Every dermatology clinic specializing in trichology receives patients daily -both men and women- seeking solutions for androgenetic alopecia. Patients are increasingly younger: nearly 30% of men begin to notice it around the age of 30, and its prevalence rises by 10% per decade. Among women, around 40% experience some degree of hair loss by the age of 50. Many see baldness as a mere aesthetic issue, but behind it often lie deeper problems, such as low self-esteem, insecurity… and also an increased risk of skin cancer caused by the early loss of the hair’s natural protection against sunlight.
There are, in fact, solutions for androgenetic alopecia, such as pharmacological treatments (minoxidil and finasteride) or hair transplants. However, not all patients feel comfortable with the long-term use of drugs, nor are they all candidates for invasive surgical procedures. In any case, over the past decades we have witnessed how available therapies could slow down hair loss (provided the patient was a suitable candidate), but could not restore damaged follicles. That led us to ask ourselves: what if we could regenerate the follicles?
This story began with my research using an energizing molecule to improve the survival of follicular units in transplants -a key factor in achieving the best possible outcome. This work, which I successfully applied in my practice at Clínica Imema in Madrid, earned an R&D&I certification and the Innovative SME seal for the protocol “New Approach for the Treatment of Androgenetic Alopecia.” At the same time, in the corridors of Hospital Clínico San Carlos in Madrid, colleagues from the Cellular Therapy Research Unit introduced us to the potential of stem cells in other diseases.
But what about in androgenetic alopecia? Could stem cells, combined with a molecule that provides them with energy to enhance their survival “awake” the “dormant” follicles and achieve lasting hair growth? A hypothesis had been born -and with it, a goal: to reverse alopecia.
Launching a study of this kind was not easy. Androgenetic alopecia does not occur spontaneously in mice, so we had to develop a model to induce it in a controlled way. This involved determining the appropriate age of the animals, ensuring that the mice adapted properly to the laboratory environment, and defining the method for administering the inducing agents. In addition, the skin of mice is much thinner than that of humans, and their hair density is much higher, which made both the administration of the products and the evaluation of hair growth more challenging, as it tended to “saturate” the digital analysis methods. In any case, we were able to demonstrate that androgenetic alopecia can be induced in mice by administering dihydrotestosterone -the same hormone responsible for this condition in humans.
Additionally, stem cells have a limited lifespan outside the body, and from our experience with transplants we knew that hair follicles need time to establish a vascular network in the recipient tissue if they are to survive. To maximize their chances, we administered an energizing molecule, adenosine triphosphate (ATP) which prolongs cell survival, giving stem cells time to release growth factors and differentiate. In this way, if the stem cells could survive long enough in the scalp, they could regenerate damaged follicles and reverse baldness.
The study design included 12 experimental groups: a control group (sham), a reference group (wild type), a placebo group, and nine experimental groups. Among the latter, one group received only stem cells; two groups were treated exclusively with adenosine triphosphate (liposomal and non-liposomal); and six groups combined stem cells (at high, medium, and low doses) with adenosine triphosphate, either liposomal or non-liposomal.
Each group was evaluated using photographic observation models, digital hair growth analysis and histological verification to confirm that visible changes corresponded to follicular regeneration at the microscopic level. We also developed specific statistical models to interpret the results, as variability among animals and hair density required a rigorous quantitative approach.
The results: among male mice treated with a low dose of stem cells and adenosine triphosphate, up to 50% achieved complete hair regrowth and the other 50% showed intense regrowth, thus reaching a 100% success rate in hair regeneration. In females treated with a medium dose, up to 50% achieved total regrowth and 40% intense regrowth, meaning that 90% of the female mice experienced significant hair growth.
Mice in day 10 (first picture) and day 21 (second picture).
These results were undoubtedly unexpected. Compared to current treatments, which depend on continuous use and offer much more modest outcomes, here we are seeing intense and -apparently- long-lasting growth. This opens up a horizon of hope that did not exist before. It has been nearly 40 years since the first effective drug for alopecia was marketed, and during all this time, pharmacological options have shown limited efficacy and dependence on ongoing use. Now, we are opening an entirely new path: an advanced therapy capable of regenerating follicles and delivering long-term results.