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Growth factors are crucial for hair development and could help treat hair diseases.

Smad1 and Smad5 are essential for hair follicle development and stem cell sleepiness.

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

Hair and nails are similar keratin structures with different shapes and growth, affected by the same diseases and environmental factors.

Bone Morphogenetic Proteins (BMPs) help control skin health, hair growth, and color, and could potentially be used to treat skin and hair disorders.

Mutant mice help researchers understand hair growth and related genetic factors.

The conclusion is that recognizing hair growth cycles can improve the precision of dietary and health assessments from hair analysis.

The document concludes that mouse models are crucial for studying hair biology and that all mutant mice may have hair growth abnormalities that require detailed analysis to identify.

Hair follicles are essential for skin health, aiding in hair growth, wound healing, and immune function.

A protein called sFRP4 from skin cells stops the development of pigment-producing cells in hair.

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

Understanding how melanocyte stem cells work could lead to new treatments for hair graying and skin pigmentation disorders.

Mice without certain skin proteins had abnormal skin and hair development.

Impaired autophagy may cause hair loss by triggering early catagen.

We need better treatments for hair loss, and while test-tube methods are helpful, they can't fully replace animal tests for evaluating new hair growth treatments.

BMP signaling controls hair follicle size and cell growth by affecting cell cycle genes.

A certain signaling pathway in mice, when increased, causes hair to gray by depleting the cells that give hair its color.

Sunlight exposure damages hair follicles, but certain stem cell-derived particles can reduce this damage and help with hair regeneration.

Human hair is made up of different keratins, some strong and some weak, with specific types appearing at various stages of hair growth.

Hair is important for protection, social interaction, and temperature control, and is made of a growth cycle-influenced follicle and a complex shaft.

KAP genes show significant genetic variability, but its impact on hair traits is unclear.

Non-coding RNAs are important for hair growth and could lead to new hair loss treatments, but more research is needed.

A protein called sFRP4 can slow down hair regrowth.

Certain miRNAs play a key role in the growth of cashmere by affecting hair follicle development and regeneration.

Stem cells, especially from fat tissue and Wharton's jelly, can potentially regenerate hair follicles and treat hair loss, but more research is needed to perfect the treatment.

Hairless mammals have genetic changes in both their protein-coding and regulatory sequences related to hair.

Hairlessness in mammals is due to complex genetic changes in both genes and regulatory regions.

A gene deletion causes the "hairless" trait in Iffa Credo rats.

Both gene and non-gene areas of DNA evolved to make some mammals hairless.

A second domain of high sulfur KAP genes on chromosome 21q23 is crucial for hair structure.