Abstract
The pathology of human diseases are now investigated using microphysiological systems (MPS) supporting vascular structures. Efforts to increase physiological relevance of these platforms have centered on the incorporation of organ-specific cellular and non-cellular constituents. However, tissue-specific cellular constituents must experience appropriate physical forces to faithfully replicate physiological function. Quantification of physical forces in MPS has received little attention. The goal of this study was to establish a simple and robust system capable of interfacing with existing pumps to quantitatively characterize the flow delivered to a MPS. The system assessed both the fluid pressure driving flow through a microphysiological platform and the resistance to flow of glass capillary tubes or a model vascular network. The system showed excellent qualitative and quantitative agreement with resistance values measured by a hydrostatic approach and predicted for laminar flow through a smooth capillary tube. Importantly, the system is optically-based without sensors contacting the circulating fluid making it ideally-suited for long-term biological studies where sterility is paramount. Benchmarking experiments were supplemented with measurements of driving pressure and flow resistance from vascular structures within a MPS in a humidified incubator. Vascular resistance measurements were consistent with published results obtained from similar microvascular networks.