The pathophysiology of several lymphatic diseases, such as lymphedema, depends on the function of lymphangions that drive lymph flow. Even though the signaling between the two main cellular components of a lymphangion, endothelial cells (LECs) and muscle cells (LMCs), is responsible for crucial lymphatic functions, there are no in vitro models that have included both cell types. Here, a fabrication technique (gravitational lumen patterning or GLP) is developed to create a lymphangion-chip. This organ-on-chip consists of co-culture of a monolayer of endothelial lumen surrounded by multiple and uniformly thick layers of muscle cells. The platform allows construction of a wide range of luminal diameters and muscular layer thicknesses, thus providing a toolbox to create variable anatomy. In this device, lymphatic muscle cells align circumferentially while endothelial cells aligned axially under flow, as only observed in vivo in the past. This system successfully characterizes the dynamics of cell size, density, growth, alignment, and intercellular gap due to co-culture and shear. Finally, exposure to pro-inflammatory cytokines reveals that the device could facilitate the regulation of endothelial barrier function through the lymphatic muscle cells. Therefore, this bioengineered platform is suitable for use in preclinical research of lymphatic and blood mechanobiology, inflammation, and translational outcomes.
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Intracellular calcium dynamics of lymphatic endothelial and muscle cells co-cultured in a Lymphangion-Chip under pulsatile flow
The lymphatic vascular function is regulated by pulsatile shear stresses through signaling mediated by intracellular calcium [Ca 2+ ] i . Further, the intracellular calcium dynamics mediates signaling between lymphatic endothelial cells (LECs) and muscle cells (LMCs), including the lymphatic tone and contractility. Although calcium signaling has been characterized on LEC monolayers under uniform or step changes in shear stress, these dynamics have not been revealed in LMCs under physiologically-relevant co-culture conditions with LECs or under pulsatile flow. In this study, a cylindrical organ-on-chip platform of the lymphatic vessel (Lymphangion-Chip) consisting of a lumen formed with axially-aligned LECs co-cultured with transversally wrapped layers of LMCs was exposed to step changes or pulsatile shear stress, as often experienced in vivo physiologically or pathologically. Through real-time analysis of intracellular calcium [Ca 2+ ] i release, the device reveals the pulsatile shear-dependent biological coupling between LECs and LMCs. Upon step shear, both cell types undergo a relatively rapid rise in [Ca 2+ ] i followed by a gradual decay. Importantly, under pulsatile flow, analysis of the calcium signal also reveals a secondary sinusoid within the LECs and LMCs that is very close to the flow frequency. Finally, LMCs directly influence the LEC calcium dynamics both under step changes in shear and under pulsatile flow, demonstrating a coupling of LEC–LMC signaling. In conclusion, the Lymphangion-Chip is able to illustrate that intracellular calcium [Ca 2+ ] i in lymphatic vascular cells is dependent on pulsatile shear rate and therefore, serves as an analytical biomarker of mechanotransduction within LECs and LMCs, and functional consequences.
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- Award ID(s):
- 1944322
- PAR ID:
- 10342351
- Date Published:
- Journal Name:
- The Analyst
- Volume:
- 147
- Issue:
- 13
- ISSN:
- 0003-2654
- Page Range / eLocation ID:
- 2953 to 2965
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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PDPN which in turn is regulated byFLCN , which has important implications toward designing functional engineered tissues. -
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- Free Publicly Accessible Full Text
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Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.1039/D2AN00396A
