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Lab-grown hair using iPSCs is being explored, but practical applications are limited. Finasteride is suggested as the only current effective treatment.

HairClone aims to rejuvenate miniaturizing hair follicles through follicle banking and cell expansion, with treatments potentially available in the UK by 2022. The process involves extracting, storing, and cloning hair follicles, but full regenerative treatments will take many years to develop.

A new "third cell" discovery in Japan could be key to fully regenerating hair follicles, with human trials possibly starting in 2027-2028. AI is expected to accelerate medical discoveries, potentially leading to a hair loss cure within a few years.

A user developed AI software to simulate hair transplants on photos, helping people visualize potential results. The tool offers photo-realistic renderings but advises caution regarding exact outcomes due to various factors.

A user is exploring VEGF gene therapy to enhance hair transplant results, considering measuring hair shaft diameter and growth rate. Suggestions include using phototrichograms and possibly adding PRP, though its effectiveness is uncertain.

A user created a free AI-powered hair transplant simulator to help visualize post-transplant results, seeking feedback and offering it as a tool for clinics. Users discussed its usefulness, limitations, and the requirement for email and phone verification to prevent abuse.

HairClone is offering a Dermal Papilla Cell Hair Multiplication procedure in Guatemala, raising questions about its effectiveness and regulatory reasons for the location. Users express skepticism and curiosity about the treatment's success and potential costs.

The conversation discusses promising hair cloning research seeking commercialization partners. Cultured hairs formed with pigment, indicating positive progress.

L'Oreal is working on hair cloning, with multiple companies using similar techniques, making hair cloning likely by 2030. The conversation expresses optimism about the progress and potential affordability of hair cloning solutions.

Han Bio plans to start clinical trials for a new hair multiplication technology this year, which could significantly reduce the cost and time of hair transplantation. The technology uses a single hair strand to cultivate enough cells for 30,000 hair strands.

Hair/scalp cloning for unlimited transplants is likely a decade away, with prior transplants not significantly affecting future options. Advances in AI and research in wound-induced hair neogenesis are promising, but infrastructure and technology constraints remain challenges.

Stem cell-related treatments and drugs like RCGD423 and WAY are being tested for hair growth. Clinics are conducting tests on patients who haven't had previous treatments.

Scientists found hidden stem cells that might reactivate hair growth. The discussion includes treatments like Minoxidil, finasteride, and RU58841.

Hair cell therapy and follicle cloning are still in experimental stages, with treatments like hair multiplication and regenerative hair therapy being marketed but not yet proven to create unlimited new follicles. There is skepticism about the effectiveness and legitimacy of these treatments, with some considering them scams.

Hair cloning and injection of dermal papilla cells are discussed, with skepticism about their availability by 2023. Users mention Minoxidil, finasteride, and hair transplants as current treatments.

A new hair growth product claims to use apple stem cells, plant collagen, and bamboo leaf extract, with a 120-day money-back guarantee. Some users are skeptical, noting the product's marketing alongside other treatments like Minoxidil, finasteride, and red light therapy.

Longitudinal partial follicular unit transplantation involves extracting part of the donor follicular unit, allowing the donor area to be overharvested without noticeable hair loss. The conversation questions if this method is practiced in clinics or if it's theoretical, and whether it relates to hair cloning or multiplication.

Dr. Kang-Yell Choi's company, CK Regeon, is developing a drug called KY19382 for hair regeneration, which involves creating fine wounds to activate stem cells. The drug is in the formulation development stage, targeting markets like the US and Korea.

PP405 shows promise for hair regrowth by manipulating stem cell characteristics and lactate dehydrogenase, with Phase 2a trials pending. Google Ventures' $15M investment suggests confidence, but results and market availability remain uncertain.

Japanese scientists discovered ABM cells, enabling successful human hair follicle cloning, potentially curing hair loss. The treatment may be available in Japan by 2028, but it will be expensive and require travel.

Adipose-derived stem cells with ATP improved hair regrowth in male and female mice with androgenetic alopecia. The most effective treatments were low dose stem cells with ATP for males and medium dose stem cells with non-liposomal ATP for females.

Transplanting mice skin to humans is not feasible due to immune rejection, but some suggest genetic modification or immune suppression could make it possible. Xenograft hair transplants are discouraged.

A Silicon Valley-backed company aims to cure hair loss. Exciting advancements include mRNA therapies, gene editing, hair cloning, AR degraders, anti-androgens, cell-based rejuvenation, and AI-based drug discovery, with hopes for FDA approval of GT20029 within 10 years.

A gel of keratin microspheres promotes hair follicle growth, showing similar effectiveness to minoxidil in mice. The treatment activates hair growth pathways and reduces inflammation, with potential applications in drug delivery for hair-related disorders.

The conversation discusses the delay in bringing FAK inhibitors and Stanford's hydrogel to market for hair transplants, with a preference for FAK inhibitors over Verteporfin due to their superior potential in preventing scarring. The user expresses frustration over the slow progress and hopes for faster development by companies like FAKnostics.

Hair cloning is being developed by companies like Kangstem Biotech and Stemson, with potential availability in a few years. Initial costs are expected to be high, but prices may decrease over time.

A user plans to experiment with creating new hair follicles using methods like derma rolling, applying lithium chloride, tannic acid, and various other substances including caffeine, ketoconazole, and raspberry ketones. They also consider using anti-inflammatories, immunosuppressants, and DHT inhibitors to potentially improve results.

User xEternex tries hair regrowth with daily broccoli sprouts, apple extract containing procyanidin b2, and microneedling. Others discuss potential issues with the experiment and share their experiences with vegetable consumption and hair growth.

SCUBE3 and GT20029 are potential treatments for hair loss, with SCUBE3 stimulating hair growth and GT20029 protecting against DHT. A combined approach using SCUBE3, finasteride or dutasteride, and later GT20029 could provide a comprehensive treatment for androgenetic alopecia.

Hair follicle regenerative therapy is being developed, with clinical trials planned in Japan, potentially allowing for hair cloning and eliminating the need for treatments like finasteride. If successful, the treatment could be available in Japan by 2025, but widespread access and affordability may take longer.