Your search keyword '"Jeroen Hameleers"' showing total 2 results

1. An integrated set-up for ex vivo characterisation of biaxial murine artery biomechanics under pulsatile conditions

Author

Myrthe M. van der Bruggen, Koen D. Reesink, Paul J. M. Spronck, Nicole Bitsch, Jeroen Hameleers, Remco T. A. Megens, Casper G. Schalkwijk, Tammo Delhaas, and Bart Spronck

Subjects

Medicine, Science

Abstract

Abstract Ex vivo characterisation of arterial biomechanics enables detailed discrimination of the various cellular and extracellular contributions to arterial stiffness. However, ex vivo biomechanical studies are commonly performed under quasi-static conditions, whereas dynamic biomechanical behaviour (as relevant in vivo) may differ substantially. Hence, we aim to (1) develop an integrated set-up for quasi-static and dynamic biaxial biomechanical testing, (2) quantify set-up reproducibility, and (3) illustrate the differences in measured arterial stiffness between quasi-static and dynamic conditions. Twenty-two mouse carotid arteries were mounted between glass micropipettes and kept fully vasodilated. While recording pressure, axial force (F), and inner diameter, arteries were exposed to (1) quasi-static pressure inflation from 0 to 200 mmHg; (2) 300 bpm dynamic pressure inflation (peaking at 80/120/160 mmHg); and (3) axial stretch (λ z ) variation at constant pressures of 10/60/100/140/200 mmHg. Measurements were performed in duplicate. Single-point pulse wave velocities (PWV; Bramwell-Hill) and axial stiffness coefficients (c ax = dF/dλ z ) were calculated at the in vivo value of λ z . Within-subject coefficients of variation were ~ 20%. Dynamic PWVs were consistently higher than quasi-static PWVs (p

Published

2021

2. Functional ex-vivo Imaging of Arterial Cellular Recruitment and Lipid Extravasation

Author

Emiel van der Vorst, Sanne Maas, Almudena Ortega-Gomez, Jeroen Hameleers, Mariaelvy Bianchini, Yaw Asare, Oliver Soehnlein, Yvonne Döring, Christian Weber, and Remco Megens

Subjects

Biology (General), QH301-705.5

Abstract

The main purpose of this sophisticated and highly versatile method is to visualize and quantify structural vessel wall properties, cellular recruitment, and lipid/dextran extravasation under physiological conditions in living arteries. This will be of interest for a broad range of researchers within the field of inflammation, hypertension, atherosclerosis, and even the pharmaceutical industry. Currently, many researchers are using in vitro techniques to evaluate cellular recruitment, like transwell or flow chamber systems with cultured cells, with unclear physiological comparability. The here introduced method describes in detail the use of a sophisticated and flexible method to study arterial wall properties and leukocyte recruitment in fresh and viable murine carotid arteries ex vivo under arterial flow conditions. This model mimics the in vivo situation and allows the use of cells and arteries isolated from two different donors (for example, wildtype vs. specific knockouts) to be combined into one experiment,thereby providing information on both leukocyte and/or endothelial cell properties of both donors. As such, this model can be considered an alternative for the complicated and invasive in vivo studies, such as parabiotic experiments.

Published

2017