单分散聚苯乙烯乳液高温成膜过程的形态观察

单分散乳液指微粒具有相同化学组成、粒径及界面性质等特征的分散体系 ,因其颗粒均一 ,结构可调 ,赋予了其很多独特性质 ,广泛应用于计量、电子、生物、分析、医学、化工和信息等领域 .同时 ,单分散微粒体系作为研究原子或分子结晶过程的模型物 [1] ,在凝聚态物理中具有重要作用 .单分散乳液在一些条件下能排列成最大密堆积规整结构 ,从而赋予乳胶膜更优异的性能 [2 ] .因此 ,研究单分散乳液的成膜过程 ,在基础理论和实际应用中具有重要意义 .软的乳胶微粒玻璃化温度在室温附近 ,它们在常温下就可形变融合成膜 ,此时水蒸发速度较慢 ,乳液中…     

The experimental study and modelling the drying kinetics of mussels using ultrasound assisted vacuum drying

In the present study, chemical compositions, drying kinetics, quality parameters and energy consumptions for mediterranean or black mussel (Mytilus galloprovincialis) subjected to ultrasound assisted vacuum drying (UAVD) were analyzed between the range of 50–70 ​°C. During drying only falling rate periods were observed. Obtained conclusions demonstrated that the moisture content and drying rate were influenced by the ultrasound assisted vacuum drying method and the drying air temperature. The ultrasound assisted vacuum drying shortened the drying period and increased the effective moisture diffusivity (D_eff). Drying led to a considerable increasing of protein and fat content. Six well-known thin layer drying models were compared with regards to coefficients of determination. The Alibas model was selected as the best one. The activation energy was calculated as 3.80 ​kW/kg. High “L1" and low "ΔE" values were obtained for dried mussels. Using of ultrasound assisted vacuum drying technique resulted in very low energy consumption.     

纳米硅酸镁锂-壳聚糖-海藻酸钠复合支架材料的制备与性能

利用真空冷冻干燥技术, 将不同质量的纳米硅酸镁锂(nLMS)与壳聚糖(CA)和海藻酸钠(SA)混合, 制备了纳米硅酸镁锂-壳聚糖-海藻酸钠(nLMS-CS-SA)复合支架材料. 研究了不同质量分数(1%, 2%, 3%, 4%)的nLMS对nLMS-CS-SA复合支架材料的外形、 微观形貌、 溶胀率、 孔隙率、 体外降解性能和生物相容性的影响, 以确定nLMS-CS-SA复合支架材料中最佳nLMS含量. 研究结果显示, nLMS-CS-SA复合支架材料是具备形态可塑性的多孔状固体, 各组材料纵断面呈片层状, 其结构疏松且内部孔隙具有高度连通性; 随着nLMS含量的增加, nLMS-CS-SA复合支架材料的孔隙率呈现先降后升的趋势; 当nLMS的质量分数为3%时, 其溶胀比最小, 体外降解速率最慢; nLMS的添加降低了nLMS-CS-SA复合支架材料的毒性. 因此, nLMS在nLMS-CS-SA复合支架材料中的最佳含量为3%.     

Sodium alginate/magnesium oxide nanocomposite scaffolds for bone tissue engineering

A simple 2‐step method, consisting of film casting and polyvinyl alcohol leaching, is proposed to prepare magnesium oxide (MO) nanoparticle‐reinforced sodium alginate scaffolds with right properties for bone tissue engineering. The cytocompatibility of the as‐prepared scaffolds was also evaluated using the 3‐(4,5‐dimethylthiazol‐2‐yl)‐2,5‐diphenyltetrazolium‐bromide yellow tetrazole assay test, wherein chondrocyte cells had been considered as target cells. According to the results, the ensuing sodium alginate nanocomposites, containing 4‐wt% MO nanoparticles, demonstrated the highest physical and mechanical properties after leaching step. The Young modulus of sodium alginate/4‐wt% MO was improved about 44%, in comparison with that of the pure alginate sample. Furthermore, incorporating MO nanoparticles up to 4 wt% controlled the liquid uptake capacity of scaffolds vis‐à‐vis the resultant pure sodium alginate sample. Moreover, with increasing the nanoparticle content, the antibacterial properties of scaffolds enhanced, but their degradation rates under in vitro conditions tapered off. With the introduction of 3‐ and 4‐wt% MO, the average diameter of the bacterial zone of the scaffold samples reduced to less than 10 mm², suggesting an insensitive antimicrobial performance, compared with the pure sodium alginate and the samples with 1‐ and 2‐wt% MO content, which exhibit antimicrobial sensitivity. 3‐(4,5‐Dimethylthiazol‐2‐yl)‐2,5‐diphenyltetrazolium‐bromide assay test also revealed the cultivated chondrocyte cells on the 4‐wt% MO nanoparticle‐reinforced scaffold possessed better interaction as well as appropriate cell attachment and proliferation than the pristine sodium alginate sample.     

Improved stability of OPALMON tablets under humid conditions. III: Application of the rotary vacuum drying method to dry Opalmon tablets

In stability studies on moisture-resistant Opalmon tablets in press-through-packages (PTP), which were placed in aluminum bags, we found that the degradation rate of the dextran formulation is faster than that of the lactose formulation. The fast degradation of the dextran formulation is attributed to residual moisture in the package because drying the tablets before packaging suppressed the degradation and there is a good correlation between the stability of the drug and the water-activity of the tablets. Therefore, we developed a new drying method for the tablets, i.e. the rotary vacuum drying method, and investigated the effects of the operating conditions such as heating temperature, rotation speed, and vacuum degree on the drying time, and the appearance of the tablets. Using the rotary vacuum drying method, the tablets were dried over a short time (30 min) on a mass production scale so that the water activity was less than 0.03. Furthermore, the tablets suffered negligible damage such as breaking and chipping during the drying process. These results indicate that the rotary vacuum drying method is useful for drying tablets on mass production scales.     

Design of a Novel Two‐Component Hybrid Dermal Scaffold for the Treatment of Pressure Sores

The aim of this study is to design a novel two‐component hybrid scaffold using the fibrin/alginate porous hydrogel Smart Matrix combined to a backing layer of plasma polymerized polydimethylsiloxane (Sil) membrane to make the fibrin‐based dermal scaffold more robust for the treatment of the clinically challenging pressure sores. A design criteria are established, according to which the Sil membranes are punched to avoid collection of fluid underneath. Manual peel test shows that native silicone does not attach to the fibrin/alginate component while the plasma polymerized silicone membranes are firmly bound to fibrin/alginate. Structural characterization shows that the fibrin/alginate matrix is intact after the addition of the Sil membrane. By adding a Sil membrane to the original fibrin/alginate scaffold, the resulting two‐component scaffolds have a significantly higher shear or storage modulus G ′. In vitro cell studies show that dermal fibroblasts remain viable, proliferate, and infiltrate the two‐component hybrid scaffolds during the culture period. These results show that the design of a novel two‐component hybrid dermal scaffold is successful according to the proposed design criteria. To the best of the authors' knowledge, this is the first study that reports the combination of a fibrin‐based scaffold with a plasma‐polymerized silicone membrane.     

3D porous acellular cartilage matrix scaffold with surface mediated sustainable release of TGF-β3 for cartilage engineering

Acellular tissue matrix scaffolds are much closer to tissue’s complex natural structure and biological characteristics, thus assess great advantages in cartilage engineering. We used rabbit costal cartilage to prepare acellular microfilaments and further 3D porous acellular cartilage scaffold via crosslinking. Poly(l-lysine)/hyaluronic acid (PLL/HA) multilayer film was then built up onto the surface of the resulting porous scaffold. Furthermore, TGF-β3 was loaded into the PLL/HA multilayer film coated scaffold to obtain a 3D porous acellular cartilage scaffold with sustained releasing of TGF-β3 up to 60 days. The success of this project will provide a new way for the treatment of articular cartilage defects. Meanwhile, the anchoring and on-site sustained releasing of growth factors mediated by polyelectrolyte multilayered film can also provide a new method for improving the biocompatibility and the biofunctionality for other implanted biomaterials.     

包埋于PLGA膜中的BSA海藻酸钙微球的制备及其释放行为

在组织工程中，为了促进和调节细胞在细胞支架上的增殖和分化，一些特殊的生物活性分子(生长因子(Growth Factor，简称GF))，必须引入支架．这些生长因子是一类具有诱导和刺激细胞增殖、维持细胞存活等生物效应的多肽蛋白类物质，因此，在组织工程研究中，生长因子是三个重要因素之一，     

Cell(MC3T3‐E1)‐Printed Poly(ϵ‐caprolactone)/Alginate Hybrid Scaffolds for Tissue Regeneration

A new cell‐printed scaffold consisting of poly(ϵ‐caprolactone) (PCL) and cell‐embedded alginate struts is designed. The PCL and alginate struts are stacked in an interdigitated pattern in successive layers to acquire a three‐dimensional (3D) shape. The hybrid scaffold exhibits a two‐phase structure consisting of cell (MC3T3‐E1)‐laden alginate struts able to support biological activity and PCL struts able to provide controllable mechanical support of the cell‐laden alginate struts. The hybrid scaffolds exhibit an impressive increase in tensile modulus and maximum strength compared to pure alginate scaffolds. Laden cells are homogeneously distributed throughout the alginate struts and the entire scaffold, resulting in cell viability of approximately 84%.     

Gelatin scaffolds functionalized by silver nanoparticle‐containing calcium alginate beads for wound care applications

The embedding of silver nanoparticle (nAg)‐containing calcium alginate (CaAlg) beads in gelatin scaffolds was aimed to reduce the burst release and prolong the release of silver (Ag⁺) ions for a long period of time. The reduced sizes of the nAg‐containing CaAlg beads were prepared by an emulsification/external gelation method. The diameter of these beads was ~2 µm. The nAg‐containing CaAlg beads were then embedded into gelatin scaffolds by a freeze‐drying method for evaluating the potential of these scaffolds as wound dressings. The compressive modulus of these scaffolds embedded with nAg‐containing CaAlg beads ranged between 7 and 9 kPa. For release study, the cumulative released amounts of Ag⁺ ions from the nAg‐containing CaAlg beads embedded in gelatin scaffolds were lower than those from the nAg‐containing CaAlg beads. Moreover, the nAg‐containing CaAlg beads embedded in gelatin scaffolds had great antibacterial activity and low cytotoxicity. Thus, these scaffolds had potential for sustaining the release and use in wound care applications, especially chronic wound. Copyright © 2016 John Wiley & Sons, Ltd.     

Surface Modification of GTA Crosslinked Collagen‐based Composite Scaffolds with Low Temperature Plasma Technology

In this study for preparing the better performance scaffold materials for peripheral nerve repairing, the collagen‐based composite scaffolds are crosslinked with glutaraldehyde and their structure and performance are investigated. The results of FTIR indicated that the collagen and chitosan are certainly crosslinked through GTA without any significant change in the chemical property. It was observed under a scanning electron microscope (SEM) that the crosslinked collagen‐based composite scaffolds had a porous three‐dimensional cross‐linked structure. The experiments showed that the biostability of the scaffold is greatly enhanced, but the GTA crosslinking induces the potential cytotoxicity and poor hydrophilic nature. To overcome these disadvantages, the low temperature plasma technology is utilized to modify the surface of the cross‐linked collagen‐based composite scaffolds in this study. Measurements of water contact angle showed that hydrophilic nature of surface of the scaffolds was improved after low temperature plasma technology modification. The cell proliferation experiments revealed that the modified collagen‐based composite scaffolds still kept their bioactivity and benefited the proliferation.     

Simulation of novel soy protein‐based systems for tissue regeneration applications

In the present research, molecular modeling methods were used to study novel porous soy protein conjugates with gelatin or alginate, which were recently developed as potential scaffolds for tissue engineering applications. Gelatin (protein) and alginate (polysaccharides) were chemically crosslinked to soy protein isolates (SPI) in order to obtain a porous 3D network. Computational tools were applied to estimate the crosslinking degree and compare the degradation rate of soy–gelatin or soy–alginate conjugates. Soy protein 3D structure was obtained from the Protein Data Bank (PDB). Alginate and gelatin structures were built and subjected to dynamic simulation using the molecular modeling package Material Studio 7.0. The crosslinking degree was estimated by the miscibility of the two reactants and the interaction with the crosslinking agents 1‐ethyl‐3‐(3‐dimethylaminopropyl) carbodiimide (EDC) or glyoxal. The calculations revealed that soy protein mixes well with gelatin but not with alginate. Radial distribution function (RDF) calculations showed that the interaction distance between alginate and EDC is significantly shorter than between gelatin and EDC, probably because of ionic attraction between the ammonium groups of EDC and the carboxylate groups in alginate, which facilitates the crosslinking reaction. The degradation rate of soy protein conjugates was related to their interaction with water. It was found that the solubility of soy–gelatin in water is higher than soy–alginate and that water molecules form more hydrogen bonds with soy–gelatin than with soy–alginate. These findings might be the reason for the observed difference in degradation rate of the two conjugates; the soy–gelatin degrades faster than soy–alginate. Copyright © 2016 John Wiley & Sons, Ltd.     

Effect of composition,solvent exchange liquid and drying method on the porous structure of phenol–formaldehyde gels

Organic gels have been synthesized by sol–gel polycondensation of phenol (P) and formaldehyde (F) catalyzed by sodium carbonate (C). The effect of synthesis parameters such as phenol/catalyst ratio (P/C), solvent exchange liquid and drying method, on the porous structure of the gels have been investigated. The total and mesopore volumes of the PF gels increased with increasing P/C ratio in the range of P/C ≤ 8, after this both properties started to decrease with P/C ratio for P/C > 8 and the gel with P/C = 8 showed the highest total and mesopore volumes of 1.281 and 1.279 cm³ g⁻¹ respectively. The gels prepared by freeze drying possessed significantly higher porosities than the vacuum dried gels. The pore volume and average pore diameter of the freeze dried gels were significantly higher than those of the vacuum dried gels. T-butanol emerged as the preferred solvent for the removal of water from the PF hydrogel prior to drying, as significantly higher pore volumes and specific surface areas were obtained in the corresponding dried gels. The results showed that freeze drying with t-butanol and lower P/C ratios were favourable conditions for the synthesis of highly mesoporous phenol–formaldehyde gels.     

Mechanical behaviour of a hydrogel film with embedded voids under the tensile load

The behaviour of alginate gel film in response to the tensile load is analysed in this paper. The bubbles of 0.5?mm diameter were embedded in the film by the fluidic method prior to gelation, thus providing uniform voidage over the entire film. Further, the intrinsic porosity of the gel matrix around the voids was varied by removing water through either evaporation under vacuum, or employing lyophilisation. The Poisson’s ratio and the modulus of elasticity were estimated from direct measurements. The viscoelasticity of the gel matrix was characterized from stress-relaxation measurement. The transient response to tensile loading and the evolution of stress contours were studied through numerical simulation in ANSYS. The ultimate strength was studied for the gel films with embedded voids of different sizes. The numerical simulations were validated by experimental measurements.

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Drying of films formed by ordered poly(ethylene oxide)-poly(propylene oxide) block copolymer gels

The drying of hydrogel films formed by poly(ethylene oxide)-poly(propylene oxide) (PEO-PPO) block copolymers (Pluronic P105 and Pluronic L64) is investigated at various air relative humidity (RH) conditions in the range 11-94%. These amphiphilic block copolymers self-assemble to form a variety of ordered (lyotropic liquid crystalline) structures as the water content decreases. The amount of water lost increases linearly with the drying time initially (constant rate region, stage I). After this linear region, a falling rate is observed (stage II). The drying rate increases with decreasing RH, thus greatly shortening the drying time. A decrease of the initial film thickness or a decrease in the initial water content shortens the drying time; however, the drying mechanism remains the same. Analysis of the experimental data shows that the hydration level in the Pluronic hydrogel mainly determines the drying rate, rather than the type of ordered structure formed. Two distinct regions (liquid/gel and solid/crystalline) are observed in the drying isotherm for PEO-PPO block copolymers and homopolymer poly(ethylene glycol)s. A model for one-dimensional water diffusion is used to fit the experimental drying results at different RH, initial film thickness, and initial water content conditions. The model accounts for the shrinkage of the film during drying and for a water diffusion coefficient that is a function of the water concentration in the film. For the experimental conditions considered here, the Biot number (Bi) is less than unity and the drying is mainly limited by evaporation at the film surface. The diffusion model is used to obtain information for cases where Bi > 1.     

Water permeability in MXene membranes: Process matters

Recent studies have shown impressive transport behaviors of water and ions within lamellar MXene membranes,which endows great promise in developing advanced separation application based high performance MXene membranes.However,most of the researches focused on modification of MXene nanoflakes and optimizing interlayer distance,leaving the impact of membrane fabrication process marginal.In this work,we studied the water flux of membranes made by vacuum filtration using delaminated MXene nanoflakes as the building-blocks.Our results show that the water permeability is extremely sensitive to the process,especially at the drying process,loading and deposit rate of nanoflakes(the feeding concentration).We find that the voids from less ordered stack rather than in-plane defects and interlayer galleries contribute to the large water permeability.The voids can be effectively avoided via deposition of MXene nanoflakes at a slow rate.Manipulating the stack of MXene nanoflakes during vacuum filtration and drying are critical for development of MXene membranes with desired performance for water permeation.     

The Use of ATR‐FTIR to Determine the Effects of Functional Groups on Interfacial Crosslinking of Reactive Nanoparticles

Abstract

The film formation and crosslinking of complementary reactive nanoparticle blends of acetoacetoxy (or acetoacetamido) functional particles with isocyanate functional particles were investigated using attenuated total reflectance‐Fourier transform infrared (ATR‐FTIR) spectroscopy. A series of copolymers of 2‐ethylhexyl methacrylate (EHMA) with acetoacetoxy ethyl methacrylate (AA), 2‐methyl‐acrylic acid 2‐methyl‐2‐(3‐oxo‐butyrylamino)‐propyl ester (AM), and dimethyl meta‐isopropenyl benzyl isocyanate (TMI) were prepared by emulsion polymerization techniques at room temperature. These blends were air‐dried on ATR‐FTIR germanium (Ge) discs while the FTIR spectra were taken during the film formation process. The interfacial crosslinking reaction between functional moieties during the film formation process was determined using the FTIR data. The reactivity of acetoacetamido group is higher than that of acetoacetoxy group and the rate constant for the crosslinking reaction between two reaction moieties of terpolymer samples is higher as compared to the blended systems.     

海藻酸壳聚糖可塑性支架材料的制备及表征

利用海藻酸钠和壳聚糖2种原料, 采用阴阳离子静电复合原理, 通过滴注法层层自组装成可搭载药物的缓释微球, 再按一定比例与海藻酸钠-壳聚糖溶液混合制成缓释微球型支架材料, 将缓释微球结构嵌入疏松多孔海绵状结构中. 研究了缓释微球的组分比对缓释微球型支架材料的孔隙率、 收缩率、 亲水性及降解性能的影响; 扫描电子显微镜照片显示, 微球结构相对完整, 多孔海绵状结构孔径为140~200 μm; 支架浸出液细胞毒性检测实验组对照组未见差异. 缓释微球体积所占比例即组分比为10%的缓释微球型支架材料孔隙率最高为68.2%~70.8%, 亲水性最好, 收缩率最低为4.4%~5.2%; 支架降解速率随缓释微球组分比升高而减慢, 组分比为20%的缓释微球型支架材料综合性能更优; 缓释微球型支架材料冻干成型前为液态, 具有良好可塑性. 缓释微球型支架材料为缓释系统与多孔支架材料有机结合提供了新思路.