Mr. Bedanga Bora the research explores the interplay between quantum physics, cosmology, and computational modeling to understand the underlying structure of the universe through both theoretical and numerical approaches. Current work investigates quantum cosmology, anisotropic expansion models, and flat-universe dynamics using FRW and Bianchi-type formalisms, employing mathematical tools such as Christoffel symbols, Dingle methods, and differential modeling to analyze early-universe behavior and potential quantum origins of spacetime. Complementary studies in magnetohydrodynamics and biomedical physics involve modeling non-Newtonian blood flow under external magnetic fields using the Herschel–Bulkley rheological framework and simulating induced magnetic fields for therapeutic applications in arterial stenosis, including nanofluid-based enhancements. Parallel research in computational biology examines the convergence of artificial and biological learning systems by simulating neural-organoid behavior, synaptic plasticity, dropout analogies, and cellular dynamics through 3D Python-based visualizations. Additional work extends to quantum communication, where theoretical models are developed to analyze the entanglement stability of nitrogen-vacancy centers in diamond lattices at room temperature. Across these domains, the overarching objective is to integrate insights from quantum theory, high-dimensional modeling, and computational simulations to construct deeper frameworks that explain how microscopic quantum mechanisms influence macroscopic physical laws and complex biological systems.