硫酸软骨素酶ABC和环磷酸腺苷缓释组织工程 支架的构建

目的:制备一种可生物降解有效安全的硫酸软骨素酶ABC(ChABC)和环磷酸腺苷(cAMP)缓释组织工程支架,使药物缓慢稳定释放,降低局部应用时对神经的刺激,促进中枢神经系统损伤后神经的修复和轴突的再生。方法:应用电纺丝技术制作的含ChABC及cAMP的聚碳酸亚丙酯及壳聚糖缓释组织工程支架,分析支架直径、载药量、包封率等参数,然后以磷酸盐缓冲液为体外释药介质观察组织工程支架的药物释放速度、药物的失活率及支架的降解速度。结果:ChABC和cAMP缓释组织工程支架在聚碳酸亚内酯质量浓度为8%、电压为10～15 kV、距离为15～20 cm时可以纺出纤维直径约3μm的平滑支架,单纯聚碳酸盐内酯纤维光滑,直径均一,壳聚糖微球光滑,聚碳酸亚内酯与壳聚糖混合后电纺丝形成的支架呈串珠样结构,其能缓慢持续释放有活性ChABC和cAMP,12 d后支架降解失重率约7%。结论:应用电纺丝方法成功制备含ChABC及cAMP的聚碳酸盐内酯及壳聚糖组织工程支架,其药物稳定释放,局部应用无神经刺激,可生物降解。     

A型肉毒杆菌毒素的壳聚糖／海藻酸钠缓释微囊研制和药物的体外释放速率研究

目的：研制包裹A型肉毒杆菌毒素的壳聚糖/海藻酸钠微囊,并测定其体外药物释放动力学。方法：采用注射器滴注法制成包裹A型肉毒杆菌毒素的壳聚糖/海藻酸钠微囊混悬液。采用高效液相色谱法测定A型肉毒杆菌毒素的标准曲线,每隔2周测定微囊所包裹的A型肉毒杆菌毒素体外释放浓度。结果：微囊形态为圆形透明颗粒状,粒径在1mm左右。用SPSS统计软件进行分析微囊中A型肉毒杆菌毒素的体外每2周释放量,显示药物累积释放量与时间之间为直线关系,基本符合药物零级释放动力学。结论：滴注法制备包裹A型肉毒杆菌毒素的壳聚糖/海藻酸钠缓释微囊制作方法简便,其药物体外释放稳定。     

VNA改性壳聚糖对阴离子染料普施安红的吸附性能

通过一步自由基聚合法,采用新壬酸乙烯酯(VNA)疏水改性壳聚糖(Cts),制得改性产物VNA-Cts。通过红外光谱和热重分析对产物进行了表征,并研究了其作为吸附剂对阴离子染料普施安红(MX-5B)的吸附能力。结果表明:VNA基团被成功地接枝到Cts主链上,VNA-Cts的最大吸附能力与Cts含量呈线性相关性,接枝率为27.2%的VNA-Cts(CtsD_27.2)具有良好的耐酸性、热稳定性和吸附染料的高效性,并且其最大饱和吸附量为1 180 mg/g;吸附模型符合Langmuir吸附等温模型和Pseudo-secongd-order动力学模型;将吸满染料的CtsD_27.2置于pH为8的NaOH溶液中,大约80%的染料会解吸附重新回到水溶液中。     

Chitosan/gelatin porous scaffolds containing hyaluronic acid and heparan sulfate for neural tissue engineering

The novel chitosan (Cs)/gelatin (Gel) porous scaffolds containing hyaluronic acid (HA) and heparan sulfate (HS) were fabricated via freeze-drying technique, and their physicochemical characteristics including pore size, porosity, water absorption, and in vitro degradation and biocompatibility were investigated. It was demonstrated that the Cs/Gel/HA/HS composite scaffolds had highly homogeneous and interconnected pores with porosity above 96% and average pore size ranging from 90 to 140?μm and a controllable degradation rate. The scanning electron microscopic images, cell viability assay, and fluorescence microscopy observation revealed that the presence of HA and HS in the scaffolds significantly promoted initial neural stem and progenitor cells (NS/PCs) adhesion and supported long-time growth in three-dimensional environment. Moreover, NS/PCs also maintained mutilineage differentiation potentials with enhanced neuronal differentiation upon induction in the Cs/Gel/HA/HS composite scaffolds in relation to Cs/Gel scaffolds. These results indicated that the Cs/Gel/HA/HS composite scaffolds were suitable for neural cells’ adhesion, survival, and growth and could offer new and important options for neural tissue engineering applications.     

Alginate/quaternized carboxymethyl chitosan/clay nanocomposite microspheres: preparation and drug-controlled release behavior

Drug-delivery systems, using natural drug carriers, have become increasingly important because of their nontoxicity and biodegradability. In this study, firstly, quaternized carboxymethyl chitosan (QCMC) was intercalated into the interlayer of organic montmorillonite (OMMT) to obtain the QCMC/OMMT nanocomposites, their structure, morphology, and thermal stability were investigated. Next, crosslinked alginate/QCMC/OMMT (AQCOM) microsphere was obtained by crosslinking with CaCl₂, and the drug-controlled release behavior was evaluated with bovine serum albumin (BSA) as model drug. The results suggested that, carboxyl groups in alginate and QCMC crosslinked with Ca²⁺, quaternary ammonium groups in QCMC or OMMT electrostatically interacted with carboxyl groups in alginate, and there was stable three-dimensional network in AQCOM microsphere. The swelling ratio of AQCOM microspheres decreased with the increase of OMMT content, the lowest one was only about 45% compared to the microsphere without OMMT of 197%. Besides, the in vitro release results for BSA indicated that the AQCOM microsphere displayed more excellent encapsulation and controlled release capacities than the microsphere without OMMT. The in vitro active cutaneous anaphylaxis test was carried out on Guinea pigs, which revealed that AQCOM microsphere did not cause anaphylaxis. Therefore, QCMC/OMMT nanocomposites from natural materials are considerably suitable to apply as drug-controlled release carriers.     

Tri-layered chitosan scaffold as a potential skin substitute

A tri-layered chitosan-based scaffold was successfully made to replicate the striation of a full-thickness skin more accurately than a single- or bi-layered scaffold, which needed weeks of co-culturing of fibroblasts and keratinocytes to achieve similar striation. Chitosan solution was freeze-dried and made into porous disks. Chitosan or chitosan–pectin in acetic acid solution was electrospun onto the chitosan disk to form a nanofibrous layer and a thin film. Examinations based on scanning electron spectroscopy showed that the scaffold was composed of a porous layer (2 mm) to simulate the dermis, a thin film (25–45 μm) to mimic the basement membrane, and a layer of nanofibers (100–200 μm) to serve as the protective epidermis. The tensile strength and modulus of the composite scaffold were significantly higher than those of the chitosan disk (p < 0.01). The composite was able to quickly absorb water and stayed intact throughout the course of the 14-day cell culture tests. The fibroblast cells seeded on both sides of the scaffolds were able to proliferate and stayed separated by the thin film.     

Development of chitosan/gelatin hydrogels incorporation of biphasic calcium phosphate nanoparticles for bone tissue engineering

Abstract

The chitosan/gelatin hydrogel incorporated with biphasic calcium phosphate nanoparticles (BCP-NPs) as scaffold (CGB) for bone tissue engineering was reported in this article. Such nanocomposite hydrogels were fabricated by using cycled freeze-thawing method, of which physicochemical and biological properties were regulated by adjusting the weight ratio of chitosan/gelatin/BCP-NPs. The needle-like BCP-NPs were dispersed into composites uniformly, and physically cross-linked with chitosan and gelatin, which were identified via Scanning Electron Microscope (SEM) images and Fourier Transform Infrared Spectroscopy (FT-IR) analysis. The porosity, equilibrium swelling ratio, and compressive strength of CGB scaffolds were mainly influenced by the BCP-NPs concentration. In vitro degradation analysis in simulated body fluids (SBF) displayed that CGB scaffolds were degraded up to at least 30?wt% in one month. Also, CCK-8 analysis confirmed that the prepared scaffolds had a good cytocompatibility through in culturing with bone marrow mesenchymal stem cells (BMSCs). Finally, In vivo animal experiments revealed that new bone tissue was observed inside the scaffolds, and gradually increased with increasing months, when implanted CGB scaffolds into large necrotic lesions of rabbit femoral head. The above results suggested that prepared CGB nanocomposites had the potential to be applied in bone tissue engineering.     

Self-aggregated nanoparticles of linoleic acid-modified glycol chitosan conjugate as delivery vehicles for paclitaxel: preparation,characterization and evaluation

A series of linoleic acid-modified glycol chitosan (LAGC) conjugates were synthesized and characterized by FTIR and ¹H NMR. The effect of the amount of linoleic acid (LA) on the physicochemical properties of LAGC conjugates was investigated. The mean diameters of three LAGC nanoparticles determined by dynamic light scattering ranged from 204 to 289 nm. The critical aggregation concentration values of LAGC conjugates in aqueous solution were 0.0148, 0.0348, and 0.0807 mg/ml, respectively. Paclitaxel (PTX) was physically loaded into the LAGC nanoparticles by a dialysis method. The drug loading content and encapsulation efficiency of PTX-loaded LAGC (PTX-LAGC) nanoparticles increased with an increasing ratio of the hydrophobic LA to hydrophilic glycol chitosan in the conjugates. PTX-LAGC nanoparticles were almost spherical in shape observed by transmission electron microscopy. In vitro release revealed that PTX release from the nanoparticles was reduced as the LA substitution degree of LAGC conjugates increased. Compared with the commercial formulation Taxol, PTX-LAGC-1 nanoparticles exhibited comparable cellular uptake and cytotoxicity against HepG2 cells in vitro. Importantly, PTX-LAGC-1 nanoparticles demonstrated the stronger antitumor efficacy against hepatic H22 tumor-bearing mice than Taxol (p < 0.05). Therefore, glycolipid-like LAGC nanoparticles had a potential as delivery vehicles for tumor therapy.     

The influence of physical structure and charge on neurite extension in a 3D hydrogel scaffold

Understanding neural cell differentiation and neurite extension in three-dimensional scaffolds is critical for neural tissue engineering. This study explores the structure-function relationship between a 3D hydrogel scaffold and neural cell process extension and examines the role of ambient charge on neurite extension in 3D scaffolds. A range of agarose hydrogel concentrations was used to generate varied gel physical structures and the corresponding neurite extension was examined. Agarose gel concentration and the corresponding pore radius are important physical properties that influence neural cell function. The average pore radii of the gels were determined while the gel was in the hydrated state and in two different dehydrated states. As the gel concentration was increased, the average pore radius decreased exponentially. Similarly, the length of neurites extended by E9 chick DRGs cultured in agarose gels depends on gel concentration. The polycationic polysaccharide chitosan and the polyanionic polysaccharide alginate were used to incorporate charge into the 3D hydrogel scaffold, and neural cell response to charge was studied. Chitosan and alginate were covalently bound to the agarose hydrogel backbone using the bi-functional coupling agent 1,1'carbonyldiimldazole. DRGs cultured in chitosan-coupled agarose gel exhibited a significant increase in neurite length compared to the unmodified agarose control. Conversely, the alginate-coupled agarose gels significantly inhibited neurite extension. This study demonstrates a strong, correlation between the ability of sensory ganglia to extend neurites in 3D gels and the hydrogel pore radius. In addition, our results demonstrate that charged biopolymers influence neurite extension in a polarity dependent manner.     

羧甲基壳聚糖复合纳米银、纳米氧化铜的制备及抑菌性研究

本研究在水热条件下利用羧甲基壳聚糖分别还原硝酸银和硫酸铜,得到稳定的羧甲基壳聚糖复合纳米银和纳米氧化铜,并测试其抑菌能力。表征测试显示,所制的纳米银为20~30 nm的球状结构,纳米氧化铜为80~100 nm的花瓣状结构,二者都均匀稳定地分布于羧甲基壳聚糖中。抑菌试验显示,不同浓度的羧甲基壳聚糖复合纳米银(A组2 mg/100 mL、B组4 mg/100 mL)的大肠杆菌抑菌率分别达到(92.6±0.8)%和(97.8±1.9)%(P<0.05),而纳米氧化铜(C组2 mg/100 mL、D组4 mg/100 mL)的大肠杆菌抑菌率分别为(89.4±1.4)%、(95.3±1.6)%(P<0.05),二者均能有效抑制大肠杆菌生长且呈现剂量依赖性。后续将进一步完善研究,使其作为抗菌材料早日应用于制备医用器具。