Cellulose Nanofiber Platform for Pesticide Sequestration in the Gastrointestinal Tract.

Exploitation of nature-derived materials is an important approach to promote environmental sustainability. Among these materials, cellulose is of particular interest due to its abundance and relative ease of access. As a food ingredient, cellulose nanofibers (CNFs) have found interesting applications as emulsifiers and modulators of lipid digestion and absorption. In this report, we show that CNFs can also be modified to modulate the bioavailability of toxins, such as pesticides, in the gastrointestinal tract (GIT) by forming inclusion complexes and promoting interaction with surface hydroxyl groups. CNFs were successfully functionalized with (2-hydroxypropyl)-ß-cyclodextrin (HPBCD) using citric acid as a crosslinker via esterification. Functionally, the potential for pristine and functionalized CNFs (FCNFs) to interact with a model pesticide, boscalid, was tested. Based on direct interaction studies, adsorption of boscalid saturated at around 3.09% on CNFs and at 12.62% on FCNFs. Using an in vitro GIT simulation platform, the adsorption of boscalid on CNFs/FCNFs was also studied. The presence of a high-fat food model was found to have a positive effect in binding boscalid in a simulated intestinal fluid environment. In addition, FCNFs were found to have a greater effect in retarding triglyceride digestion than CNFs (61% vs 30.6%). Overall, FCNFs were demonstrated to evoke synergistic effects of reducing fat absorption and pesticide bioavailability through inclusion complex formation and the additional binding of the pesticide onto surface hydroxyl groups on HPBCD. By adopting food-compatible materials and processes for production, FCNFs have the potential to be developed into a functional food ingredient for modulating food digestion and the uptake of toxins.

Effects of ingested nanocellulose and nanochitosan materials on carbohydrate digestion and absorption in an in vitro small intestinal epithelium model.

Nanoscale materials derived from natural biopolymers like cellulose and chitosan have many potentially useful agri-food and oral drug delivery applications. Because of their large and potentially bioactive surface areas and other unique physico-chemical properties, it is essential when evaluating their toxicological impact to assess potential effects on the digestion and absorption of co-ingested nutrients. Here, the effects of cellulose nanofibers (CNF), cellulose nanocrystals (CNC), and chitosan nanoparticles (Chnp) on the digestion and absorption of carbohydrates were studied. Starch digestion was assessed by measuring maltose released during simulated digestion of starch solutions. Glucose absorption was assessed by measuring translocation from the resulting digestas across an in vitro transwell tri-culture model of the small intestinal epithelium and calculating the area under the curve increase in absorbed glucose, analogous to the glycemic index. At 1% w/w, CNF and Chnp had small but significant effects (11% decrease and 14% increase, respectively) and CNC had no effect on starch hydrolysis during simulated digestion of a 1% w/w rice starch solution. In addition, at 2% w/w CNC had no effect on amylolysis in 1% solutions of either rice, corn, or wheat starch. Similarly, absorption of glucose from digestas of starch solutions (i.e., from maltose), was unaffected by 1% w/w CNF or CNC, but was slightly increased (10%, p<0.05) by 1% Chnp, possibly due to the slightly higher maltose concentration in the Chnp-containing digestas. In contrast, all of the test materials caused sharp increases (~1.2, 1.5, and 1.6 fold for CNC, CNF, and Chnp, respectively) in absorption of glucose from starch-free digestas spiked with free glucose at a concentration corresponding to complete hydrolysis of 1% w/w starch. The potential for ingested cellulose and chitosan nanomaterials to increase glucose absorption could have important health implications. Further studies are needed to elucidate the mechanisms underlying the observed increases and to evaluate the potential glycemic effects in an intact in vivo system.

Convection and the Extracellular Matrix Dictate Inter- and Intra-Biofilm Quorum Sensing Communication in Environmental Systems.

The mechanisms and impact of bacterial quorum sensing (QS) for the coordination of population-level behaviors are well studied under laboratory conditions. However, it is unclear how, in otherwise open environmental systems, QS signals accumulate to sufficient concentration to induce QS phenotypes, especially when quorum quenching (QQ) organisms are also present. We explore the impact of QQ activity on QS signaling in spatially organized biofilms in scenarios that mimic open systems of natural and engineered environments. Using a functionally differentiated biofilm system, we show that the extracellular matrix, local flow, and QQ interact to modulate communication. In still aqueous environments, convection facilitates signal dispersal while the matrix absorbs and relays signals to the cells. This process facilitates inter-biofilm communication even at low extracellular signal concentrations. Within the biofilm, the matrix further regulates the transport of the competing QS and QQ molecules, leading to heterogenous QS behavior. Importantly, only extracellular QQ enzymes can effectively control QS signaling, suggesting that the intracellular QQ enzymes may not have evolved to degrade environmental QS signals for competition.

The role of PEG architecture and molecular weight in the gene transfection performance of PEGylated poly(dimethylaminoethyl methacrylate) based cationic polymers.

In this study, we report the synthesis of well-defined model PEGylated poly(dimethylaminoethyl methacrylate) based cationic polymers composed of different PEG architecture with controlled PEG and nitrogen content via reversible addition-fragmentation chain transfer (RAFT) polymerization, and study the effects of PEG architecture and polymer molecular weight on gene delivery and cytotoxicity. Investigation of the physico-chemical interactions of these model cationic polymers with DNA demonstrated that all these polymers effectively complexed with DNA, and PEG topology did not significantly affect the abilities of the polymers to complex and release DNA. However the size and zeta potential of the complexes were found to be influenced by PEG architecture. The polymers with the block-like configurations formed nanosized DNA complexes. In contrast, considerably higher molecular weight was necessary for the copolymer with the statistical configuration of short PEG chains to form such a small complex. Cell line-dependent influence of PEG architecture on cellular uptake, gene expression efficiency and cell viability of the polymer-DNA complexes was observed. The diblock copolymer-DNA complexes induced higher gene expression than the brush-like block copolymer-DNA complexes, and the statistical copolymer-DNA complexes mediated much lower gene expression than the block-like copolymers-DNA complexes. Increasing the molecular weight of statistical polymer to some extent improved gene expression efficiency. The statistical copolymer was less cytotoxic as compared to the block-like copolymers. These findings provide important insights into the effect of PEGylation nature on gene expression, which will be useful for the design of PEGylated gene delivery polymers.

Hydrolytic degradation characteristics of irradiated multi-layered PLGA films.

Poly(lactide-co-glycolide) (PLGA) has been extensively investigated for controlled drug release. Because they undergo bulk degradation, they do not allow for a good controlled-release of drugs. The objective of this study is therefore to understand if a multi-layer-cum-irradiation technique would elicit surface erosion from PLGA polymers. A linear loss of mass and film thinning from PLGA films were observed. Also, the erosion of the top layer, of this multi-layered structure, accelerates degradation of the underlying layers. It is this effect that results in the observed pseudo-surface erosion for irradiated multi-layered PLGA.