Lectures related to Nanocubes and Regenerative Medicine

Nanomaterials in Tissue Engineering

Explores the use of nanomaterials in tissue engineering, covering scaffold construction, fiber bonding, rapid prototyping, and enhancement of electrical properties.

Polymers and Particles in Biomaterials

Explores the use of polymers, hydrogels, and particles in various biomaterials applications, covering topics such as drug delivery, cell adhesion, and tissue engineering.

Tissue Patterning: Engineering Complex Organ Patterns

Explores tissue patterning, focusing on complex organ patterns through cell interactions and morphogen gradients.

Organoids: Model Systems in Tissue Engineering

Explores the development and applications of organoids in tissue engineering and disease modeling using miniature in vitro constructs.

Organoids: Miniature Multicellular Tissue Constructs

Explores organoids, miniature tissue constructs mimicking living tissues, covering derivation methods, applications, and bridging in vitro and in vivo models.

Materials for Biomaterials: Overview & Applications

Series covers the fundamentals of biomaterials and their applications in various fields.

Organs and Organoids: Engineering and Applications

Explores the formation and applications of organs and organoids, highlighting their potential to revolutionize medical research.

Tissue Engineering: Biomaterials and Stem Cells

Explores the requirements of materials for tissue engineering, focusing on stem cells and biomaterials' role in controlling stem-cell fate and tissue regeneration.

Extracellular Matrix: Structure, Function, and Engineering

Discusses the structure and function of the extracellular matrix and its engineering for tissue applications.

Artificial ECMs: Design, Applications, and Challenges

Delves into artificial ECMs, synthetic biomaterials, and challenges in tissue engineering.

Material Engineering in Cancer Immunotherapy

Covers the evasion of immune pressure by tumors, cancer immunotherapies, drug delivery strategies, and the impact of nanoparticle characteristics on tumor penetration.

Immune Engineering: Materials and Applications

Covers the basics of immune engineering, materials for drug delivery, vaccination, and cancer immunotherapy, including current research examples.

Tissue Mechanobiology: Vertex Models and ECM Fibers

Explores particle, lattice, and vertex models in tissue mechanobiology, focusing on cell interactions and ECM fibers.

Material Engineering in Cancer Immunotherapy

Explores tumor immune evasion, drug delivery challenges, and nanoparticle strategies in cancer treatment, including the impact of checkpoint inhibitors and hydrogels.

Engineering Artificial Cells and Organs: A Biological Perspective

Covers the engineering of artificial cells and organs, emphasizing material applications in biological systems.

Ligand-Receptor Interactions: Mechanisms and Quantification

Covers ligand-receptor interactions, their mechanisms, and how to quantify binding affinities in biological systems.

Immune Cell Engineering: Targeting Checkpoint Inhibitors

Explores immune cell engineering for cancer therapy, emphasizing checkpoint inhibitor targeting through innovative delivery methods.

Tailoring Biomaterials for Stem Cell Biology

Explores engineering artificial stem cell niches, biomaterial screening, and microarrayed niche fabrication.