Abstract
The purpose of this manuscript is to introduce the absence of H2O2 decomposition in the human hair follicle medulla. This absence is attributed to an absence of the antioxidants that are essential for the elimination of reactive oxygen species generated during cellular respiration. The present assumption is that the human hair follicle follicular melanogenesis (FM) involves sequentially the melanogenic activity of follicular melanocytes, the transfer of melanin granules into cortical and medulla keratinocytes, and the formation of pigmented hair shafts. The introduction of an airborne gradual hydrogen peroxide (H2O2) molecules transfer into water, has allowed for the slow down of H2O2 decomposition speed when contacting human tissue. The usual explosive reaction commonly seen has been avoided; and previously unseen details of the H2O2 breakdown anatomical locations within the human hair follicle reaction can now be detected. Dynamic video-recordings show for the first time H2O2 decomposition occurring in the cortical and cortex areas. Published evidence links cellular H2O2 breakdown and metabolism. A new paradigm is herein introduced where the human hair medulla is excluded from H2O2 breakdown, thus inferring the absence of metabolic activity from FM.
Highlights
The purpose of this communication is to demonstrate for the first time dynamic evidence challenging the anatomical sites identified as to where melanogenesis takes place in the human follicle [1]
Exogenous (H2O2) molecules decompose when penetrating an injured hair follicle; this breakdown is caused in sites of active metabolism
This manuscript reintroduces a desktop optical microscopy technique [2] developed for the slowing of H2O2 decomposition speed. This allowed for the demonstration that H2O2 breakdown occurs in the cortical/cortex areas of the hair follicle
Summary
The purpose of this communication is to demonstrate for the first time dynamic evidence (via video-recordings) challenging the anatomical sites identified as to where melanogenesis takes place in the human follicle [1]. Exogenous (H2O2) molecules decompose when penetrating an injured hair follicle; this breakdown is caused in sites of active metabolism. This manuscript reintroduces a desktop optical microscopy technique [2] developed for the slowing of H2O2 decomposition speed. This allowed for the demonstration (video-recordings) that H2O2 breakdown occurs in the cortical/cortex areas of the hair follicle. Attempts to duplicate the experiment failed in gray or dark hairs
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