温敏性乙二醇壳聚糖水凝胶的制备及药物缓释性能

以乙二醇壳聚糖为原料, 乙酸酐为酰化剂, 通过N-乙酰化反应, 制得了新型温敏性高分子乙酰化乙二醇壳聚糖. 通过核磁共振氢谱(¹H NMR)、 傅里叶变换红外光谱(FTIR)及试管倒置法对乙酰化乙二醇壳聚糖的结构及温敏性进行了表征, 通过扫描电子显微镜(SEM)和紫外-可见分光光度计(UV-Vis)对水凝胶的微观形貌和体外药物释放性能进行了研究. 结果表明, 随着反应时间和乙酸酐与乙二醇壳聚糖氨基摩尔比的增加, 产物的乙酰度逐渐增加; 乙酰化乙二醇壳聚糖溶液具有热可逆温敏性溶胶-凝胶转变行为, 可以通过控制乙酰化乙二醇壳聚糖的乙酰度和溶液浓度, 使溶胶-凝胶转变温度处于室温至体温(25~37 ℃)之间; 乙酰化乙二醇壳聚糖水凝胶具有“高度孔隙化且孔隙之间相互连通”的结构特点, 通过控制乙酰度和溶液浓度, 可使其孔径大小处于1~40 μm范围内; 乙酰化乙二醇壳聚糖水凝胶的乙酰度为89.90%时, 质量分数为5%~7%的水凝胶对抗癌药物吉西他滨具有缓释作用, 载药凝胶的释药时间可达3~5 d. 乙酰化乙二醇壳聚糖有望在药物释放及组织工程等领域得到广泛应用.     

Facile preparation of titanium phosphate‐modified chitosan for selective capture of phosphopeptides

A facile two‐step method for preparing chitosan‐based immobilized metal ion affinity chromatography was developed. First, chitosan was phosphorylated by esterification with phosphoric acid, and then titanium was chelated onto the phosphorylated chitosan. The obtained chitosan‐based titanium immobilized metal ion affinity chromatography was ultrafine microparticles and had good dispersibility in acidic buffer. The selectivity and sensitivity were evaluated by phosphopeptide enrichment of mixtures of α‐casein and bovine serum albumin. The enriched peptides were analyzed by mass spectrum. Enrichment protocols were optimized and the optimum‐loading buffer was 80% acetonitrile with 1% trifluoroacetic acid. With α‐casein concentration as low as 2 pmol, 12 phosphopeptides were detected with considerably high intensity from the digest mixtures of α‐casein and bovine serum albumin with molar ratio of 1:200. The microparticles was also applied in real biological samples, 29 phosphoproteins containing 40 phosphorylated sites were identified from salt‐stressed Arabidopsis thaliana leaves.     

Formation of calcium carbonate films on chitosan substrates in the presence of polyacrylic acid

In this investigation, chitosan membranes with different surface average degrees of deacetylation (DA) are prepared and then are employed as the support matrix to culture calcium carbonate (CaCO₃). In the presence of high concentration of polyacrylic acid (PAA), the CaCO₃ films obtained on the surface of all chitosan films mainly consisted of vaterite, which suggests the presence of bulk PAA plays an overwhelming part in stabilizing the vaterite. As a comparison, the influences of active groups indicate that only in case of low concentration PAA the thin CaCO₃ films grown on chitosan with 8% DA mainly consisted of vaterite owing to the strong nucleation ability of -NH₂ group, whereas, for those grown on chitosan with 80% DA the CaCO₃ films mainly consisted of aragonite. A more complex scenario revealed that in the case of intermediate concentration of PAA the formed polymorphs behave as mixtures of vaterite and aragonite.     

Effect of peroxide depolymerization of chitosan on properties of chitosan sulfate particles produced from this substance

Effect of the oxidative destruction of chitosan on the rate at which a dispersed phase is formed in its dilute solutions in the presence of sulfate ions and on the composition, size and ζ-potential of submicrometer chitosan sulfate particles being formed was studied. It was found that the particle size steadily decreases as the molecular mass of chitosan becomes smaller, and the sedimentation stability of aqueous dispersions increases in the absence of surfactants. The \(\nu _{SO_4 } :\nu _{NH_2 }\) molar ratio in chitosan sulfate particles is independent of the molecular mass of chitosan and varies within the range 0.45–0.46. A pH-dependence of the sign of the ζ-potential with isoelectric point at pH 5.0 was found for particles based on destructed chitosan.     

The use of DSC curves to determine the acetylation degree of chitin/chitosan samples

The use of DSC curves is proposed as an alternative method to determine the degree of N-acetylation (DA) in chitin/chitosan samples, based in both peak area and height of the decomposition signal. Samples with DA from 74 to 16% were prepared from a chitin commercial sample and the DA was determined by ¹H NMR, ¹³C CP/MAS NMR and IR spectra. The effect of water content, heating rate, sample mass and gas flow on the DSC peaks were evaluated and optimized. Using optimized conditions a linear relationship between peak area and height with the DA could be achieved with linear correlation coefficients of −0.998 and −0.999 (n = 7), respectively. The calibration graphs were used to determine the DA of a commercial chitosan sample with relative errors ranging from 2 to 3% for both peak area and peak height, when compared with the DA determined by ¹H NMR method.     

Formation and properties of positively charged colloids based on polyelectrolyte complexes of biopolymers

Formation of colloids based on polyelectrolyte complexes (PECs) was mainly studied with synthetic polyelectrolytes. In this study, we describe the elaboration of positively charged PEC particles at a submicrometer level obtained by the complexation between two charged polysaccharides, chitosan as polycation and dextran sulfate (DS) as polyanion. The complexes were elaborated by dropwise addition of default amounts of DS to excess chitosan. Quasi-elastic light scattering was used to investigate in detail the influence of the characteristics of components (chain length, degree of acetylation) and parameters linked to the reaction of complexation (molar mixing ratio, ionic strength, concentration in polymer) on the sizes and polydispersity of colloids. Chain length of chitosan is the major parameter affecting the dimensions of the complexes, high molar mass chitosans leading to the largest particles. Variations of hydrodynamic diameters of PECs with the molar mass of chitosan are consistent with a mechanism of particle formation through the segregation of the neutral and then hydrophobic blocks of the polyelectrolyte complexed segments. Resulting particles display probably a structure constituted by a neutral core surrounded by a chitosan shell ensuring the colloidal stabilization. Such a structure was evidenced by measurements of electrophoretic mobilities revealing that the positive charge of particles was decreasing with pH, in relation with the neutralization of excess glucosamine hydrochloride moieties.     

The kinetics of chitosan depolymerisation at different temperatures

The stability (in terms of molar mass) of chitosan potentially plays an important role in its behaviour and functional properties in a wide range of applications and therefore any changes over time must be understood.The weight-average molar masses and intrinsic viscosities of chitosan solutions at different temperatures (4, 25 and 40 °C) have been investigated using size exclusion chromatography coupled to multi-angle laser light scattering (SEC-MALLS) and a “rolling ball” viscometer respectively. The weight-average molar mass (M_w) and the intrinsic viscosity ([η]) both decrease with increased storage time, although this phenomenon is more pronounced at elevated temperatures.Good correlation was found between the changes in molar mass and intrinsic viscosity with time and these parameters were used to determine the depolymerisation constant (k) and the activation energy (E_a).Knowledge of the effect of storage conditions (e.g. temperature) is important in the understanding the stability of chitosan solutions, but whether or not chitosan depolymerisation will be detrimental to its intended application will depend on the functional significance of the changes that occur.     

Biocompatible hydrogel for cartilage repair with adjustable properties

Synthesis of hydrogel at mild conditions is considered one most important challenge, especially if the hydrogel will be used for hosting bioactive materials or drugs. The procedure of hydrogel preparation should have no effect on the properties of the hosted materials. Hyaluronic acid (HA) was modified by adding dialdehyde groups to its structure to facilitate formation of hydrogel at very mild conditions. Dialdehyde HA (DHA) was prepared through oxidation of HA using sodium metaperiodate as oxidizing agent. The prepared DHA was characterized by Fourier‐transform infrared (FTIR) spectroscopy and X‐ray diffraction (XRD) and aldehyde content. A hydrogel was prepared using different chitosan/DHA molar ratio and fixed amount of glutaraldehyde at 25°C. The prepared hydrogel has tunable properties and pores size depending on the chitosan/DHA molar ratio. Sodium diclofenac was loaded on the hydrogel as a model drug. The hydrogel was characterized by FTIR spectroscopy, swelling rate, gel fraction, drug release profile, and cytotoxicity. The results obtained indicated that the properties of the prepared hydrogel, including gelling time, gel fraction, swelling, pores size, and drug release profile are highly tuned depending on the chitosan/DHA molar ratio. The drug loading efficiency was in the range of 70% to 85%. The cytotoxicity results reveal that the prepared hydrogel has a very low toxicity in presence and absence of sodium diclofenac.     

Study of bulk chain coupling reactions. III. Reaction between bisoxazolines or bisoxazlines and carboxy-terminated oligomers

2,2′-Bis(2-oxazoline) and 2,2′-bis[5,6-dihydro-(4H)-1,3-oxazine] have been used as chain coupling reagents ( CC ) and reacted in the bulk with α,ω-dicarboxy-poly(2,2′-oxydiethylene adipate) ( PS ) or with α,ω-dicarboxy-polyamide 12 ( PA ). The reactions have been followed by viscosimetry, titration of COOH groups and ¹H- and ¹³C-NMR spectroscopy. Either with the PS/CC or PA/CC systems, or with the model system dodecanoic acid ( DA )/ CC , the reactions were fast, since in most cases 80% conversion was reached after 15 min reaction. The expected DA dimer or high molar mass PA or PS polymers were obtained. No significant side reaction has been detected. The thermal stability of the resulting polymers is higher than that of starting oligomers. Due to the introduction of CC units in the chains, the crystallinity of PA/CC is slower than that of starting PA . © 1995 John Wiley & Sons, Inc.     

Preparation of gadopentetic acid-loaded chitosan microparticles for gadolinium neutron-capture therapy of cancer by a novel emulsion-droplet coalescence technique.

Biodegradable gadopentetic acid (Gd-DTPA)-loaded chitosan microparticles (Gd-microCPs) were prepared as a device for gadolinium neutron-capture therapy (Gd-NCT) by a novel emulsion-droplet coalescence technique: a water-in-oil (w/o) emulsion A containing chitosan and Gd-DTPA in droplets and a w/o emulsion B containing NaOH in droplets were mixed and stirred to solidify chitosan as a result of collision and coalescence between droplets of each emulsion. Gd-microCPs prepared by using 100% deacetylated chitosan in 25% Gd-DTPA solution were 4.1 microns (non-lyophilized) and 3.3 microns (lyophilized) in mass median diameter, and were 3.4% in gadolinium content, corresponding to 11.7% as Gd-DTPA. The particle size and gadolinium content of Gd-microCPs were not affected by Gd-DTPA concentration in the chitosan medium. However, the deacetylation degree of chitosan influenced the particle size; as the deacetylation degree of chitosan decreased, the particle size increased. The incorporated Gd-DTPA was not released entirely from Gd-microCPs in an isotonic phosphate buffered saline solution despite the high water-solubility of Gd-DTPA (less than 0.8% with every type of Gd-microCPs). These results indicated that ion-complex formation might be contributable to incorporation of Gd-DTPA. As a preliminary study, it was confirmed that the loss of gamma-ray emission by gadolinium-loading in microparticle was negligible in the thermal neutron irradiation test in vitro. These results suggested that Gd-microCPs could be a useful device for intratumoral injection into solid tumor on Gd-NCT.     

Ultrasound-assisted synthesis of ethyl hexanoate using heterogeneous catalyst: Optimization using Box-Behnken design

Ultrasound-assisted synthesis of ethyl hexanoate was studied in a solvent-free system using Amberlyst-15 as a heterogeneous catalyst. The effect of reaction parameters was evaluated by employing Box Behnken Design. Maximum conversion was obtained as 83.9% experimentally with operating temperature 60 °C, ethanol to hexanoic acid molar ratio as 3, 60% duty cycle, 11% catalyst loading, 10% molecular sieves, and 80 W input power which were optimized through one parameter at a time. The optimal conditions for maximum 86.66% conversion obtained by Box Behnken Design operated in Response Surface Methodology were 62.8 °C temperature, 3.31 ethanol to hexanoic acid molar ratio, and 51.58% duty cycle. The absence of external mass transfer resistances was proved by evaluating Mear's criterion. Thiele modulus and effectiveness factor were determined to study the influence of internal mass transfer resistance qualitatively. The kinetics of the heterogeneous reaction was modeled using Langmuir-Hinshelwood model. The activation energy was calculated as 24.61 kJ/mol.     

Preparation of electrospun chitosan/poly(vinyl alcohol) membranes

Electrospinning of chitosan from its solutions in 2% aqueous acetic acid was studied by adding poly(vinyl alcohol) (PVA) as a “guest” polymer. Properties of the chitosan/PVA solutions including viscosity, conductivity, and surface tension were measured, and effects of the polymer concentration, chitosan/PVA mass ratio and processing parameters (applied voltage, flow rate, capillary-to-collector distance) on the electrospinnability of chitosan/PVA were investigated. Analyses of scanning electron micrographs and transmission electron micrographs suggested that the chitosan/PVA ultrafine fibers were often obtained along with beads, and chitosan was located in the elctrospun fibers as well as in the beads. Uniform chitosan/PVA fibers with an average diameter of 99 ± 21 nm could be prepared from a 7% chitosan/PVA solution in 40:60 mass ratio. Results of Fourier transform infrared spectroscopy and X-ray diffraction demonstrated that there were possible hydrogen bonds between chitosan and PVA molecules, which could weaken the strong interaction in chitosan itself and facilitate chitosan/PVA electrospinnability. The electrospun chitosan/PVA membranes showed higher water uptake and would have potential applications in wound dressings.     

探索利用无机结合肽PT2(DRTSTWR)制备纳米铂晶体

实验中首先利用固定化于PET(聚对苯二甲酸己二醇酯)膜上无机结合肽PT2 (DRTSTWR)制备出铂微晶体. 然后用游离的PT2与PtCl₄在室温和pH中性环境中反应24 h, 所得产物用TEM观察, 其多数为1～2 nm呈方形和球形晶体, 经EDX分析显示晶体的元素组成中Pt远大于Cl的含量, 显然晶体不可能是PtCl₄或PtCl₂; 样品的XPS谱图中出现了结合能值为71.0 eV峰(Pt_4f标准值71.1 eV), 确认晶体为铂纳晶, 由此推断无机结合肽PT2在无细胞状态下能够作为模板仿生合成铂晶体. 继而在反应体系中加入不同浓度的壳聚糖和聚丙烯酸钠, 观察到纳米粒子的粒径和形貌随表面活性剂的加入发生了改变. 加入5倍的壳聚糖制备的铂晶体的直径在12～15.5 nm之间, 晶体排布似乎有成线状的趋势. 加入5倍的聚丙烯酸钠制备的铂晶体, 形貌更加规整, 以球形颗粒为主, 粒子直径在6～8 nm之间.     

N,N,N-trimethylchitosan iodide complexes with a weak or a strong polyacid and nanoparticles thereof

Polyelectrolyte complexes (PECs) were prepared from N,N,N-trimethylchitosan iodide (TMCh) of different molar mass and a weak polyacid-poly(acrylic acid) (PAA) or a strong polyacid-poly(2-acrylamido-2-methylpropanesulfonic acid) (PAMPS). The quaternization of the amino groups of chitosan enabled the formation of water-insoluble PECs in a broad pH range—from 3 to 12 and from 1 to 12 for TMCh/PAA and TMCh/PAMPS, respectively. Whereas the stoichiometry of the TMCh/PAA complex was pH dependant, the stoichiometry of the TMCh/PAMPS complex did not depend on pH. The stoichiometry and the yield of the complexes were influenced by the molar mass of TMCh. PEC nanoparticles were produced by mixing dilute solutions of the oppositely charged polyelectrolytes as revealed by dynamic light scattering analyses. The size of the particles was in the range of 135–924 nm and depended on the polyelectrolyte molar mass, the initial polyelectrolyte concentration, and the molar fraction of the TMCh units. Microbiological screening against Staphylococcus aureus and Escherichia coli revealed that PECs between TMCh and PAA or PAMPS have a good antibacterial effect, which is more slowly pronounced than that of the starting TMCh of different molar mass.     

Development and characterization of new insulin containing polysaccharide nanoparticles

A nanoparticle insulin delivery system was prepared by complexation of dextran sulfate and chitosan in aqueous solution. Parameters of the formulation such as the final mass of polysaccharides, the mass ratio of the two polysaccharides, pH of polysaccharides solution, and insulin theorical loading were identified as the modulating factors of nanoparticle physical properties. Particles with a mean diameter of 500 nm and a zeta potential of approximately −15 mV were produced under optimal conditions of DS:chitosan mass ratio of 1.5:1 at pH 4.8. Nanoparticles showed spherical shape, uniform size and good shelf-life stability. Polysaccharides complexation was confirmed by differential scanning calorimetry and Fourier transformed infra-red spectroscopy. An association efficiency of 85% was obtained. Insulin release at pH below 5.2 was almost prevented up to 24 h and at pH 6.8 the release was characterized by a controlled profile. This suggests that release of insulin is ruled by a dissociation mechanism and DS/chitosan nanoparticles are pH-sensitive delivery systems. Furthermore, the released insulin entirely maintained its immunogenic bioactivity evaluated by ELISA, confirming that this new formulation shows promising properties towards the development of an oral delivery system for insulin.     

O-季铵化-N-壳聚糖Schiff碱的合成及表征

对壳聚糖氨基和羟基进行化学改性,合成了水溶性双功能化壳聚糖衍生物O-季铵化-N-壳聚糖Schiff碱(O-HTCCS);用红外光谱表征了产物的结构;确定了O-HTCCS的最佳合成条件,并测定了其溶解性能.结果表明,合成O-HTCCS的最佳条件为:壳聚糖Schiff碱/缩水甘油三甲基氯化铵(GTMAc)摩尔比为1∶5;反应时间24 h;反应温度70℃.在最佳条件下合成O-HTCCS的产率为78.5%,季铵化度为89.7%.与此同时,O-HTCCS的水溶性随季铵化度的增大而提高,季铵化度达到70%以上能溶于水;且其在有机溶剂中的溶解性优于壳聚糖.     

Development and characterization of new insulin containing polysaccharide nanoparticles

A nanoparticle insulin delivery system was prepared by complexation of dextran sulfate and chitosan in aqueous solution. Parameters of the formulation such as the final mass of polysaccharides, the mass ratio of the two polysaccharides, pH of polysaccharides solution, and insulin theorical loading were identified as the modulating factors of nanoparticle physical properties. Particles with a mean diameter of 500 nm and a zeta potential of approximately −15 mV were produced under optimal conditions of DS:chitosan mass ratio of 1.5:1 at pH 4.8. Nanoparticles showed spherical shape, uniform size and good shelf-life stability. Polysaccharides complexation was confirmed by differential scanning calorimetry and Fourier transformed infra-red spectroscopy. An association efficiency of 85% was obtained. Insulin release at pH below 5.2 was almost prevented up to 24 h and at pH 6.8 the release was characterized by a controlled profile. This suggests that release of insulin is ruled by a dissociation mechanism and DS/chitosan nanoparticles are pH-sensitive delivery systems. Furthermore, the released insulin entirely maintained its immunogenic bioactivity evaluated by ELISA, confirming that this new formulation shows promising properties towards the development of an oral delivery system for insulin.     

脱氢枞氧基聚氧乙烯缩水甘油醚接枝羟乙基壳聚糖水凝胶制备及其性能

通过脱氢枞醇聚氧乙烯（10）醚（DA（EO）₁₀H）与环氧氯丙烷缩合后,再在NaOH存在下脱氯化氢得到脱氢枞氧基聚氧乙烯（10）缩水甘油醚（DA（EO）₁₀GE）,然后通过DA（EO）₁₀GE对羟乙基壳聚糖（HECTS）的接枝制备DA（EO）₁₀GE接枝羟乙基壳聚糖（DA（EO）₁₀GE-g-HECTS）,最后利用Genipin对DA（EO）₁₀GE-g-HECTS进行交联,得到DA（EO）₁₀GE-g-HECTS/Genipin水凝胶。研究结果表明：DA（EO）₁₀GE对HECTS糖单元摩尔比的增加能提高DA（EO）₁₀GE-g-HECTS的接枝度,并延长其与Genipin交联形成凝胶的时间;增加Genipin的用量可提高接枝产物与Genipin交联形成凝胶的能力;负载于DA（EO）₁₀GE-g-HECTS/Genipin凝胶中的氯霉素在人工肠液中的累积释放率与时间的关系,可以很好地用Boltzmann函数描述,且提高接枝度和降低Genipin用量有利于提高药物的最终累积释放率;低接枝度DA（EO）₁₀GE-g-HECTS经Genipin交联形成的载药凝胶,其药物释放行为符合一级动力学方程的特征。     

Carboxyl terminated polyamide 12 chain extension using a dioxazoline coupling agent

High molar mass Polyester Amide was obtained by coupling reaction of Carboxyl-Terminated Polyamide 12 (CTPA) with a dioxazoline (OO). The analysis of the experimental condition effects on the reaction conversion and the structure of the polymer obtained did not show any particular side reaction. A kinetic study comparing the reactivity of the dioxazoline used with CTPA and decanoic acid (DA) as model reactants showed the equireactivity of the two oxazoline functions and of the acid functions of the CTPA and DA. A kinetic model was proposed. The reaction rate at different temperatures and the activation energy were calculated. The evolution of the different reactant concentrations were modeled and compared with experimental data. © 1997 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 35: 3697–3705, 1997     

Microparticles based on chitosan–hyaluronic acid interpolyelectrolyte complex,which provide stability of aqueous dispersions

Turbidimetric titration and laser scattering methods were used to assess the phase behavior of mixtures of chitosan and hyaluronic acid in aqueous solutions in relation to interaction conditions. Conditions were found in which stable water dispersions with particle size of up to 573 nm can be obtained. It was found that the molar ratios and the overall concentration mode of the starting-polyelectrolyte solutions affect the particle size.