开发基于加速度传感器的可穿戴式酒精检测方法。

IF 3 Q2 SUBSTANCE ABUSE

Alcohol (Hanover, York County, Pa.) Pub Date : 2024-10-14 DOI:10.1111/acer.15465

Nicholas J Bush, Adriana K Cushnie, Madison Sinclair, Huda Ahmed, Rachel Schorn, Tongzhen Xie, Jeff Boissoneault

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Data were collected at a local state fair (n = 194), where participants drank water at specified intervals interspersed with confounding behaviors (e.g., touching nose, rubbing forehead, or yawning) while wearing an Android-based smartwatch for 10 min. Participants were randomized to receive one of three drinking container shapes: pint, martini, or wine.Results: The random forest model achieved an overall testing accuracy of 93% (sensitivity = 0.32; specificity = 0.99; positive predictive value = 0.74). The distributional algorithm achieved an overall accuracy of 95% (sensitivity = 0.76; specificity = 0.97; positive predictive value = 0.72). The distributional algorithm had a significantly greater accuracy (t(193) = 7.73, p < 0.001, d = 0.56) and sensitivity (t(193) = 24.5, p < 0.001, d = 1.76). 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引用次数: 0

摘要

背景：酒精是一种普遍使用的物质，会对公众健康造成严重影响。酒精治疗往往被污名化，在可及性和可负担性方面都受到限制，这表明酒精治疗需要创新。加速度传感器无需用户输入即可检测饮酒情况，并广泛应用于可穿戴设备中，从而提高了可及性和可负担性：我们比较了分布式分类法和随机森林分类法，以检测和评估基于传感器的饮酒数据。数据是在当地的一个州博览会上收集的（n = 194），参与者在佩戴基于安卓系统的智能手表 10 分钟的过程中，以规定的间隔喝水，同时穿插一些干扰行为（如摸鼻子、揉额头或打哈欠）。参与者被随机分配到三种形状的饮水容器中：品脱、马提尼或葡萄酒：随机森林模型的总体测试准确率为 93%（灵敏度 = 0.32；特异性 = 0.99；阳性预测值 = 0.74）。分布式算法的总体准确率为 95%（灵敏度 = 0.76；特异性 = 0.97；阳性预测值 = 0.72）。分布式算法的准确率明显更高（t(193) = 7.73，p lower(193) = 16.92，p upper(193) = -9.85，p lower(193) = 1.72，p = 0.044；thigher(193) = -3.96，p lower(193) = 1.98，p = 0.025；thigher(193) = 0.160，p = 0.564）：总之，研究结果表明，消费级智能手表可以利用机器学习和分布算法来检测和测量饮酒行为。这项工作为今后的研究提供了方法论基础，以便分析酒精使用的行为药理学，并开发可及的及时临床干预措施。

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Development of an accelerometer-based wearable sensor approach for alcohol consumption detection.

Background: Alcohol is a commonly used substance associated with significant public health consequences. Treatment is often stigmatized and limited with regard to both access and affordability, demonstrating the need for innovations in alcohol treatment. Accelerometer sensors can detect drinking without user input and are widely incorporated into wearable devices, increasing accessibility and affordability.

Methods: We compared a distributional and random forest classification approach to detect and evaluate sensor-based drinking data. Data were collected at a local state fair (n = 194), where participants drank water at specified intervals interspersed with confounding behaviors (e.g., touching nose, rubbing forehead, or yawning) while wearing an Android-based smartwatch for 10 min. Participants were randomized to receive one of three drinking container shapes: pint, martini, or wine.

Results: The random forest model achieved an overall testing accuracy of 93% (sensitivity = 0.32; specificity = 0.99; positive predictive value = 0.74). The distributional algorithm achieved an overall accuracy of 95% (sensitivity = 0.76; specificity = 0.97; positive predictive value = 0.72). The distributional algorithm had a significantly greater accuracy (t(193) = 7.73, p < 0.001, d = 0.56) and sensitivity (t(193) = 24.5, p < 0.001, d = 1.76). Equivalency testing demonstrated significant equivalency to the ground truth for sip duration (t_lower(193) = 16.92, p < 0.001; t_upper(193) = -9.85, p < 0.001) and between-sip interval (t_lower(193) = 1.72, p = 0.044; t_higher(193) = -3.96, p < 0.001). However, the random forest did not have significant equivalency to the ground truth for between-sip interval (t_lower(193) = 1.98, p = 0.025; t_higher(193) = 0.160, p = 0.564).

Conclusions: Overall, the results indicated that consumer-grade smartwatches can be utilized to detect and measure alcohol use behavior using machine learning and distributional algorithms. This work provides the methodological foundation for future research to analyze the behavioral pharmacology of alcohol use and develop accessible just-in-time clinical interventions.

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来源期刊

Alcohol (Hanover, York County, Pa.)

CiteScore

5.40

自引率

0.00%

发文量