Explainable Artificial Intelligence for Drug Discovery and Development: A Comprehensive Survey

Alizadehsani, Roohallah; Oyelere, Solomon Sunday; Hussain, Sadiq; Jagatheesaperumal, Senthil Kumar; Calixto, Rene Ripardo; Rahouti, Mohamed; Roshanzamir, Mohamad; De Albuquerque, Victor Hugo C.

doi:10.1109/access.2024.3373195

IEEE Access

2024

DOI: 10.1109/access.2024.3373195

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Explainable Artificial Intelligence for Drug Discovery and Development: A Comprehensive Survey

Roohallah Alizadehsani,

Solomon Sunday Oyelere,

Sadiq Hussain

et al.

Abstract: The field of drug discovery has experienced a remarkable transformation with the advent of artificial intelligence (AI) and machine learning (ML) technologies. However, as these AI and ML models are becoming more complex, there is a growing need for transparency and interpretability of the models. Explainable Artificial Intelligence (XAI) is a novel approach that addresses this issue and provides a more interpretable understanding of the predictions made by machine learning models. In recent years, there has b… Show more

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Cited by 5 publications

References 93 publications

(97 reference statements)

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A review of Explainable Artificial Intelligence in healthcare

Sadeghi,

Alizadehsani,

CIFCI

et al. 2024

Computers and Electrical Engineering

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A review of Explainable Artificial Intelligence in healthcare

Sadeghi,

Alizadehsani,

CIFCI

et al. 2024

Computers and Electrical Engineering

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Deep learning for personalized health monitoring and prediction: A review

Damaševičius,

Jagatheesaperumal,

Kandala

et al. 2024

Computational Intelligence

Self Cite

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Personalized health monitoring and prediction are indispensable in advancing healthcare delivery, particularly amidst the escalating prevalence of chronic illnesses and the aging population. Deep learning (DL) stands out as a promising avenue for crafting personalized health monitoring systems adept at forecasting health outcomes with precision and efficiency. As personal health data becomes increasingly accessible, DL‐based methodologies offer a compelling strategy for enhancing healthcare provision through accurate and timely prognostications of health conditions. This article offers a comprehensive examination of recent advancements in employing DL for personalized health monitoring and prediction. It summarizes a diverse range of DL architectures and their practical implementations across various realms, such as wearable technologies, electronic health records (EHRs), and data accumulated from social media platforms. Moreover, it elucidates the obstacles encountered and outlines future directions in leveraging DL for personalized health monitoring, thereby furnishing invaluable insights into the immense potential of DL in this domain.

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Real-Time Cardiac Abnormality Monitoring and Nursing for Patient Using Electrocardiographic Signals

Ao,

Zhai,

Jiang

et al. 2024

Cardiology

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Introduction Cardiovascular disease care is a critical clinical application that necessitates real-time monitoring models. Previous models required the use of multi-lead signals and could not be customized as needed. Traditional methods relied on manually designed supervised algorithms, based on empirical experience, to identify waveform abnormalities and classify diseases, and were incapable of monitoring and alerting abnormalities in individual waveforms. Methods This research reconstructed the vector model for arbitrary leads using the phase space time delay method, enabling the model to arbitrarily combine signals as needed while possessing adaptive denoising capabilities. After employing automatically constructed machine learning algorithms and designing for rapid convergence, the model can identify abnormalities in individual waveforms and classify diseases, as well as detect and alert on abnormal waveforms. Result Effective noise elimination was achieved, obtaining a higher degree of loss function fitting. Afterwards, the detail differences of the electrocardiogram signal were amplified using a single-lead three-dimensional model. A cropping algorithm was used to remove waveforms severely interfered by external factors. Then, automatic neural network recognition was used. The automatic network generation model was designed effectively for different data types. The accuracy of patient identification is 98.2%, and the accuracy for healthy patients is 99.2%. Conclusion The elastic wavelet neural network can automatically denoise. Through the three-dimensional model, the detailed changes of electrocardiogram signals of different diseases can be observed. The cropping algorithm effectively identified the interfered and destroyed waveforms. The automatic neural network is capable of carrying out disease type classification and patient identity classification.

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Explainable Artificial Intelligence for Drug Discovery and Development: A Comprehensive Survey

Cited by 5 publications

References 93 publications

A review of Explainable Artificial Intelligence in healthcare

A review of Explainable Artificial Intelligence in healthcare

Deep learning for personalized health monitoring and prediction: A review

Real-Time Cardiac Abnormality Monitoring and Nursing for Patient Using Electrocardiographic Signals

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