Modulation of functional pendant chains within poly(ethylene glycol) hydrogels for refined control of protein release

Hydrogels are highly attractive delivery vehicles for therapeutic proteins. Their innate biocompatibility, hydrophilicity and aqueous permeability allow stable encapsulation and release of proteins. The release rates also can be controlled simply by altering the crosslinking density of the polymeric network. However, the crosslinking density also influences the mechanical properties of hydrogels, generally opposite to the permeability. In addition, the release of larger proteins may be hindered below critically diminished porosity determined by the crosslinking density. Herein, the physical properties of the hydrogels are tuned by presenting functional pendant chains, independent of crosslinking density. Heterobifunctional poly(ethylene glycol) monomethacrylate (PEGMA) with various end functional groups is synthesized and copolymerized with PEG dimethacrylate (PEGDA) to engineer PEG hydrogels with pendant PEG chains. The pendant chains of the PEG hydrogels consisting of sulfonate, trimethylammonium chloride, and phenyl groups are utilized to provide negative charge, positive charge and hydrophobicity, respectively, to the hydrogels. The release rates of proteins with different isoelectric points are controlled in a wide range by the type and the density of functional pendant chains via electrostatic and hydrophobic interactions

The significance of peroxisomes in secondary metabolite biosynthesis in filamentous fungi

Peroxisomes are ubiquitous organelles characterized by a protein-rich matrix surrounded by a single membrane. In filamentous fungi, peroxisomes are crucial for the primary metabolism of several unusual carbon sources used for growth (e.g. fatty acids), but increasing evidence is presented that emphasize the crucial role of these organelles in the formation of a variety of secondary metabolites. In filamentous fungi, peroxisomes also play a role in development and differentiation whereas specialized peroxisomes, the Woronin bodies, play a structural role in plugging septal pores. The biogenesis of peroxisomes in filamentous fungi involves the function of conserved PEX genes, as well as genes that are unique for these organisms. Peroxisomes are also subject to autophagic degradation, a process that involves ATG genes. The interplay between organelle biogenesis and degradation may serve a quality control function, thereby allowing a continuous rejuvenation of the organelle population in the cells

Silicate Clay-Hydrogel Nanoscale Composites for Sustained Delivery of Small Molecules

Hydrogels have been widely used for therapeutic delivery applications due to their tunability and biocompatibility, although delivery of small molecules is difficult due to high burst release and rapid diffusion from the device. Nanosilicate clays (nanoclays) have shown the adsorption potential of small molecules, offering a lever to prolong the release kinetics of hydrogel delivery devices. However, further characterization of small molecule–nanoclay interactions and their effect on molecule release is needed to allow for the custom design of tunable nanocomposite hydrogel delivery devices. Here, we have characterized the adsorption of small molecules onto three nanoclays, Laponite, montmorillonite, and halloysite, and monitored their release in various conditions. The layered structures of Laponite and montmorillonite led to cationic exchange of the small molecules into the interlayer space, whereas the small molecules were adsorbed onto the surface of the tubular halloysite. The addition of nanoclays to polyethylene glycol (PEG) hydrogels significantly slowed the release of small molecules, especially from Laponite (500-fold decrease) and montmorillonite (∼3000-fold decrease) composite gels. Cationic small molecules were shown to be released significantly slower from nanocomposite hydrogels than anionic ones. The incubation time of small molecules with nanoclays prior to hydrogel encapsulation also played a key role in determining their release rate, with montmorillonite showing near-immediate adsorption while halloysite exhibited a higher dependence on incubation time due to slower adsorption kinetics. Release buffer salt concentration and pH were shown to affect release kinetics due to modulation of nanoclay–small molecule interactions. These results show the potential for formation of a highly tunable nanocomposite hydrogel delivery device for a greatly prolonged release of small molecules compared to traditional hydrogels