Exploration of hybrid deep learning algorithms for covid-19 mrna vaccine degradation prediction system

International Journal of Advances in Intelligent Informatics Pub Date : 2022-11-30 DOI:10.26555/ijain.v8i3.950

Soon Hwai Ing, A. Abdullah, M. Y. Mashor, Z. Mohamed-Hussein, Z. Mohamed, W. C. Ang

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引用次数: 1

Abstract

Coronavirus causes a global pandemic that has adversely affected public health, the economy, including every life aspect. To manage the spread, innumerable measurements are gathered. Administering vaccines is considered to be among the precautionary steps under the blueprint. Among all vaccines, the messenger ribonucleic acid (mRNA) vaccines provide notable effectiveness with minimal side effects. However, it is easily degraded and limits its application. Therefore, considering the cruciality of predicting the degradation rate of the mRNA vaccine, this prediction study is proposed. In addition, this study compared the hybridizing sequence of the hybrid model to identify its influence on prediction performance. Five models are created for exploration and prediction on the COVID-19 mRNA vaccine dataset provided by Stanford University and made accessible on the Kaggle community platform employing the two deep learning algorithms, Long Short-Term Memory (LSTM) as well as Gated Recurrent Unit (GRU). The Mean Columnwise Root Mean Square Error (MCRMSE) performance metric was utilized to assess each model’s performance. Results demonstrated that both GRU and LSTM are befitting for predicting the degradation rate of COVID-19 mRNA vaccines. Moreover, performance improvement could be achieved by performing the hybridization approach. Among Hybrid_1, Hybrid_2, and Hybrid_3, when trained with Set_1 augmented data, Hybrid_3 with the lowest training error (0.1257) and validation error (0.1324) surpassed the other two models; the same for model training with Set_2 augmented data, scoring 0.0164 and 0.0175 MCRMSE for training error and validation error, respectively. The variance in results obtained by hybrid models from experimenting claimed hybridizing sequence of algorithms in hybrid modeling should be concerned.

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混合深度学习算法在covid-19 mrna疫苗降解预测系统中的探索

冠状病毒引起全球大流行，对公共卫生、经济，包括生活的方方面面都产生了不利影响。为了控制传播，收集了无数的测量数据。接种疫苗被认为是蓝图下的预防措施之一。在所有疫苗中，信使核糖核酸(mRNA)疫苗具有显著的有效性和最小的副作用。然而，它很容易降解，限制了它的应用。因此，考虑到预测mRNA疫苗降解率的重要性，提出了这项预测研究。此外，本研究还比较了杂交模型的杂交顺序，以确定其对预测性能的影响。在斯坦福大学提供的COVID-19 mRNA疫苗数据集上创建了5个模型，用于探索和预测，并在Kaggle社区平台上使用长短期记忆(LSTM)和门控循环单元(GRU)两种深度学习算法。使用平均柱状均方根误差(MCRMSE)性能度量来评估每个模型的性能。结果表明，GRU和LSTM均可用于预测COVID-19 mRNA疫苗的降解率。此外，通过执行杂交方法可以实现性能改进。在杂种_1、杂种_2和杂种d_3模型中，用Set_1增强数据训练时，杂种d_3模型的训练误差(0.1257)和验证误差(0.1324)最低;采用Set_2增强数据进行模型训练，训练误差和验证误差的MCRMSE分别为0.0164和0.0175。在混合建模中，需要注意实验中所要求的算法的杂交顺序所得到的混合模型结果的差异。

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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来源期刊

International Journal of Advances in Intelligent Informatics Computer Science-Computer Vision and Pattern Recognition

CiteScore

3.00

自引率

0.00%

发文量