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壳聚糖/乙酰半胱氨酸纳米粒子的性质及体外释药性 总被引:2,自引:0,他引:2
制备了一种基于壳聚糖/乙酰半胱氨酸偶合物(CS-NAC)的新型巯基纳米粒子并进行了结构表征, 同时对纳米粒子的黏附性、溶胀性和药物释放进行了测试. 结果表明, 纳米粒子具有较小的粒径(140~210 nm)和正的表面电位(19.5~31.7 mV), 胰岛素的载药量达到13%~42%. 这些性质随着巯基含量的变化而变化. 与壳聚糖纳米粒子相比, 巯基壳聚糖纳米粒子表现出了更强更快的黏附性质. 体外释放研究结果表明, 巯基壳聚糖纳米粒子的胰岛素释放具有pH响应性. 在pH=6.8时, 15 min即能释放58.6 %的胰岛素; 而在pH=5.4时, 24 h内仅有不到40%的胰岛素被释放. 因此, CS-NAC纳米粒子用于胰岛素的黏膜给药体系具有很好的应用前景. 相似文献
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本文采用原位聚合法制备了以四肽YPLG为模板的毛细管分子印迹整体柱,在毛细管电色谱模式下以模板分子和它的结构类似物YPGL为样品,对分子印迹聚合物的识别机理进行了研究。这两种四肽由于化学结构相似且等电点非常相近,普通的电色谱和毛细管电泳方法分离非常困难。但我们的实验表明,印迹整体柱对模板分子具有特异性识别能力,因此YPLG与YPGL之间的分离因子为1.73,分离度达3.72。实验中系统地研究了流动相中有机溶剂的含量、缓冲溶液的pH值、缓冲溶液的盐浓度以及柱温对四肽识别的影响。实验中我们观察到模板在印迹柱上具有非线性的Van’t Hoff行为,揭示可能存在多重保留机理。本研究结果表明,在毛细管电色谱模式下,分子印迹整体柱的分子识别主要决定于样品与印迹聚合物之间的氢键作用以及印迹孔穴的三维结构。 相似文献
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采用基于分子动力学理论的Forcite模拟软件包对含不同浓度的单、双空位缺陷硅烯薄膜的超晶胞体系进行优化,并对其力学性能进行了计算和分析.结果表明:随着空位缺陷浓度的增加,硅烯薄膜的拉梅常数、泊松比、体弹模量和剪切模量呈线性递减趋势,而由于空位缺陷附近键长的缩减导致硅烯薄膜"硬化"与空位缺陷浓度的增加导致硅烯晶格中硅原子密度降低,两种体制的竞争使得硅烯杨氏模量表现出先升高在降低的趋势. 相似文献
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Dual-band negative-index properties of the silver-SU-8-silver sandwich configuration, perforated with a square array of cross dipole apertures, are simulated and analyzed in the midinfrared region. The first and the second negative-index bands correspond to the (1,0) and (1,1) internal surface plasmon polariton (SPP) modes, respectively. The internal and external SPP modes acquired by the SPP dispersion relation of the metal/dielectric/metal model match well with the simulated transmission peaks. The effective parameters for the two negative-index bands are retrieved using simulated S parameters. The coupling effect between the (1,1) internal SPP mode and the localized resonance mode can be tuned by the arm length of cross dipole, which can weaken or destroy the negative electromagnetic response of the second negative-index band. The electric quadrupole mode of the second negative-index band accounts for its strong dependence on the dielectric loss of the interlayer. 相似文献
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采用矩形前沿分析法对原位聚合的对-羟基苯甲酸印迹整体柱的热力学吸附等温线进行了测定. 印迹整体柱的吸附等温线是分别以乙腈、甲醇、 四氢呋喃和含有体积分数分别为1%, 3%, 5%和7%乙酸的乙腈为流动相以及在以甲醇为流动相时柱温分别为20, 40和50 ℃的条件下测定的. 吸附等温线表明, 印迹整体柱对模板分子的吸附能力比其结构类似物(邻-羟基苯甲酸)的吸附能力强. 用双Langmuir方程对不同条件下得到的实验数据进行拟合, 得到模板分子和邻-羟基苯甲酸在印迹整体柱各种吸附位点上的饱和吸附量和键合常数, 结果表明, 流动相中乙酸含量、有机溶剂的性质和柱温对模板分子容量因子的影响比对邻-羟基苯甲酸的大, 造成印迹聚合物的选择性随条件的变化而发生了明显的改变. 相似文献
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Formulation and numerical evaluation of a novel twice-interpolation finite element method (TFEM) is presented for solid mechanics problems. In this method, the trial function for Galerkin weak form is constructed through two stages of consecutive interpolation. The primary interpolation follows exactly the same procedure of standard FEM and is further reproduced according to both nodal values and averaged nodal gradients obtained from primary interpolation. The trial functions thus constructed have continuous nodal gradients and contain higher order polynomial without increasing total freedoms. Several benchmark examples and a real dam problem are used to examine the TFEM in terms of accuracy and convergence. Compared with standard FEM, TFEM can achieve significantly better accuracy and higher convergence rate, and the continuous nodal stress can be obtained without any smoothing operation. It is also found that TFEM is insensitive to the quality of the elemental mesh. In addition, the present TFEM can treat the incompressible material without any modification. 相似文献
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Formulation and numerical evaluation of a novel four-node quadrilateral element with continuous nodal stress(Q4-CNS)are presented.Q4-CNS can be regarded as an improved hybrid FE-meshless four-node quadrilateral element(FE-LSPIM QUAD4), which is a hybrid FE-meshless method.Derivatives of Q4-CNS are continuous at nodes, so the continuous nodal stress can be obtained without any smoothing operation.It is found that,compared with the standard four-node quadrilateral element(QUAD4),Q4- CNS can achieve significantly better accuracy and higher convergence rate.It is also found that Q4-CNS exhibits high tolerance to mesh distortion.Moreover,since derivatives of Q4-CNS shape functions are continuous at nodes,Q4-CNS is potentially useful for the problem of bending plate and shell models. 相似文献