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Human hair follicles can regenerate and recover after severe injury by going through a brief abnormal resting phase before growing again.

The "Punch Assay" can regenerate hair follicles efficiently in mice and has potential for human hair regeneration.

Researchers created human hair follicles using a new method that could help treat hair loss.

Scientists created a lab-grown hair follicle model that behaves like real hair and could improve hair loss treatment research.

Adiponectin reduces inflammation and bone loss in joint replacements.

Skin grafting is a key procedure for repairing skin defects, with the success depending on the right graft choice, donor site management, and aftercare.

The basement membrane matrix helps rebuild hair follicles faster and more effectively.

Platelet-rich plasma can help grow more mouse hair follicles, but it doesn't work for human hair follicles yet.

The right amount of retinoic acid is essential for normal hair growth and development.

The study developed a new way to create hair-growing tissue that can help regenerate hair follicles and control hair growth direction.

The study created a new type of microsphere that effectively regrows hair.

Scientists turned mouse stem cells into skin cells that can grow into skin layers and structures.

Submental tissue is good for repairing mouth area skin with minimal scarring and good cosmetic results.

The tumescent technique improves hair micrografting by providing lasting anesthesia, reducing bleeding, and increasing patient comfort.

Certain cells from hair follicles can create new hair and contribute to hair growth when implanted in mice.

Larger spheroids improve hair growth, but size doesn't guarantee thicker hair.

Improving the environment and cell interactions is key for creating human hair in the lab.

The flap assay grows the most natural hair but takes the longest, the chamber assay is hard work but gives dense, normal hair, and the patch assay is quick but creates poorly oriented hair with some issues.

Hair growth environment recreated with challenges; stem cells make successful skin organoids.

The 3D skin model is better for hair growth research and testing treatments.

A device was made in 2008 to measure hair loss severity. Other findings include: frizzy mutation in mice isn't related to Fgfr2, C/EBPx marks preadipocytes, Cyclosporin A speeds up hair growth in mice, blocking plasmin and metalloproteinases hinders healing, hyperbaric oxygen helps ischemic wound healing, amniotic membranes heal wounds better than polyurethane foam, rhVEGF165 from a fibrin matrix improves tissue flap viability and induces VEGF-R2 expression, and bFGF enhances wound healing and reduces scarring in rabbits.

Fat-related cells are important for initiating hair growth.

Scientists have found a way to create hair follicles from skin cells of newborn mice, which can grow and cycle naturally when injected into adult mouse skin.

Hair follicle stem cells are key for hair and skin regeneration, can be reprogrammed, and have potential therapeutic uses, but also carry a risk of cancer.

EVAL membranes help create cell structures that can regrow hair follicles.

Hair follicle stem cells are a promising source for tissue repair and treating skin or hair diseases.

Hair growth is influenced by interactions between skin layers, growth factors, and hormones, but the exact mechanisms are not fully understood.

Researchers developed a 3D model of human hair follicle cells that can help understand hair growth and test new hair loss treatments.

Scientists created a long-lasting stem cell line from human hair that can turn into different skin and hair cell types.

PI3K/Akt pathway is crucial for hair growth and regeneration.