From Bits to Atoms: Machine Learning and Nanotechnology for Cancer Therapy
Author(s): Mawuli Agboklu, Frederick A Adrah, Prince Mawuli Agbenyo, Hope Nyavor
Cancer therapy has seen significant advancements in recent years, with the integration of machine learning and nanotechnology emerging as a promising new approach to improve treatment outcomes. This paper explores the synergistic potential of machine learning and nanotechnology-based platforms in enhancing cancer therapy. The paper also proposes a conceptual framework for using Gold Nanoparticles (AuNPs) and Data Mining for enhanced Photothermal therapy. Machine learning techniques offer the ability to analyze large datasets of patient information, tumor characteristics and treatment responses to develop personalized treatment plans tailored to patients. By harnessing machine learning algorithms and nanomedicine, clinicians can optimize treatment strategies, predict treatment outcomes and identify novel therapeutic targets. Nanotechnology provides a multipurpose platform for targeted drug delivery, imaging and diagnostics in cancer therapy. Nanoparticle-based drug delivery systems can deliver therapeutic agents directly to tumor sites while minimizing off-target effects and enhancing treatment efficacy. Additionally, nanoscale imaging agents and sensors enable early detection of cancer biomarkers and monitoring of treatment responses. This work also bridges the gap between scientific research and clinical applications. The integration of machine learning and nanotechnology offers several advantages for enhanced cancer therapy, including personalized treatment approaches, enhanced drug delivery efficiency, early detection methods and predictive modeling for treatment responses. This paper highlights recent advancements, challenges, and future directions in leveraging machine learning and nanotechnology to optimize cancer therapy and improve patient outcomes.