Explores polymer synthesis basics, including step and radical chain polymerization, molecular weight control, copolymerization, and crosslinked polymers for microengineering.
Explores the fundamentals and applications of hydrogel biomaterials, covering preparation methods, characterization techniques, and biocompatibility aspects.
Explores the tissue engineering paradigm, focusing on steps of cell isolation, seeding cells on a scaffold, cell stimulation in a bioreactor, and implantation of tissue engineered constructs.
Covers the use of macro-materials in tissue engineering, including key components, scaffold classification, bioresorbable polymers, and hydrogel applications.
Explores the transformation of raw materials into commercial products in the chemical industry, focusing on the production of industrial organic chemicals and polymers.
Explores the classification, molecular structures, mechanical behavior, and viscoelastic properties of polymers, emphasizing temperature effects and material responses.
Explores the mechanisms of polymer synthesis, including radical chain polymerization and the synthesis of high molecular weight poly(lactic acid) for compostable materials and biomaterials.
Explores polymer synthesis techniques and their impact on molecular characteristics, including living free radical polymerization and macromolecular engineering.
Explores the evolution and applications of Metal-Free Atom Transfer Radical Polymerization, highlighting the advantages of light-mediated polymerization and the challenges in achieving precise control over polymer synthesis.
Explores the use of nanomaterials in tissue engineering, covering scaffold construction, fiber bonding, rapid prototyping, and enhancement of electrical properties.
