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Researchers created early-stage hair-like structures from skin cells, showing how these cells can self-organize, but more is needed for complete hair growth.

Skin patterns form through molecular signals and genetic factors, affecting healing and dermatology.

Skin patterns are formed by simple reaction-diffusion mechanisms.

BMP2 and BMP7 have opposite roles in feather formation.

The document concludes that computational models are useful for understanding immune responses and could improve cancer immunotherapy.

Feather patterns form through genetic and epigenetic controls, with cells self-organizing into periodic patterns.

The conclusion is that understanding how patterns form in biology is crucial for advancing research and medical science.

Fingerprints form uniquely before birth due to specific genetic pathways and local signals.

The conclusion is that understanding how feathers and hairs pattern can help in developing hair regeneration treatments.

The conclusion is that skin and hair patterns are formed by a mix of cell activities, molecular signals, and environmental factors.

Experiments can shape how feathers grow and develop.

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

Turing patterns are now recognized as important in developmental biology.

Estrogen affects hair growth and skin cell multiplication.

The wild garlic plant, Allium macrostemon Bunge, can promote hair growth and could potentially be used to treat hair loss.

Different body areas in mice produce different hair types due to interactions between skin layers.

Certain signals and genes play a key role in hair growth and regeneration, and understanding these could lead to new treatments for skin regeneration.

The document concludes that understanding hair follicles requires more research using computational methods and an integrative approach, considering the current limitations in hair treatment products.

Researchers developed a mouse model that tracks hair growth using bioluminescence, improving accuracy in studying hair cycles.

Epidermal stem cells create and maintain skin structures like hair and nails through specific signaling pathways and vary by location and function.

Cat color patterns are determined early in development by gene expression and epidermal changes, with the Dickkopf 4 gene playing a crucial role.

Chemokine signaling is important for hair development.

The study found that the protein Dkk4 helps regulate hair growth by controlling Wnt signaling in mice.

Scientists made working hair follicles using stem cells, helping future hair loss treatments.

Ginsenoside Re from ginseng may help hair grow by blocking a specific growth-inhibiting pathway.

Tissue stiffness affects hair follicle regeneration, and Twist1 is a key regulator.

A topical BRAF inhibitor, vemurafenib, can speed up wound healing and promote hair growth, especially in diabetic patients.

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

KY19382 helps regrow hair and create new hair follicles.

Valproic Acid helps regrow hair in mice and activates a hair growth marker in human cells.