204 resultados para PLGA
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药物释放体系因其具有提高药物的疗效,降低药物的毒副作用,减少药物的服用次数,拓宽给药途径等特点,而成为近几年来人们研究的热点。生物可降解高分子,由于它们在体内可以降解,降解产物可以被机体吸收或代谢,不存在积累在体内的危险,因此成为药物释放体系的载体的首选材料。特别是脂肪族聚酷类高分子,在与聚乙二醇形成嵌段共聚物后,不仅具有生物可降解性,而月_大大地改善了材料与人体的生物相容性,作为药物载体材料时,延长了药物在体内的循环时间,降低了免疫响应性,引起了人们的极大兴趣。因此本论文主要是以MPEG-PLA两嵌段聚合物为药物的载体材料,详细研究了高分子量的MPEG-PLA两嵌段聚合物对紫杉醇的包裹,研究了MPEG-PLA和PLGA聚合物合金对胰岛素固体粉末的包裹,以及低分子量的MPEG-PLA的紫杉醇前药的合成、表征和由它制备而成的胶束的一些性质,取得了一些有意义的结果:1、采用改进的O/W乳液法,用高分子量的MPEG-PLA嵌段共聚物实现了对紫杉醇的纳米化包裹,并证实了聚合物的分子量对所制备的纳米微球的粒径的影响:分子量越大,粒径越大。同时发现了微球粒径越小,药物的包裹量越低。2、用扫描电镜(SEM)、光电子能谱(XPS)、差热分析(DSC)对纳米微球进行了分析和测定,结果表明,微球的尺寸在30Om-800nm范围,紫杉醇在纳米微球的表面几乎不存在,而是以无定形的状态分布在纳米微球中。3、对纳米微球中紫杉醇体外释放行为进行了侧定。它们显现出了明显的双相行为,即在初期释放速度很快,随后的释放速度变慢。同时,研究了MPEG-PLA的分子量对释放行为的影响:聚合物分子量越大,紫杉醇释放的速度就越慢。4、用固体粉末法和双乳液法对胰岛素进行了包裹,其中固体粉末法采用的是PLGA和MPEG-PLA两聚合物的混合溶液对纳米胰岛素颗粒进行了包裹,包裹率分析表明:固体粉末法对药物的包裹率高于双乳液法。所得的微球都是很好的球形,其尺寸在1-3um左右,它的剖面是核壳结构,胰岛素以晶粒的形式被包裹在微球中间。5、对固体粉末法和双乳液法制备的微球的体外释放行为进行了对比,发现由两种聚合物合金制备的微球的暴释现象得到了缓解,同时发现两种聚合物的配比不一样,其暴释缓解的程度不一样。6、以辛酸亚锡为催化剂成功地合成了低分子量的MPEG-PLA两嵌段聚合物。二经基乙酸配与过量的叔丁醇在DMAP存在下反应,成功制得了二轻基乙酸单叔丁酷。MPEG-PLA的端经基与二经基乙酸单叔丁酷在DCC参与下脱水酷化再将叔丁基去保护,便得到端梭基的MPEG-PLA。7、端基为梭基的MPEG-PLA与紫杉醇的2’-羟基或7-轻基进行了酷化反应,制备出MPEG-PLA-紫杉醇前药。8、制备了四种低分子量的MPEG-PLA-紫杉醇前药,用1H NMR和GPC进行了表征分析。紫杉醇前药中紫杉醇的含量最高可达到20%,依赖于MPEG-PLA中PLA段的长度。9、用荧光探针法考察了MPEG-PLA两嵌段聚合物和MPEG-PLA-紫杉醇前药的胶束化行为,发现前药总比相对应的两嵌段聚合物有更低的临界胶束浓度(CMC)。用透射电镜观察了胶束的形貌和尺寸大小,以及接药前后胶束尺寸的变化。发现都是很好的球状胶束,MPEG-PLA两嵌段聚合物和MPEG-PLA-紫杉醇前药胶束的平均粒径分别为25±3nm和33士Znm,说明聚合物在接药后,随着疏水部分分子量的增加,所形成的胶束粒径也增大。
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The objective of this study was to evaluate degradation behavior and the feasibility of biodegradable polymeric stents in common bile duct (CBD) repair and reconstruction. Various molar ratios of lactide (LA) and glycolide (GA) in poly(L-lactide-co-glycolide) (PLGA) were synthesized and processed into a circular tubing of similar to 10.0 mm outer diameter and a wall thickness of about 2.0 mm.
Resumo:
聚L-谷氨酸苄酯(PBLG)用体积分数为33%的HBr-醋酸溶液脱保护得到聚L-谷氨酸(PLGA).采用正交实验研究了温度、时间、溶剂及33%HBr-醋酸溶液用量在脱保护过程中对聚L-谷氨酸分子量的影响.结果表明,反应温度越高,时间越长,溶剂二氯乙酸用量越大,PBLG降解越快,得到的PLGA分子量越小;33%HBr-醋酸溶液的影响则相反,随着33%HBr-醋酸溶液用量的增加,反应体系酸性减弱,PBLG溶解度降低,肽键断裂减缓,PLGA分子量也就相对较大
Resumo:
以牛血清白蛋白(BSA)为模型药物,研究了一种新型载药微球的水包油包固体(S/O/W)乳化法.用纳米尺寸的SiO2吸附溶液中的BSA,得到粒径约为30nm的含药粒子,再用PLGA包裹含药粒子.考察不同制备条件对载药量和包封率的影响,并与传统的双乳法(W/O/W)进行了对比,发现该制备方法提高了药物的载药量(由2.5%到3.1%)和包封率(由72%到90%以上),同时提高了药物活性.
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Nanohydroxyapatite (op-HA) surface-modified with L-lactic acid oligomer (LAc oligomer) was prepared by LAc oligomer grafted onto the hydroxyapatite (HA) surface. The nanocomposite of op-HA/PLGA with different op-HA contents of 5, 10, 20 and 40 wt.% in the composite was fabricated into three-dimensional scaffolds by the melt-molding and particulate leaching methods. PLGA and the nanocomposite of HA/PLGA with 10 wt.% of ungrafted hydroxyapatite were used as the controls. The scaffolds were highly porous with evenly distributed and interconnected pore structures, and the porosity was around 90%. Besides the macropores of 100-300 mu m created by the leaching of NaCl particles, the micropores (1-50 mu m) in the pore walls increased with increasing content of op-HA in the composites of op-HA/PLGA. The op-HA particles could disperse more uniformly than those of pure HA in PLGA matrix. The 20 wt.% op-HA/PLGA sample exhibited the maximum mechanical strength, including bending strength (4.14 MPa) and compressive strength (2.31 MPa). The cell viability and the areas of the attached osteoblasts on the films of 10 wt.% op-HA/PLGA and 20 wt.% op-HA/PLGA were evidently higher than those on the other composites.
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Insulin has been encapsulated in poly(lactic-co-glycolic acid) (PLGA) microspheres by solid-in-oil-in-oil (S/O/O) emulsion technique using DMF/corn oil as new solvent pairs. To get better encapsulation efficiency, insulin nanoparticles were prepared by the modified isoelectric point precipitation method so that it had good dispersion in the inner oil phase. The resulting microspheres had drug loading of 10% (w/w), while the encapsulation efficiency could be up to 90-100%. And the insulin release from the microspheres could last for 60 days. Microspheres encapsulated original insulin with the same method had lower encapsulation efficiency, and shorter release period. Laser scanning confocal microscopy indicated the insulin nanoparticle and original insulin had different distribution in microspheres. The results suggested that using insulin nanoparticle was better than original insulin for microsphere preparation by S/O/O method.
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Nanocomposite of hydroxyapatite (HAP) surface-grafted with poly(L-lactide) (PLLA) (g-HAP) shows a wide application for bone fixation materials due to its improved interface compatibility, mechanical property and biocompatibility in our previous study. In this paper, a 3-D porous scaffold of g-HAP/poly (lactide-co-glycolide) (PLGA) was fabricated using the solvent casting/particulate leaching method to investigate its applications in bone replacement and tissue engineering. The composite of un-grafted HAP/PLGA and neat PLGA were used as controls. Their in vivo mineralization and osteogenesis were investigated by intramuscular implantation and replacement for repairing radius defects of rabbits. After surface modification, more uniform distribution of g-HAP particles but a lower calcium exposure on the surface of g-HAP/PLGA was observed. Intramuscular implantation study showed that the scaffold of g-HAP/PLGA was more stable than that of PLGA, and exhibited similar mineralization and biodegradability to HAP/PLGA at the 12-20 weeks post-surgery.
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Paclitaxel-loaded poly(ethylene glycol)-b-poly(L-lactide (LA)) (PEG-PLA) micelles were prepared by two methods. One is physical encapsulation of paclitaxel in micelles composed of a PEG-PLA block copolymer and the other is based on a PEG-PLA-paclitaxel conjugate, abbreviated as "conjugate micelles" Their physicochemical characteristics, e.g. critical micelle concentration (CMC), morphology, and micelle size distribution were then evaluated by means of fluorescence spectroscopy, scanning electron microscopy (SEM), and dynamic light scattering (DLS). The results show that the CMC of PEG-PLA-paclitaxel and PEG-PLA are 6.31 x 10(4) and 1.78 x 10(-3) g L-1, respectively. Both micelles assume a spherical shape with comparable diameters and have unimodal size distribution. Moreover, in vitro drug delivery behavior was studied by high performance liquid chromatography (HPLC). The antitumor activity of the paclitaxel-loaded micelles against human liver cancer H7402 cells was evaluated by 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) method.
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SiO2-CaO-P2O5 gel bioglass (BG) nanoparticles with the diameter of 40 nm were synthesized by sol-gel approach. The surface of BG nanoparticles was grafted through the ring-open polymerization of the L-lactide to yield poly (L-lactide) (PLLA) grafted gel particle (PLLA-g-BG). The PLLA-g-BG was further blended with poly(lactide-co-glycolide) (PLGA) to prepare the nanocomposites of PLLA-g-BG/PLGA with the various blend ratios of two phases. PLLA-g-BG accounted 10%, 20% and 40% in the composite, respectively. TGA, ESEM and EDX were used to analyze the graft ratio of PLLA-g-BG, the dispersion of nano-particles and the surface elements of the composites respectively. The rabbit osteoblasts were seeded and cultured on the thin films of composites in vitro. The cell adhesion, spreading and growth of osteoblasts were analyzed with FITC staining, NIH Image J software and MTT assay. The change of cell cycle was monitored by flow cytometry (FCM). The results demonstrated that the Surface modification of BG with PLLA could significantly improve the dispersing of the particles in the matrix of PLGA. The nanocomposite with 20% PLLA-g-BG exhibited superior surface properties, including roughness and plenty of silicon, calcium and phosper, to enhance the adhesion, spreading and proliferation of osteoblasts.
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The copolymer poly(L-lactic acid)-b-poly(L-cysteine) (PLA-b-PCys) was co-electrospun with PLGA into ultrafine fibers. The reduced glutathione (GSH) was conjugated to the fiber surfaces via disulfide bonds. The glutathione S-transferase (GST) was captured onto the GSH fibers via specific substrate-enzyme interaction between the bound GSH and GST. The captured GST was eluted with free GSH aqueous solution and lyophilized to get pure GST powders. The results show that the GSH moieties on the fiber surface retain the bioactivity of the free GSH and thus they can bind specifically with GST and the GST in solution is captured onto the fiber surface. In addition, the bound GSH is not as active as free GSH so that the captured GST can be eluted off from the fiber by free GSH aqueous solution. Based on this principle, GST itself or its fused proteins can be separated and purified very easily. The preliminary purification efficiency is 6.5 mg center dot(g(PCys))(-1). Further improvements are undertaken.
Resumo:
To improve the mechanical properties of the composites of poly(lactide-co-glycolide) (PLGA, LA/GA = 80/20) and the carbonate hydroxyapatite (CHAP) particles, the rice-form or claviform CHAP particles with 30-40 nm in diameter and 100-200 nm in length were prepared by precipitation method. The uncalcined CHAP particles have a coarse surface with a lot of global protuberances, which could be in favor of the interaction of the matrix polymer to the CHAP particles. The nanocomposites of PLGA and surface grafted CHAP particles (g-CHAP) were prepared by solution mixing method. The structure and properties of the composites were subsequently investigated by the emission scanning electron microscopy, the tensile strength testing, and the cell culture. When the contents of g-CHAP were in the range of 2-15 wt %, the PLGA/g-CHAP nanocomposites exhibited an improved elongation at break and tensile strength. At the 2 wt % content of g-CHAP, the fracture strain was increased to 20%) from 4-5% for neat PLGA samples. Especially at g-CHAP content of 15 wt %, the tensile strength of PLGA/g-CHAP composite was about 20% higher than that of neat PLGA materials. The tensile moduli of composites were increased with the increasing of filler contents, so that the g-CHAP particles had both reinforcing and toughening effects on the PLGA composites. The results of biocompatibility test showed that the higher g-CHAP contents in PLGA composite facilitated the adhesion and proliferation properties of osteoblasts on the PLGA/g-CHAP composite film.
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Self-assembling of novel biodegradable ABC-type triblock copolymer poly(ethylene glycol)-poly(L-lactide)-poly(L-glutamic acid) (PEG-PLLA-PLGA) is studied. In aqueous media, it self-assembles into a spherical micelle with the hydrophobic PLLA segment in the core and the two hydrophilic segments PEG and PLGA in the shell. With the lengths of PEG and PLLA blocks fixed, the diameter of the micelles depends on the length of the PLGA block and on the volume ratio of H2O/dimethylformamide (DMF) in the media. When the PLGA block is long enough, morphology of the self-assembly is pH-dependent. It assembles into the spherical micelle in aqueous media at pH 4.5 and into the connected rod at or below pH 3.2. The critical micelle concentration (cmc) of the copolymer changes accordingly with decreasing solution pH. Both aggregation states can convert to each other at the proper pH value. This reversibility is ascribed to the dissociation and neutralization of the COOH groups in the LGA residues. When the PLGA block is short compared to the PEG or PLLA block, it assembles only into the spherical micelle at various pH values.
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Polyelectrolyte complexes (PECs) were prepared by mixing aqueous solutions of chitosan (CS) and poly(L-glutamic acid) (PLGA) at various pH. It was found that the stoichiometry of the PECs depends on pH.An investigation of the PECs using Fourier transform infrared spectroscopy proved that the formation of the complexes is due to electrostatic interaction between –NH3 + groups of CS and –COO− groups of PLGA. The solid PECs were characterized using wide-angle X-ray diffraction, which suggested that a strong interaction occurs between the two polymers at pH = 4 or 5 and relatively weak interaction at pH = 3. These results were further confirmed by thermogravimetric analysis data. Transmission electron microscopy showed that the complexes have a spherical shape. The effect of ionic strength on the size of the PECs was also studied using dynamic light scattering. It was found that the size of the PECs is dependent on pH.
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以生物可降解乙交酯和丙交酯的无规共聚物 ( PL GA )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~ 30 μm,微球中利福平的平均质量分数为 2 4 .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 4 2~84 d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 PL GA微球具有显著的长效、恒量药物缓释作用.
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Advances in tissue engineering require biofunctional scaffolds that can provide not only physical support for cells but also chemical and biological cues needed in forming functional tissues. To achieve this goal, a novel RGD peptide grafted poly(ethylene glycol)-b-poly(L-lactide)-b-poly(L-glutamic acid) (PEG-PLA-PGL/RGD) was synthesized in four steps (1) to prepare diblock copolymer PEG-PLA-OH and to convert its -OH end group into -NH2 (to obtain PEG-PLA-NH2), (2) to prepare triblock copolymer PEG-PLA-PBGL by ring-opening polymerization of NCA (N-carboxyanhydride) derived from benzyl glutamate with diblock copolymer PEG-PLA-NH2 as macroinitiator, (3) to remove the protective benzyl groups by catalytic hydrogenation of PEGPLA-PBGL to obtain PEG-PLA-PGL, and (4) to react RGD (arginine-glycine-(aspartic amide)) with the carboxyl groups of the PEG-PLA-PGL. The structures of PEG-PLA-PGL/RGD and its precursors were confirmed by H-1 NMR, FT-IR, amino acid analysis, and XPS analysis. Addition of 5 wt % PEG-PLA-PGL/RGD into a PLGA matrix significantly improved the surface wettability of the blend films and the adhesion and proliferation behavior of human chondrocytes and 3T3 cells on the blend films. Therefore, the novel RGD-grafted triblock copolymer is expected to find application in cell or tissue engineering.
