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Genetic mutations can cause hair growth disorders by affecting key genes and signaling pathways.

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

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

Roxithromycin, an antibiotic, can increase hair growth and might be used as a treatment for hair loss.

The extract from Bacillus/Trapa japonica fruit helps increase hair growth and could be a potential treatment for hair loss.

Increased PPARGC1α relates to hair thinning in common baldness.

Intense pulsed light treatment effectively reduces underarm hair by making hair follicles smaller and extending their resting phase.

Hair diameter and curvature are mostly determined by genetics.

Transplanted hair follicles can change and adapt to new areas of the body, with the immune system possibly playing a role in this adjustment.

Examining scalp biopsies in different ways helps better diagnose hair loss types.

Gender affects hair and scalp characteristics, with differences in hormone responses, graying patterns, and trace metals.

The document concludes that there are various causes and treatments for hair loss, with hair transplantation being a notable option.

OCT can effectively examine and reveal details about human hair and scalp conditions.

Some treatments like topical oxygen and stem cells show promise for wound healing and hair growth, but evidence for modern dressings over traditional ones is limited.

Researchers found new hair and nail genes, how hair reacts to UV, differences in white and pigmented hair growth, nerve changes in alopecia, treatments for baldness and alopecia, a toenail condition linked to a genetic disorder, and that nail fungus is more common in people with psoriasis.

Wnt signaling is crucial for pigmented hair regeneration by controlling stem cell activation and differentiation.

Future hair loss treatments should aim to extend hair growth, reactivate resting follicles, reverse shrinkage, and possibly create new follicles, with gene therapy showing promise.

Noggin is necessary to start the hair growth phase in skin after birth.

Hair color production in mice is closely linked to the hair growth phase and may also influence hair growth itself.

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

Hair follicle dermal stem cells are key for regenerating parts of the hair follicle and determining hair type.

Understanding hair follicle anatomy helps diagnose hair disorders.

Human hair follicle organ culture is a useful model for hair research with potential for studying hair biology and testing treatments.

Tiny particles from stem cells help activate hair growth cells and encourage hair growth in mice without being toxic.

Understanding the mouse hair cycle is crucial for cancer research.

MicroRNA-214 is important for skin and hair growth because it affects the Wnt pathway.

The p75 neurotrophin receptor is important for hair follicle regression by controlling cell death.

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

The document concludes that understanding the genes and pathways involved in hair growth is crucial for developing treatments for hair diseases.

The p53 protein helps control hair follicle shrinking by promoting cell death in mice.