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Mathematical modeling can improve regenerative medicine by predicting biological processes and optimizing therapy development.

Sericin hydrogels heal skin wounds well, regrowing hair and glands with less scarring.

Blocking casein kinase 1 in skin cells can help melanocyte precursors move better, potentially helping with conditions like vitiligo or gray hair.

Turning off the Lhx2 gene in mouse embryos leads to slower wound healing and scars.

Laser therapy helped new hair grow in scarred skin for three patients.

TLR3 activation helps improve skin and hair follicle healing in mice.

PDGF signaling is crucial for maintaining and renewing hair follicle stem cells, which could help treat hair loss.

New treatments for skin and hair repair show promise, but further improvements are needed.

Men with baldness due to androgenetic alopecia still have hair stem cells, but lack specific cells needed for hair growth.

Partial hair follicle extraction can effectively double the number of hair follicles for transplants, with most surviving and growing normally after a year.

HPV genes in mice improve ear tissue healing by speeding up skin growth and repair.

Fat-related cells are important for initiating hair growth.

Dermal cells are key in controlling hair growth and could potentially be used in hair loss treatments, but more research is needed to improve hair regeneration methods.

SCDSFs from zebrafish embryos are beneficial for treating cancer, regenerating tissues, and improving conditions like psoriasis and alopecia.

Three specific proteins can turn adult skin cells into hair-growing cells, suggesting a new hair loss treatment.

DPP4, a molecule in skin, helps heal large wounds and regrow hair follicles when its levels are reduced.

Hair follicle regeneration is possible but challenging, especially in humans, due to the need for specific cells and a better understanding of how they signal growth.

Full thickness wounds on Lanyu pigs' skin resulted in abnormal skin structure and function due to changes in molecular expression patterns.

Researchers found a way to turn skin cells into cells that can grow new hair.

New hair can grow from large wounds in mice, but less so as they age, involving reprogramming of skin cells and specific molecular pathways.

The research found that different types of fibroblasts are involved in wound healing and that some blood cells can turn into fat cells during this process.

Spiny mice are better at regenerating hair after injury than laboratory mice and could help us understand how to improve human skin repair.

M2 macrophages, a type of immune cell, help in new hair growth on scars by producing growth factors.

FGF9 from certain cells can trigger new hair growth during wound healing, but humans have fewer of these cells, which may limit hair regrowth.

A substance called FGF9 from certain immune cells can trigger new hair growth during wound healing in mice, but humans may not have the same response due to fewer of these cells.

Two growth factors, PDGF and FGF2, can potentially be used together to grow enough cells for a hair loss treatment, but their exact function on human cells needs further confirmation.

Hair follicles are complex, dynamic mini-organs that help us understand cell growth, death, migration, and differentiation, as well as tissue regeneration and tumor biology.

Bioengineering can potentially treat hair loss by regenerating hair follicles and cloning hair, but the process is complex and needs more research.

A new skin treatment using a patient's own cells healed chronic wounds effectively and was preferred over traditional grafts.

Dermal sheath cells can help grow new hair follicles and show promise in treating hair loss.