Explores the use of nanomaterials in tissue engineering, covering scaffold construction, fiber bonding, rapid prototyping, and enhancement of electrical properties.
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 development of a high-resolution 3D printing technology for advanced biomaterials, focusing on Melt Electrowriting (MEW) and its exceptional stability and fiber diameter control.
Covers the formation and applications of organoids, including brain, skin, and intestinal organoids, as well as the engineering of tissues and the concept of organ-on-a-chip.
Explores the use of polymers, hydrogels, and particles in various biomaterials applications, covering topics such as drug delivery, cell adhesion, and tissue engineering.
Explores organoids, miniature tissue constructs mimicking living tissues, covering derivation methods, applications, and bridging in vitro and in vivo models.
Explores the definition, key properties, synthesis schemes, and applications of hydrogels as biomaterials, emphasizing their importance in drug delivery, tissue engineering, and cell biology.
Explores biofabrication and bioprinting, covering automated generation of functional products from living cells, biomaterials, and bioactive molecules, along with challenges and advancements in tissue engineering.
