Overexpression of Cyclooxygenase-1 Correlates with Poor Prognosis in Renal Cell Carcinoma

Yu, Zu-Hu,Zhang, Qiang,Wang, Ya-Dong,Chen, Jing,Jiang, Zhi-Mao,Shi, Min,Guo, Xin,Qin, Jie,Cui, Guang-Hui,Cai, Zhi-Ming,Gui, Yao-Ting,Lai, Yong-Qing Asian Pacific Journal of Cancer Prevention 2013 Asian Pacific journal of cancer prevention Vol.14 No.6

The aim of this study was to evaluate expression of COX-1 in renal cell carcinoma (RCC) and its prognostic value. mRNA of COX-1 was detected in 42 paired RCC and adjacent normal tissues with quantitative realtime polymerase chain reaction (qRT-PCR). Expression of COX-1 was also evaluated in 196 RCC sections and 91 adjacent normal tissues with immunohistochemistry. Statistical analysis was performed to assess COX-1 expression in RCC and its prognostic significance. The results of qRT-PCR showed mRNA levels of COX-1 in RCC tissues to be significantly higher than that in adjacent normal tissues (p < 0.001). Immunohistochemical assays also revealed COX-1 to be overexpressed in RCC tissues (p < 0.001). Statistical analysis demonstrated high expression of COX-1 was correlated with tumour size (p = 0.002), pathological stage (p = 0.003), TNM stage (p = 0.003, 0.007, 0.027, respectively), and tumour recurrence (p < 0.001). Survival analysis indicated patients with high expression of COX-1 had shorter survival time (p < 0.001), and COX-1 was an independent predictor. This is the first study to reveal overexpression of COX-1 in RRC and point to use as a prognostic marker in affected patients.

Preparation of Robust Aramid/Epoxy Composites through Enhancing the Interface Performance by Nanocoating Solution

Tingli Hu,Zengxiao Wang,Yutong Cao,Zu Ming Hu,Jun Rong Yu,Yan Wang 한국섬유공학회 2022 Fibers and polymers Vol.23 No.4

Aramid fiber reinforced composites (AFRC) have attracted considerable attention because of its high strength andmodulus. But the poor interface due to the smooth fiber surface and few active groups limits the application of the finalcomposites. In this study, robust AFRC was achieved via dip-coating approach. Instead of Kevlar fiber, sulfonefunctionalizedpoly(p-phthaloyl-p-phenylenediamine) (SPPTA) was served as precursor to prepare nanocoating solution. Byfurther grafting epichlorohydrin (ECH) and Shellac (SLC), the functional coating solution was obtained. After modification,the roughness and the polarity of the fiber were considerably improved. The modified AF/epoxy composites showedexcellent interfacial bonding and mechanical properties. For the sample grafted with SLC, the interfacial shear strength(IFSS) reached 43.7 MPa with a significant enhancement by 21.4 %; while the inter-laminar shear strength (ILSS) reached48.6 MPa with a reinforcement of 45.9 %. The flexural strength and tensile strength were increased to 283 MPa and831 MPa, indicating that the study provides an effective method to achieve high strength AFRC.

Poly (dimethyl siloxane)/poly (2-hydroxyethyl methacrylate) interpenetrating polymer network beads as potential capsules for biomedical use

Qi Tang,Jun-Rong Yu,Lei Chen,Jing Zhu,Zu-Ming Hu 한국물리학회 2011 Current Applied Physics Vol.11 No.3

Silicone hydrogels represent a series of novel materials designed for extensive applications especially in the biomedical field. In the current work, a method to obtain poly (dimethyl siloxane)/poly (2-hydroxyethyl methacrylate) (PDMS/PHEMA) interpenetrating polymer network (IPN) beads was developed. With further optimization, up to 43% PHEMA was incorporated into size controllable PDMS microspheres,offers an improved hydrophilicity and thus a reduced protein adsorption for long-term use. Furthermore, we found the PDMS/PHEMA IPN beads possess a hollow capsule-like structure, proposing their application as novel drug delivery vehicles. In vitro release studies have demonstrated two release patterns of these IPN beads for water-soluble drugs just by modulating the drug concentration, suggesting their possible applications in different delivery systems.

Structure and Properties of Polyimide (BTDA-TDI/MDI co-polyimide) Fibers Obtained by Wet-Spinning

Hong Bing Xiang,Zhong Huang,Li Qi Liu,Lei Chen,Jing Zhu,Zu Ming Hu,Jun Rong Yu 한국고분자학회 2011 Macromolecular Research Vol.19 No.7

BTDA-TDI/MDI (P84, synthesized by the condensation of 2,4-diisocyanato-1-methylbenzene and 1,1' -methylenebis(4-isocyanatobenzene) with 5,5'-carbonylbis(l,3-isobenzofurandione)) co-polyimide fibers were prepared by wet-spinning. The basic spinning conditions were found from the studies of dope viscosity, ternary phase diagrams, coagulation value, and precipitation value. The effect of the coagulation bath composition on the morphology of as-spun fibers was investigated and a theoretical approach was used to understand the coagulation phenomena. Scanning electron microscopy (SEM) showed that the cross-sectional shape of the fiber deviated more from an ellipse shape with the increasement of N-methyl-2-pyrrdidinone (NMP) content. The surface and cross section morphology of the as-spun fibers was also analyzed by the rate of diffusion and phase separation. The as-spun fibers were treated in heating tubes without drawing at different temperatures. The gravimetric analysis spectra showed that the BTDA-TDI/MDI co-polyimide fibers, which had been heat treated at 350 and 400 ℃, possessed better thermal properties than the as-spun fibers, a large weight loss was observed only above 550 ℃. Heat treatment of the fibers resulted in relatively high tensile strength and modulus. The fibers spun in Bath C (70/30, NMP/water, wt/wt)and Bath D (80/20, NMP/water, wt/wt) showed better thermal properties and higher tensile strength.

Effect of Gel-spun Solution Concentration on the Structure and Properties of UHMWPE Monofilaments with Coarse Denier

Hongqiu Wang,Rong Liu,Jun Rong Yu,Jing Zhu,Yan Wang,Zu Ming Hu 한국섬유공학회 2022 Fibers and polymers Vol.23 No.7

Even though many efforts about the preparation of ultra-high molecular weight polyethylene (UHMWPE) fibershave been reported since last century, the spinning technology of high solution concentration UHMWPE fibers was stillpursued by many researchers and industry members. Not only because solution concentration is a key factor that significantlyinfluences the structure and properties of gel-spun UHMWPE fibers, but also because the high concentration UHMWPEspinning technology could greatly improve the production efficiency and reduce the spinning cost. In this study, highabrasion resistance UHMWPE fibers were prepared via gel-spinning with UHMWPE solution concentration of 8-16 wt%,subsequently extracting, drying and ultra-drawing. The effects of solution concentration on the fiber solvent phase separation,crystallization properties, abrasion resistance properties and mechanical capacities were investigated in detail. The resultsindicated that increasing solution concentration can reduce the time to reach phase separation equilibrium state that couldefficiently shorten the productive time; meanwhile, the abrasion resistance of the fibers was also significantly improved.

Preparation and properties of morphology controlled poly(2-hydroxyethyl methacrylate)/poly(N-vinyl pyrrolidone) double networks for biomedical use

Qi Tang,Jun-Rong Yu,Lei Chen,Jing Zhu,Zu-Ming Hu 한국물리학회 2010 Current Applied Physics Vol.10 No.3

Poly(2-hydroxyethyl methacrylate)/poly(N-vinyl pyrrolidone) (PHEMA/PVP) double networks (DN) were prepared using a sequential method by incorporating a second network of crosslinked PVP into PHEMA. We found that the distributions of the two networks can be regulated just by modulating the morphology of the first network, thus giving expected high water content of these gels. Fourier transform infrared (FTIR) spectroscopy and scanning electronic microscopy (SEM) were used to confirm the structure of the DN. The incorporation of more hydrophilic PVP enhanced swelling ability of these gels. Because of improved hydrophilicity, the PHEMA/PVP DN exhibited higher loading capability for water-soluble substance than that of pure PHEMA, while showed a slower release rate than corresponding HEMA/NVP copolymer hydrogel. It is suggested that the DN gels are potential biomaterials for wound dressing, medical implants and other drug delivery systems.