使用可穿戴生物传感器的阿片类药物滥用监测过程中基于机器学习的协作非依从性检测方法。

Rohitpal Singh, Brittany Lewis, Brittany Chapman, Stephanie Carreiro, Krishna Venkatasubramanian
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引用次数: 9

摘要

可穿戴生物传感器可用于监测阿片类药物的使用,鉴于目前阿片类药物在美国的流行,这是一个可怕的社会后果问题。这种监测可以促使采取干预措施,促进行为改变。基于生物传感器的监测的有效性受到患者对监测的协作性不遵守(CNA)的潜在威胁。我们将CNA定义为在监视过程中将自己的生物传感器提供给他人的过程。本文的主要目的是利用可穿戴生物传感器的加速度计和血容量脉冲(BVP)测量,并使用机器学习来解决阿片类药物监测中CNA检测的新问题。我们使用了从11名因阿片类药物过量而被送往医院急诊科接受纳洛酮治疗的患者中收集的加速度计和BVP数据。然后,我们使用收集到的数据为个体患者建立个性化分类器,以捕获其血容量脉冲和三轴加速度计读数的独特性。为了评估我们的检测方法,我们通过替换(或不替换)一个患者的生物传感器读数片段来模拟CNA的存在(和不存在)。总的来说,当合作者是我们数据集中另外10名患者之一时,我们的平均检测准确率为90.96%,当合作者来自14名用户的数据之前从未被我们的分类器看到时,我们的平均检测准确率为86.78%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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A Machine Learning-based Approach for Collaborative Non-Adherence Detection during Opioid Abuse Surveillance using a Wearable Biosensor.

Wearable biosensors can be used to monitor opioid use, a problem of dire societal consequence given the current opioid epidemic in the US. Such surveillance can prompt interventions that promote behavioral change. The effectiveness of biosensor-based monitoring is threatened by the potential of a patient's collaborative non-adherence (CNA) to the monitoring. We define CNA as the process of giving one's biosensor to someone else when surveillance is ongoing. The principal aim of this paper is to leverage accelerometer and blood volume pulse (BVP) measurements from a wearable biosensor and use machine-learning for the novel problem of CNA detection in opioid surveillance. We use accelerometer and BVP data collected from 11 patients who were brought to a hospital Emergency Department while undergoing naloxone treatment following an opioid overdose. We then used the data collected to build a personalized classifier for individual patients that capture the uniqueness of their blood volume pulse and triaxial accelerometer readings. In order to evaluate our detection approach, we simulate the presence (and absence) of CNA by replacing (or not replacing) snippets of the biosensor readings of one patient with another. Overall, we achieved an average detection accuracy of 90.96% when the collaborator was one of the other 10 patients in our dataset, and 86.78% when the collaborator was from a set of 14 users whose data had never been seen by our classifiers before.

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Biomedical Engineering Systems and Technologies: 15th International Joint Conference, BIOSTEC 2022, Virtual Event, February 9–11, 2022, Revised Selected Papers Comparative Analysis of Patient Distress in Opioid Treatment Programs using Natural Language Processing The h-ANN Model: Comprehensive Colonoscopy Concept Compilation using Combined Contextual Embeddings TAX-Corpus: Taxonomy based Annotations for Colonoscopy Evaluation DeIDNER Model: A Neural Network Named Entity Recognition Model for Use in the De-identification of Clinical Notes
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