G-Induced Loss of Consciousness Prediction Using a Support Vector Machine.

IF 0.9 4区医学 Q4 BIOPHYSICS

Aerospace medicine and human performance Pub Date : 2024-01-01 DOI:10.3357/AMHP.6301.2024

Nobuhiro Ohrui, Yuji Iino, Koichiro Kuramoto, Azusa Kikukawa, Koji Okano, Kunio Takada, Tetsuya Tsujimoto

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引用次数: 0

Abstract

INTRODUCTION: Gravity-induced loss of consciousness (G-LOC) is a major threat to fighter pilots and may result in fatal accidents. The brain has a period of 5-6 s from the onset of high +G_z exposure, called the functional buffer period, during which transient ischemia is tolerated without loss of consciousness. We tried to establish a method for predicting G-LOC within the functional buffer period by using machine learning. We used a support vector machine (SVM), which is a popular classification algorithm in machine learning.METHODS: The subjects were 124 flight course students. We used a linear soft-margin SVM, a nonlinear SVM Gaussian kernel function (GSVM), and a polynomial kernel function, for each of which 10 classifiers were built every 0.5 s from the onset of high +G_z exposure (Classifiers 0.5-5.0) to predict G-LOC. Explanatory variables used for each SVM were age, height, weight, with/without anti-G suit, +G_z level, cerebral oxyhemoglobin concentration, and deoxyhemoglobin concentration.RESULTS: The performance of GSVM was better than that of other SVMs. The accuracy of each classifier of GSVM was as follows: Classifier 0.5, 58.1%; 1.0, 54.8%; 1.5, 57.3%; 2.0, 58.1%; 2.5, 64.5%; 3.0, 63.7%; 3.5, 65.3%; 4.0, 64.5%; 4.5, 64.5%; and 5.0, 64.5%.CONCLUSION: We could predict G-LOC with an accuracy rate of approximately 65% from 2.5 s after the onset of high +G_z exposure by using GSVM. Analysis of a larger number of cases and factors to enhance accuracy may be needed to apply those classifiers in centrifuge training and actual flight.Ohrui N, Iino Y, Kuramoto K, Kikukawa A, Okano K, Takada K, Tsujimoto T. G-induced loss of consciousness prediction using a support vector machine. Aerosp Med Hum Perform. 2024; 95(1):29-36.

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使用支持向量机预测 G 诱导的意识丧失。

引言：重力诱发的意识丧失（G-LOC）是战斗机飞行员面临的主要威胁，可能导致致命事故。从开始接触高+Gz开始，大脑会有一段5-6秒的时间，称为功能缓冲期，在此期间，大脑可以承受短暂的缺血而不会失去知觉。我们试图利用机器学习建立一种预测功能缓冲期内 G-LOC 的方法。我们使用了支持向量机（SVM），这是机器学习中一种流行的分类算法。我们使用了线性软边际 SVM、非线性 SVM 高斯核函数（GSVM）和多项式核函数，从高 +Gz 暴露开始每 0.5 秒（分类器 0.5-5.0）建立 10 个分类器来预测 G-LOC。结果：GSVM 的表现优于其他 SVM。GSVM 各分类器的准确率如下：结论：通过使用 GSVM，我们可以在高 +Gz 暴露开始后 2.5 秒内预测 G-LOC，准确率约为 65%。Ohrui N, Iino Y, Kuramoto K, Kikukawa A, Okano K, Takada K, Tsujimoto T. 使用支持向量机预测 G 诱导的意识丧失。Aerosp Med Hum Perform.2024; 95(1):29-36.

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来源期刊

Aerospace medicine and human performance PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH -MEDICINE, GENERAL & INTERNAL

CiteScore

1.10

自引率

22.20%

发文量

272

期刊介绍： The peer-reviewed monthly journal, Aerospace Medicine and Human Performance (AMHP), formerly Aviation, Space, and Environmental Medicine, provides contact with physicians, life scientists, bioengineers, and medical specialists working in both basic medical research and in its clinical applications. It is the most used and cited journal in its field. It is distributed to more than 80 nations.