Low-Level Light Therapy Downregulates Scalp Inflammatory Biomarkers in Men With Androgenetic Alopecia and Boosts Minoxidil 2% to Bring a Sustainable Hair Regrowth Activity.

BACKGROUND AND OBJECTIVES: Low-level light therapies using visible to infrared light are known to activate several cellular functions, such as adenosine triphosphate and nitric oxide synthesis. However, few clinical observations report its biological consequences for skin and scalp homeostasis. Since scalp inflammation was recognized as a potential physiological obstacle to the efficacy of the reference hair regrowth drug Minoxidil in vivo and since perifollicular inflammation is the hallmark of about 50%-70% follicular units in androgenetic alopecia, we decided to investigate whether the anti-inflammatory activity of LLLT/GentleWaves® device were assigned to L'Oréal by Light BioScience L.L.C., Virginia Beach, VA (US) could enhance hair regrowth activity of Minoxidil. STUDY DESIGN/MATERIALS AND METHODS: We conducted a first experimental clinical study on 64 men with androgenetic alopecia using LLLT/GentleWaves®, 590-nm predominant wavelength 70 seconds, specifically pulsed once per day, for 3 days, and we performed a whole-genome analysis of treated scalp biopsies. In a second clinical study, including 135 alopecic volunteers, we evaluated the hair regrowth activity in response to the upgraded LLLT/GentleWaves® device and Minoxidil. RESULTS: In the first clinical study, whole-genome analysis of treated scalp biopsies showed downregulation of scalp inflammatory biomarkers, such as AP1/FOSB messenger RNA (mRNA) and mir21, together with the disappearance of CD69 mRNA, specific to scalp-infiltrating T cells of about 50% of the studied volunteers prior to the LLLT/GentleWaves® treatment. In the second clinical study, we observed that LLLT/GentleWaves® was able to boost the hair regrowth activity of a Minoxidil 2% lotion to the extent of the highest concentration (5%) in terms of efficacy, number of responders, and perceived performance. CONCLUSIONS: Altogether, these observations suggest the potential benefit of LLLT/GentleWaves® as a noninvasive adjunctive technology for skin and scalp conditions, where a mild perifollicular inflammation is involved. Lasers Surg. Med. 2021. Copyright © 2021 Wiley Periodicals LLC.

Investigation of Different Iontophoretic Currents Profiles for Short-Term Applications in Cosmetics.

This study aimed at investigating the effect of electrical current profile upon the iontophoretic transport of (i) ascorbic acid (AA) and (ii) ellagic acid (EA), into porcine skin in vitro, and the impact of the physicochemical properties of both actives on their mechanism of transport when formulated in cosmetic compositions. The experiments were performed using a proprietary iontophoretic device containing a roller to apply the formulation. Three current profiles were tested: (i) galvanic direct current (DC), (ii) square unipolar pulse current (SPC), and (iii) galvanic direct current (DC) + pulse current (PC). The skin samples were collected at different sampling points, extracted and analyzed by HPLC. Results suggested that the DC + PC mode for only 5 min was able to significantly increase the delivery of AA from o/w cosmetic compositions. The use of this current profile might improve the skin penetration of AA due to electromigration and passive diffusion, the latter being facilitated by the physical enhancement method. The SPC mode significantly improved the passage of EA in its neutral form from cosmetic o/w formulations by electroosmosis. Tailoring specific electrical current modes considering the ionization state of active ingredients would allow the design of short and personalized cosmetic treatments that significantly improve the penetration efficiency of the active ingredients and possibly reduce the doses applied.

Human hair keratin network and curvature.

BACKGROUND: In human hair, very little is known about the substructures relating to the curl pattern. The interpretation of the macroscopic shape of the fiber at the molecular and cellular scales is still unclear. METHODS: A comparative and multiscale study was carried out on a set of human hair samples, ranging in shape from straight to tightly curled, in order to investigate structural elements that might be related to hair curl pattern. RESULTS: At the macroscopic level, the frequency and amplitude of cross-sectional rotations were found to be crucial for an accurate description of curliness. At the cellular level, transmission electron microscopy experiments made it possible to confirm that macrofibril organization was strongly related to hair curliness. The curly hair follicles exhibited retrocurvature, independent of ethnic origin. A direct comparison of straight hair and curly hair highlighted an intrinsic asymmetry in the proliferative compartment that clearly extended above the Auber line on the convex side of the curvature. This phenomenon caused delayed differentiation of both inner and outer root sheaths. The hair cortex itself was elliptical and asymmetric, as evidenced by hHa8 keratin. In curly hair, this hair keratin accumulated on the concave side of the curvature, whereas, in straight hair, positive cortical cells were evenly distributed throughout the circular fiber. CONCLUSION: The curly shape of the hair shaft seems to result from the asymmetric differentiation of the precortex. Hair fiber can thus be considered as a shape memory material.