Anna Gonzalez-Tendero1, Chong Zhang2,3, Vedrana Balicevic4, Rubén Cárdenes1,2, Sven Loncaric4, Constantine Butakoff2, Bruno Paun2, Anne Bonnin5,6, Patricia Garcia-Cañadilla2, Emma Muñoz-Moreno1, Eduard Gratacós1, Fatima Crispi1, Bart Bijnens2,7. 1. Fetal i+D Fetal Medicine Research Center, BCNatal-Barcelona Center for Maternal-Fetal and Neonatal Medicine (Hospital Clínic and Hospital Sant Joan de Deu), IDIBAPS, University of Barcelona, and Centre for Biomedical Research on Rare Diseases (CIBER-ER), Barcelona, Spain. 2. PhySense, DTIC, Universitat Pompeu Fabra, Barcelona, Spain. 3. CellNetworks, Heidelberg, Germany. 4. Faculty of Electrical Engineering and Computing, University of Zagreb, Zagreb, Croatia. 5. European Synchrotron Radiation Facility, Grenoble, France. 6. Paul Scherrer Institut, Villigen, Switzerland. 7. ICREA, Barcelona, Spain.
Abstract
BACKGROUND: While individual cardiac myocytes only have a limited ability to shorten, the heart efficiently pumps a large volume-fraction thanks to a cell organization in a complex 3D fibre structure. Subclinical subtle cardiac structural remodelling is often present before symptoms arise. Understanding and early detection of these subtle changes is crucial for diagnosis and prevention. Additionally, personalized computational modelling requires knowledge on the multi-scale structure of the whole heart and vessels. METHODS AND RESULTS: We developed a rapid acquisition together with visualization and quantification methods of the integrated microstructure of whole in-vitro rodents hearts using synchrotron based X-ray phase-contrast tomography. These images are formed not only by X-ray absorption by the tissue but also by wave propagation phenomena, enhancing structural information, thus allowing to raise tissue contrast to an unprecedented level. We used a (ex-vivo) normal rat heart and fetal rabbit hearts suffering intrauterine growth restriction as a model of subclinical cardiac remodelling to illustrate the strengths and potential of the technique. For comparison, histology and diffusion tensor magnetic resonance imaging was performed. CONCLUSIONS: We have developed a novel, high resolution, image acquisition, and quantification approach to study a whole in-vitro heart at myofibre resolution, providing integrated 3D structural information at microscopic level without any need of tissue slicing and processing. This superior imaging approach opens up new possibilities for a systems approach towards analysing cardiac structure and function, providing rapid acquisition of quantitative microstructure of the heart in a near native state. Published on behalf of the European Society of Cardiology. All rights reserved.
BACKGROUND: While individual cardiac myocytes only have a limited ability to shorten, the heart efficiently pumps a large volume-fraction thanks to a cell organization in a complex 3D fibre structure. Subclinical subtle cardiac structural remodelling is often present before symptoms arise. Understanding and early detection of these subtle changes is crucial for diagnosis and prevention. Additionally, personalized computational modelling requires knowledge on the multi-scale structure of the whole heart and vessels. METHODS AND RESULTS: We developed a rapid acquisition together with visualization and quantification methods of the integrated microstructure of whole in-vitro rodents hearts using synchrotron based X-ray phase-contrast tomography. These images are formed not only by X-ray absorption by the tissue but also by wave propagation phenomena, enhancing structural information, thus allowing to raise tissue contrast to an unprecedented level. We used a (ex-vivo) normal rat heart and fetal rabbit hearts suffering intrauterine growth restriction as a model of subclinical cardiac remodelling to illustrate the strengths and potential of the technique. For comparison, histology and diffusion tensor magnetic resonance imaging was performed. CONCLUSIONS: We have developed a novel, high resolution, image acquisition, and quantification approach to study a whole in-vitro heart at myofibre resolution, providing integrated 3D structural information at microscopic level without any need of tissue slicing and processing. This superior imaging approach opens up new possibilities for a systems approach towards analysing cardiac structure and function, providing rapid acquisition of quantitative microstructure of the heart in a near native state. Published on behalf of the European Society of Cardiology. All rights reserved.
Authors: Alexander Isaak; Dmitrij Kravchenko; Narine Mesropyan; Christoph Endler; Leon M Bischoff; Thomas Vollbrecht; Daniel Thomas; Darius Dabir; Sebastian Zimmer; Ulrike Attenberger; Daniel Kuetting; Julian A Luetkens Journal: Radiol Cardiothorac Imaging Date: 2022-06-09
Authors: Juan A Núñez; Alice Goring; Eric Hesse; Philipp J Thurner; Philipp Schneider; Claire E Clarkin Journal: Sci Rep Date: 2017-10-16 Impact factor: 4.379
Authors: Patricia Garcia-Canadilla; Tom de Vries; Anna Gonzalez-Tendero; Anne Bonnin; Eduard Gratacos; Fatima Crispi; Bart Bijnens; Chong Zhang Journal: PLoS One Date: 2019-06-21 Impact factor: 3.240