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Multi-omics techniques help understand the molecular causes of androgenetic alopecia.

The study concluded that the arachidonic acid pathway and the protein KRT79 play a role in determining the fineness of cashmere.

New hair loss treatments could be improved by using combined biological markers.

Adding soybean oil to Nonomuraea dietziae increases production of a beneficial compound by improving metabolism and enzyme systems.

The research found that certain factors in hair follicle cells control hair growth and development, and these could be used to create new treatments for hair loss.

Human hair shows promise for non-invasive medical testing, but more research is needed to standardize its use.

Personalized medicine in dermatology uses molecular biomarkers to improve diagnosis and treatment but needs further advancements for practical use.

Scientists are using clumps of special stem cells to improve organ repair.

Lef1 is essential for normal skin, hair growth, and healing wounds in mice.

Hair loss in Androgenetic Alopecia is caused by genetics, aging, and lifestyle, leading to hair follicle shrinkage and related health risks.

The research created a detailed map of skin cells, showing that certain cells in basal cell carcinoma may come from hair follicles and could help the cancer grow.

Omics techniques are needed to understand the scalp microbiome's role in alopecia areata for new treatments.

Curcumin may help reverse aging by targeting specific genes.

Different types of fibroblasts play various roles in kidney repair and aging, and may affect chronic kidney disease outcomes.

New technologies help us better understand how skin microbes affect skin diseases.

Tiny RNA molecules help control the growth of plant hairs.

Drug repurposing is a cost-effective way to find new uses for existing drugs, speeding up treatment development.

The research identified key proteins and genes that may influence wool bending in goats.

NF-κB signaling is crucial in many diseases and can be targeted for new treatments.

A new MBTPS2 gene variant disrupts fat metabolism and collagen production, causing Osteogenesis imperfecta.

Different types of fibroblasts play specific roles in wound healing and cancer, which could help improve treatments.

Two microRNAs affect hair follicle development in sheep by targeting specific genes.

Women with PCOS have more Bifidobacterium in their gut compared to those without PCOS.

Proteomics combined with other technologies can lead to a better understanding of skin diseases.

Organoids created from stem cells are used to model diseases, test drugs, and develop personalized and regenerative medicine.

Human skin xenografting could improve our understanding of skin development, renewal, and healing.

Machine learning is effective in predicting gene functions and their relationships with diseases.

Newborn skin cells can change into wound-healing cells more easily than adult ones, which might explain why baby skin heals without scars. Understanding this could help treat chronic wounds and prevent scarring.

The Wnt/β-catenin pathway is important for body functions and diseases, and targeting it may treat conditions like cancer, but with safety challenges.

Dermal fibroblasts have adjustable roles in wound healing, with specific cells promoting regeneration or scar formation.