新方法制备不溶性丝素薄膜及其性质研究

报道一种制备不溶性丝素蛋白薄膜的新方法.在温和搅拌下,将丝素溶液浓缩至16%,通过调整干燥温度和干燥速率,直接获得不溶于水的丝素薄膜.薄膜结构通过FTIR-ATR和XRD测定,同时对薄膜的机械性能进行研究.结果表明,丝素薄膜在干燥温度高于60℃时,有充足的β折叠结构存在,机械性能良好.当干燥温度为70℃时,材料的拉伸强度和断裂伸长率分别为29.8MPa和59.6%,远远强于经过甲醇处理的丝素薄膜的机械性能.当干燥温度高于60℃时,材料在水中具有优异的稳定性.由于在丝素薄膜的制备中避免了甲醇的使用并使材料具有更好的机械性能,此方法制备的丝素薄膜更为安全,应用会更广泛.     

光谱法研究钙离子对丝素蛋白溶解过程中结构的影响

为研究丝素蛋白在氯化钙溶液溶解过程中结构的阶段性变化特征,通过荧光光谱、紫外可见吸收光谱和拉曼光谱技术探讨了不同溶解时间下钙离子对丝素蛋白结构的影响情况。结果表明,在90℃左右,丝素蛋白与氯化钙溶液(Ca Cl2∶H2O=111∶180,质量比)作用0~30 min的时间段内,随着溶解时间的延长,钙离子逐渐渗透到丝素蛋白分子中,与丝氨酸(Ser)、酪氨酸(Tyr)侧链羟基进行配位而形成螯合物,丝素蛋白逐渐溶胀,分子结构变得松弛,埋藏在非结晶区内的色氨酸(Trp)和Tyr也逐渐暴露出来,分子构象由β-折叠向α-螺旋或无规线团转变。此外,外源性荧光探针(ANS)的结果表明,随着溶解时间的延长,丝素蛋白中的疏水性基团逐渐暴露于溶液中。电镜结果表明,丝素蛋白在氯化钙溶液的作用下逐渐由带状转变为片层状,最终呈球状结构。这些结果对调控丝素蛋白在氯化钙溶液中的溶解过程有着较为重要的现实意义。     

天然蚕丝丝素蛋白的乳化活性

采用不同油相制备了系列丝素蛋白乳液, 研究了丝素蛋白浓度、 油相体积分数和油相极性对丝素蛋白的乳化活性指数、 丝素蛋白乳液的稳定性和类型及乳液液滴的微观形态、 粒径与zeta电位的影响, 探讨了丝素蛋白的乳化活性和乳液稳定机制. 结果表明, 丝素蛋白具有两亲性和表面活性, 可在油水界面富集并形成稳定的黏弹性保护膜; 丝素蛋白的乳化活性随其浓度的增大而减小, 随油相体积分数的增大而增大; 丝素蛋白浓度和油相体积分数的增加可提高稳定乳液体积分数.     

丝素纳米颗粒的制备及应用于L-天冬酰胺酶的固定化

丝素蛋白纤维溶于高浓度中性盐溴化锂溶液或氯化钙-乙醇-水三元溶剂中, 经过透析和纯化可以制成3种液态丝素. SDS-PAGE分析结果表明, 其分子量分布范围明显不同. 应用能与水混溶的有机溶剂如丙酮等可将这种丝素制成丝素纳米颗粒, 用SEM观察到丝素纳米颗粒粒径分布范围为50~120 nm. 以戊二醛为交联剂, 将治疗急性淋巴性白血病常用酶制剂L-天冬酰胺酶共价结合在丝素纳米颗粒上. 酶活性分析结果表明, 由肽链断裂较少的丝素制备的纳米颗粒更适合于酶的生物结合. 酶动力学研究结果表明, 这种固定化酶活性回收率为44%, 热稳定性较游离酶有明显提高, 最适pH值范围加宽为6.0~8.0, 最适反应温度提高10 ℃; 抗胰蛋白酶水解能力明显增强. 结果表明, 丝素纳米颗粒与丝素蛋白膜一样, 是一种酶固定化的良好载体, 在药物缓释系统方面具有潜在的研究和开发价值.     

表面活性剂促进的阻燃剂ATBS的合成

用四溴双酚S(TBS)为原料,以滴加方式加入醚化剂烯丙基氯,在NaOH水溶液中用十六烷基三甲基溴化铵(CTAB)催化醚化法和其它表面活性剂促进醚化法合成了收率、纯度均较高的阻燃剂四溴双酚S双烯丙基醚(ATBS)。研究了催化剂用量、滴加时间、异丙醇用量、水用量对ATBS收率及纯度的影响。在烯丙基氯用量为15 mL、TBS为28.3 g、CTAB为0.1~0.18 g、反应温度65~75℃、保温时间4 h,ATBS收率可达95.5%~97.5%,纯度为95.5%~98.0%。当n(烯丙基氯)∶n(TBS)=1∶2.5、反应温度80~90℃、保温时间8 h,表面活性剂DBS为0.8~1.0 g、OP-10为0.5 g、OS-15为0.8 g时,ATBS最佳收率分别为95.2%、97.3%和95.5%,纯度分别为94.0%、92.7%和90.1%。     

磷改性β沸石催化剂上催化裂化轻汽油的醚化

在小型固定床反应装置上,考察了负载磷的β沸石催化剂的制备条件对其催化性能的影响以及醚化反应温度、压力、醇烯摩尔比、LHSV对醚化反应的影响。实验结果表明,浸渍磷的质量分数为2%的Hβ催化剂具有较好的醚化活性。在最佳反应条件(温度70 ℃,压力0.8 MPa,LHSV 1.0 h-1,醇烯摩尔比1.0)下,该催化剂的叔碳烯烃的总转化率可达到56.91%。负载磷后的催化剂具有活性好、选择性高、不易失活等优点。反应性能均优于Hβ催化剂。     

吉非替尼的合成新工艺研究

以6-羟基-7-甲氧基喹唑啉-4-酮(1)为起始原料,在离子液体催化下与N-(3-氯丙基)吗啉(2)醚化,然后经氯代再与3-氯-4-氟苯胺进行亲核取代反应,得到目标产物吉非替尼,三步反应总收率为68.7%。通过改变反应物配比、离子液体用量和反应温度,得到了关键中间体3的优化制备工艺条件:n(1)∶n(2)=1.0∶1.2;离子液体四氟硼酸1-甲基-4-丁基咪唑鎓用量为原料1的质量的5%;95℃下反应5h。在此条件下,醚化收率约93.6%。该路线具有反应条件温和、分离简单、路线短和总收率较高的特点,为吉非替尼的工业化生产提供了实验依据。     

交联羧甲基红薯淀粉降低水中Ca~(2+)含量的研究

以环氧氯丙烷为交联剂,氯乙酸为羧甲基化试剂,合成交联羧甲基红薯淀粉并且研究其降低水中的Ca2+含量的效果.结果显示,交联羧甲基红薯淀粉吸附ca2+的适宜条件为,淀粉取代度0.721、2%淀粉用量、pH 8,吸附时间30min、吸附温度70℃下,交联羧甲基红薯淀粉对水中Ca2+的吸附量可达4.53mmol/L,Ca2+清除率为75.33%.交联羧甲基红薯淀粉吸附Ca2+的行为遵从Langmuir等温吸附方程.     

高浓度高Al13含量聚合氯化铝溶液的制备

通过快速加碱在82 ℃下合成0.2 mol·L^-1、Al_b为60%～70%的低浓度高Al_b聚合氯化铝(L-PAC)，在热侧温度为50～95 ℃，冷侧温度约9～12 ℃的条件下进行膜蒸馏浓缩，制备出总铝浓度在2 mol·L^-1以上，Al_b含量大于90%，Al₁₃含量约为70%的高浓度高Al_b含量的聚合氯化铝溶液。对膜蒸馏浓缩过程中热侧温度、PAC的碱化度和初始pH值等因素对最终聚合氯化铝溶液产品中聚铝形态分布、总铝浓度的影响进行了初步研究，发现在热侧温度低于70 ℃、碱化度为2.47、初始pH值为5.0 ± 0.2的条件下，可以得到高浓度、高Al_b含量的聚合氯化铝溶液，纳米Al₁₃形态在较高的浓度下可以存在；低温贮存条件下，高浓度PAC中Al_b相当稳定。     

乙二醇基炭黑色浆的制备及其性能

通过超细分散法制备了乙二醇基炭黑色浆,采用单因素变量法阐明分散剂与炭黑质量比、研磨时间和研磨转速对炭黑粒径的影响规律,通过正交实验优化炭黑分散工艺来制备乙二醇基炭黑色浆,并对炭黑在乙二醇溶液中的形貌结构及其分散状态进行了观察。结果表明,分散剂与炭黑质量比为1∶10、研磨时间为180 min、研磨转速为3500 r/min时,炭黑的分散效果最好,平均粒径为170.89 nm,并且在乙二醇溶液中的离心稳定性在90%以上,耐热稳定性在90%以上,具有良好的储存稳定性。     

醚化β-环糊精的制备及其混合膜对二甲苯异构体的选择性

采用WilliamSon合成法使氯化苄(PhCH2Cl)与β-环糊精(β-CD)进行醚化反应.红外光谱表明,所得产物为醚化β-CD.根据元素分析结果,计算出各反应的取代度和转化率.系统地考察了反应条件对转化率和取代度的影响.此外,考察了醚化β-CD与聚乙烯醇缩丁醛(PVB)共混膜对含10%对二甲苯的对/间二甲苯混合液的渗透气化性能的影响.结果显示,30℃时,共混膜的分离因子α可达1.16,而对二甲苯PX的渗透通量J高达70.57g/(m2·h).     

Miscibility and biodegradability of silk fibroin/carboxymethyl chitin blend films

Blend films of silk fibroin and carboxymethyl chitin were prepared by solution casting using water as a cosolvent. The blend films were subjected to post-treatment with an aqueous methanol solution to induce beta-sheet formation of silk fibroin. The miscibility of the blend films both before and after methanol treatments was investigated in terms of chemical interactions, morphologies, thermal properties, and crystal structures by using FTIR spectroscopy, SEM, DSC, and XRD. The results indicate that the blend between silk fibroin and CM-chitin was semi-miscible because only the amorphous parts of the polymers were compatible with each other. The enzymatic degradation showed that the incorporation of CM-chitin enhanced biodegradability and swelling ability of silk fibroin.     

Synthesis, thermal properties, and biodegradability of propyl-etherified starch

High amylose corn starch (HACS) was etherified with 1-bromopropane in dimethyl sulfoxide. The structure of the products was characterized by infra-red and ¹H-NMR spectroscopy. The degree of substitution (DS) on glucose unit calculated from ¹H-NMR spectrum was varied from 0.9 to 2.7 by changing feed ratio of 1-bromopropane to HACS. Thermogravimetric analysis reveals that the etherified HACS has a higher decomposition temperature than unmodified HACS. Differential scanning calorimetry analysis reveals that the etherified starch has a clear glass transition temperature which decreased with increasing DS, and that no melting point is observed. This result demonstrates that the etherified HACS mainly consists of amorphous region. The biodegradation rate decreases with increasing degree of etherification.     

蚕丝蛋白与硅溶胶复合材料的研究

采用动态力学测试手段(DMA)并结合扫描电镜和拉曼光谱等方法,考察了用桑蚕丝蛋白与二氧化硅水分散体系(硅溶胶)制备的复合材料的结构与性质.结果表明,在此共混体系中,直径约为100 nm的二氧化硅聚集体与丝蛋白连续相的界面相容性良好.动态力学测试发现,复合材料的动态力学性能在15℃到55℃范围相对于纯丝蛋白材料得到了改善,二氧化硅组分的加入对丝蛋白分子链段的运动性有所阻碍,从而导致了40℃模量损耗的消失.     

Two-step preparation and thermal characterization of cationic 2-hydroxypropyltrimethylammonium chloride hemicellulose polymers from sugarcane bagasse

Cationic sugarcane bagasse hemicellulose derivatives with a relatively low degree of substitution (0.01-0.54) containing quaternary ammonium groups were prepared by etherification with 3-chloro-2-hydroxypropyltrimethylammonium chloride or preferably with 2,3-epoxypropyltrimethylammonium chloride using sodium hydroxide as a catalyst in aqueous solution. The extent of etherification was measured by yield percentage and degree of substitution (DS). The DS values of the products could be controlled by adjusting the molar ratio of etherifying agent to anhydroxylose units in hemicelluloses and the molar ratio of sodium hydroxide to etherifying reagent. In comparison, the etherified hemicellulose preparations were characterized by both degradative methods such as thermal analysis, and non-degradative techniques such as gel permeation chromatography (GPC), Fourier transform infrared (FT-IR), and ¹³C nuclear magnetic resonance (NMR) spectroscopy. It was found that a significant degradation of the hemicellulose polymers occurred during etherification under the alkaline conditions used. The thermal stability of the etherified hemicelluloses was lower than that of the unmodified hemicellulose polymers.     

丝素蛋白膜上5-氟尿嘧啶的包埋及其释放

讨论了包埋在丝素膜中的５－氟脲嘧啶（５－ＦＵ）的固定状况,在不同ＰＨ值下测定了丝素５－ＦＵ复合膜中药物的释放,实验结果表明：５－ＦＵ均匀地被包埋在丝素膜中,即丝素膜可以作为５－ＦＵ载体,经过比涂层保护,丝素５－ＦＵ复合膜中的５－ＦＵ溶解释放速率变慢,释放时间延长;经涂层的 素５－ＦＵ复合膜在接近丝素蛋白等电点（ＰＨ＝４．５）时,５－ＦＵ在溶液中释放速度较慢,释放时间较长,表明用调节外部溶液ＰＨ值的     

Green Process to Prepare Silk Fibroin/Gelatin Biomaterial Scaffolds

A new all‐aqueous and green process is described to form three‐dimensional porous silk fibroin matrices with control of structural and morphological features. Silk‐based scaffolds are prepared using lyophilization. Gelatin is added to the aqueous silk fibroin solution to change the silk fibroin conformation and silk fibroin–water interactions through adjusting the hydrophilic interactions in silk fibroin–gelatin–water systems to restrain the formation of separate sheet like structures in the material, resulting in a more homogenous structure. Water annealing is used to generate insolubility in the silk fibroin–gelatin scaffold system, thereby avoiding the use of organic solvents such as methanol to lock in the β‐sheet structure. The adjusting of the concentration of gelatin, as well as the concentration of silk fibroin, leads to control of morphological and functional properties of the scaffolds. The scaffolds were homogeneous in terms of interconnected pores, with pore sizes ranging from 100 to 600 µm, depending on the concentration of silk fibroin used in the process. At the same time, the morphology of the scaffolds changed from lamellar sheets to porous structures based on the increase in gelatin content. Compared with salt‐leaching aqueous‐derived scaffolds and hexafluoroisopropanol (HFIP)‐derived scaffolds, these freeze‐dried scaffolds had a lower content of β‐sheet, resulting in more hydrophilic features. Most of gelatin was entrapped in the silk fibroin–gelatin scaffolds, without the burst release in PBS solution. During in vitro cell culture, these silk fibroin–gelatin scaffolds had improved cell‐compatibility than salt‐leaching silk fibroin scaffolds. This new process provides useful silk fibroin‐based scaffold systems for use in tissue engineering. Furthermore, the whole process is green, including all‐aqueous, room temperature and pressure, and without the use of toxic chemicals or solvents, offering new ways to load bioactive drugs or growth factors into the process.

     

Porous 3‐D scaffolds from regenerated Antheraea pernyi silk fibroin

In this study, porous three‐dimensional (3‐D) materials were prepared with the regenerated Antheraea pernyi (A. pernyi) silk fibroin by freeze‐drying from a lithium thiocyanate solution of its fibers. The relationship between preparation conditions and morphological structures of 3‐D materials was also studied. We concluded that with the decrease in A. pernyi silk fibroin solution concentration and the increase in the freezing temperature, the porosity and the average pore diameter of the 3‐D materials were increased while the pore density was decreased. By adjusting the freezing temperature and the silk fibroin solution concentration, the 3‐D materials having the average pore diameter of 75–260 µm and the porosity of 70–90% can efficiently be produced. As a kind of new material with excellent biocompatibility and bioactivity, the material is expected to be applied to tissue regeneration scaffolds. Copyright © 2007 John Wiley & Sons, Ltd.     

Structural changes of silk fibroin membranes induced by immersion in methanol aqueous solutions

Structural changes of native and regenerated silk fibroin membranes were induced by immersion in water-methanol solutions and examined as a function of immersion time and methanol concentration. X-ray diffractometry and infrared spectroscopy data showed that transition from random coil to β-sheet structure occurred favorably when both native and regenerated silk fibroin membranes were immersed in water-methanol solutions, regardless of the different immersion time. Only native silk membrane, treated for 2 min with pure methanol, maintained its original amorphous structure, as demonstrated by differential scanning calorimetric (DSC) curves. The degree of displacement, measured by thermomechanical analysis (TMA), was much greater for regenerated than for native silk fibroin membranes. SDS-PAGE pattern showed that native silk fibroin has a molecular weight of 350, while the regenerated sample is formed by a large number of polypeptides in the range of 200-50 KD. The amount of acidic and basic amino acids decreased slightly in regenerated silk fibroin. Physical properties of silk membranes treated with water-methanol solutions are discussed in terms of membrane structure, treatment conditions, and chemical structure of starting material. © 1994 John Wiley & Sons, Inc.