聚羟基丁酸酯缓释微球的制备与性能

用溶剂蒸发法制备了以新型生物可降解材料聚羟基丁酸酯为载体、以安定为模药的缓释微球,讨论了药物与载体之比对药物含量与包封率的影响,以及制备微球条件对药物释放性能的影响;微球平均粒径为30～40 μm,粒径分布在 1～1.5之间,最大载药量为19.51%;最高包封率为67.11%;体外累积释放曲线呈"两相"释放特征并拌随初始的"突释效应".扫描电镜观察微球表面呈皱缩表观形态结构,微球内部横断面具有孔道与孔洞,在4℃与室温(20～25 ℃)条件下密封,避光环境下性质稳定.     

聚羟基丁酯酯缓释微球的制备及性能

用溶剂蒸发法制备了以新型生物可降解材料聚羟基丁酸酯为载体、以安定为模药的缓释微球,讨论了药物与载体之比对药物含量与包封率的影响,以及制备微球条件对药物释放性能的影响;微球平均粒径为３０～４０μｍ,粒径分布在１～１．５之间,最大载药量为１９．５１％;最高包封率为６７．１１％;体外累积释放曲线呈“两相”释放特征并拌随初始的“突释效应”。扫描电镜观察微球表面呈皱缩表观形态结构,微球内部横断面具有孔道与孔     

微乳液法制备可共载水溶和脂溶药物的壳聚糖季铵盐乙醇脂质体的载药性能表征

采用微乳液法制备了可包载脂溶性和水溶性药物的羧甲基壳聚糖十八烷基季铵盐(OQCMC)乙醇脂质体,研究了OQCMC乙醇高分子脂质体的相图、粒径和电位、对药物的包封及释放能力及共载水溶性和脂溶性荧光染料后的细胞内递送能力.结果表明:OQCMC上长链季铵盐分子的取代度和共乳化剂乙醇的加入量对相图中微乳区域的面积影响不大;微乳液法可制备包载水溶性长春新碱(VCR)、脂溶性消炎痛(IMC)或二者共载的OQCMC载药微球,微球粒径为(52.40±0.55)nm,分布均匀;微乳液体系对VCR的最大载药率为22.7%,对IMC的最大载药率为20.1%,二者共载时,VCR的最大载药率为12.2%,IMC的最大载药率为10.0%;载药微球对药物具有缓控释功能.OQCMC乙醇高聚物脂质体可有效地包载荧光染料异硫氰酸荧光素FITC(水溶性)和尼罗红(脂溶性),并将二者递送到卵巢癌HO8901细胞内.     

基于壳聚糖衍生物的蛋白质药物载体材料的制备及性能

在离子液体均相体系中合成了一种新型两亲性窄分子量分布的低聚壳聚糖衍生物月桂基-琥珀酰化壳聚糖(LSCOS). 以LSCOS为载体材料, 以牛血清蛋白(BSA)为模板蛋白, 以戊二醛为交联剂, 用油包水(W/O)乳化交联法制备了包载BSA的BSA/LSCOS缓释载药微球. 通过扫描电子显微镜(SEM)、 透射电子显微镜(TEM)及紫外-可见光谱(UV-Vis)研究了BSA/LSCOS比率和戊二醛/LSCOS比率对微球的形貌结构、 包埋率、 载药率和体外药物释放特性的影响. 结果表明, 在离子液体中合成的LSCOS包覆了BSA, 形成的微球粒径约为1 μm, 微球表面随BSA用量的增加变得光滑, 随戊二醛用量的增加变得粗糙. BSA的累积释放率与BSA包载量成正比, 与交联剂添加量成反比, 因此, 可通过控制蛋白质药物的添加比率和交联剂用量来控制蛋白质药物体外释放率.     

以PHBV-PLGA为载体的硫酸庆大霉素缓释微球

以生物可降解聚羟基丁酸酯和羟基戊酸酯的共聚物(PHBV)、乙交酯和丙交酯的无规共聚物(PLGA)两种高分子作为壁材,采用复乳溶剂挥发法,制备了包裹硫酸庆大霉素(GS)的载药微球。在扫描电镜下观察到所得微球表面呈多孔状,为球形或椭圆形,粒径在20~80μm。分析结果表明,包封率在60%以上,在体外16~20 d内药物全部释放,90 d微球体外降解50%左右。     

阿司匹林-蒙脱土-壳聚糖缓释微球的制备及其体外释放性能

利用溶液法预先制备壳聚糖(Cs)-蒙脱土(MMT)复合材料(Cs-MMT),以Cs-MMT、Cs为原料,采用反相悬浮聚合法制得一种新型药物缓释体系阿司匹林-蒙脱土-壳聚糖载药微球(Asp-MMT-Cs)。采用FT-IR、SEM表征了Cs-MMT和Asp-MMT-Cs载药微球的结构及形态;设计正交实验优化了Asp-MMT-Cs载药微球的制备工艺;通过体外释放实验探讨了载药微球在不同模拟释放液中的释药规律。结果表明:所得微球球形度好,粒径分布较均匀;最优工艺制得的载药微球平均粒径为81.20μm,载药量为9.61%,包封率为76.78%。该缓释体系具有pH敏感性,更倾向于在pH较高的磷酸盐缓冲溶液中释放。     

PLA/MSM缓释微球的制备及生物活性

采用膜乳化-液中干燥法制备出担载二甲基砜(MSM)的聚乳酸(PLA)微球(PLA/MSM), 并研究了膜孔径、 搅拌转速和MSM浓度对载药微球形貌、 尺寸、 载药量、 体外释放及细胞活性的影响; 采用场发射环境扫描电子显微镜(ESEM)观察微球形貌、 尺寸及分布, 用等离子体发射光谱(ICP-AES)法检测PLA/MSM微球载药量、 包封率及体外释放, 采用ESEM观察微球内部结构, 并通过体外细胞培养和噻唑蓝(MTT)法检测MC-3T3-E1细胞的增殖能力. 研究结果表明, 膜乳化法制备的载药微球规整, 呈典型的圆球状, 表面光滑, 内部有多孔结构. 当膜孔径为5.1 μm且搅拌转速为500 r/min时, PLA/MSM微球大小更为均一; 当体系中MSM质量分数为8.6%时, 载药量可达到77.43%. 随着膜孔径减小及药物浓度的增加, 体外释放速率加快, 但初期均无明显的突释现象, 约10 d后累积释放量达到89.2%. 细胞实验结果显示, 在膜孔径为5.1 μm且MSM质量分数为8.6%的条件下, 制备的载药微球在细胞培养7 d时表现出明显的促增殖作用.     

聚[碳酸(亚丁酯-co-ε-己内酯)酯]的制备及其载药微球性能的研究

采用阴离子配位聚合方法, 合成了二氧化碳、1,2-环氧丁烷与ε-己内酯的三元共聚物: 聚[碳酸(亚丁酯-co-ε-己内酯)酯](PBCL). 并采用复相乳液(W/O/W)溶剂挥发法制备了包裹抗菌药物甲磺酸帕珠沙星的可降解微球. 对聚合物进行了FTIR, ¹H NMR, ¹³C NMR, DSC, TGA和WAXD等表征, 以及降解性能和载药微球特性的研究. 结果表明, PBCL热稳定性及降解性能优于聚碳酸亚丁酯(PBC). 所得PBCL微球球形规整、表面光滑. 大部分微球粒径在0.5～1 μm的范围内, 载药量和包封率分别达到38.21%和87.9%. 微球的体外释药性能研究在pH 7.4的磷酸缓冲溶液中进行, 释放21 d后, PBCL微球的累积释药量为84.74%, PBC微球的释药量仅为17.29%. 药物的体外释放行为符合Higuchi方程. PBCL载药微球具有长效缓释作用.     

生物降解聚酯包埋利福平缓释微球的制备及释放行为

以生物可降解乙交酯和丙交酯的无规共聚物(PLGA)为载体,将抗结核病药利福平溶解于PLGA的有机溶液中,采用通常乳化-溶剂挥发方法制备了药物缓释微球.研究了影响微球制备的工艺条件.用电子显微镜观察了微球及降解后的表面形态,测定了微球粒径及载药量,评价了载药微球的体外释放行为.结果表明,以质量分数为1%的明胶为稳定剂,制备的微球形态完整,粒径范围为10～30μm,微球中利福平的平均质量分数为24.3%.体外释药时间可以通过高分子的降解速率来调控,本实验的释药时间可以在42～84d之间调控,药物缓释达到了理想的零级动力学释放.因此,利福平PLGA微球具有显著的长效、恒量药物缓释作用.     

壳交联pH响应型PLGA载药微球的制备与研究

首先采用一次乳化法制备出PLGA[聚(乳酸-羟基乙酸)]纳米微球,并通过静电吸附将阳离子聚合物壳聚糖修饰到PLGA微球表面,然后以香草醛为交联剂对壳聚糖进行化学交联,得到一种壳交联的p H响应型纳米微球(PCV),微球粒径为(277.60±38.01)nm,表面电位为(21.60±4.51)m V.微球稳定性评价结果显示微球在24 h内粒径变化较小;流式细胞仪检测显示细胞对PCV微球的摄取量比未经修饰的PLGA微球的摄取量高;空白微球细胞毒性实验表明在空白微球浓度小于80μg/m L时细胞的存活率达93.24%.以多西他赛(DTX)为模型药物进行包载,该纳米微球DTX的载药率为7.48%,包封率为34.98%;体外药物释放实验显示,该微球在p H=5.0环境下孵育90 h的药物积累释放率达58.66%,而在p H=7.4的环境下的药物积累释放率为50.63%;此外,载DTX微球毒性试验结果表明该载药微球对A549肺癌细胞有较强的杀伤作用,其IC50值可达0.0009μg/m L.     

ICP-OES测定醋酸酯淀粉中10种元素含量

醋酸酯淀粉样品经微波消解后,采用电感耦合等离子体发射光谱（ICP-OES）法测定其中钾、钙、钠、镁、铜、铁、锌、锰、磷、镍等10种元素含量.方法线性范围宽,线性相关系数r大于0.999 4,回收率为90.0%~106.7%,RSD小于3.9%.方法具有操作简单、快速、准确、可靠等优点,在醋酸酯淀粉分析中,取得了令人满意的结果.检测结果表明：醋酸酯淀粉中含有丰富的钙元素,磷、钾、钠元素含量较丰富,含有微量的镁、铜、铁、锰、镍等元素.     

One-pot synthesis, optical property and self-assembly of monodisperse silver nanospheres

High-quality spherical silver (Ag) nanocrystals have been synthesized by using a one-pot approach, in which pre-synthesis of organometallic precursors is not required. This reaction involves the thermolysis of a mixed solution of silver acetate and n-dodecanethiol in a non-coordinating organic solvent. The size of the as-obtained Ag nanospheres can be controlled by adjusting the reaction time, reaction temperature and the amount of silver acetate added. The growth and nucleation process of the resultant Ag nanospheres have been studied by employing UV-vis absorption spectra and transmission electron microscopy (TEM) images. Furthermore, these Ag nanospheres have good self-assembly behaviors, and they are easily self-assembled into two- or three-dimensional superlattice structures due to the bundling and interdigitation of thiolate molecules adsorbed on Ag nanospheres. This one-pot synthetic procedure is simple and highly reproducible, which may be extended to prepare other noble-metal nanocrystals.     

制备核-壳结构聚合物纳米微球和空心球的原位聚合方法的普适性研究

采用原位聚合制备核-壳结构聚合物纳米微球和空心球的新方法, 利用甲基丙烯酸2-羟丙酯(HPMA)和乙酸乙烯酯(VAc)两种单体, 在类似的反应条件下, 成功地制备了以聚(ε-己内酯)(PCL)为核, 分别以交联PHPMA和PVAc为壳的纳米微球; 将微球的核酶解后, 分别得到了对应的交联PMAA空心球和交联PVA空心球. 结果表明, 原位聚合制备核-壳结构聚合物微球的新方法具有一定的普适性, 适用于单体可溶于水而生成的聚合物不溶于水的体系.     

草酸镁空心纳米结构的一步低热固相化学合成(英)

Nanostructuredmaterialsareafocusedresearchfieldduetotheirunusualpropertiesandpotentialap-plicationsrangingfrommesoscopicresearchtothede-velopmentofnanodevices[1,2].Especially,allsortsofnanoscalematerialswithspecificstructureorinter-estingmorphologyhavepro…     

Generalization of in-situ polymerization method for preparing core-shell polymeric nanospheres and hollow spheres

According to the new method of preparing core-shell nanospheres developed by our group, by using two monomers, 2-hydroxypropyl methacrylate(HPMA) and vinyl acetate(VAc), two kinds of core-shell nanospheres with poly(ɛ-caprolactone) (PCL) as the core and crosslinked poly(2-hydroxypropyl methacrylate) (PHPMA) or poly(vinyl acetate) (PVAc) as the shell were successfully prepared under similar conditions. After degrading the PCL cores of the two kinds of nanospheres by lipase, the corresponding crosslinked poly(methyl acrylic acid) hollow spheres and crosslinked poly(vinyl alcohol) hollow spheres were obtained. Results indicate that the new method we proposed for preparing core-shell polymeric nanospheres via in-situ polymerization can be generalized to a certain extent, and it is suitable for many systems provided the monomer used is soluble in water, while its corresponding polymer is insoluble in water. Translated from Chemical Journal of Chinese University, 2006, 27(9): 1762–1766 [译自: 高等学校化学学报]     

In situ formation of chitosan-cyclodextrin nanospheres for drug delivery

Chitosan-cyclodextrin nanospheres were prepared by in situ formation through Michael addition between N-maleated chitosan (NMC) and per-6-thio-β-cyclodextrin sodium salt in an aqueous medium. This facile preparation method did not involve any organic solvent and surfactant. Through adjusting the preparation conditions, the nanospheres with a relatively narrow size distribution could be obtained. The obtained nanospheres were characterized by TEM and particle size analyzer. Doxorubicin hydrochloride (DOX·HCl), a water soluble anticancer drug, was loaded in the nanospheres with a high encapsulation efficiency. The in vitro drug release showed that the release of DOX·HCl from the nanospheres could be effectively sustained. The cytotoxicity evaluation showed the drug loaded nanospheres exhibited efficient inhibition on HeLa cells.     

Synthesis and Biodegradation of St-g-poly（MMA-co-VAc） Initiated by Manganic Pyrophosphate

Methyl methacrylate (MMA) and vinyl acetate (VAc) were grafted onto corn starch with manganic pyrophosphate { [Mn(H2P2O7)3]^3- } as the initiator and water as the reaction medium, The influences of reaction conditions, including pH value, initiator concentration, monomer concentration and its composition, on percent grafting and grafting efficiency were investigated. The graft copolymer was characterized by means of IR spectroscopy, scanning electron micrograph(SEM) and ^1H NMR spectroscopy. The biodegradation experiment showed that the degradation of corn starch-g-poly(MMA-co-VAc) was mainly from starch. However,after poly VAc in the side chain was transformed into poly vinyl alcohol(PVA), both starch and the grafted side chain could be degraded completely.     

Nonaqueous synthesis of uniform polyaniline nanospheres Via cellulose acetate template

In acetone solution, uniform polyaniline (PANI) nanospheres have been successfully synthesized by using cellulose acetate (CA) as a single template, which provides the first example of uniform PANI nanospheres synthesized in nonaqueous system. Our result exhibits that the CA micelle in nonaqueous medium plays a unique role in controlling size and uniformity of PANI nanospheres. A detail formation mechanism for the uniform PANI nanospheres has been proposed. In addition, the gas sensitivity and time response of the PANI nanospheres to NH₃ gas have been investigated, which shows superior gas sensing performance even at 1 ppm of NH₃ gas. © 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2012     

Seed‐Mediated Synthesis of Single‐Crystal Gold Nanospheres with Controlled Diameters in the Range 5–30 nm and their Self‐Assembly upon Dilution

Single‐crystal gold nanospheres with controlled diameters in the range 5–30 nm were synthesized by using a facile approach that was based on successive seed‐mediated growth. The key to the success of this synthesis was the use of hexadecyltrimethylammonium chloride (CTAC) as a capping agent and a large excess of ascorbic acid as a reductant to ensure fast reduction and, thus, single crystallinity and a spherical shape of the resultant nanoparticles. The diameters of the gold nanospheres could be readily controlled by varying the amount of seeds that were introduced into the reaction system. The gold nanospheres could be produced with uniform diameters of up to 30 nm; thus, their localized surface plasmon resonance properties could be directly compared with the results that were obtained from theoretical calculations. Interestingly, we also found that these gold nanospheres self‐assembled into dimers, larger aggregates, and wavy nanowires when they were collected by centrifugation, dispersed in deionized water, and then diluted to different volumes with deionized water.     

A magnetic biomimetic nanocatalyst for cleaving phosphoester and carboxylic ester bonds under mild conditions

[Structure: see text] As a result of the unique surface structure of nanospheres, Asp and His residues supported on a 12 nm maghemite nanoparticle worked collaboratively as a biomimetic nanocatalyst for hydrolyzing paraoxon (phosphoester) and 4-nitrophenyl acetate (carboxylic ester) in Milli-Q water (pH 7.0) at 37 degrees C, without employing extremes of pH or heavy metals. Our nanocatalyst could be facilely recovered via magnetic concentration. The isolated catalyst exhibited long-term stability, showing no significant loss of its catalytic activity for repeated uses after 3 months.