Targeted and Intrinsic Activity of HA-Functionalized PEI-Nanoceria as a Nano Reactor in Potential Triple-Negative Breast Cancer Treatment.

Although there has been considerable achievement in the field of breast cancer therapeutics, tackling the disturbing issue of highly potent triple-negative breast cancer (TNBC) still remains a hurdle in cancer therapeutics. Here, for the first time we propose a poly(ethylenimine) (PEI)-mediated approach for the synthesis of hyaluronic acid (HA) tagged cerium oxide nanoparticles (CePEI-NPs) as a therapeutic agent in TNBC. Primarily, the formulated HA-CePEI-NPs upon treatment displayed superior anticancer effect by exhibiting the loss of mitochondrial membrane potential (MMP). These particles acted as a nano reactor by the generation of reactive oxygen species (ROS) during the treatment. We further evaluated the caspase activity which divulgated the activation of caspases-3 and -9 while there was a decrease in the level of Bcl-2. The treatment also resulted in the release of cytochrome c (Cyt c), and in addition, features such as pynknosis and G2/M phase arrest were also noted. Hence the nano reactor property of nano ceria in activating mitochondrial-mediated intrinsic apoptosis highlights its promising role as a nano drug for therapeutic applications in TNBC.

Recent developments and applications of immobilized laccase.

Laccase is a promising biocatalyst with many possible applications, including bioremediation, chemical synthesis, biobleaching of paper pulp, biosensing, textile finishing and wine stabilization. The immobilization of enzymes offers several improvements for enzyme applications because the storage and operational stabilities are frequently enhanced. Moreover, the reusability of immobilized enzymes represents a great advantage compared with free enzymes. In this work, we discuss the different methodologies of enzyme immobilization that have been reported for laccases, such as adsorption, entrapment, encapsulation, covalent binding and self-immobilization. The applications of laccase immobilized by the aforementioned methodologies are presented, paying special attention to recent approaches regarding environmental applications and electrobiochemistry.

Reversed micelles of polymeric surfactants in nonpolar organic solvents. A new microheterogeneous medium for enzymatic reactions.

A new microheterogeneous non-aqueous medium for enzymatic reactions, based on reversed micelles of a polymeric surfactant, was suggested. The surfactant termed CEPEI, was synthesized by successive alkylation of poly(ethyleneimine) with cetyl bromide and ethyl bromide and was found to be able to solubilize considerable amounts of water in benzene/n-butanol mixtures. The hydrodynamic radius of polymeric-reversed micelles was estimated to be in the range 22-51 nm, depending on the water content of the system, as determined by means of the quasi-elastic laser-light scattering. Polymeric reversed micelles were capable of solubilizing enzymes (alpha-chymotrypsin and laccase) in nonpolar solvents with retention of catalytic activity. Due to the strong buffering properties of CEPEI over a wide pH range, it could maintain any adjusted pH inside hydrated reversed micelles. It was found that catalytic behavior of enzymes entrapped in polymeric reversed micelles was rather insensitive to the pH of the buffer solution introduced into the system as an aqueous component, but determined mostly by acid-base properties of the polymeric surfactant itself. Both catalytic activity and stability of entrapped alpha-chymotrypsin and laccase were found to increase with increasing water content of the system. Under certain conditions, the entrapment of alpha-chymotrypsin into CEPEI reversed micelles resulted in a considerable increase in catalytic activity and stability as compared to aqueous solution. CEPEI reversed micelles were demonstrated to be promising enzyme carriers for use in membrane reactors. Owing to the large dimensions of CEPEI reversed micelles, they are effectively kept back by a semipermeable membrane, thus allowing an easy separation of the reaction product and convenient recovery of the enzyme.