Abstract
All human cells are coated by a surface layer of proteoglycans, glycosaminoglycans (GAGs) and plasma proteins, called the glycocalyx. The glycocalyx transmits shear stress to the cytoskeleton of endothelial cells, maintains a selective permeability barrier, and modulates adhesion of blood leukocytes and platelets. Major components of the glycocalyx, including syndecans, heparan sulfate, and hyaluronan, are shed from the endothelial surface layer during conditions including ischaemia and hypoxia, sepsis, atherosclerosis, diabetes, renal disease, and some viral infections. Studying mechanisms of glycocalyx damage in vivo can be challenging due to the complexity of immuno-inflammatory responses which are inextricably involved. Previously, both static as well as perfused in vitro models have studied the glycocalyx, and have reported either imaging data, assessment of barrier function, or interactions of blood components with the endothelial monolayer. To date, no model has simultaneously incorporated all these features at once, however such a model would arguably enhance the study of vasculopathic processes. This review compiles a series of current in vitro models described in the literature that have targeted the glycocalyx layer, their limitations, and potential opportunities for further developments in this field.
Highlights
All cells in humans are coated by a surface layer of glycans called the glycocalyx [1, 2]
In a murine model by Wang et al reducing sulphation by 60% with an endothelium-specific knockout of N-acetyl glucosamine N-deacetylase-N-sulfotransferase-1, which is required for the addition of sulfate to heparan sulfate chains, decreased neutrophil infiltration [10]
This paper aims to review current in vitro models which study glycocalyx pathophysiology, with an aim to identify areas of potential further development in this field
Summary
All cells in humans are coated by a surface layer of glycans called the glycocalyx [1, 2]. This coating is a matrix consisting of various proteoglycans, glycosaminoglycans (GAGs), and plasma proteins, and it provides endothelial cellular mechano-sensation and transduction [3]. The composition of the glycocalyx is in a state of constant flux, as it continuously replenishes components that are removed by flowing plasma [4]. The glycocalyx offers a scaffold to which plasma proteins and GAGs may bind [4, 5], and remains an inactive structure until plasma constituents are bound, at which point it becomes the physiologically active endothelial surface layer [6].
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