev  et al.  2023 ). It is crucial to consider that chronic diseases may progress significantly before formal diagnosis, spanning preclinical and clinical stages ( Megari 2013 ); however the likelihood of this occurring before cerebrovascular events is minimal.\nThe multifaceted pathogenesis involves numerous factors, including genetics, developmental origins, and environmental influences shaped by lifestyle ( Fig. 2 ). Some studies in this review did not account for common risk factors such as obesity, smoking, physical inactivity, and underlying chronic diseases, such as diabetes or hypertension, whether undiagnosed or poorly controlled. This oversight could mask or exaggerate the true association. Adjusting for these variables would provide deeper insights and help isolate any potential specific impact of infertility treatments on stroke risk.\nWithout establishing the underlying cause of infertility, it becomes challenging to attribute the increased risk of stroke solely to the treatment. Conditions such as PCOS and tubal defects, common causes of infertility, are closely related to hypertension and heart disease, complicating the association ( Farland  et al.  2023 ). In addition, few studies have reported the association between ovarian hyperstimulation syndrome (OHSS) and infertility treatments such as controlled ovarian stimulation (COS) or ovulation induction, which, in turn, can cause serious vascular problems ( Namavar Jahromi  et al.  2018 ,  Koh  et al.  2021 ). These treatments may increase stroke risk through factors such as estrogen-induced blood clotting, changes in blood clotting ability, or damage to blood vessels due to disruptions in the body’s hormonal balance ( Dicpinigaitis  et al.  2024 ). In contrast, a recent large-scale study observed a very low hospitalization rate of 4.06/100,000 population, with no ischemic strokes reported among them ( Seitz  et al.  2025 ). Given the current level of evidence, it is very challenging to attribute the risk of stroke to OHSS. Understanding these complexities is crucial for accurately assessing how infertility treatments affect stroke risk in women. However, many studies did not specify the duration of infertility treatment exposure. Some patients were advised to undergo multiple cycles, even after unsuccessful attempts, which could help establish a clearer dose-response relationship. Furthermore, some studies had insufficient follow-up periods to accurately determine stroke incidence.\nThe geographical distribution of infertility treatment and its link to stroke is uneven. Most studies included in our analysis focused on specific countries such as the USA, Canada, Sweden, and Taiwan. The global burden remains staggering, with limited evidence, highlighting a critical need for broader exploration to understand this immensely widespread issue.\nDespite the limited number of studies, this review analyzed data from nearly 406,438 women. Our stringent inclusion criteria restricted the number of studies and data analyzed but effectively captured the associations of interest. Since data on infertility treatment and stroke were derived from medical records, recall bias is expected to be minimal. However, a few limitations should be acknowledged. The primary limitation is the scarcity of research data on both qualitative and quantitative aspects of infertility treatments and stroke. Due to the small and heterogeneous study pool, we could not assess reporting bias using funnel plots. In addition, insufficient studies precluded analysis by type of stroke or infertility treatment.\n\nIn conclusion, the review could not conclusively establish the association between ART and stroke due to conflicting evidence reported across the included studies. It is still unclear whether the background conditions predisposing women to infertility, the direct causes of infertility, or ART itself increase the risk of stroke among women undergoing ART. It also remains unclear how long after ART the occurrence of stroke could be attributed to ART. Future research should focus on defining the timeframe for stroke risk after infertility treatments and identifying specific treatments linked to a higher risk. Robust prospective studies or real-world evidence investigations with suitable comparisons are essential to address these research gaps, thereby informing clinical practice and guiding patient care effectively.\nBased on our findings, it is imperative to emphasize that continuous monitoring of infertility treatments and long-term follow-up are crucial to detect and prevent stroke risks effectively. Addressing these knowledge gaps is vital for understanding the relationship between infertility treatments and stroke. We propose comprehensive stroke and cardiovascular risk assessments for women seeking infertility treatment, regardless of the type of treatment. Establishing longitudinal registries to monitor the occurrence of chronic diseases in women undergoing ART is also advised. These registries, with robust design and appropriate comparative groups to explore the complex interplay of factors associated with stroke and their underlying mechanisms, are critical to inform evidence-informed ART.\n\nThe authors declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the work reported.\n\nThis research did not receive any specific grant from any funding agency in the public, commercial, or not-for-profit sector.\n\nAV and AKA conceptualized and designed the study and contributed to drafting and revising the manuscript. MMRG and AKA developed the systematic search strategy, screened studies, and extracted data. AV, AMA, VD, and PR conducted the quality assessment of included studies and contributed to the interpretation of findings. MMRG and AKA performed data analysis and assisted in result visualization. PR provided domain expertise, contributed to the discussion, and critically revised the manuscript. AV, MMRG, and AKA supervised the project, provided expert guidance, and finalized the manuscript for submission. All authors reviewed and approved the final version of the manuscript.","source_license":"CC-BY-4.0","license_restricted":false}