Empirical and Theoretical Analysis of Particle Diffusion in Mucus

Abstract: Mucus is a complex fluid that coats multiple organs in animals. Various physicochemical properties can alter the diffusion of microscopic particles in mucus, impacting drug delivery, virus infection, and disease development. The simultaneous effect of these physicochemical properties in particle diffusion, however, remains elusive. Here, we analyzed 106 published experiments to identify the most dominant factors controlling particle diffusion in mucus. The effective diffusion—defined using a one-second samplin… Show more

“…Other studies also highlight the limited diffusion of positively charged molecules in porcine gastric mucus (Desai and Vadgama, 1991) and nanoparticles in porcine jejunal mucus (Crater and Carrier, 2010). Such phenomena can be attributed to electrostatic interactions between the diffusing cation and the negatively charged mucin domains (Cobarrubia et al, 2021;Griffiths et al, 2015).…”

Development and validation of a porcine artificial colonic mucus model reflecting the properties of native colonic mucus in pigs

“…Other studies also highlight the limited diffusion of positively charged molecules in porcine gastric mucus (Desai and Vadgama, 1991) and nanoparticles in porcine jejunal mucus (Crater and Carrier, 2010). Such phenomena can be attributed to electrostatic interactions between the diffusing cation and the negatively charged mucin domains (Cobarrubia et al, 2021;Griffiths et al, 2015).…”

Development and validation of a porcine artificial colonic mucus model reflecting the properties of native colonic mucus in pigs

“…7,13 Moreover, particles with a near-neutral zeta potential (ζ) exhibit the most efficient diffusion through mucus. 14 Therefore, current mucus penetration strategies focus on neutralizing the surface charge and shielding the hydrophobic surface properties of nanocarriers. In our previous work, we surface coated bovine milk derived exosomes (mExo) with polyethylene glycol (PEG), providing a hydrophilic coating to reduce interactions between mExo particles and mucus.…”

Milk exosomes anchored with hydrophilic and zwitterionic motifs enhance mucus permeability for applications in oral gene delivery

Predicting the capsid architecture of phages from metagenomic data