Abstract
Regenerative medicine (RM) exploits stem cells to construct biological replacements and repair damaged tissues, offering an alternative to daunting organ transplantation. Even while RM has advanced quickly, building an entire organ remains beyond our capabilities. Experts are thus investigating the adoption of biologically generated composites that preserve the tissue's crucial physiological, morphological, and mechanical characteristics. Noncellular tissues like extracellular matrix offer cells a milieu similar to their physiological niche, becoming a promising substitute for synthetic composites. In this context, amnion, the membrane enclosing the fetus, is a great contender since it is widely obtainable and economical. Given its biochemical and anatomic characteristics, and the extensive supply of stem cells, growth factors, and matrix proteins, the amnion is considered a fantastic candidate to employ in RM. Decellularized amniotic membrane (DAM) has many uses as two- and three-dimensional scaffolds, anchoring for cell adhesion and expansion for tissue regeneration, and as carrier systems for cell and drug cargoes. The present research aims to assess the recent surge in DAM-RM research, potentially to get beyond the existing barriers impeding the RM's clinical translation landscape. The present paper draws a comprehensive picture of the experimental evidence and clinical trials regarding exploiting DAM in RM.