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The circadian clock influences the behavior and regeneration of stem cells in the body.

Human hair follicle stem cells can turn into multiple cell types but lose some of this ability after being grown in the lab for a long time.

Topical drugs and near-infrared light therapy show potential for treating alopecia.

β-Catenin signaling is involved in brain cell growth after injury and could be a therapy target.

Melanocyte development from neural crest cells is complex and influenced by many factors, and better understanding could help treat skin disorders.

The document concludes that for hair and feather growth, it's better to target the environment around stem cells than the cells themselves.

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

Prolactin affects the production of different keratins in human hair, which could lead to new treatments for skin and hair disorders.

Technique creates 3D cell spheroids for hair-follicle regeneration.

Hedgehog signaling helps keep hair follicle stem cells the same in both young and old human skin.

Epidermal stem cells could lead to new treatments for skin and hair disorders.

Certain signals and genes play a key role in hair growth and regeneration, and understanding these could lead to new treatments for skin regeneration.

Multiphoton microscopy is a promising tool for detailed skin imaging and could improve patient care if its challenges are addressed.

Blocking BACE1 and BACE2 enzymes causes hair color loss in mice.

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

Two-photon microscopy helps observe hair follicle stem cell behaviors in mice.

Brain hormones significantly affect hair color and could potentially be used to prevent or reverse grey hair.

Human skin cells can create new hair follicles when transplanted into mice.

Hair follicles offer promising targets for delivering drugs to treat hair and skin conditions.

Scarring alopecias are complex hair loss disorders that require early treatment to prevent permanent hair loss.

New understanding of the causes of primary cicatricial alopecia has led to better diagnosis and potential new treatments.

Advancements in creating skin grafts with biomaterials and stem cells are promising, but more research is needed for clinical application.

Fat cells are important for tissue repair and stem cell support in various body parts.

Hormones and neuroendocrine factors control hair growth and color, and more research could lead to new hair treatment options.

Engineered skin substitutes can grow hair but have limitations like missing sebaceous glands and hair not breaking through the skin naturally.

The gelatin/β-TCP scaffold with nanoparticles improves wound healing and skin regeneration.

Lizards can regrow their tails, and studying this process helps understand scar-free healing and limb regeneration.

Hair follicle regeneration in skin grafts may be possible using stem cells and tissue engineering.

Aging in hair follicle stem cells leads to hair graying, thinning, and loss.

Sweat glands and hair follicles are structurally connected within a specific layer of skin fat.