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胃内容物对呼气酒精浓度-经皮酒精浓度关系的影响。

Effects of stomach content on the breath alcohol concentration-transdermal alcohol concentration relationship.

机构信息

Department of Psychology, University of Southern California, Los Angeles, USA.

Department of Mathematics, University of Southern California, Los Angeles, USA.

出版信息

Drug Alcohol Rev. 2021 Nov;40(7):1131-1142. doi: 10.1111/dar.13267. Epub 2021 Mar 12.

DOI:10.1111/dar.13267
PMID:33713037
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8848829/
Abstract

INTRODUCTION

Wearable devices that obtain transdermal alcohol concentration (TAC) could become valuable research tools for monitoring alcohol consumption levels in naturalistic environments if the TAC they produce could be converted into quantitatively-meaningful estimates of breath alcohol concentration (eBrAC). Our team has developed mathematical models to produce eBrAC from TAC, but it is not yet clear how a variety of factors affect the accuracy of the models. Stomach content is one factor that is known to affect breath alcohol concentration (BrAC), but its effect on the BrAC-TAC relationship has not yet been studied.

METHODS

We examine the BrAC-TAC relationship by having two investigators participate in four laboratory drinking sessions with varied stomach content conditions: (i) no meal, (ii) half and (iii) full meal before drinking, and (iv) full meal after drinking. BrAC and TAC were obtained every 10 min over the BrAC curve.

RESULTS

Eating before drinking lowered BrAC and TAC levels, with greater variability in TAC across person-device pairings, but the BrAC-TAC relationship was not consistently altered by stomach content. The mathematical model calibration parameters, fit indices, and eBrAC curves and summary score outputs did not consistently vary based on stomach content, indicating that our models were able to produce eBrAC from TAC with similar accuracy despite variations in the shape and magnitude of the BrAC curves under different conditions.

DISCUSSION AND CONCLUSIONS

This study represents the first examination of how stomach content affects our ability to model estimates of BrAC from TAC and indicates it is not a major factor.

摘要

简介

如果可穿戴设备能够获得的经皮酒精浓度(TAC)可以转换为对自然环境下酒精摄入量的定量有意义的估计,那么它们可能成为监测酒精摄入量的有价值的研究工具。我们的团队已经开发出了从 TAC 生成 eBrAC 的数学模型,但目前尚不清楚各种因素如何影响模型的准确性。胃内容物是已知会影响呼吸酒精浓度(BrAC)的因素之一,但它对 BrAC-TAC 关系的影响尚未得到研究。

方法

我们通过让两名研究人员参与四项实验室饮酒试验来研究 BrAC-TAC 关系,这些试验具有不同的胃内容物条件:(i)无餐,(ii)半餐和(iii)全餐前饮酒,以及(iv)全餐后饮酒。在 BrAC 曲线期间,每 10 分钟获取一次 BrAC 和 TAC。

结果

饮酒前进食会降低 BrAC 和 TAC 水平,并且 TAC 在人与人之间的配对中变化更大,但胃内容物并未改变 BrAC-TAC 关系。数学模型校准参数、拟合指数以及 eBrAC 曲线和汇总得分输出并不一致地取决于胃内容物,这表明尽管在不同条件下 BrAC 曲线的形状和幅度存在差异,我们的模型仍能够以相似的准确性从 TAC 生成 eBrAC。

讨论与结论

本研究首次考察了胃内容物如何影响我们从 TAC 模型化 BrAC 估计的能力,并表明它不是主要因素。

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Deconvolving the input to random abstract parabolic systems: a population model-based approach to estimating blood/breath alcohol concentration from transdermal alcohol biosensor data.
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2
Estimation of the Distribution of Random Parameters in Discrete Time Abstract Parabolic Systems with Unbounded Input and Output: Approximation and Convergence.
Commun Appl Anal. 2019;23(2):287-329. doi: 10.12732/caa.v23i2.4. Epub 2019 Jan 18.
3
Estimating the Distribution of Random Parameters in a Diffusion Equation Forward Model for a Transdermal Alcohol Biosensor.
Automatica (Oxf). 2019 Aug;106:101-109. doi: 10.1016/j.automatica.2019.04.026. Epub 2019 May 16.
4
Special issue on alcohol biosensors: Development, use, and state of the field: Summary, conclusions, and future directions.
Alcohol. 2019 Dec;81:161-165. doi: 10.1016/j.alcohol.2019.07.001. Epub 2019 Jul 9.
5
Wearable Electrochemical Alcohol Biosensors.
Curr Opin Electrochem. 2018 Aug;10:126-135. doi: 10.1016/j.coelec.2018.05.014. Epub 2018 May 23.
6
Applying a novel population-based model approach to estimating breath alcohol concentration (BrAC) from transdermal alcohol concentration (TAC) biosensor data.
Alcohol. 2019 Dec;81:117-129. doi: 10.1016/j.alcohol.2018.09.005. Epub 2018 Sep 20.
7
Estimating the quantity and time course of alcohol consumption from transdermal alcohol sensor data: A combined laboratory-ambulatory study.
Alcohol. 2019 Dec;81:111-116. doi: 10.1016/j.alcohol.2018.08.015. Epub 2018 Sep 1.
8
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Alcohol Alcohol. 2017 Jan;52(1):35-41. doi: 10.1093/alcalc/agw058. Epub 2016 Aug 13.
9
Development of a real-time repeated-measures assessment protocol to capture change over the course of a drinking episode.
Alcohol Alcohol. 2015 Mar;50(2):180-7. doi: 10.1093/alcalc/agu100. Epub 2015 Jan 7.
10
Estimating BrAC from transdermal alcohol concentration data using the BrAC estimator software program.
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