The effect of nanoparticle permeation on the bulk rheological properties of mucus from the small intestine.

The effectiveness of delivering oral therapeutic peptides, proteins and nucleotides is often hindered by the protective mucus barrier that covers mucosal surfaces of the gastrointestinal (GI) tract. Encapsulation of active pharmaceutical ingredients (API) in nanocarriers is a potential strategy to protect the cargo but they still have to pass the mucus barrier. Decorating nanoparticles with proteolytic enzymes has been shown to increase the permeation through mucus. Here we investigate the effect of poly(acrylic acid) (PAA) nanoparticles decorated with bromelain (BRO), a proteolytic enzyme from pineapple stem, on the bulk rheology of mucus as well as non-decorated poly(lactic-co-glycolic acid) (PLGA) nanoparticles. Porcine intestinal mucus from the small intestine was incubated for 30min in the presence of PLGA nanoparticles or polyacrylic nanoparticles decorated with bromelain (PAA-BRO). The effect of nanoparticles on the rheological properties, weight of gel, released glycoprotein content from mucus as well as the viscosity of liquid removed was assessed. Treatment with nanoparticles decreased mucus gel strength with PAA-BRO reducing it the most. PAA-BRO nanoparticles resulted in the release of increased glycoprotein from the gel network whereas mucus remained a gel and exhibited a similar breakdown stress to control mucus. Therefore it would be possible to use bromelain to increase the permeability of nanoparticles through mucus without destroying the gel and leaving the underlying mucosa unprotected.

Mucus permeating thiomer nanoparticles.

The aim of this study was to develop and evaluate a novel mucoadhesive drug delivery system based on thiolated poly(acrylic acid) nanoparticles exhibiting mucolytic properties to enhance particle diffusion into deeper mucus regions before adhesion. Mediated by a carbodiimide, cysteine and the mucolytic enzyme papain were covalently attached to poly(acrylic acid) via amide bond formation. The conjugates were co-precipitated with calcium chloride in order to obtain papain modified (PAA-pap) and thiolated nanoparticles (PAA-cys) as well as particles containing both conjugates (PAA-cys-pap). The nanoparticulate systems were characterized regarding particle size distribution and zeta potential. Particle transport was investigated by diffusion studies across intestinal mucus using two different techniques. Furthermore, mucoadhesive properties of all particles were evaluated via rheological measurements. Results demonstrated that all nanoparticles were in a size range of 158-214 nm and showed negative zeta potentials. Due to the presence of papain, the PAA-cys-pap particles were capable of cleaving mucoglycoprotein substructures and consequently exhibited a 2.0-fold higher penetration into the mucus layer in comparison with PAA-cys particles. Within the rheological studies, an 1.9-fold increase in mucoadhesion could be achieved for the nanoparticulate system based on thiolated PAA compared to papain modified particles (PAA-pap). Therefore, the newly developed particulate system (PAA-cys-pap) is characterized by mucoadhesive as well as mucolytic properties. The combination of both effects - mucus-permeating and mucoadhesive properties - might be a promising strategy for the development of oral drug delivery systems to overcome the mucus barrier and providing a prolonged residence time close to the absorption membrane.