Rabbit Induced Pluripotent Stem Cells-Derived Mesenchymal Stem Cells for Enhanced Wound Healing

Medicine, Orthopedics, Basic Medical Sciences, Life Sciences, Cell Biology, Bioengineering,
induced pluripotent stem cells   mesenchymal stem cells   rabbit   wound healing   regenerative medicine   SB431542   differentiation  

Academic Background and Research Motivation In recent years, the field of stem cell and regenerative medicine has developed rapidly. Due to their multipotency and self-renewal capacity, stem cells have become a vital cell source for tissue repair and regeneration. Among the many types of stem cells, Mesenchymal Stem Cells (MSCs) have drawn consider...

Progress in Biomaterials-Enhanced Vascularization by Modulating Physical Properties

Materials Science, Medicine, Life Sciences, Bioengineering,
tissue engineering   vascularization   physical property   material modification   regenerative medicine  

Research on the Modulation of Physical Properties of Biomaterials to Enhance Vascularization Background Introduction In the fields of tissue engineering and regenerative medicine, the formation of a vascular system and adequate blood perfusion are crucial for ensuring the supply of nutrients and oxygen within biomaterials. However, existing biomate...

Volumetric Additive Manufacturing for Cell Printing: Bridging Industry Adaptation and Regulatory Frontiers

Chemistry, Chemical Engineering, Engineering, Materials Science, Medicine, Life Sciences, Cell Biology, Biochemistry, Bioengineering,
volumetric additive manufacturing   cell printing   light-based printing   tomography   additive manufacturing   regenerative medicine   tissue engineering  

Applications of Volumetric Additive Manufacturing in Cell Printing Academic Background Volumetric Additive Manufacturing (VAM) is a revolutionary 3D printing technology capable of rapidly creating complex three-dimensional structures, particularly in the field of cell printing. VAM can mimic the structures of natural tissues, offering new possibili...