Subject-invariant feature learning for mTBI identification using LSTM-based variational autoencoder with adversarial regularization

IF 1.3 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Frontiers in signal processing Pub Date : 2022-11-30 DOI:10.3389/frsip.2022.1019253
Shiva Salsabilian, L. Najafizadeh
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Abstract

Developing models for identifying mild traumatic brain injury (mTBI) has often been challenging due to large variations in data from subjects, resulting in difficulties for the mTBI-identification models to generalize to data from unseen subjects. To tackle this problem, we present a long short-term memory-based adversarial variational autoencoder (LSTM-AVAE) framework for subject-invariant mTBI feature extraction. In the proposed model, first, an LSTM variational autoencoder (LSTM-VAE) combines the representation learning ability of the variational autoencoder (VAE) with the temporal modeling characteristics of the LSTM to learn the latent space representations from neural activity. Then, to detach the subject’s individuality from neural feature representations, and make the model proper for cross-subject transfer learning, an adversary network is attached to the encoder in a discriminative setting. The model is trained using the 1 held-out approach. The trained encoder is then used to extract the representations from the held-out subject’s data. The extracted representations are then classified into normal and mTBI groups using different classifiers. The proposed model is evaluated on cortical recordings of Thy1-GCaMP6s transgenic mice obtained via widefield calcium imaging, prior to and after inducing injury. In cross-subject transfer learning experiment, the proposed LSTM-AVAE framework achieves classification accuracy results of 95.8% and 97.79%, without and with utilizing conditional VAE (cVAE), respectively, demonstrating that the proposed model is capable of learning invariant representations from mTBI data.
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基于lstm的对抗正则化变分自编码器mTBI识别的主体不变特征学习
由于来自受试者的数据差异很大,开发识别轻度创伤性脑损伤(mTBI)的模型通常具有挑战性,导致mTBI识别模型难以推广到来自未见受试者的数据。为了解决这个问题,我们提出了一个基于长短期记忆的对抗变分自编码器(LSTM-AVAE)框架,用于主题不变的mTBI特征提取。在该模型中,首先,LSTM变分自编码器(LSTM-VAE)将变分自编码器(VAE)的表征学习能力与LSTM的时间建模特性相结合,从神经活动中学习潜在空间表征。然后,为了将受试者的个性从神经特征表征中分离出来,并使模型适合跨主题迁移学习,在判别设置中将对手网络附加到编码器上。该模型使用1 - hold -out方法进行训练。然后使用经过训练的编码器从滞留对象的数据中提取表征。然后使用不同的分类器将提取的表示分类为正常组和mTBI组。在诱导损伤之前和之后,通过宽视场钙成像获得Thy1-GCaMP6s转基因小鼠的皮质记录来评估所提出的模型。在跨学科迁移学习实验中,LSTM-AVAE框架在不使用条件VAE (cVAE)和使用条件VAE (cVAE)的情况下,分类准确率分别达到95.8%和97.79%,表明该模型能够从mTBI数据中学习不变表征。
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