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Two specific hair keratin genes are active during hair growth and decline as hair transitions to rest.

Endoglin is crucial for proper hair growth cycles and stem cell activation in mice.

The G60S Connexin43 mutation causes hair growth issues and poor hair quality in mice, similar to human ODDD patients.

Monotreme hair structure and protein distribution are similar to other mammals, but their inner root sheath cornifies differently, suggesting a unique evolution from reptile skin.

Nanog gene boosts stem cells, helps hair growth, and may treat hair loss.

sPLA2-IIA increases growth in hair follicle stem cells and cancer cells, suggesting it could be targeted for hair growth and cancer treatment.

Keratin injections can promote hair growth by affecting hair-forming cells and tissue development.

The EDAR gene mutation leads to thinner and more deformed hair shafts.

Activin B helps start and grow hair follicles in mice.

L-(+)-Tartaric Acid may help increase certain hair growth genes without harming cells.

Blue light helps hair growth by affecting specific proteins in hair follicle cells.

The hedgehog signaling pathway is crucial for hair growth but not for the initial creation of hair follicles.

Estrogens significantly influence hair growth by interacting with receptors in hair follicles and may help regulate the hair growth cycle.

Understanding hair growth involves complex interactions between molecules and could help treat hair disorders.

The Sonic hedgehog pathway is crucial for new hair growth during mouse skin healing.

Sonic hedgehog signaling is crucial for hair growth and maintaining hair follicle identity.

Oxidative stress contributes to hair graying and loss as we age.

The telogen phase of hair growth is active and important for preparing hair follicles for regeneration, not just a resting stage.

The document concludes that hair is complex, with a detailed growth cycle, structure, and clinical importance, affecting various scientific and medical fields.

Cyclosporine A may help treat hair loss by blocking a protein that inhibits hair growth.

Understanding how hair follicle stem cells work can help find new ways to prevent hair loss and promote hair growth.

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

Glutamine metabolism affects hair stem cell maintenance and their ability to change back to stem cells.

Heparan sulfate is important for hair growth, preventing new hair formation in mature skin, and controlling oil gland development.

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

BMP6 and Wnt10b control whether hair follicles are resting or growing.

Cell-based therapies using dermal papilla cells and adipocyte lineage cells show potential for hair regeneration.

Skin and hair can help us understand organ regeneration, especially how certain stem cells might be used to form new organs.

Hair disorders are caused by a complex mix of biology, genetics, hormones, and environmental factors, affecting hair growth and leading to conditions like alopecia.

Dogs could be good models for studying human hair growth and hair loss.