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Calcium signals and SHH guide the direction of feather growth in chicken skin.

Wound healing insights can improve regenerative medicine.

2011 dermatological research found new skin aging markers, hair loss causes, skin defense mechanisms, and potential for new treatments.

Human hair is complex and grows in cycles starting from embryonic life.

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

Testosterone may worsen hair loss by affecting hair growth signals, while different prostaglandins can either hinder or promote hair growth.

The stiffness of a wound affects hair growth during healing, with less stiff areas growing more hair.

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

New nanofiber technology improves wound healing by supporting cell growth and delivering treatments directly to the wound.

The Multi-Organ-Chip improves the growth and quality of skin and hair in the lab, potentially replacing animal testing.

Researchers created hair-inducing human cell clusters using a 3D culture method.

Apoptosis contributes to hair loss in androgenetic alopecia.

The microenvironment, especially mechanical forces, plays a crucial role in hair growth and could lead to new treatments for hair loss.

Certain skin cells near the base of hair muscles may help renew and stabilize skin, possibly affecting skin disorder understanding.

Men are increasingly using energy-based skin treatments for workplace success, with lasers and other devices effectively improving skin and body appearance.

MicroRNA-205 helps hair grow by changing the stiffness and contraction of hair follicle cells.

Hyaluronic acid injections improve skin thickness and quality, protecting against aging in rats.

Low energy laser therapy effectively treats certain skin conditions and improves recovery time without side effects.

New therapies are being developed that target integrin pathways to treat various diseases.

The conclusion is that accurately replicating the complexity of the extracellular matrix in the lab is crucial for creating realistic human tissue models.

Fibroblasts are crucial for tissue repair and inflammation, and understanding them can help treat fibrotic diseases.

Large-scale fibronectin nanofibers help heal wounds and repair tissue in a skin model of a mouse.

Microneedles are effective for painless drug delivery and promoting wound healing and tissue regeneration.

Fibroblast-derived growth factors and exosomes can significantly improve skin aging.

New research shows that skin diversity is influenced by different types of dermal fibroblasts and their development, especially involving the Wnt/β-catenin pathway.

The scaffolds significantly sped up wound healing in dogs and were safe.

Stem cells from hair follicles in a special gel show strong potential for bone regeneration.

Human pluripotent stem cells could be used to make platelets for medical use, but safety, effectiveness, and cost issues need to be resolved.

Targeting drugs to hair follicles can treat skin conditions, but reaching deep follicle areas is hard and needs more research.

Women with scarring alopecia are less likely to have used hormone replacement therapy or oral contraceptives compared to those with female pattern hair loss.