The assembly of aqueous gold nanoparticles on the surface of polyurethane (PU) spheres
leading to [gold nanoparticle shell]−[polyurethane core] structures is demonstrated. The
assembly of gold nanoparticles on the polymer microspheres occurs through interaction of
the nitrogens in the polymer with the nanoparticles. Such direct assembly obviates the need
to perform additional surface modification of the polymer microspheres, which is an important
step in other polymer-based core−shell structure protocols. The nanogold−PU material is
then conjugated with the enzyme pepsin, leading to the formation of a new class of biocatalyst.
In relation to the free enzyme in solution, the new bioconjugate material exhibited a slightly
higher biocatalytic activity and significantly enhanced pH and temperature stability. The
use of gold nanoparticle-labeled polymer microspheres in pepsin bioconjugation enables easy
separation from the reaction medium and reuse of the bioconjugate over six reaction cycles.
Microencapsulation of the water soluble pesticide monocrotophos (MCR), using polyurethane (PU) as the carrier polymer, has been developed using two types of steric stabilizers, namely PLMA macrodiol and PLMA-g-PEO graft copolymer. The microencapsulation process is carried out in non-aqueous medium and at a moderate temperature to avoid any chemical degradation of monocrotophos during the encapsulation process. Microcapsules were characterized by optical microscopy and SEM for particle size and morphology, respectively. The effects of loading of MCR, crosslinking density of PU, and nature of steric stabilizer on the release of MCR from PU microcapsules have been studied.
Controlled release formulations help to encapsulate agrochemicals and deliver at a sustained rate. Growing environmental challenges have increased the need for controlled release systems based on sustainable feed-stocks. To this end, we report here the preparation and properties of a monolith-type controlled release granular formulation based on two ubiquitous biopolymers, starch and cellulose. Cellulose nanofibers (CNFs) derived from waste sugarcane bagasse were mixed with gelatinized maize starch and urea formaldehyde to yield nanocomposite granular formulation. Dimethyl phthalate (DMP) was used as model encapsulant. The morphology of CNFs and CNFreinforced starch granules was characterized by transmission electron microscopy, scanning electron microscopy, BET porosimetry, and X-ray tomography. Incorporation of only 2−4 wt % CNFs led to a significant reduction in porosity as compared to that for neat starch granules, while the water uptake was enhanced by 20−30%. Reinforcing starch with CNFs led to a significant reduction in initial release rate and yet higher overall release of DMP, thereby allowing effective utilization of entrapped chemicals. This interesting release behavior could be attributed to two competing factors, water uptake-induced diffusion and barrier effects rendered by nanocellulose network.
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