Mesenchymal stem cells (MSCs) are emerging as key players in regenerative medicine for the treatment of various diseases associated with the inflammation and degeneration, thereby aiding in therapeutic advancements. Several tissues have been identified as potential sources of MSCs including the bone marrow, cord blood, dental pulp, umbilical cord, adipose tissue, peripheral blood, and fetal liver, of which some are clinically recognized. MSCs are capable of differentiating into cells of multiple lineages and therefore established as suitable candidates for transplantation in damaged organs. They have added advantage of higher proliferation, easy expansion, and, more importantly, the absence of HLA class II receptors, with potential applications extending toward allogenic settings. MSCs are actively involved in different mechanisms related to repair and regeneration of tissues via immunomodulation, transdifferentiation, paracrine factors, etc. They are known to exhibit profound immunomodulatory effect on T and B cells and natural killer (NK) cells mediated via soluble factors and direct cell-cell contact. The MSCs activate the immune responses and inhibit proliferation, maturation, and differentiation of T and B cells. The MSC-activated immune responses induce the expression of regulatory T cells (Tregs). A plethora of studies have established that MSCs suppress immune responses via immunomodulation that makes them a preferred cell source for the use in clinical trials.
Part of the book: Immune Response Activation and Immunomodulation
Regenerative medicine has been coming into spotlight ever since the realisation that conventional treatments are not enough, and the need for specific therapies has emerged. This, however, has paved way for cell-free therapy using extracellular vesicles. A two-dimensional (2D) cell culture model is widely recognised as the “gold standard” for researching cellular communications ex vivo. Although the 2D culture technique is straightforward and easy to use, it cannot replicate the in vivo ECM interactions & microenvironment. On the contrary, 3D culture culturing technology has emerged which include structures such as spheroids and organoids. Organoids are small replicas of in vivo tissues and organs, which faithfully recreate their structures and functions. These could be used as models to derive stem cells based EVs for manufacturing purposes. The linkages between infection and cancer growth, as well as mutation and carcinogenesis, may be modelled using this bioengineered platform. All in all, 3D culturing derived EVs serves as a novel platform for diagnostics, drug discovery & delivery, and therapy.
Part of the book: Possibilities and Limitations in Current Translational Stem Cell Research