Your search keyword '"Schittny, Johannes"' showing total 3 results

1. Pulmonary acini exhibit complex changes during postnatal rat lung development.

Author

Haberthür, David, Yao, Eveline, Barré, Sébastien F., Cremona, Tiziana P., Tschanz, Stefan A., and Schittny, Johannes C.

Subjects

LUNG development, LUNGS, LIGHT sources, RATS, ADULTS

Abstract

Pulmonary acini represent the functional gas-exchanging units of the lung. Due to technical limitations, individual acini cannot be identified on microscopic lung sections. To overcome these limitations, we imaged the right lower lobes of instillation-fixed rat lungs from postnatal days P4, P10, P21, and P60 at the TOMCAT beamline of the Swiss Light Source synchrotron facility at a voxel size of 1.48 μm. Individual acini were segmented from the three-dimensional data by closing the airways at the transition from conducting to gas exchanging airways. For a subset of acini (N = 268), we followed the acinar development by stereologically assessing their volume and their number of alveoli. We found that the mean volume of the acini increases 23 times during the observed time-frame. The coefficients of variation dropped from 1.26 to 0.49 and the difference between the mean volumes of the fraction of the 20% smallest to the 20% largest acini decreased from a factor of 27.26 (day 4) to a factor of 4.07 (day 60), i.e. shows a smaller dispersion at later time points. The acinar volumes show a large variation early in lung development and homogenize during maturation of the lung by reducing their size distribution by a factor of 7 until adulthood. The homogenization of the acinar sizes hints at an optimization of the gas-exchange region in the lungs of adult animals and that acini of different size are not evenly distributed in the lungs. This likely leads to more homogeneous ventilation at later stages in lung development. [ABSTRACT FROM AUTHOR]

Published

2021

2. A multi-scale model of gas transport in the lung to study heterogeneous lung ventilation during the multiple-breath washout test.

Author

Hasler, David, Anagnostopoulou, Pinelopi, Nyilas, Sylvia, Latzin, Philipp, Schittny, Johannes, and Obrist, Dominik

Subjects

MULTISCALE modeling, RESPIRATORY organs, GAS distribution, LUNGS, TISSUE mechanics, PULMONARY function tests

Abstract

The multiple-breath washout (MBW) is a lung function test that measures the degree of ventilation inhomogeneity (VI). The test is used to identify small airway impairment in patients with lung diseases like cystic fibrosis. However, the physical and physiological factors that influence the test outcomes and differentiate health from disease are not well understood. Computational models have been used to better understand the interaction between anatomical structure and physiological properties of the lung, but none of them has dealt in depth with the tracer gas washout test in a whole. Thus, our aim was to create a lung model that simulates the entire MBW and investigate the role of lung morphology and tissue mechanics on the tracer gas washout procedure. To this end, we developed a multi-scale lung model to simulate the inert gas transport in airways of all size. We then applied systematically different modifications to geometrical and mechanical properties of the lung model (compliance, residual airway volume and flow resistance) which have been associated with VI. The modifications were applied to distinct parts of the model, and their effects on the gas distribution within the lung and on the gas concentration profile were assessed. We found that variability in compliance and residual volume of the airways, as well as the spatial distribution of this variability in the lung had a direct influence on gas distribution among airways and on the MBW pattern (washout duration, characteristic concentration profile during each expiration), while the effects of variable flow resistance were negligible. Based on these findings, it is possible to classify different types of inhomogeneities in the lung and relate them to specific features of the MBW pattern, which builds the basis for a more detailed association of lung function and structure. [ABSTRACT FROM AUTHOR]

Published

2019

3. Automated computer-assisted quantitative analysis of intact murine lungs at the alveolar scale.

Author

Lovric, Goran, Vogiatzis Oikonomidis, Ioannis, Mokso, Rajmund, Stampanoni, Marco, Roth-Kleiner, Matthias, and Schittny, Johannes C.

Subjects

PULMONARY alveoli, MEDICAL imaging systems, THREE-dimensional imaging, LABORATORY mice, COMPUTED tomography, IMAGE processing, PHYSIOLOGY

Abstract

Using state-of-the-art X-ray tomographic microscopy we can image lung tissue in three dimensions in intact animals down to a micrometer precision. The structural complexity and hierarchical branching scheme of the lung at this level of details, however, renders the extraction of biologically relevant quantities particularly challenging. We have developed a methodology for a detailed description of lung inflation patterns by measuring the size and the local curvature of the parenchymal airspaces. These quantitative tools for morphological and topological analyses were applied to high-resolution murine 3D lung image data, inflated at different pressure levels under immediate post mortem conditions. We show for the first time direct indications of heterogeneous intra-lobar and inter-lobar distension patterns at the alveolar level. Furthermore, we did not find any indication that a cyclic opening-and-collapse (recruitment) of a large number of alveoli takes place. [ABSTRACT FROM AUTHOR]

Published

2017