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Scarless healing is complex and influenced by genetics and environment, while better understanding could improve scar treatment.

Nanotechnology shows promise for better chronic wound healing but needs more research.

MSCs and their exosomes may speed up skin wound healing but need more research for consistent use.

Fibroblasts are important in healing diabetic wounds, but high sugar levels can harm their function and slow down the healing process.

3D bioprinting in plastic surgery could lead to personalized grafts and fewer complications.

The research confirms that Hidradenitis Suppurativa is characterized by increased inflammation, disrupted skin cell organization, and abnormal metabolic processes.

Antiviral drugs, especially daclatasvir, may be a new treatment for a rare skin disease, improving survival and reducing symptoms in mice.

Immune cells are essential for skin regeneration using biomaterial scaffolds.

Biopolymers are increasingly used in cosmetics for their non-toxicity and skin benefits, with future biotech advancements likely to expand their applications.

Different types of sun exposure damage skin cells and immune cells, with chronic exposure leading to more severe and lasting damage.

Immune activities and specific genes are important in male pattern baldness.

Biomimetic scaffolds are better than traditional methods for growing cells and could help regenerate various tissues.

Aging skin is affected by inflammation, reduced stem cell function, and slower wound healing.

Improving dermal papilla cells can help regenerate hair follicles.

The right cells and signals can potentially lead to scarless wound healing, with a mix of natural and external wound healing controllers possibly being the best way to achieve this.

Nanofiber scaffolds help wounds heal by delivering drugs directly to the injury site.

Special gels help heal diabetic foot sores and reduce the risk of amputation or death.

Different fibroblasts play key roles in skin healing and scarring.

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

The research identified proteins that change as goat hair follicles begin to form, helping to understand how cashmere grows.

Reductive stress messes up collagen balance and alters cell signaling in human skin cells, which could help treat certain skin diseases.

The study found specific proteins that could mark different growth stages of cashmere goat hair and may help improve cashmere production.

Genes affecting wool fiber thickness in Angora rabbits were identified, which could help breed finer wool.

TRPV4 helps cells repair tissue and reduce scarring by controlling calcium levels.

Understanding gene expression in hair follicles can reveal insights into hair growth and disorders.

Human hair grows better in a special gel that mimics skin.

The enzymes Tet1, Tet2, and Tet3 are important for the development of hair follicles and determining hair shape by controlling hair keratin genes.

Epithelial-mesenchymal interactions control hair growth cycles through specific molecular signals.

Biomaterials with MSC-derived substances could improve tissue repair and have advantages over direct cell therapy.

Tiny particles called extracellular vesicles could help with skin healing and hair growth, but more research is needed.