Scientists Create 3-D Models of Whole Mouse Organs -- COMPAMED Trade Fair
Foto: Mouse Organs
Mouse lung: Collagen fibers (green)
outline the bronchiole pathways against
a background of elastin tissue (red);
© Michael Levene/Yale University

Combining an imaging technique called multiphoton microscopy with "optical clearing," which uses a solution that renders tissue transparent, the researchers were able to scan mouse organs and create high-resolution images e. g. of the brain, lung and testicles. They then created 3D models of the organs—a feat that, until now, was only possible by slicing the organs into thin sections.

With traditional microscopy, researchers are only able to image tissues up to depths on the order of 300 microns, or about three times the thickness of a human hair. In that process, tissue samples are cut into thin slices, stained with dyes to highlight different structures and cell types, individually imaged, and then stacked back together to create 3D models. The Yale team, by contrast, was able to avoid slicing or staining the organs by relying on natural fluorescence generated from the tissue itself.

Multiphoton can image a larger field-of-view at much greater depths and is limited only by the size of the lens used. Once the tissue is cleared using a standard solution that makes it virtually transparent to optical light, the researchers shine different wavelengths of light on it to excite the inherently fluorescent tissue. The fluorescence is displayed as different colours that highlight the different structures and tissue types.

"The intrinsic fluorescence is just as effective as conventional staining techniques," said the team leader Michael Levene. "It's like creating a virtual 3D biopsy that can be manipulated at will. And you have the added benefit that the tissue remains intact even after it's been imaged."

The Yale team was able to reach depths in excess of two millimetres. Meaning the new technique could be used to create 3D models of biopsies. This could be especially useful in tissues where the direction of a cancerous growth may make it difficult to know how to slice tissue sample.

"Fluorescence microscopy plays such a key role throughout biology and medicine," Leven said. "The range of applications of this technique is immense, including everything from improved evaluation of patient tissue biopsies to fundamental studies of how the brain is wired."; Source: Yale University