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Mice skin has components that could help with hair growth and might be used for diabetes treatment.

The study found that a specific area of the hair follicle helps start hair growth by reducing the blocking effects on certain cells and controlling growth signals.

Dermal EZH2 controls skin cell growth and differentiation in mice.

Chemotherapy and radiation therapy cause skin and hair damage by altering gene expression and signaling pathways.

Hair growth phase and certain genes can speed up wound healing, while an inflammatory mediator can slow down new hair growth after a wound. Understanding these factors can improve tissue regeneration during wound healing.

Damage to skin releases dsRNA, which activates TLR3 and helps in skin and hair follicle regeneration.

Prolactin affects hair growth and skin conditions, and could be a target for new skin disease treatments.

Newborn mouse skin cells can grow hair and this process can be recreated in adult cells to potentially help with hair loss.

Progress has been made in skin and nerve regeneration, but more research is needed to improve methods and ensure safety.

β-Catenin signaling is involved in brain cell growth after injury and could be a therapy target.

Touch sensitivity in mouse skin decreases during hair growth due to changes in touch receptors.

Sebaceous glands play a key role in skin health, immunity, and various skin diseases.

Melanoblasts migrate to the skin using various pathways, and understanding this process could help with skin disease research.

Pannexin 3 helps skin and hair growth by controlling a protein called Epiprofin.

Human prenatal skin develops an immune network early on that helps with skin formation and healing without scarring.

Melatonin treatment helps improve skin health in postmenopausal rats.

Hairless protein is crucial for healthy skin and hair, and its malfunction can cause hair loss.

Genetically modified sheep with more β-catenin grew more wool without changing the wool's length or thickness.

The research reveals how early embryonic mouse skin develops from simple to complex structures, identifying various cell types and their roles in this process.

Adult esophageal cells can start to become like skin cells, with a key pathway influencing this change.

Controlled light treatment in mouse skin speeds up healing and hair growth.

CD133+ progenitor cells have therapeutic potential for diabetic ulcers and heart attack recovery, with manageable risks.

The nucleus is key in controlling skin growth and repair by coordinating signals, gene regulators, and epigenetic changes.

The Hairless gene is crucial for healthy skin and hair growth.

Ovol2 is crucial for hair growth and skin healing by controlling cell movement and growth.

Different scaffold patterns improve wound healing and immune response in mouse skin, with aligned patterns being particularly effective.

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

Older people's sweat glands are less effective at helping skin wounds heal due to weaker cell connections.

Adult stem cells with Tp63 can form hair and skin cells when placed in new skin, showing they have hidden abilities for skin repair.

Nestin identifies specific progenitor cells in hair follicles that can become outer root sheath cells.