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The conclusion is that hair growth can be improved by activating hair cycles, changing the surrounding environment, healing wounds to create new hair follicles, and using stem cell technology.

The conclusion is that Fgf18 and Tgf-ß signaling could be targeted for hair loss treatments.

Androgens are important for normal ovarian function and estrogen production, but may not be the main cause of follicle death.

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.

The document explains hair growth and shedding, factors affecting it, and methods to evaluate hair loss, emphasizing the importance of skin biopsy for diagnosis.

Hair follicles can help wounds heal faster and this knowledge could be used to treat chronic skin ulcers, with a potential use of a special stem cell hydrogel to enhance healing.

Understanding glycans and enzymes that alter them is key to controlling hair growth.

Melatonin receptors in hair follicles help regulate hair growth and could treat hair loss.

A new painless method to collect hair follicles helps study DNA damage and aging.

Hair greying is linked to reduced ATM protein in hair cells, which protects against stress and damage.

Memory T cells in the skin balance staying put and moving into the blood, clustering around hair follicles, and increasing in number after infection.

Hair growth is influenced by factors like genetics and nutrition, and more research is needed to understand hair loss and growth mechanisms.

AGA causes hair loss through follicle miniaturization and hair cycle changes; regrowth depends on anagen initiation in kenogen follicles.

The mTurq2-Col4a1 mouse model shows that cells can divide while attached to stable basement membranes during development.

Stem cell niches are crucial for regulating stem cell behavior and tissue health, and their decline can impact aging and cancer.

Antibiotics can reduce acne but may lead to resistant bacteria, and understanding the skin's bacteria is important for treatment.

The document describes how to tell different types of non-scarring hair loss apart by looking at hair and scalp tissue under a microscope.

Keratin 79 marks a new group of cells that are key for creating and repairing the hair follicle's structure.

Accurate clinical, histological, and genetic methods are key for understanding and treating hair disorders.

Live imaging has advanced our understanding of stem cell behavior and raised new research questions.

Some stem cells in the body rarely divide, which could help create better treatments for diseases and aging.

Blocking TSLP reduces skin inflammation and cell overgrowth in psoriasis.

Certain cells outside the hair follicle's bulge area can quickly regenerate damaged hair follicles, potentially helping to reduce hair loss from cancer treatments.

Two-photon microscopy effectively tracks live stem cell activity in mouse skin with minimal harm and clear images.

New technologies help us better understand how skin microbes affect skin diseases.

Blackcurrant extract may help reduce hair loss by promoting stem cell activity in hair follicles.

Dermal papilla cells are key for hair growth and color, influencing hair type and size, and their interaction with stem cells could help treat hair loss and color disorders.

Acne is a common skin condition linked to diet, hormones, and genetics, and early treatment can prevent scarring.

3D microenvironments in microwells improve hair follicle stem cell behavior and hair regeneration.

Androgens and androgen receptors are important for metabolic health, affecting how the body uses glucose and fats through mitochondrial function.