Cyclic strain has antifibrotic effects on the human cardiac fibroblast transcriptome in a human cardiac fibrosis-on-a-chip platform

Publication date

2023-08

Authors

Gartner, Thomas BraccoORCID 0000-0001-8422-7824
Wang, Ye
Leiteris, Laurynas
van Adrichem, Iris
Marsman, JudithORCID 0000-0001-6542-3571
Goumans, Marie José
Bouten, Carlijn V.C.
Sluijter, JoostORCID 0000-0003-2088-9102ISNI 0000000392195257
den Toonder, Jaap M.J.
Suyker, Willem J LISNI 0000000394629063

Editors

Advisors

Supervisors

Document Type

Article

Collections

Open Access logo

License

taverne

Abstract

In cardiac fibrosis, in response to stress or injury, cardiac fibroblasts deposit excessive amounts of collagens which contribute to the development of heart failure. The biochemical stimuli in this process have been extensively studied, but the influence of cyclic deformation on the fibrogenic behavior of cardiac fibroblasts in the ever-beating heart is not fully understood. In fact, most investigated mechanotransduction pathways in cardiac fibroblasts seem to ultimately have profibrotic effects, which leaves an important question in cardiac fibrosis research unanswered: how do cardiac fibroblasts stay quiescent in the ever-beating human heart? In this study, we developed a human cardiac fibrosis-on-a-chip platform and utilized it to investigate if and how cyclic strain affects fibrogenic signaling. The pneumatically actuated platform can expose engineered tissues to controlled strain magnitudes of 0–25% – which covers the entire physiological and pathological strain range in the human heart – and to biochemical stimuli and enables high-throughput screening of multiple samples. Microtissues of human fetal cardiac fibroblasts (hfCF) embedded in gelatin methacryloyl (GelMA) were 3D-cultured on this platform and exposed to strain conditions which mimic the healthy human heart. The results provide evidence of an antifibrotic effect of the applied strain conditions on cardiac fibroblast behavior, emphasizing the influence of biomechanical stimuli on the fibrogenic process and giving a detailed overview of the mechanosensitive pathways and genes involved, which can be used in the development of novel therapies against cardiac fibrosis.

Keywords

Cardiac fibroblast, Disease modeling, Fibrosis, Mechanotransduction, Organ-on-chip technology, Taverne, Biomaterials, Biomedical Engineering, Mechanics of Materials

Citation

Bracco Gartner, T C L, Wang, Y, Leiteris, L, van Adrichem, I, Marsman, J, Goumans, M J, Bouten, C V C, Sluijter, J P G, den Toonder, J M J, Suyker, W J L & Hjortnaes, J 2023, 'Cyclic strain has antifibrotic effects on the human cardiac fibroblast transcriptome in a human cardiac fibrosis-on-a-chip platform', Journal of the mechanical behavior of biomedical materials, vol. 144, 105980. https://doi.org/10.1016/j.jmbbm.2023.105980