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Blood stem cells are diverse, influenced by many factors, and understanding them is key for progress in regenerative medicine.

Stem cell offspring help control their parent stem cells, affecting tissue health, healing, and cancer.

Different types of stem cells and their environments are key to skin repair and maintenance.

Applying pseudoceramide improved skin and hair health.

Stem cells can create hair follicles, potentially treating permanent hair loss, and healthy skin and hair depend on mitochondrial function and special fats.

Hair follicle stem cells are important for maintaining healthy skin and interact with many signals.

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

Gene network oscillations inside hair stem cells are key for hair growth regulation and could help treat hair loss.

Melanocytes are important for skin and hair color and protect the skin from UV damage.

Removing the Crif1 gene in mouse skin disrupts skin balance and hair growth.

The extracellular matrix is crucial for controlling skin stem cell behavior and health.

Aging reduces skin stem cell function, leading to changes like hair loss and slower wound healing.

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

Hair follicle stem cells have significant potential for treating various disorders.

EdnrB signaling helps melanocyte stem cells regenerate and could be targeted to treat pigmentation issues.

Low ERCC3 gene activity is linked to non-pigmented hair growth.

Hair growth environment recreated with challenges; stem cells make successful skin organoids.

The skin's basement membrane is specially designed to support different types of connections between skin layers and hair follicles.

Blood cells turned into stem cells can become skin cells similar to normal ones, potentially helping in skin therapies.

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

Hair thinning causes stem cell loss through a process involving Piezo1, calcium, and TNF-α.

Aging changes hair stem cells and their environment, leading to gray hair and hair thinning, but understanding these changes could help develop treatments for hair regeneration.

Hair graying may be caused by stem cell depletion from stress or melanocyte damage.

Special proteins are important for skin balance, healing, and aging, and affect skin stem cells.

Skin stem cells interacting with their environment is crucial for maintaining and regenerating skin and hair, and understanding this can help develop new treatments for skin and hair disorders.

Advancements in tissue engineering show promise for hair follicle regeneration to treat hair loss.

Patient-derived melanocytes can potentially treat vitiligo by restoring skin pigmentation.

The study found new details about human hair growth and suggests that preventing a specific biological pathway could potentially treat hair graying.

Hair loss and aging are caused by the breakdown of a key protein in hair stem cells.

TGF-β signaling is crucial for stem cell maintenance, differentiation, and has implications for cancer treatment.