Interfacial behaviour of bovine testis hyaluronidase

Optimization and mechanisms of proteolytic enzyme immobilization onto large-pore mesoporous silica nanoparticles: Enhanced tumor penetration

Immobilization of proteolytic enzymes onto nanocarriers is effective to improve drug diffusion in tumors through degrading the dense extracellular matrix (ECM). Herein, immobilization and release behaviors of hyaluronidase, bromelain, and collagenase (Coll) on mesoporous silica nanoparticles (MSNs) were explored. A series of cationic MSNs (CMSNs) with large and adjustable pore sizes were synthesized, and investigated together with two anionic MSNs of different pore sizes. CMSNs4.0 exhibited the highest enzyme loading capacity for hyaluronidase and bromelain, and CMSNs4.5 was the best for Coll. High electrostatic interaction, matched pore size, and large pore volume and surface area favor the immobilization. Changes of the enzyme conformations and surface charges with pH, existence of a space around the immobilized enzymes, and the depth of the pore structures, affect the release ratio and tunability. The optimal CMSNs-enzyme complexes exhibited deep and homogeneous penetration into pancreatic tumors, a tumor model with the densest ECM, with CMSNs4.5-Coll as the best. Upon loading with doxorubicin (DOX), the CMSNs-enzyme complexes induced high anti-tumor efficiencies. Conceivably, the DOX/CMSNs4.5-NH2-Coll nanodrug exhibited the most effective tumor therapy, with a tumor growth inhibition ratio of 86.1 %. The study provides excellent nanocarrier-enzyme complexes, and offers instructive theories for enhanced tumor penetration and therapy.

Application of Formulation Principles to Stability Issues Encountered During Processing, Manufacturing, and Storage of Drug Substance and Drug Product Protein Therapeutics

The field of formulation and stabilization of protein therapeutics has become rather extensive. However, most of the focus has been on stabilization of the final drug product. Yet, proteins experience stress and degradation through the manufacturing process, starting with fermentaition. This review describes how formulation principles can be applied to stabilize biopharmaceutical proteins during bioprocessing and manufacturing, considering each unit operation involved in prepration of the drug substance. In addition, the impact of the container on stabilty is discussed as well.

Evaluation of in-vitro cytotoxic effect of 5-FU loaded-chitosan nanoparticles against spheroid models

PURPOSE

The studies investigate the anticancer activity of 5-fluorouracil (5-FU)-hyaluronidase (Hase) enzyme-loaded chitosan nanoparticles (5-FUChnps) using three-dimensional (3D) spheroid HCT-116 culture. Hase-loaded nanoparticles (Chnps) have recently been used to improve the efficacy of chemotherapeutic drugs for cancer treatment. It has been found that administration of Hase improves tumor vessel densities and increase perfusion within tumor.

METHODS

Particle size and zeta potential of the nanoparticles were determined using a particle size analyzer while Fourier transform infrared (FTIR) was used to investigate the interactions among the various components making up the chitosan nanoparticles. Cytotoxic effects of 5-FU and 5FUchnps against dimensional (2D) and 3D spheroid cultures were assessed using trypan blue assay.

RESULTS

Low molecular weight chitosan (Chi_L) nanoparticle size was determined to between 215 to 670 nm while medium molecular weight chitosan (Chi_M) nanoparticle size ranged from 151 to 778 nm. All 5FUChnps exhibited a zeta potential value ranging from +4 to +37 mV. Among the 16 formulations prepared, formulation #7 (5-FUChnps₇) was selected for the in-vitro cytotoxic studies based on its high 5-FU entrapment efficiency (59%). 5FUchnps treated 3D HCT-116 culture exhibited significant growth inhibition compared with 5-FU treated groups. Further, spheroids with significant growth inhibition exhibited high spheroid volume and non-spherical shapes.

CONCLUSION

5-FUChnps were significantly cytotoxic to the 3D HCT-116 cultures than that of the free 5-FU. Chnps proved to have the ability to deliver and improve the anticancer activity of 5-FU in 3D HCT-116 culture studies.

Sealing hyaluronic acid microgels with oppositely-charged polypeptides: A simple strategy for packaging hydrophilic drugs with on-demand release

A simple route to deliver on demand hydrosoluble molecules such as peptides, packaged in biocompatible and biodegradable microgels, is presented. Hyaluronic acid hydrogel particles with a controlled structure are prepared using a microfluidic approach. Their porosity and their rigidity can be tuned by changing the crosslinking density. These negatively-charged polyelectrolytes interact strongly with positively-charged linear peptides such as poly-l-lysine (PLL). Their interactions induce microgel deswelling and inhibit microgel enzymatic degradability by hyaluronidase. While small PLL penetrate the whole volume of the microgel, PLL larger than the mesh size of the network remain confined at its periphery. They make a complexed layer with reduced pore size, which insulates the microgel inner core from the outer medium. Consequently, enzymatic degradation of the matrix is fully inhibited and non-affinity hydrophilic species can be trapped in the core. Indeed, negatively-charged or small neutral peptides, without interactions with the network, usually diffuse freely across the network. By simple addition of large PLL, they are packaged in the core and can be released on demand, upon introduction of an enzyme that degrades selectively the capping agent. Single polyelectrolyte layer appears as a simple generic method to coat hydrogel-based materials of various scales for encapsulation and controlled delivery of hydrosoluble molecules.

Simultaneous elastase-, hyaluronidase- and collagenase-capillary electrophoresis based assay. Application to evaluate the bioactivity of the red alga Jania rubens

There have been many efforts to search for affordable and efficient cosmetic ingredients from natural sources and to evaluate their bioactivities using eco-responsible tools. Hyaluronidase, elastase and collagenase are responsible for the degradation of the main components of the extracellular matrix, namely the hyaluronic acid, elastin and collagen, respectively. The aim of this work was to develop a single capillary electrophoresis method to monitor simultaneously the activities of these three enzymes, without reactant immobilization or radioactivity use. The developed approach was used to evaluate the bioactivity of the red alga Jania rubens after microwave- or electrochemical-assisted extraction. For this purpose, the incubation time, the reactant concentrations, the separation buffer and the detection system were carefully chosen. CE with double detection system, LIF and HRMS connected in series, was used to ensure the simultaneous analysis of the substrates and products of the three enzymatic reactions. The optimized enzymatic conditions allowed the use of the same protocol to assess the 3 enzyme activities. These conditions consisted of 10 min pre-incubation of the enzyme (with alga extract) at 37 °C; 10 min incubation with the substrate at 37 °C and 10 min stop-time at 90 °C. 1.4 nL of each reaction mixture were co-injected into a 85 cm total length capillary using short-end injection. Ammonium acetate (50 mM, pH 9.0) was used for electrophoretic separation. All substrates and products were simultaneously detected in less than 10 min with good peak symmetry and efficiency, sufficient intra-day and inter-day repeatabilities (RSD < 4.5%; n = 3) and excellent LOQ (<5 nM). The results obtained using this multiple CE-based enzymatic assay showed the significant effect of Jania rubens ethanolic extracts on elastase, hyaluronidase and the metalloproteinase MMP-1.

Stratification of chondroitin sulfate binding sites in 3D-model of bovine testicular hyaluronidase and effective size of glycosaminoglycan coat of the modified protein

A 3D-model of bovine testicular hyaluronidase (BTH) was constructed based on established tertiary structure of human hyaluronidase Hyal1 using a molecular homological modeling method in silico. The analysis of the BTH 3D-model demonstrated lysine residue stratification during enzyme modification. The 3D-model of chondroitin sulfate (CHS)-modified hyaluronidase (BTH-CHS) was obtained by modeling covalent binding of lysine residues with benzoquinone-activated CHS. The degree of enzyme modification and the length of CHS chains were varied during 3D modeling. The importance of deep BTH modification degree for the formation of active and stable enzyme derivatives was shown, as determined earlier experimentally. The effective size of the CHS coat for productive BTH modification was confirmed. It is theoretically achieved at the increase in molecular mass of BTH-CHS derivative to approximately 140-180 kDa and can be practically obtained, according to experimental data, using CHS of different molecular mass (30-50 as well as 120-140 kDa).