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The review concludes that innovations in regenerative medicine, tissue engineering, and developmental biology are essential for effective tissue repair and organ transplants.

Fat tissue stem cells show promise for repairing different body tissues and are being tested in clinical trials.

Sponges made of soy protein and β-chitin with human cells from hair or fat can speed up healing of chronic wounds.

Fat under the skin releases HGF which helps hair grow and gain color.

Inflammation helps stem cells repair tissue by directing their behavior.

Artificial skin development has challenges, but new materials and understanding cell behavior could improve tissue repair. Also, certain growth factors and hydrogel technology show promise for advanced skin replacement therapies.

Heparin and protamine are promising in tissue repair and organ regeneration, including skin and hair.

Fat tissue under the skin affects hair growth and aging; reducing its inflammation may help treat hair loss.

Injecting a person's own fat stem cells into their skin can make it look younger and improve double eyelids for over a year.

MSC-protein helps regenerate gum tissue and bone.

Removing REDD1 in mice increases skin fat by making fat cells larger and more numerous.

Using Platelet-Rich Plasma and Adipose-Derived Mesenchymal Stem Cells together can improve healing, including wound healing, bone regeneration, and hair growth.

Low-dose UVB light improves hair growth effects of certain stem cells by increasing reactive oxygen species.

Human skin can provide stem cells for tissue repair and regeneration, but there are challenges in obtaining and growing these cells safely.

Fat stem cells from diabetic mice can help heal skin wounds in other diabetic mice.

Hyaluronic acid and polycaprolactone improve skin regeneration, with polycaprolactone having a stronger effect on healing and tissue repair.

The conclusion is that hair growth can be improved by activating hair cycles, changing the surrounding environment, healing wounds to create new hair follicles, and using stem cell technology.

The new biomaterial inspired by ancient Chinese medicine effectively promotes hair growth and heals wounds in burned skin.

Transplanting growing hair follicles into scars can help regenerate and improve scar tissue.

Different stem cells have benefits and challenges for tissue repair, and more research is needed to find the best types for each use.

Electrospun matrices help regenerate skin and hair follicles using PCL and collagen scaffolds.

The circadian clock is crucial for tissue renewal and regeneration, affecting stem cell functions and having implications for health and disease.

The Wnt/β-catenin pathway is important for tissue development and has potential in regenerative medicine, but requires more research for therapeutic use.

Electrospun nanofibers show promise for enhancing blood vessel growth in tissue engineering but need further research to improve their effectiveness.

Stem cell niches are adaptable and key for tissue maintenance and repair.

Mice with enhanced regeneration abilities may help develop new regenerative medicine therapies.

Bacteria can help skin regenerate through a process called IL-1β signaling.

Wound healing insights can improve regenerative medicine.

Fetal-maternal stem cells in a mother's hair can help with tissue repair and regeneration long after childbirth.

3D cell-derived matrices improve tissue regeneration and disease modeling.