Longitudinal artificial intelligence-based deep learning models for diagnosis and prediction of the future occurrence of polyneuropathy in diabetes and prediabetes

IF 2.7 4区 医学 Q2 CLINICAL NEUROLOGY
Yun-Ru Lai , Wen-Chan Chiu , Chih-Cheng Huang , Ben-Chung Cheng , Chia-Te Kung , Ting Yin Lin , Hui Ching Chiang , Chia-Jung Tsai , Chien-Feng Kung , Cheng-Hsien Lu
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Abstract

Objective

The objective of this study was to develop artificial intelligence-based deep learning models and assess their potential utility and accuracy in diagnosing and predicting the future occurrence of diabetic distal sensorimotor polyneuropathy (DSPN) among individuals with type 2 diabetes mellitus (T2DM) and prediabetes.

Methods

In 394 patients (T2DM=300, Prediabetes=94), we developed a DSPN diagnostic and predictive model using Random Forest (RF)-based variable selection techniques, specifically incorporating the combined capabilities of the Clinical Toronto Neuropathy Score (TCNS) and nerve conduction study (NCS) to identify relevant variables. These important variables were then integrated into a deep learning framework comprising Convolutional Neural Networks (CNNs) and Long Short-Term Memory (LSTM) networks. To evaluate temporal predictive efficacy, patients were assessed at enrollment and one-year follow-up.

Results

RF-based variable selection identified key factors for diagnosing DSPN. Numbness scores, sensory test results (vibration), reflexes (knee, ankle), sural nerve attributes (sensory nerve action potential [SNAP] amplitude, nerve conduction velocity [NCV], latency), and peroneal/tibial motor NCV were candidate variables at baseline and over one year. Tibial compound motor action potential amplitudes were used for initial diagnosis, and ulnar SNAP amplitude for subsequent diagnoses. CNNs and LSTMs achieved impressive AUC values of 0.98 for DSPN diagnosis prediction, and 0.93 and 0.89 respectively for predicting the future occurrence of DSPN. RF techniques combined with two deep learning algorithms exhibited outstanding performance in diagnosing and predicting the future occurrence of DSPN. These algorithms have the potential to serve as surrogate measures, aiding clinicians in accurate diagnosis and future prediction of DSPN.

基于人工智能的纵向深度学习模型,用于诊断和预测糖尿病和糖尿病前期多发性神经病变的未来发生率。
研究目的本研究旨在开发基于人工智能的深度学习模型,并评估其在诊断和预测2型糖尿病(T2DM)和糖尿病前期患者未来发生糖尿病远端感觉运动性多发性神经病(DSPN)方面的潜在实用性和准确性:在 394 名患者(T2DM=300 人,糖尿病前期=94 人)中,我们使用基于随机森林(RF)的变量选择技术开发了 DSPN 诊断和预测模型,特别是结合临床多伦多神经病变评分(TCNS)和神经传导研究(NCS)的综合能力来识别相关变量。然后将这些重要变量整合到由卷积神经网络(CNN)和长短期记忆(LSTM)网络组成的深度学习框架中。为了评估时间预测效果,在入组和一年随访时对患者进行了评估:基于射频的变量选择确定了诊断 DSPN 的关键因素。麻木评分、感觉测试结果(振动)、反射(膝关节、踝关节)、鞍神经属性(感觉神经动作电位[SNAP]振幅、神经传导速度[NCV]、潜伏期)和腓肠肌/胫骨运动NCV是基线和一年内的候选变量。胫骨复合运动动作电位振幅用于初步诊断,尺骨 SNAP 振幅用于后续诊断。CNN 和 LSTM 对 DSPN 诊断预测的 AUC 值达到了令人印象深刻的 0.98,对未来 DSPN 发生的预测 AUC 值分别为 0.93 和 0.89。射频技术与两种深度学习算法相结合,在诊断和预测 DSPN 的未来发生方面表现出色。这些算法有可能作为代用指标,帮助临床医生准确诊断和预测 DSPN 的未来。
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来源期刊
CiteScore
5.20
自引率
3.30%
发文量
55
审稿时长
60 days
期刊介绍: Neurophysiologie Clinique / Clinical Neurophysiology (NCCN) is the official organ of the French Society of Clinical Neurophysiology (SNCLF). This journal is published 6 times a year, and is aimed at an international readership, with articles written in English. These can take the form of original research papers, comprehensive review articles, viewpoints, short communications, technical notes, editorials or letters to the Editor. The theme is the neurophysiological investigation of central or peripheral nervous system or muscle in healthy humans or patients. The journal focuses on key areas of clinical neurophysiology: electro- or magneto-encephalography, evoked potentials of all modalities, electroneuromyography, sleep, pain, posture, balance, motor control, autonomic nervous system, cognition, invasive and non-invasive neuromodulation, signal processing, bio-engineering, functional imaging.
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