Emerging Technology Integration - Artificial Intelligence (AI) and Machine Learning (ML) for Predictive Analysis for Safety and Toxicity Assessment in Environmental Toxicology

Stephen Okechukwuyem Ojji

doi:10.18535/ijsrm/v12i05.ec03

Abstract

Environmental toxicology is facing unprecedented challenges due to the escalating complexity of environmental issues. Traditional methodologies for safety and toxicity assessment are struggling to keep pace with the rapid evolution of pollutants and their impacts on ecosystems and human health. In response to this pressing need, there has been a paradigm shift in the field towards the integration of Artificial Intelligence (AI) and Machine Learning (ML) techniques. This research article delves into the transformative potential of AI and ML in environmental toxicology, elucidating how these advanced computational tools offer promising solutions for predictive analysis.

By leveraging vast datasets and sophisticated algorithms, AI and ML enable more efficient, accurate, and timely assessment of environmental risks. They empower researchers and policymakers to anticipate and mitigate potential hazards before they escalate into crises. This paper provides a comprehensive overview of the diverse applications of AI and ML in environmental toxicology, ranging from predictive modeling of chemical hazards to early detection of environmental threats.

Furthermore, it highlights the potential of AI and ML to revolutionize decision-making processes in environmental management and policy formulation. By synthesizing vast amounts of data and identifying complex patterns and correlations, these technologies offer invaluable insights for crafting evidence-based policies and strategies to safeguard the environment and public health.

This research article underscores the pivotal role of AI and ML in addressing the multifaceted challenges of environmental toxicology. Through their integration, we have the opportunity to enhance our understanding of environmental risks, optimize resource allocation, and ultimately, pave the way towards a more sustainable and resilient future.

Keywords

Artificial IntelligenceMachine LearningEnvironmental ToxicologyPredictive AnalysisSafety AssessmentToxicity Assessmental 1. Introduction

References

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[refR-2] Oyeniyi, J., & Oluwaseyi, P. Emerging Trends in AI-Powered Medical Imaging: Enhancing Diagnostic Accuracy and Treatment Decisions.Google Scholar ↗

[refR-3] Singh, A. V., Rosenkranz, D., Ansari, M. H. D., Singh, R., Kanase, A., Singh, S. P., ... & Luch, A. (2020). Artificial intelligence and machine learning empower advanced biomedical material design to toxicity prediction. Advanced Intelligent Systems, 2(12), 2000084.Google Scholar ↗

[refR-4] Rehan, H. (2024). The Future of Electric Vehicles: Navigating the Intersection of AI, Cloud Technology, and Cybersecurity. Valley International Journal Digital Library, 1127-1143.Google Scholar ↗

[refR-5] Jiao, Z., Hu, P., Xu, H., & Wang, Q. (2020). Machine learning and deep learning in chemical health and safety: a systematic review of techniques and applications. ACS Chemical Health & Safety, 27(6), 316-334.Google Scholar ↗

[refR-6] Chadee, A. A., Martin, H. H., Mwasha, A., & Otuloge, F. (2022). Rationalizing critical cost overrun factors on public sector housing programmes. Emerging Science Journal, 6(3), 647-666.Google Scholar ↗

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[refR-8] Rehan, Hassan. "AI-Driven Cloud Security: The Future of Safeguarding Sensitive Data in the Digital Age." Journal of Artificial Intelligence General science (JAIGS) ISSN: 3006-4023 1, no. 1 (2024): 47-66.Google Scholar ↗

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[refR-11] Pulicharla, M. R. (2023). Hybrid Quantum-Classical Machine Learning Models: Powering the Future of AI. Journal of Science & Technology, 4(1), 40-65.Google Scholar ↗

[refR-12] Mittal, C. (2024). An Empirical Study on Cybersecurity Awareness, Cybersecurity Concern, and Vulnerability to Cyber-attacks. Valley International Journal Digital Library, 1144-1158.Google Scholar ↗

[refR-13] Oyeniyi, J. UNVEILING THE COGNITIVE CAPACITY OF CHATGPT: ASSESSING ITS HUMAN-LIKE REASONING ABILITIES.Google Scholar ↗

[refR-14] Wang, X., Wu, Y. C., & Ma, Z. (2024). Blockchain in the courtroom: exploring its evidentiary significance and procedural implications in US judicial processes. Frontiers in Blockchain, 7, 1306058.Google Scholar ↗

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[refR-23] Weng, Y., & Wu, J. (2024). Fortifying the global data fortress: a multidimensional examination of cyber security indexes and data protection measures across 193 nations. International Journal of Frontiers in Engineering Technology, 6(2), 13-28.Google Scholar ↗

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[refR-25] Keyan, K. S., Alanany, R., Kohil, A., & Khan, O. M. (2023). E3 Ubiquitin Ligase TRIP12 controls exit from mitosis via positive regulation of MCL-1 in response to taxol. Cancers, 15(2), 505.Google Scholar ↗

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[refR-32] Liang, Y., Wang, X., Wu, Y. C., Fu, H., & Zhou, M. (2023). A Study on Blockchain Sandwich Attack Strategies Based on Mechanism Design Game Theory. Electronics, 12(21), 4417.Google Scholar ↗

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[refR-36] Rehan, H. (2024). AI-Driven Cloud Security: The Future of Safeguarding Sensitive Data in the Digital Age. Journal of Artificial Intelligence General science (JAIGS) ISSN: 3006-4023, 1(1), 47-66.Google Scholar ↗

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[refR-39] Adeyeri, T. B. (2024). Blockchain and AI Synergy: Transforming Financial Transactions and Auditing. Blockchain Technology and Distributed Systems, 4(1), 24-44.Google Scholar ↗

[refR-40] Lee, Z., Wu, Y. C., & Wang, X. (2023, October). Automated Machine Learning in Waste Classification: A Revolutionary Approach to Efficiency and Accuracy. In Proceedings of the 2023 12th International Conference on Computing and Pattern Recognition (pp. 299-303).Google Scholar ↗