Mechanical properties of biomimetic tissue adhesive based on the microbial transglutaminase-catalyzed crosslinking of gelatin

Fibrin sealants are a type of soft tissue adhesive that employs biochemical reactions from the late stages of the blood coagulation cascade. Intrinsic to these adhesives are a structural protein and a transglutaminase crosslinking enzyme. We are investigating an alternative biomimetic adhesive based on gelatin and a calcium-independent microbial transglutaminase (mTG). Rheological measurements show that mTG catalyzes the conversion of gelatin solutions into hydrogels, and gel times are on the order of minutes depending on the gelatin type and concentration. Tensile static and dynamic loading of the adhesive hydrogels in bulk form demonstrated that the Young's modulus ranged from 15 to 120 kPa, and these bulk properties were comparable to those reported for hydrogels obtained from fibrin-based sealants. Lap-shear adhesion tests of porcine tissue were performed using a newly published American Society for Testing and Materials (ASTM) standard for tissue adhesives. The gelatin-mTG adhesive bound the opposing tissues together with ultimate adhesive strengths of 12-23 kPa which were significantly higher than the strength observed for fibrin sealants. Even after failure, strands of the gelatin-mTG adhesive remained attached to both of the opposing tissues. These results suggest that gelatin-mTG adhesives may offer the benefits of fibrin sealants without the need for blood products.     

Dextran and gelatin based photocrosslinkable tissue adhesive

A two-component tissue adhesive based on biocompatible and bio-degradable polymers (oxidized urethane dextran (Dex-U-AD) and gelatin) was prepared and photocrosslinked under the ultraviolet (UV) irradiation. The adhesive could adhere to surface of gelatin, which simulated the human tissue steadily. The structures of above Dex-U-AD were characterized by FTIR, (1)H NMR spectroscopy and XRD. The adhesion property of result products was evaluated by lap-shear test. The maximum adhesion strength could reach to 4.16±0.72MPa which was significantly higher than that of fibrin glue. The photopolymerization process of Dex-U-AD/gelatin was monitored by real time infrared spectroscopy (RTIR). It took less than 5min to complete the curing process. The cytotoxicity of Dex-U-AD/gelatin also was evaluated which indicated that Dex-U-AD/gelatin gels were nontoxic to L929 cell. The relationship between all the above-mentioned properties and degree of oxidization of Dex-U-AD was assessed. The obtained products have the potential to serve as tissue adhesive in the future.     

Regulation of adipose‐tissue‐derived stromal cell orientation and motility in 2D‐ and 3D‐cultures by direct‐current electrical field

Cell alignment and motility play a critical role in a variety of cell behaviors, including cytoskeleton reorganization, membrane‐protein relocation, nuclear gene expression, and extracellular matrix remodeling. Direct current electric field (EF) in vitro can direct many types of cells to align vertically to EF vector. In this work, we investigated the effects of EF stimulation on rat adipose‐tissue‐derived stromal cells (ADSCs) in 2D‐culture on plastic culture dishes and in 3D‐culture on various scaffold materials, including collagen hydrogels, chitosan hydrogels and poly(L‐lactic acid)/gelatin electrospinning fibers. Rat ADSCs were exposed to various physiological‐strength EFs in a homemade EF‐bioreactor. Changes of morphology and movements of cells affected by applied EFs were evaluated by time‐lapse microphotography, and cell survival rates and intracellular calcium oscillations were also detected. Results showed that EF facilitated ADSC morphological changes, under 6 V/cm EF strength, and that ADSCs in 2D‐culture aligned vertically to EF vector and kept a good cell survival rate. In 3D‐culture, cell galvanotaxis responses were subject to the synergistic effect of applied EF and scaffold materials. Fast cell movement and intracellular calcium activities were observed in the cells of 3D‐culture. We believe our research will provide some experimental references for the future study in cell galvanotaxis behaviors.     

Improving the efficiency of CHO cell line generation using glutamine synthetase gene knockout cells

Although Chinese hamster ovary (CHO) cells, with their unique characteristics, have become a major workhorse for the manufacture of therapeutic recombinant proteins, one of the major challenges in CHO cell line generation (CLG) is how to efficiently identify those rare, high‐producing clones among a large population of low‐ and non‐productive clones. It is not unusual that several hundred individual clones need to be screened for the identification of a commercial clonal cell line with acceptable productivity and growth profile making the cell line appropriate for commercial application. This inefficiency makes the process of CLG both time consuming and laborious. Currently, there are two main CHO expression systems, dihydrofolate reductase (DHFR)‐based methotrexate (MTX) selection and glutamine synthetase (GS)‐based methionine sulfoximine (MSX) selection, that have been in wide industrial use. Since selection of recombinant cell lines in the GS‐CHO system is based on the balance between the expression of the GS gene introduced by the expression plasmid and the addition of the GS inhibitor, L‐MSX, the expression of GS from the endogenous GS gene in parental CHOK1SV cells will likely interfere with the selection process. To study endogenous GS expression's potential impact on selection efficiency, GS‐knockout CHOK1SV cell lines were generated using the zinc finger nuclease (ZFN) technology designed to specifically target the endogenous CHO GS gene. The high efficiency (～2%) of bi‐allelic modification on the CHO GS gene supports the unique advantages of the ZFN technology, especially in CHO cells. GS enzyme function disruption was confirmed by the observation of glutamine‐dependent growth of all GS‐knockout cell lines. Full evaluation of the GS‐knockout cell lines in a standard industrial cell culture process was performed. Bulk culture productivity improved two‐ to three‐fold through the use of GS‐knockout cells as parent cells. The selection stringency was significantly increased, as indicated by the large reduction of non‐producing and low‐producing cells after 25 µM L‐MSX selection, and resulted in a six‐fold efficiency improvement in identifying similar numbers of high‐productive cell lines for a given recombinant monoclonal antibody. The potential impact of GS‐knockout cells on recombinant protein quality is also discussed. Biotechnol. Bioeng. 2012; 109:1007–1015. © 2011 Wiley Periodicals, Inc.     

Chemically cross-linked chitosan hydrogel loaded with gelatin for chondrocyte encapsulation

Composite hydrogels can be used as a scaffolding material for chondrogenesis, which requires a biomimetic environment to maintain chondrocyte morphology and phenotype. In this study, gelatin molecules were loaded into a hydrogel polymerized from a chitosan derivative (CML) to form a semi-interpenetrating polymer network. While the porous structure of the hydrogels in the dry state was not dependent on the gelatin content, the collapse extent and pore size decreased as the gelatin content increased. The gelatin loading also reduced the swelling ratio of the CML hydrogel and enhanced the hydrogel strength at 20°C due to gelation of the gelatin. The release behavior of the gelatin from the CML hydrogel could be controlled by many factors, such as the amount of gelatin, temperature, and solution pH. The weight loss of the composite hydrogel was expedited after gelatin loading and showed a positive relationship with the gelatin content. The results of in vitro cell culture in the hydrogels revealed that gelatin loading improved cell viability and promoted proliferation and glycosaminoglycans secretion of chondrocytes. This new scaffold production technology for chondrocyte encapsulation provides a further step towards CML applications in tissue engineering and other biomedical areas.     

明胶/海藻酸钠/沙蒿胶复合水凝胶的制备及表征

为探究明胶（G）、海藻酸钠（SA）,沙蒿胶（ASKG）对复合水凝胶的力学性能、溶胀和保湿性能的影响,采用共混-离子交联法制备海藻酸钠/明胶/沙蒿胶复合水凝胶,并对制得的水凝胶进行结构表征和溶血率测试。结果表明:当G质量分数为2.5%,SA为1.5%,ASKG为0.7%时,复合水凝胶压缩强度达到427.2 kPa,拉伸强度达到563.449 kPa,断裂伸长率为117%,溶胀率为744%,且具有较好的保湿性能。红外光谱表明,由于沙蒿胶中存在大量羟基,因此加入沙蒿胶后在3 300 cm^-1～3 600 cm^-1羟基峰形变宽。G/SA/ASKG复合水凝胶溶血率低于5%,具有较好的网络孔结构和血液相容性,为复合水凝胶在医用敷料方面的应用提供一定的参考价值。     

Methionine sulfoximine supplementation enhances productivity in GS–CHOK1SV cell lines through glutathione biosynthesis

In Lonza Biologics' GS Gene Expression System?, recombinant protein‐producing GS–CHOK1SV cell lines are generated by transfection with an expression vector encoding both GS and the protein product genes followed by selection in MSX and glutamine‐free medium. MSX is required to inhibit endogenous CHOK1SV GS, and in effect create a glutamine auxotrophy in the host that can be complemented by the expression vector encoded GS in selected cell lines. However, MSX is not a specific inhibitor of GS as it also inhibits the activity of GCL (a key enzyme in the glutathione biosynthesis pathway) to a similar extent. Glutathione species (GSH and GSSG) have been shown to provide both oxidizing and reducing equivalents to ER‐resident oxidoreductases, raising the possibility that selection for transfectants with increased GCL expression could result in the isolation of GS–CHOKISV cell lines with improved capacity for recombinant protein production. In this study we have begun to address the relationship between MSX supplementation, the amount of intracellular GCL subunit and mAb production from a panel of GS–CHOK1SV cell lines. We then evaluated the influence of reduced GCL activity on batch culture of an industrially relevant mAb‐producing GS–CHOK1SV cell line. To the best of our knowledge, this paper describes for the first time the change in expression of GCL subunits and recombinant mAb production in these cell lines with the degree of MSX supplementation in routine subculture. Our data also shows that partial inhibition of GCL activity in medium containing 75 µM MSX increases mAb productivity, and its more specific inhibitor BSO used at a concentration of 80 µM in medium increases the specific rate of mAb production eight‐fold and the concentration in harvest medium by two‐fold. These findings support a link between the inhibition of glutathione biosynthesis and recombinant protein production in industrially relevant systems and provide a process‐driven method for increasing mAb productivity from GS–CHOK1SV cell lines. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 33:17–25, 2017     

Core‐shell nanofibers: Integrating the bioactivity of gelatin and the mechanical property of polyvinyl alcohol

Coaxial electrospinning is used to fabricate nanofibers with gelatin in the shell and polyvinyl alcohol (PVA) in the core in order to derive mechanical strength from PVA and bioactivity from gelatin. At a 1:1 PVA/gelatin mass ratio, the core‐shell nanofiber scaffolds display a Young's modulus of 168.6 ± 36.5 MPa and a tensile strength of 5.42 ± 1.95 MPa, which are significantly higher than those of the scaffolds composed solely of gelatin or PVA. The Young's modulus and tensile strength of the core‐shell nanofibers are further improved by reducing the PVA/gelatin mass ratio from 1:1 to 1:3. The mechanical analysis of the core‐shell nanofibers suggests that the presence of the gelatin shell may improve the molecular alignment of the PVA core, transforming the semi‐crystalline, plastic PVA into a more crystallized, elastic PVA, and enhancing the mechanical properties of the core. Lastly, the PVA/gelatin core‐shell nanofibers possess cellular viability, proliferation, and adhesion similar to these of the gelatin nanofibers, and show significantly higher proliferation and adhesion than the PVA nanofibers. Taken together, the coaxial electrospinning of nanofibers with a core‐shell structure permits integration of the bioactivity of gelatin and the mechanical strength of PVA in single fibers. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 336–346, 2014.     

Hypophysectomy decreases and growth hormone increases the turnover and mass of rat liver glutamine synthetase

Hypophysectomy diminishes rat liver glutamine synthetase (GS) activity and growth hormone (GH) administration restores this activity to normal levels; brain GS is unaffected. We have now investigated the effects of long-term hypophysectomy (45-day) and GH treatment on the GS mass (amount of enzyme) and turnover in rat liver and brain. Labeled GS was isolated by immunoprecipitation at intervals between one and six days after pulse administration of [U-14C] leucine and the GS half-life (t1/2) was determined. The GS mass was obtained by immunoassay and by calculation using the specific activity of purified GS. GS turnover was calculated by multiplying the GS mass by the first-order rate constant of degradation (kd). During the time course of each experiment, the GS mass did not change, indicating that in each of the three hormonal states studied, a steady state existed. Hypophysectomy increased the t1/2 of hepatic GS from 3.8 to 8.8 days and decreased GS turnover from 0.38 to 0.1 microgram/100 g body wt/day; the GH regimen used restored the turnover to above normal levels, 0.6 microgram/100 g body wt/day. The GS mass decreased from 2.0 to 1.2 micrograms/100 g body wt and GH restored the GS mass to normal levels. The brain enzyme was not affected by hypophysectomy or GH.     

Acyl-gelatins for cell-hybrid biomaterials: preparation of gelatins with high melting point and affinity for hydrophobic surfaces

In the development of cell-hybrid biomaterials, the functional activity of cells depends on the selective binding of cells to artificial ligands on the biomaterials. The extracellular matrix (ECM) is the most important ligand for cell activity. ECM is known to contain collagen, one of whose constituents is gelatin. Although natural gelatin has good cell attachment properties, the melting point of gelatin hydrogel is lower than body temperature. Thus, non-chemically cross-linked gelatin hydrogel is not a biomaterial that is used for prostheses. In the present study, we report the preparation of acyl-gelatin hydrogels with high melting point (>37 degrees C) and high affinity for hydrophobic surfaces for easy handling for transportation and adhesion activities on the hydrophobic surfaces. In addition, the doubling time of endothelial cells on the coated cell culture plate was faster than that of natural gelatin owing to the higher adhesion activity of acyl-gelatin. The results clearly demonstrated that the acyl-gelatin acted as an interface that enabled cell adhesion to artificial materials surfaces.     

Self-assembly and adhesion of DOPA-modified methacrylic triblock hydrogels

Marine mussels anchor to a variety of surfaces by secreting liquid proteins that harden and form water-resistant bonds to a variety of surfaces. Studies have revealed that these mussel adhesive proteins contain an unusual amino acid, 3,4-dihydroxy-L-phenylalanine (DOPA), which is believed to be responsible for the cohesive and adhesive properties of these proteins. To separate the cohesive and adhesive roles of DOPA, we incorporated DOPA into the midblock of poly(methyl methacrylate)-poly(methacrylic acid)-poly(methyl methacrylate) (PMMA-PMAA-PMMA) triblock copolymers. Self-assembled hydrogels were obtained by exposing triblock copolymer solutions in dimethyl sulfoxide to water vapor. As water diffused into the solution, the hydrophobic end blocks formed aggregates that were bridged by the water-soluble midblocks. Strong hydrogels were formed with polymer weight fractions between 0.01 and 0.4 and with shear moduli between 1 and 5 kPa. The adhesive properties of the hydrogels on TiO2 surfaces were investigated by indentation with a flat-ended cylindrical punch. At pH values of 6 and 7.4, the fully protonated DOPA groups were highly adhesive to the TiO2 surfaces, giving values of approximately equal to 2 J/m2 for the interfacial fracture energy, which we believe corresponds to the cohesive fracture energy of the hydrogel. At these pH values, the DOPA groups are hydrophobic and have a tendency to aggregate, so contact times of 10 or 20 min are required for these high values of the interfacial strength to be observed. At a pH of 10, the DOPA groups were hydrophilic and highly swellable, but less adhesive gels were formed. Oxidation of DOPA groups, a process that is greatly accelerated at a pH of 10, decreased the adhesive performance of the hydrogels even further.     

Biotinylated biodegradable nanotemplated hydrogel networks for cell interactive applications

We describe the synthesis of a novel biotinylated nanotextured degradable hydrogel that can be rapidly surface engineered with a diverse range of biotinylated moieties. The hydrogel is synthesized by reacting methacrylated biotin-PEG with dimethacrylated P LA-b- PEG-b-P LA (LPLDMA, PEG = poly(ethylene glycol), PLA = poly(lactic acid)),or dimethacrylated PEG-b-P LA-b- PEG (PLPDMA). Methacrylated biotin-PEG is prepared by reacting biotin-PEG-OH with methacrylic anhydride. Biotin-PEG-OH is prepared by reacting alpha-hydroxy-omega-amine PEG with N-hydroxysuccinimide-biotin. Confirmation of the final product is determined using (1)H NMR and Fourier transform infrared spectroscopy (FTIR). The integrity and surface presentation of the biotin units is observed spectrophotometrically using the HABA/avidin assay. To produce nanostructured polymer topography, a self-assembling lyotropic liquid crystalline mesophase is used as a polymerization template, generating biotinylated hydrogels with highly organized lamellar matrix geometry. Traditionally processed isotropic hydrogels are used for comparison. Scanning electron microscopy shows that isotropic hydrogels have a smooth glassy appearance while lamellar templated hydrogels have defined surface topographical features that enhance preosteoblast human palatal mesenchymal cell (HEPM) attachment. Engineering the surfaces of the hydrogels with cell adhesive Arg-Gly-Asp (RGD) peptide sequences using the biotin-avidin interaction significantly enhances cell attachment. Surface engineering of cell adhesive peptides in conjunction with the lamellar template induced surface topography generates additive enhancements in cell attachment.     

Increased matrix synthesis by fibroblasts with decreased proliferation on synthetic chitosan-gelatin porous structures

Influence of mechanical characteristics and matrix architecture of substrates used in cell culture is an important issue to tissue engineering. Chitosan‐based materials have been processed into porous structures, injectable gels and membranes, and are investigated to regenerate various tissues. However, the effect of these structures on cell growth and matrix production in accordance with each of the differing scaffolds has not been examined. We investigated the influence of porous structures, hydrogels, and membranes on the growth of normal human fibroblasts and their matrix production in a serum‐free system. We used chitosan alone and in combination with gelatin. Injectable hydrogels were prepared using 2‐glycerol phosphate. From the same solution, porous scaffolds and membranes were formed using controlled rate freezing and lyophilization, and air‐drying, respectively. Fibroblast growth was evaluated on the 4th and 10th days using flow cytometry and CFDA‐SE pre‐staining. Cell morphology was assessed using actin and nucleus staining. Total protein content, collagen, tropoelastin, and MMP2/MMP‐9 activity in the media supernatant were assessed by BCA, Sircol?, Fastin Elastin, and fluorogeneic peptide assays. Collagen accumulated in the matrix was assessed by Sircol? assay after pepsin/acetic acid digestion and by Masson's Trichrome staining. These results showed increased viability of fibroblasts on chitosan–gelatin porous scaffold with decreased proliferation relative to tissue culture plastic (TCP) surface despite the cells showing spindle shape. The total protein, collagen, and tropoelastin contents were higher in the spent media from chitosan–gelatin porous scaffolds compared to other conditions. MMP2/MMP9 activity was comparable to TCP. An increase in collagen content was also observed in the matrix, suggesting increased matrix deposition. In summary, matrix production is influenced by the form of chitosan structures, which significantly affects the regenerative process. Biotechnol. Bioeng. 2012; 109:1314–1325. © 2011 Wiley Periodicals, Inc.     

Evaluation of Fibroblasts Adhesion and Proliferation on Alginate-Gelatin Crosslinked Hydrogel

Due to the relatively poor cell-material interaction of alginate hydrogel, alginate-gelatin crosslinked (ADA-GEL) hydrogel was synthesized through covalent crosslinking of alginate di-aldehyde (ADA) with gelatin that supported cell attachment, spreading and proliferation. This study highlights the evaluation of the physico-chemical properties of synthesized ADA-GEL hydrogels of different compositions compared to alginate in the form of films. Moreover, in vitro cell-material interaction on ADA-GEL hydrogels of different compositions compared to alginate was investigated by using normal human dermal fibroblasts. Viability, attachment, spreading and proliferation of fibroblasts were significantly increased on ADA-GEL hydrogels compared to alginate. Moreover, in vitro cytocompatibility of ADA-GEL hydrogels was found to be increased with increasing gelatin content. These findings indicate that ADA-GEL hydrogel is a promising material for the biomedical applications in tissue-engineering and regeneration.     

Crystal structures of VAP1 reveal ADAMs' MDC domain architecture and its unique C-shaped scaffold

ADAMs (a disintegrin and metalloproteinase) are sheddases possessing extracellular metalloproteinase/disintegrin/cysteine-rich (MDC) domains. ADAMs uniquely display both proteolytic and adhesive activities on the cell surface, however, most of their physiological targets and adhesion mechanisms remain unclear. Here for the first time, we reveal the ADAMs' MDC architecture and a potential target-binding site by solving crystal structures of VAP1, a snake venom homolog of mammalian ADAMs. The D-domain protrudes from the M-domain opposing the catalytic site and constituting a C-shaped arm with cores of Ca2+ ions. The disintegrin-loop, supposed to interact with integrins, is packed by the C-domain and inaccessible for protein binding. Instead, the hyper-variable region (HVR) in the C-domain, which has a novel fold stabilized by the strictly conserved disulfide bridges, constitutes a potential protein-protein adhesive interface. The HVR is located at the distal end of the arm and faces toward the catalytic site. The C-shaped structure implies interplay between the ADAMs' proteolytic and adhesive domains and suggests a molecular mechanism for ADAMs' target recognition for shedding.     

Characterization of CNPY5 and its family members

The Canopy (CNPY) family consists of four members predicted to be soluble proteins localized to the endoplasmic reticulum (ER). They are involved in a wide array of processes, including angiogenesis, cell adhesion, and host defense. CNPYs are thought to do so via regulation of secretory transport of a diverse group of proteins, such as immunoglobulin M, growth factor receptors, toll‐like receptors, and the low‐density lipoprotein receptor. Thus far, a comparative analysis of the mammalian CNPY family is missing. Bioinformatic analysis shows that mammalian CNPYs, except the CNPY1 homolog, have N‐terminal signal sequences and C‐terminal ER‐retention signals and that mammals have an additional member CNPY5, also known as plasma cell‐induced ER protein 1/marginal zone B cell‐specific protein 1. Canopy proteins are particularly homologous in four hydrophobic alpha‐helical regions and contain three conserved disulfide bonds. This sequence signature is characteristic for the saposin‐like superfamily and strongly argues that CNPYs share this common saposin fold. We showed that CNPY2, 3, 4, and 5 (termed CNPYs) localize to the ER. In radioactive pulse‐chase experiments, we found that CNPYs rapidly form disulfide bonds and fold within minutes into their native forms. Disulfide bonds in native CNPYs remain sensitive to low concentrations of dithiothreitol (DTT) suggesting that the cysteine residues forming them are relatively accessible to solutes. Possible roles of CNPYs in the folding of secretory proteins in the ER are discussed.     

Local Application of Ibandronate/Gelatin Sponge Improves Osteotomy Healing in Rabbits

Delayed healing or non-union of skeletal fractures are common clinical complications. Ibandronate is a highly potent anti-catabolic reagent used for treatment of osteopenia and fracture prevention. We hypothesized that local application of ibandronate after fracture fixation may improve and sustain callus formation and therefore prevent delayed healing or non-union. This study tested the effect of local application of an ibandronate/gelatin sponge composite on osteotomy healing. A right-side distal-femoral osteotomy was created surgically, with fixation using a k-wire, in forty adult male rabbits. The animals were divided into four groups of ten animals and treated by: (i) intravenous injection of normal saline (Control); (ii) local implantation of absorbable gelatin sponge (GS); (iii) local implantation of absorbable GS containing ibandronate (IB+GS), and (iv) intravenous injection of ibandronate (IB i.v.). At two and four weeks the affected femora were harvested for X-ray photography, computed tomography (CT), biomechanical testing and histopathology. At both time-points the results showed that the calluses in both the ibandronate-treated groups, but especially in the IB+GS group, were significantly larger than in the control and GS groups. At four weeks the cross sectional area (CSA) and mechanical test results of ultimate load and energy in the IB+GS group were significantly higher than in other groups. Histological procedures showed a significant reduction in osteoclast numbers in the IB+GS and IB i.v. groups at day 14. The results indicate that local application of an ibandronate/gelatin sponge biomaterial improved early osteotomy healing after surgical fixation and suggest that such treatment may be a valuable local therapy to enhance fracture repair and potentially prevent delayed or non-union.     

支架材料对棕色脂肪源性干细胞向起搏细胞诱导分化的影响

目的观察不同三维支架材料对棕色脂肪来源干细胞（BADSCs）诱导分化成起搏细胞的效果,为构建生物起搏器提供实验依据。 方法将培养7 d的原代BADSCs分别种植到胶原海绵、明胶海绵和透明质酸水凝胶3种不同的材料中,在不同时间用光镜和扫描电镜观察细胞-支架复合体中细胞形态学的变化,免疫荧光染色检测心肌细胞、起搏细胞相关蛋白的表达。采用单因素方差分析。 结果细胞在3种支架上均能存活、增殖,LIVE/DEAD检测显示,培养3 d的胶原海绵、明胶海绵和透明质酸水凝胶3种细胞-支架复合物死细胞率分别为（46.35±1.50）%、（47.00±1.60）%和（1.76±1.08）%,其中细胞在透明质酸水凝胶中死亡率最低,并且细胞-透明质酸水凝胶复合物可自发性地搏动,三组比较差异具有统计学意义（F = 37.56,P < 0.05）。培养至2周时,胶原海绵、明胶海绵和透明质酸水凝胶中Connexin45细胞阳性率分别为（10.67±1.25）%、（13.67±1.25）%和（21.00±1.60）%,差异有统计学意义（F = 9.435,P < 0.01）,HCN2细胞阳性率分别为（11.00±1.60）%、（14.00±2.16）%和（34.33±3.68）%,差异有统计学意义（F = 17.52,P < 0.01）,HCN4细胞阳性率分别为（18.67±2.05）%、（13.00±1.60）%和（66.00±2.94）%,差异有统计学意义（F = 27.96,P < 0.01）,Sr细胞阳性率分别为（13.00±1.63）%、（14.33±1.24）%和（75.33±3.30）%,差异有统计学意义（F = 36.40,P < 0.01）,水凝胶中Connexin45、HCN2、HCN4和Sr的细胞阳性率均高于胶原海绵和明胶海绵,差异均具有统计学意义（P < 0.05）。 结论BADSCs在胶原海绵、明胶海绵和透明质酸水凝胶中均能很好地生长和分化,但透明质酸水凝胶更适用于组织工程化起搏器的构建。     

Structural Analysis of a Glycoside Hydrolase Family 11 Xylanase from Neocallimastix patriciarum: INSIGHTS INTO THE MOLECULAR BASIS OF A THERMOPHILIC ENZYME*

The catalytic domain of XynCDBFV, a glycoside hydrolase family 11 (GH11) xylanase from ruminal fungus Neocallimastix patriciarum previously engineered to exhibit higher specific activity and broader pH adaptability, holds great potential in commercial applications. Here, the crystal structures of XynCDBFV and its complex with substrate were determined to 1.27–1.43 Å resolution. These structures revealed a typical GH11 β-jelly-roll fold and detailed interaction networks between the enzyme and ligands. Notably, an extended N-terminal region (NTR) consisting of 11 amino acids was identified in the XynCDBFV structure, which is found unique among GH11 xylanases. The NTR is attached to the catalytic core by hydrogen bonds and stacking forces along with a disulfide bond between Cys-4 and Cys-172. Interestingly, the NTR deletion mutant retained 61.5% and 19.5% enzymatic activity at 55 °C and 75 °C, respectively, compared with the wild-type enzyme, whereas the C4A/C172A mutant showed 86.8% and 23.3% activity. These results suggest that NTR plays a role in XynCDBFV thermostability, and the Cys-4/Cys-172 disulfide bond is critical to the NTR-mediated interactions. Furthermore, we also demonstrated that Pichia pastoris produces XynCDBFV with higher catalytic activity at higher temperature than Escherichia coli, in which incorrect NTR folding and inefficient disulfide bond formation might have occurred. In conclusion, these structural and functional analyses of the industrially favored XynCDBFV provide a molecular basis of NTR contribution to its thermostability.     

Synthesis and characterization of dendron cross-linked PEG hydrogels as corneal adhesives

In pursuit of a wound-specific corneal adhesive, hydrogels formed by the reaction of propionaldehyde, butyraldehyde, or 2-oxoethyl succinate-functionalized poly(ethylene glycol) (PEG) with a peptide-based dendritic cross-linker (Lys(3)Cys(4)) were characterized. These macromers react within minutes of mixing to form transparent and elastic hydrogels with in vitro degradation times that range from hours to months based on the type of bonds formed during the cross-linking reaction, either thiazolidine or pseudoproline. The mechanical properties of these materials, determined via parallel plate rheology, were dependent on the polymer concentration, as was the hydrogel adhesive strength, which was determined by lap shear adhesive testing. In addition, these hydrogels were efficacious in closing ex vivo 4.1 mm central corneal lacerations: wounds closed with these hydrogel adhesives were able to withstand intraocular pressure values equivalent to, or in excess of, those obtained by closing the wounds with suturing.