3D mapping of lipid orientation in biological tissues such as skin

January 15th, 2013 in Physics / General Physics
Mapping of lipid assemblies in a human skin biopsy. P-THG microscopy allows molecular order to be probed in situ at the micrometric scale. (Left) Diagram showing the structure of the outer layer of the skin, the stratum corneum (SC). Multilamellar lipid structures surround dead cells known as corneocytes. These organized structures contribute to the skin barrier function. (Right) Mapping of the average orientation of lipids in a fold of the stratum corneum of a human skin biopsy, obtained by P-THG microscopy. The image shows a 3 µm thick optical section recorded 30 µm under the surface of the skin. © École Polytechnique, CNRS, Inserm / American Physical Society


Mapping of lipid assemblies in a human skin biopsy. P-THG microscopy allows molecular order to be probed in situ at the micrometric scale. (Left) Diagram showing the structure of the outer layer of the skin, the stratum corneum (SC). Multilamellar lipid structures surround dead cells known as corneocytes. These organized structures contribute to the skin barrier function. (Right) Mapping of the average orientation of lipids in a fold of the stratum corneum of a human skin biopsy, obtained by P-THG microscopy. The image shows a 3 µm thick optical section recorded 30 µm under the surface of the skin. © École Polytechnique, CNRS, Inserm / American Physical Society

A non-invasive method that makes it possible to observe in situ how assemblies of lipids are oriented in biological tissues, and which does not require any labeling or preparation, has been developed by physicists from the Laboratoire d'Optique et Biosciences (CNRS / Inserm / École Polytechnique). This work, published on the 14 January 2013 in the online journal Physical Review X, should enable the detection and characterization of certain pathologies associated with molecular disorders in the skin or in the nervous tissue.

Multilamellar assemblies of lipids (fats) play a key role in certain physiological functions, not just within the skin (which serves as a protective barrier against external aggressions) but also in the way neurons function. The disorganization of these assemblies is often linked to serious pathologies. However, the techniques normally used to determine the arrangement of molecules, such as X-ray scattering or , are not suitable for studying intact biological tissues with good cellular resolution. In addition, they often require labeling and/or significant sample preparation.

First developed in the 1990s, multiphoton microscopy allows intact to be observed in three dimensions with sub-cellular resolution at depths exceeding several hundred micrometers. Researchers from the Laboratoire d'Optique et Biosciences have identified a new indicator, known as P-THG (polarized third-), which is sensitive to molecular order in multi-layer lipid assemblies. Thanks to this optical contrast source, it is now possible to map the general orientation and degree of alignment of lipid assemblies in three dimensions and also to observe their possible disorganization. This novel multiphoton thus provides a non-invasive tool for probing molecular alignment in situ in biological media.

Mapping of molecular orientation in an artificial lipid assembly using polarized third-harmonic generation (P-THG) microscopy (left). Diagram showing the molecular structure of a multilamellar lipid assembly (right). P-THG mapping of molecular orientation in an amalgamation of multilamellar lipid vesicles. This virtual optical section, obtained without labeling, shows that the molecules are oriented perpendicularly at the interfaces. © École Polytechnique, CNRS, Inserm / American Physical Society.

This approach enables scientists to map, with unparalleled sensitivity and contrast, the organization of lipids in human skin biopsies without prior preparation or labeling. This work lays the foundations for future developments in multiphoton microscopy as a method for measuring molecular order in intact biological media and opens the way to potential novel applications for detecting and studying the early stages of pathologies linked to molecular disorders.

More information: Probing ordered lipid assemblies with polarized third-harmonic generation microscopy. Maxwell Zimmerley, Pierre Mahou, Delphine Débarre, Marie-Claire Schanne-Klein and Emmanuel Beaurepaire. Physical Review X, 14 January 2013. dx.doi.org/10.1103/PhysRevX.3.011002

Provided by CNRS

"3D mapping of lipid orientation in biological tissues such as skin." January 15th, 2013. http://phys.org/news/2013-01-3d-lipid-biological-tissues-skin.html