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Alpha-melanocyte-stimulating hormone helps manage skin inflammation and protect against UV damage.

The study concluded that the developed models are effective for studying hair growth mechanisms and testing new treatments.

The skin communicates with the nervous system, and targeting neurohormones like melatonin and oxytocin could help treat skin issues.

Stem cells improve nerve repair by enhancing blood vessel growth.

Neurotrophins, especially NGF, are crucial for pain development and management.

A parasite-derived molecule speeds up skin healing and affects immune cell behavior without increasing scarring.

Merkel cells stabilize nerve endings in the skin, and they change independently of each other.

IL-1 promotes fat cell growth in skin, while WNT inhibits it and encourages scar formation.

Single-cell sequencing shows that different types of macrophages have unique roles in wound healing.

Sphingosine 1-phosphate and its receptor S1PR3 are key in controlling mechanical pain.

Certain immune cells worsen post-surgery gut paralysis by activating a specific immune response.

Neurotrophins are important for hair growth and response to stress.

Sensory neuron and Merkel cell changes in the skin happen independently during normal skin maintenance.

Nerve fibers may worsen mast cell activity, leading to abnormal elastic fiber buildup from sun exposure.

Stress increases nerve growth factor, causing hair loss in mice.

A soluble factor in developing mouse whisker pads boosts nerve growth factor mRNA production.

A new microneedle patch helps repair spinal cord injuries by reducing scarring and promoting nerve growth.

The model helps understand scar contraction and develop new treatments.

IFNγ-primed MSC secretomes can improve joint health by reducing inflammation and supporting tissue repair.

Human body's immune cells are more common in the layer of fat just beneath the skin than in deeper fat layers.

Enhancing glycolysis in mesenchymal stromal/stem cells boosts their immune functions and therapy potential.

Immune-epithelial interactions are crucial for tissue repair, but unchecked can cause diseases.

Biomimetic nanovesicles can speed up diabetic wound healing by regulating immune cell behavior and metabolism.

Sensory neuron and Merkel-cell changes in the skin happen independently during normal skin maintenance.

The secretome helps protect and regenerate retinal cells by enabling communication between stem cells and retinal cells.

Nanomedicine-based immunotherapy shows promise in improving tissue repair and regeneration.

The skin's immune system helps it regenerate and fight infections.

3D cultures can create active macrophages from fat tissue.

Engineered nanovesicles from hair follicle stem cells enable scarless healing of infected wounds.

Mitochondrial Complex I reduces inflammation and increases bone breakdown by affecting certain immune cells.