| Literature DB >> 34608756 |
Julie Chauvel-Picard1, Vincent Bérot2, Linda Tognetti3, Carmen Orte Cano4, Margot Fontaine4, Clément Lenoir4, Javiera Pérez-Anker5,6, Susana Puig5,6, Arnaud Dubois7, Sandra Forestier8, Jilliana Monnier9,10, Randa Jdid8, Gabriel Cazorla8, Mélanie Pedrazzani11, Antoine Sanchez11,12, Sébastien Fischman11, Pietro Rubegni3, Véronique Del Marmol4, Joseph Malvehy5,6, Elisa Cinotti3,10, Jean L Perrot2,10, Mariano Suppa4,10,13.
Abstract
Epidermal three-dimensional (3D) topography/quantification has not been completely characterized yet. The recently developed line-field confocal optical coherence tomography (LC-OCT) provides real-time, high-resolution, in-vivo 3D imaging of the skin. This pilot study aimed at quantifying epidermal metrics (epidermal thicknesses, dermal-epidermal junction [DEJ] undulation and keratinocyte number/shape/size) using 3D LC-OCT. For each study participant (8 female, skin-type-II, younger/older volunteers), seven body sites were imaged with LC-OCT. Epidermal metrics were calculated by segmentations and measurements assisted by artificial intelligence (AI) when appropriate. Thicknesses of epidermis/SC, DEJ undulation and keratinocyte nuclei volume varied across body sites. Evidence of keratinocyte maturation was observed in vivo: keratinocyte nuclei being small/spherical near the DEJ and flatter/elliptical near the skin surface. Skin microanatomy can be quantified by combining LC-OCT and AI. This technology could be highly relevant to understand aging processes and conditions linked to epidermal disorders. Future clinical/research applications are to be expected in this scenario.Entities:
Keywords: LC-OCT; dermal-epidermal junction; healthy skin; keratinocytes quantification; layer thicknesses; non-invasive 3D imaging
Mesh:
Year: 2021 PMID: 34608756 DOI: 10.1002/jbio.202100236
Source DB: PubMed Journal: J Biophotonics ISSN: 1864-063X Impact factor: 3.207