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PRP treatment improves hair growth, and the device used can affect results, with some being more effective.

Low fluence photoepilation temporarily removes hair by targeting the hair follicle's pigmented area without severe damage.

The document concludes that specific cells are essential for hair growth and more research is needed to understand how to maintain their hair-inducing properties.

Human hair follicle organ culture is a useful model for hair research with potential for studying hair biology and testing treatments.

The telogen phase of hair growth is active and important for preparing hair follicles for regeneration, not just a resting stage.

Hair grows faster in the morning and is more vulnerable to damage from radiation due to the internal clock in hair follicle cells.

Androgens have complex effects on hair growth, promoting it in some areas but causing hair loss in others, and our understanding of this is still evolving.

The document concludes that assessing hair follicle damage due to cyclophosphamide in mice involves analyzing structural changes and suggests a scoring system for standardized evaluation.

Restoring hair bulb immune privilege is crucial for managing alopecia areata.

Nerves and chemicals in the body can affect hair growth and loss.

Male hormones and their receptors play a key role in hair loss and skin health, with potential new treatments being explored.

Hair follicles are hormone-sensitive and involved in growth and other functions, with potential for new treatments, but more research is needed.

Notch/CSL signaling controls hair follicle differentiation through Wnt5a and FoxN1.

Activating the Wnt/β-catenin pathway could lead to new hair loss treatments.

Mutant mice help researchers understand hair growth and related genetic factors.

Correcting nutrient deficiencies may help with hair loss, but the benefits of supplements without a deficiency are uncertain and could be harmful.

Procyanidin compounds from grape seeds were found to significantly increase mouse hair growth.

Wnt10b overexpression can regenerate hair follicles, possibly helping treat hair loss and alopecia.

Certain mice without specific receptors or mast cells don't lose hair from stress.

Aging mice have slower hair regeneration due to changes in signal balance, but the environment, not stem cell loss, controls this, suggesting treatments could focus on environmental factors.

Hair grays due to oxidative stress and fewer functioning melanocytes.

The conclusion is that hair growth can be improved by activating hair cycles, changing the surrounding environment, healing wounds to create new hair follicles, and using stem cell technology.

Human hair follicle stem cells can turn into multiple cell types but lose some of this ability after being grown in the lab for a long time.

Some women with common hair loss may develop permanent hair loss.

The conclusion is that recognizing hair growth cycles can improve the precision of dietary and health assessments from hair analysis.

Human hair follicles can regenerate after removal, but with low success rate.

Human hair follicles produce and respond to erythropoietin, helping protect against stress.

Cyclosporine A may help treat hair loss by blocking a protein that inhibits hair growth.

Dermal papilla cells help wounds heal better and can potentially grow new hair.

The hair follicle is a great model for research to improve hair growth treatments.