Chitooligosaccharide reconstitutes intestinal mucus layer to improve oral absorption of water-soluble drugs.

Intestinal mucus is a complex natural hydrogel barrier with unique physical properties that impede the absorption of various oral drugs. Both washout from the upper water layer and the physical resistance of the mucus layer particularly affect bioavailability of, especially, highly water-soluble molecules. One potential strategy for designing pharmaceutical formulations is to add absorption enhancers (AEs). However, there are few reports of AEs that work on mucus and their underlying mechanisms, leading to imprecise application. In this study, we investigated chitooligosaccharide (COS) as a safe, low-cost, and effective oral drug AE. We revealed the hydrodynamic law of interaction between COS and the intestinal mucus layer, which was associated with absorption benefiting mucus structural reconstruction. Based on this, we designed a translational strategy to improve the bioavailability of a group of soluble oral drugs by drinking COS solution before administration. Moreover, this research is expected to expand its application scenario by reducing drug dosage such as avoiding gastro-intestinal irritation and slowing veterinary antibiotic resistance.

The role of host cell glycans on virus infectivity: The SARS-CoV-2 case

Long and complex chains of sugars, called glycans, often coat both the cell and protein surface. Glycans both modulate specific interactions and protect cells. On the cell surface, these sugars form a cushion known as the glycocalyx. Here, we show that Heparan Sulfate (HS) chains - part of the glycocalyx - and other glycans - expressed on the surface of both host and virus proteins - have a critical role in modulating both attractive and repulsive potentials during viral infection. We analyse the SARS-CoV-2 virus, modelling its spike proteins binding to HS chains and two key entry receptors, ACE2 and TMPRSS2. We include the volume exclusion effect imposed on the HS chains impose during virus insertion into glycocalyx and the steric repulsion caused by changes in the conformation of the ACE2 glycans involved in binding to the spike. We then combine all these interactions, showing that the interplay of all these components is critical to the behaviour of the virus. We show that the virus tropism depends on the combinatorial expression of both HS chains and receptors. Finally, we demonstrate that when both HS chains and entry receptors express at high density, steric effects dominate the interaction, preventing infection.