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Modulating BMP activity changes the number, size, shape, and type of ectodermal organs.

Macrophages help heal nerves by aiding the maturation of Schwann cells and are important for nerve repair.

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

Fat cells in the skin help start healing and form important repair cells after injury.

Stem cell plasticity is crucial for wound healing but can also contribute to cancer development.

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

Asia has made significant progress in tissue engineering and regenerative medicine, but wider clinical use requires more development.

Macrophages help regrow hair by activating stem cells using AKT/β-catenin and TNF.

Hair, teeth, and mammary glands develop similarly at first but use different genes later.

The document concludes that the hair cycle is a complex process involving growth, regression, and rest phases, regulated by various molecular signals.

Laminin-511 is crucial for early hair growth and maintaining important hair development signals.

A WNT10A gene mutation leads to ectodermal dysplasia by disrupting cell growth and differentiation.

Turing patterns are now recognized as important in developmental biology.

Activating the Wnt/β-catenin pathway could lead to new hair loss treatments.

TNF family proteins are crucial for the development of skin features like hair, teeth, and mammary glands.

The Foxn1 gene mutation causes hairlessness and immune system issues, and understanding it could lead to hair growth disorder treatments.

Mammals might fail to regenerate not because they lack the right cells, but because of how cells respond to their surroundings, and changing this environment could enhance regeneration.

The skin protects the body and is constantly renewed by stem cells; disruptions can lead to cancer.

Feather growth and regeneration involve complex patterns, stem cells, and evolutionary insights.

Skin development in mammals is controlled by key proteins and signals from underlying cells, involving stem cells for maintenance and repair.

The TGF-β family helps control how cells change and move, affecting skin, hair, and organ development.

Drosha and Dicer are essential for hair follicle health and preventing DNA damage in skin cells.

EGF and KGF signalling prevent hair follicle formation and promote skin cell development in mice.

Stress hormone corticosterone blocks a growth factor to slow down hair stem cell activity and hair growth.

Dermal Papilla cells are a promising tool for evaluating hair growth treatments.

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.

Mice lacking a key DNA methylation enzyme in skin cells have a lower chance of activating stem cells necessary for hair growth, leading to progressive hair loss.

mTOR signaling helps activate hair stem cells by balancing out the suppression caused by BMP during hair growth.

Electrospun nanofibers show promise for enhancing blood vessel growth in tissue engineering but need further research to improve their effectiveness.

PRP and HF-MSCs treatment improves hair growth, thickness, and density in androgenetic alopecia.