Polymer Nanocomposites Based Thermo-Sensitive Gel for Paclitaxel and Temozolomide Co-Delivery to Glioblastoma Cells.

In this work, we have reported the preparation and optimization of paclitaxel (PTX) and temozolomide (TMZ) loaded monomethoxy (polyethylene glycol)-poly(D, L-lactide-co-glycolide) (mPEG-PLGA) nanocomposite which is a thermo-sensitive gel delivery system to glioblastoma. We utilized the orthogonal design and homogeneous design for the optimal drug-loaded nanoparticles (NPs) and composite gel prescription, respectively. The physicochemical characteristics of NPs and rheological properties of the gel were analyzed. Then the in vitro release of the gel was determined with a membrane-less diffusion system. Finally, the cytotoxic and apoptosis-inducing effects of the gel on the human malignant glioblastoma cell line U87 and C6 rat glioblastoma cell line were evaluated by MTT and flow cytometry apoptosis assay, respectively. The transmission electron microscopy (TEM) analysis revealed the optimized NPs with a relatively uniform diameter and distribution. The homogeneous design and rheological determination showed that the optimized gel prescription was 250 mg/mL Pluronic F127 (F127), 0.5% hydroxy propyl methylcellulose (HPMC-100M), 0.5% Pluronic F68 (F68), 0.5% sodium alginate (SA) and suitable NPs, which possessed the appropriate gelation behaviors: gelation temperature 28.01 degrees C, gelation time 127.1 s and corrosion speed 0.1892 g/cm2 x hr; and rheological properties: suitable elasticity modulus, viscosity modulus and low phase angle. The in vitro results suggested that the PTX and TMZ were sustainedly released from nanoparticles or the composite gel, and the release and elimination time greatly prolonged; and the composite gel possessed much higher growth-inhibiting effect and apoptosis-inducing rate in U87 and C6 cells than other formulations. These findings demonstrated that the optimal gel was a promising delivery system for the interstitial chemotherapy to glioblastoma.

Delivery of Liver-Specific miRNA-122 Using a Targeted Macromolecular Prodrug toward Synergistic Therapy for Hepatocellular Carcinoma.

Hepatocellular carcinoma (HCC) poses a great threat to human health. The elegant combination of gene therapy and chemotherapy by nanocarriers has been repeatedly highlighted to realize enhanced therapeutic efficacy relative to monotreatment. However, the leading strategy to achieve the efficient codelivery of the gene and drug remains the electrostatic condensation with the nucleic acid and the hydrophobic encapsulation of drug molecules by the nanocarriers, which suffers substantially from premature drug leakage during circulation and severe off-target-associated side effects. To address these issues, we reported in this study the codelivery of liver-specific miRNA-122 and anti-cancer drug 5-fluorouracil (5-Fu) using a macromolecular prodrug approach, that is, electrostatic condensation with miRNA-122 using galactosylated-chitosan-5-fluorouracil (GC-FU). The delivery efficacy was evaluated comprehensively in vitro and in vivo. Specifically, the biocompatibility of GC-FU/miR-122 nanoparticles (NPs) was assessed by hemolysis activity analysis, BSA adsorption test, and cell viability assay in both normal liver cells (L02 cells) and endothelial cells. The resulting codelivery systems showed enhanced blood and salt stability, efficient proliferation inhibition of HCC cells, and further induction apoptosis of HCC cells, as well as downregulated expression of ADAM17 and Bcl-2. The strategy developed herein is thus a highly promising platform for an effective codelivery of miRNA-122 and 5-Fu with facile fabrication and great potential for the clinical translation toward HCC synergistic therapy.

Catalytic performance of lignin peroxidase in a novel reverse micelle.

To enhance the catalytic activity of lignin peroxidase (LiP) in a reverse micelle, a synthesized two-tail nonionic surfactant N-gluconyl glutamic acid didecyl ester (GGDE) was used to formulate a novel reverse micelle. Based on the LiP catalyzed oxidation of veratryl alcohol (VA) in this novel GGDE/TritonX-100-cyclohexane-H(2)O reverse micelle, the effects of the size of the reverse micelle, the buffer pH, and the concentration of H(2)O(2) on the catalytic activity of LiP were investigated. Under the optimized conditions, the catalytic efficiency of LiP in the GGDE/TritonX-100 reverse micelle was 40 times higher than that in the AOT reverse micelle. The full expression of catalytic activity of LiP in this medium was mainly due to the lack of electrostatic interaction between LiP and the head group of GGDE and TritonX-100 and to the size fit between LiP and the inner water cavity of the reverse micelle.

Co-Delivery of Triptolide and Curcumin for Ovarian Cancer Targeting Therapy via mPEG-DPPE/CaP Nanoparticle.

Triptolide has proven to possess anticancer potential and been widely used for anti-cancer research. However, the liver and kidney toxicity has limited its application in cancer treatment. In this study, a drug delivery system based on mPEG-DPPE/calcium phosphate was developed to co-load triptolide and curcumin (TP and Curc-NPs). The coefficient of drug interaction (CDI) was calculated to determine the optimal concentration of the two drugs. When the concentration of triptolide was 25.22 ng/mL and the concentration of curcumin was 6.62 µg/mL, the two drugs reached the maximum synergistic killing effects on SKOV-3 tumor cells. The TP and Curc-NPs was prepared using ultrasonic emulsification. Flow cytometry results revealed that the TP and Curc-NPs arrested cell-cycle in the S and G2/M phases and exhibited a strong ability to induce apoptosis. Intracellular reactive oxygen species (ROS) results indicated that curcumin could reduce the intracellular ROS level caused by triptolide. The mRNA levels of heat shock protein (HSP) were detected by qTR-PCR and the results showed that the TP and Curc-NPs could lower the HSP70 mRNA level while could not reduce the HSP90 mRNA level. The animal experiments demonstrated the favorable curative effects of the TP and Curc-NPs, and the tumor inhibition rate reached 68.78%. The results of the pathological examinations demonstrated that the nanoparticles had no significant toxic effects on important organs. In conclusion, the TP and Curc-NPs exerted synergistic effects on ovarian cancer in vitro and in vivo, and the toxicity caused by triptolide may be reduced by curcumin through anti-oxidative stress effects. The TP and Curc-NPs could be a promising strategy for ovarian cancer.

Biocompatible and colloidally stabilized mPEG-PE/calcium phosphate hybrid nanoparticles loaded with siRNAs targeting tumors.

Calcium phosphate nanoparticles are safe and effective delivery vehicles for small interfering RNA (siRNA), as a result of their excellent biocompatibility. In this work, mPEG-PE (polyethylene glycol-L-α-phosphatidylethanolamine) was synthesized and used to prepare nanoparticles composed of mPEG-PE and calcium phosphate for siRNA delivery. Calcium phosphate and mPEG-PE formed the stable hybrid nanoparticles through self-assembly resulting from electrostatic interaction in water. The average size of the hybrid nanoparticles was approximately 53.2 nm with a negative charge of approximately -16.7 mV, which was confirmed by dynamic light scattering (DLS) measurements. The nanoparticles exhibited excellent stability in serum and could protect siRNA from ribonuclease (RNase) degradation. The cellular internalization of siRNA-loaded nanoparticles was evaluated in SMMC-7721 cells using a laser scanning confocal microscope (CLSM) and flow cytometry. The hybrid nanoparticles could efficiently deliver siRNA to cells compared with free siRNA. Moreover, the in vivo distribution of Cy5-siRNA-loaded hybrid nanoparticles was observed after being injected into tumor-bearing nude mice. The nanoparticles concentrated in the tumor regions through an enhanced permeability and retention (EPR) effect based on the fluorescence intensities of tissue distribution. A safety evaluation of the nanoparticles was performed both in vitro and in vivo demonstrating that the hybrid nanoparticle delivery system had almost no toxicity. These results indicated that the mPEG-PE/CaP hybrid nanoparticles could be a stable, safe and promising siRNA nanocarrier for anticancer therapy.

Thermo-sensitive composite hydrogels based on poloxamer 407 and alginate and their therapeutic effect in embolization in rabbit VX2 liver tumors.

Interventional embolization therapy is an effective, most widely used method for inoperable liver tumors. Blood-vessel-embolic agents were essential in transarterial embolization (TAE). In this work, thermo-sensitive composite hydrogels based on poloxamer 407, sodium alginate, hydroxymethyl cellulose and iodixanol (PSHI), together with Ca2+ (PSHI-Ca2+) were prepared as liquid embolic agents for TAE therapy to liver cancer. With increasing temperature, PSHI exhibited two phase states: a flowing sol and a shrunken gel. Rheology tests showed good fluidity and excellent viscoelastic behavior with a gelation temperature (GT) of 26.5°C. The studies of erosion indicated that PSHI had calcium ion-related erosion characteristics and showed a slow erosion rate in an aqueous environment. When incubated with L929 cells, the thermo-sensitive composite hydrogels had low cytotoxicity in vitro. The results of analyzing the digital subtraction angiography and computed tomography images obtained from in vitro and in vivo assays indicated a good embolic effect in the renal arteries of normal rabbits. Angiography and histological studies on VX2 tumor-bearing rabbits indicated that PSHI-Ca2+ successfully occluded the tumors, including the peripheral vessels. In conclusion, PSHI-Ca2+ was a promising embolic agent for transarterial embolization therapy.

Function and mechanism of a low-molecular-weight peptide produced by Gloeophyllum trabeum in biodegradation of cellulose.

A special low-molecular-weight peptide named Gt factor, was isolated and purified via HPLC from the culture extract of the brown-rot fungus Gloeophyllum trabeum. It had high-affinity Fe(3+)-chelating ability and could reduce Fe(3+) to Fe(2+). In the presence of O(2), it could produce hydroxyl radicals HO*. The effects of Gt factor on cellulose degradation suggested that Gt factor could disrupt inter- and intra- hydrogen bonds in cellulose chains by a HO*-involved mechanism. This resulted in depolymerization of cellulose chains, which produced more reducing and non-reducing ends, thus making cellulose accessible for further degradation. This pathway was quite different from the hydrolytic processes driven by cellulases, and Gt factor might play an important role in the early stage of cellulose depolymerization by brown-rot fungi.

Morphologies and phylogenetic classification of cellulolytic myxobacteria.

The evolutionary distances of the 16S rDNA sequences in cellulolytic myxobacteria are less than 3%, which units all the strains into a single genus, Sorangium. The size of myxospores and the shape of sporangioles, rather than fruiting body colors or swarm morphologies are consistent with the changes of the 16S rDNA sequences. It is suggested that there are at least two species in the genus Sorangium: one includes strains with small myxospores and spherical sporangioles, and the color of the fruiting bodies is normally orange or brown, though sometimes yellow or black. The second species has large myxospores, polyhedral sporangioles with many inter-cystic substrates, and normally deep brown to black color.

Quantitative estimate of the effect of cellulase components during degradation of cotton fibers.

A comprehensive mechanistic kinetic model for enzymatic degradation of cotton fibers has been established based on a complete factorial experiment in combination with multivariate stepwise regression analysis. The analysis of the statistical parameter value in the model suggests that the enzymatic degradation of cotton fiber is a progressive and heterogeneous process that includes, at least, two courses that occur sequentially and then progress in parallel. Cellulose fibers were first depolymerized or solubilized by the synergism between cellobiohydrolase I (CBHI) and endoglucanase I (EGI), and then the oligomers obtained were randomly hydrolyzed into glucose by EGI and beta-glucosidase. The proposed model can be applied to the quantitative estimation of the effects of three cellulase components, CBHI, EGI, and beta-glucosidase separately, or in combination during the entire process of cellulose degradation. The validity of the proposed model has been verified by a filter paper activity assay. Its other applicability was also discussed.

[Research on population structure and distribution characteristic of indigenous microorganism in post-polymer-flooding oil reservoir].

Denaturing gradient gel electrophoresis (DGGE) method and principal component analysis (PCA) method were used to analyze the structures of microorganism population in injection wells and production wells of a post-polymer-flooding oil reservoir in Daqing oil field. The results showed that the dominant species in injection wellhead were aerobic bacteria Pseudomonas and Acinenobacter. Facultative anaerobic bacteria Enterbacter was the dominant bacteria in near area of injection wells. Bacteria detected in production wells included Thauera, Clostridia, Pseudomonas, Petrobacter and some uncultured bacteria. Methanosaeta turned out to be the only archaea detected in injection wells, which was an aceticlastic methane-producing archaeon. Archaea detected in production wells consisted of Methanomicrobium, Methanospirillum and Methanobacterium. In general, aerobic bacteria, facultative anaerobe, and strictly anaerobic bacteria distributed successively from injection wells to production wells in this block. The dominant populations of archaea were different between injection wells and production wells, while were influenced by different environments and microbial metabolism products.

[Studies on the catalytic performance of lignin peroxidase in nonionic reversed micelles].

Lignin peroxidase (LiP) hosted in Brij 30/cyclohexane/water nonionic reversed micelle could express its catalytic activity, but in Triton X-100/n-pentanol/cyclohexane/water nonionic reversed micelle LiP didn't show any catalytic activity. Some key factors that affected the catalytic activity of LiP in Brij 30 reversed micelle were studied at 20 degrees C. The optimum conditions were:omega0 = 8.5, pH = 2.2, [Brij30] = 600 mmol/L; under these conditions the half time of LiP was ca. 50 hours. As compared with the properties of LiP in aqueous solution, the activity of LiP hosted in Brij 30 reversed micelle dropped, but its stability improved greatly. To reveal the role of normal alcohol, which was a necessary component for forming Triton X-100 reversed micelles, the effect of n-pentanol on the catalytic activity of LiP in Brij 30 reversed micelle was investigated. Results indicated that high concentration of the alcohol deactivated LiP. So it was deduced that the phenomenon that LiP hosted in the Triton X-100 reversed micelles could not express its activity was mainly due to the alcohol co-surfactant.