![]() On the science and ethics of cloning, gene editing methods with special focus on geneĮditing in stem cells. Therapy and generating chimeras for organ transplantation. How do Stem Cells work: How to induce stem cells to differentiate into particularĬell types? New stem cell-assisted technologies such as mitochondrial replacement Of stem cell research, and the potential for stem cell therapies. Introduction to Stem Cells: Basic overview of stem cells-what they are, the history Bioethics: Animal and human experimentation, informed consent, euthanasia,Įthical issues in feasibility studies, ethical clearance BE 304 Markets, case studies from India and abroadĩ. Medical devices: Classes of medical devices, considerations for design andĭevelopment, introduction to regulatory processes in Indian, U.S., and European Magnetic resonance, ultrasound, and nuclear medicineĨ. Brief overview of imaging: Optical microscopy, X-Rays, computed tomography, Biosignals: Acquiring and analyzing biosignals, electrocardiogram (ECG),Įlectroencephalography (EEG), electromyogram (EMG), thermography, blood flowħ. Healing processes, replacement of diseased tissues, tissue engineering in controlĦ. Tissue engineering: Challenges in organ transplantation, cell culture, regulation of Selection, tissue-biomaterial interactions, safety testingĥ. Biomaterials: Materials in medicine, lessons from nature on biomaterial design and Physics and mechanics of locomotion (e.g., walking, running, swimming), design inĤ. Viscoelasticity), mechanics of tissues (e.g., cartilage, ligaments, tendon, muscle), Biomechanics: Basic mechanics (elasticity, viscosity, deformation and Systems, communication systems, respiration, digestion, circulation, removal ofģ. Overview of anatomy and physiology: Cellular organization, tissues, major organ Needs, interfacing with clinicians, research, and developmentĢ. ![]() Biomedical engineers and modern health care systems: Addressing unmet clinical TheĬourse topics will include the following:ġ. To the analyses of physiological systems for addressing challenges in health care. ![]() We will discuss applications of elementary engineering principles This course will provide an introductory overview of the multi-disciplinary field ofīiomedical engineering. Nanotechnology with molecules of life: Proteins-Proteins Structures, Designs, Nanomachines, Origami designs and Applications Carbohydrates-Glyconanotechnology, Applications in Glycobiology, vaccination, delivery and cell biology Lipids-Structure, function, designs, membranes and applications in drug delivery formulations and cell biology Combinatorial Bionanotechnology-Hybrid formulations, structures, functions and applications.ĭNA Nanotechnology: Structure of DNA- Why DNA is genetic material of life? Naturally occuring DNA nanomachines Discovery of DNA nanotechnology - Initial designs and validations Multi-arm DNA based 1/2/3D nanodevices DNA Origami Non-canonical Motifs and applications-Aptamers, i-motif, G-quadruplexes.Īpplications of DNA Nanotechnology: Cell Engineering Theranostics Diagnostics (Biosensing) and therapeutic applications Biomedical Applications-Bioimaging including super-resolution imaging and single-particle tracking DNA based computing and robotics. Introduction to Nanotechnology and special focus on Bionanotechnology. Bionanotechnology – Principles and Applications
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