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"Faces" of the day:

Katharina Jandl

Nina Höller

Nariae Baik-Schneditz

Ellen Heitzer

Marianne Brodmann

Ewald Kolesnik

Bernhard Schwaberger

Maximilian Seles

Gabor Toth-Gayor

Lukas Peter Mileder

Niels Hammer

Christian Josef Hill

Christian Viertler

Philipp Klaritsch

Daniel Scherr

Harald Köfeler

Gerhard Pichler

Roland Malli

Michael Fuchsjäger

Gernot Plank

Peter Fickert

Richard Zigeuner

Peter Holzer

Selected Publication:

SHR Neuro Cancer Cardio Lipid Metab Microb

Pukaluk, A; Wittgenstein, AS; Leitinger, G; Kolb, D; Pernitsch, D; Schneider, SA; Knöbelreiter, P; Horak, V; Bredies, K; Holzapfel, GA; Pock, T; Sommer, G.
An ultrastructural 3D reconstruction method for observing the arrangement of collagen fibrils and proteoglycans in the human aortic wall under mechanical load.
Acta Biomater. 2022; 141:300-314 Doi: 10.1016/j.actbio.2022.01.036
Web of Science PubMed FullText FullText_MUG

 

Co-authors Med Uni Graz

Kolb Dagmar

Leitinger Gerd

Pernitsch Dominique

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Abstract:

An insight into changes of soft biological tissue ultrastructures under loading conditions is essential to understand their response to mechanical stimuli. Therefore, this study offers an approach to investigate the arrangement of collagen fibrils and proteoglycans (PGs), which are located within the mechanically loaded aortic wall. The human aortic samples were either fixed directly with glutaraldehyde in the load-free state or subjected to a planar biaxial extension test prior to fixation. The aortic ultrastructure was recorded using electron tomography. Collagen fibrils and PGs were segmented using convolutional neural networks, particularly the ESPNet model. The 3D ultrastructural reconstructions revealed a complex organization of collagen fibrils and PGs. In particular, we observed that not all PGs are attached to the collagen fibrils, but some fill the spaces between the fibrils with a clear distance to the collagen. The complex organization cannot be fully captured or can be severely misinterpreted in 2D. The approach developed opens up practical possibilities, including the quantification of the spatial relationship between collagen fibrils and PGs as a function of the mechanical load. Such quantification can also be used to compare tissues under different conditions, e.g., healthy and diseased, to improve or develop new material models. STATEMENT OF SIGNIFICANCE: The developed approach enables the 3D reconstruction of collagen fibrils and proteoglycans as they are embedded in the loaded human aortic wall. This methodological pipeline comprises the knowledge of arterial mechanics, imaging with transmission electron microscopy and electron tomography, segmentation of 3D image data sets with convolutional neural networks and finally offers a unique insight into the ultrastructural changes in the aortic tissue caused by mechanical stimuli.

Find related publications in this database (Keywords)

Human aorta

Collagen fibrils and proteoglycans

Biaxial extension test

Electron tomography

Segmentation

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