Arman Naseri MSc , David Tax PhD , Pim van der Harst MD, PhD , Marcel Reinders PhD , Ivo van der Bilt MD, PhD
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Therefore, ML methods that are data efficient, ie, needing a low number of labels, are required to detect potential clinical value in patterns found in wearable data.</p></div><div><h3>Objective</h3><p>The primary study objective of the ME-TIME (Machine Learning Enabled Time Series Analysis in Medicine) study is to design an ML model that can detect atrial fibrillation (AF) and heart failure (HF) from wearable data in a data-efficient manner. To achieve this, self-supervised and weakly supervised learning techniques are used.</p></div><div><h3>Methods</h3><p>Two hundred subjects (100 reference, 50 AF, and 50 HF) are being invited to participate in wearing a Fitbit fitness tracker for 3 months. Interested volunteers are sent a questionnaire to determine their health, in particular cardiovascular health. Volunteers without any (history of) serious illness are assigned to the reference group. Participants with AF and HF are recruited in the Haga teaching hospital in The Hague, The Netherlands.</p></div><div><h3>Results</h3><p>Enrollment commenced on May 1, 2022, and as of the time of this report, 62 subjects have been included in the study. Preliminary analysis of the data reveals significant inter-subject variability. Notably, we identified heart rate recovery curves and time-delayed correlations between heart rate and step count as potential strong indicators for heart disease.</p></div><div><h3>Conclusion</h3><p>Using self-supervised and multiple-instance learning techniques, we hypothesize that patterns specific to AF and HF can be found in continuous data obtained from smartwatches.</p></div>","PeriodicalId":72527,"journal":{"name":"Cardiovascular digital health journal","volume":"4 6","pages":"Pages 165-172"},"PeriodicalIF":2.6000,"publicationDate":"2023-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S2666693623000737/pdfft?md5=8336905ff497def43550b2ab9ed5a430&pid=1-s2.0-S2666693623000737-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Data-efficient machine learning methods in the ME-TIME study: Rationale and design of a longitudinal study to detect atrial fibrillation and heart failure from wearables\",\"authors\":\"Arman Naseri MSc , David Tax PhD , Pim van der Harst MD, PhD , Marcel Reinders PhD , Ivo van der Bilt MD, PhD\",\"doi\":\"10.1016/j.cvdhj.2023.09.001\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><h3>Background</h3><p>Smartwatches enable continuous and noninvasive time series monitoring of cardiovascular biomarkers like heart rate (from photoplethysmograms), step counter, skin temperature, et cetera; as such, they have promise in assisting in early detection and prevention of cardiovascular disease. 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引用次数: 0
摘要
背景智能手表能够对心率(来自光速图)、步数计数器、皮肤温度等心血管生物标记进行连续、无创的时间序列监测;因此,它们有望协助早期检测和预防心血管疾病。虽然这些生物标志物对医生可能没有直接用处,但机器学习(ML)模型可以找到与临床相关的模式。遗憾的是,ML 模型通常需要有监督(即注释)的数据,而对大量连续数据进行标注非常耗费人力。因此,需要数据效率高的 ML 方法(即只需少量标签)来检测可穿戴数据中发现的模式是否具有潜在的临床价值。目标ME-TIME(Machine Learning Enabled Time Series Analysis in Medicine)研究的主要研究目标是设计一种 ML 模型,以数据效率高的方式从可穿戴数据中检测心房颤动(AF)和心力衰竭(HF)。为此,研究人员采用了自监督和弱监督学习技术。方法研究人员邀请 200 名受试者(100 名参照者、50 名房颤受试者和 50 名心衰受试者)佩戴 Fitbit 健身追踪器 3 个月。有兴趣的志愿者会收到一份调查问卷,以确定其健康状况,尤其是心血管健康状况。没有任何严重疾病(病史)的志愿者被分配到参照组。患有房颤和高血压的受试者在荷兰海牙的哈加教学医院招募。结果2022年5月1日开始招募,截至本报告发布时,已有62名受试者被纳入研究。对数据的初步分析表明,受试者之间的差异很大。值得注意的是,我们发现心率恢复曲线和心率与步数之间的延时相关性是心脏病的潜在有力指标。结论利用自监督和多实例学习技术,我们假设可以从智能手表获得的连续数据中发现房颤和高血压的特定模式。
Data-efficient machine learning methods in the ME-TIME study: Rationale and design of a longitudinal study to detect atrial fibrillation and heart failure from wearables
Background
Smartwatches enable continuous and noninvasive time series monitoring of cardiovascular biomarkers like heart rate (from photoplethysmograms), step counter, skin temperature, et cetera; as such, they have promise in assisting in early detection and prevention of cardiovascular disease. Although these biomarkers may not be directly useful to physicians, a machine learning (ML) model could find clinically relevant patterns. Unfortunately, ML models typically need supervised (ie, annotated) data, and labeling of large amounts of continuous data is very labor intensive. Therefore, ML methods that are data efficient, ie, needing a low number of labels, are required to detect potential clinical value in patterns found in wearable data.
Objective
The primary study objective of the ME-TIME (Machine Learning Enabled Time Series Analysis in Medicine) study is to design an ML model that can detect atrial fibrillation (AF) and heart failure (HF) from wearable data in a data-efficient manner. To achieve this, self-supervised and weakly supervised learning techniques are used.
Methods
Two hundred subjects (100 reference, 50 AF, and 50 HF) are being invited to participate in wearing a Fitbit fitness tracker for 3 months. Interested volunteers are sent a questionnaire to determine their health, in particular cardiovascular health. Volunteers without any (history of) serious illness are assigned to the reference group. Participants with AF and HF are recruited in the Haga teaching hospital in The Hague, The Netherlands.
Results
Enrollment commenced on May 1, 2022, and as of the time of this report, 62 subjects have been included in the study. Preliminary analysis of the data reveals significant inter-subject variability. Notably, we identified heart rate recovery curves and time-delayed correlations between heart rate and step count as potential strong indicators for heart disease.
Conclusion
Using self-supervised and multiple-instance learning techniques, we hypothesize that patterns specific to AF and HF can be found in continuous data obtained from smartwatches.
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