低分子量N,O-羧甲基壳聚糖的合成及吸湿保湿性能

采用不同反应温度、反应时间和低分子量壳聚糖与氯乙酸摩尔比,在非均相反应体系中合成了不同取代度的低分子量N,O-羧甲基壳聚糖。当反应温度为60°C,反应时间为4h,低分子量壳聚糖与氯乙酸投料比为1∶1.5时,目标产物的取代度可达71%。吸湿保湿性能测定表明:取代度越大,低分子量N,O-羧甲基壳聚糖的吸湿保湿性越好,在相对湿度为81%,取代度从27%增大到71%时,其吸湿性从32.14%增大到37.27%,保湿性从310.72%增大到348.69%。     

羧甲基壳聚糖的取代度及保湿性

吸湿性;分子量;羧甲基壳聚糖的取代度及保湿性     

电导滴定法同时测定羧甲基壳聚糖的取代度、脱乙酰度和-COONa分布系数

<正>羧甲基壳聚糖是壳聚糖的重要水溶性衍生物之一,具有良好的保湿性、乳化性、成膜性、抗菌性、络合性和安全无毒性等优点,是一种在工业、农业、食品、环保和医药等领域有广泛应用的两性醚聚合物[1-3]。取代度(DS)和脱乙酰度(DD)是影响羧甲基壳聚糖质量和化学性质的两个重要参数,-COONa型体分布系数则是决定其水溶性的另一     

新型载药壳聚糖季铵盐的合成、结构与性能

通过羧甲基壳聚糖接枝二甲基十八烷基环氧丙基氯化铵, 制备了一系列不同取代度和分子量的羧甲基壳聚糖十八烷基季铵盐(QACMC). 用傅立叶变换红外(FTIR)光谱、核磁共振谱(1H-NMR)、X射线衍射(XRD)谱、差式扫描量热法(DSC)等对其分子结构、结晶和热性能进行研究, 同时研究QACMC的吸湿保湿性能, 并与透明质酸(HA)、壳聚糖(chitosan)和羧甲基壳聚糖(CMC)进行比较. 结果表明, QACMC具有较好的结晶性和热稳定性, 结晶度可达72.3%; 其吸湿保湿性低于透明质酸(HA)和羧甲基壳聚糖, 而受季铵基团取代度和QACMC分子量的影响, 羧酸盐和季铵盐两种亲水基团对QACMC吸湿性的影响不具有协同作用; QACMC对亲脂性药物盐酸米诺环素的载药率可达10.9%(质量分数), 远高于壳聚糖和羧甲基壳聚糖.     

壳聚糖季铵化衍生物的吸湿性与保湿性

壳聚糖季铵化衍生物的吸湿性与保湿性许晨，卢灿辉（福建师范大学高分子研究所福州３５０００７）关键词壳聚糖季铵盐，壳聚糖衍生物，吸湿性，保湿性壳聚糖是从虾、蟹等废弃甲壳中提取得到的一种生物活性物质［１，２］，由于其特有的直链聚阳离子结构，成膜附于角蛋白与...     

低分子量N-羧丁酰壳聚糖的合成及其吸湿保湿性

低分子量N-羧丁酰壳聚糖的合成及其吸湿保湿性;低分子量壳聚糖;低分子量N-羧丁酰壳聚糖;吸湿性;保湿性     

羧甲基壳聚糖基生物医用材料降解代谢行为的研究进展

作为一种水溶性多糖高分子材料,羧甲基壳聚糖(carboxymethyl chitosan, CMCTs)具有优异的生物相容性和生物降解性以及保湿、止血、抗菌、可吸收等一系列优良的功能特性,因而被广泛应用于医工交叉领域。羧甲基壳聚糖进入体内后,在酶、氧、微生物、水等环境适宜时能够被降解,并经吸收、代谢、排泄。其体内降解速率主要取决于材料的尺寸、脱乙酰度、取代度、分子量等。了解羧甲基壳聚糖在动物体内的降解代谢行为,对羧甲基壳聚糖在转化过程中的质量控制和临床应用至关重要。然而就目前而言,羧甲基壳聚糖在生物体内降解代谢的影响因素及其体内吸收、分布、代谢、排泄规律缺乏系统性总结,这一现状从基础层面严重制约了其在生物医药领域的进一步发展。基于上述问题,本文对近年来羧甲基壳聚糖基生物医用材料的降解、代谢相关研究进行梳理和总结,重点阐述了羧甲基壳聚糖作为可降解材料的生物学特性、降解方式、代谢过程等,系统揭示羧甲基壳聚糖体内降解、代谢的规律,并对植入物尺寸、脱乙酰度、取代度、分子量、交联度及成分比例等影响羧甲基壳聚糖降解速率的主要因素进行归纳,以期为羧甲基壳聚糖基生物医用材料的研发和转化研究提供参考。     

N-烷基壳聚糖的合成及其溶致液晶行为

合成了一系列具有不同取代基(甲基、乙基、丙基、丁基)的壳聚糖衍生物——N 烷基壳聚糖,通过控制反应物摩尔比获得了一系列不同取代度的产物.不同取代基及不同取代度的衍生物均具有溶致液晶性,考察了同一碳链不同取代度和相近取代度不同碳链长度的衍生物对其液晶临界行为的影响.结果表明：同一碳链长度时,取代度对临界浓度的影响不大;而当取代度相近时,随着碳链长度增加,临界浓度也随之增大.此结果与Onsager和Flory的刚性棒理论相符.粉末X射线衍射实验进一步证实了这一结果.     

烷基化改性壳聚糖制备条件对酚类化合物吸附的影响

采用脂肪醛与壳聚糖反应生成Schiff's碱,再用NaBH4还原制备了N-烷基化壳聚糖衍生物. 用元素分析测定了其取代度. 考察了不同烷基化条件对庚醛改性壳聚糖取代度和吸附性能的影响. 结果表明,反应时间、醛/壳聚糖配比和反应温度等因素影响烷基化壳聚糖的取代度. 在n(醛)∶ n(壳聚糖)=4∶ 1、反应温度为100 ℃和反应时间为8 h条件下,庚醛改性壳聚糖的取代度趋于最大值,取代度的增加有利于改性壳聚糖对2,4-二氯酚的吸附. 不同链长脂肪醛改性壳聚糖对酚的吸附影响结果表明,随着烷基化链长的增加,改性壳聚糖产物对酚的吸附量增加,但链长超过7个C时,吸附量反而下降.庚醛改性壳聚糖的吸附效果最好.     

羟丙基三甲基氯化铵壳聚糖制备的可控性研究

用壳聚糖与缩水甘油三甲基氯化铵反应制备羟丙基三甲基氯化铵壳聚糖,所得产物的结构受壳聚糖分子量和脱乙酰度、反应温度、反应时间、壳聚糖与缩水甘油三甲基氯化铵投料比的影响。实验结果表明：随着反应温度升高,羟丙基三甲基氯化铵壳聚糖的取代度增加,在70～80℃达最大;反应时间增加,取代度增加,产物分子量降低。缩水甘油三甲基氯化铵与壳聚糖比例达3：1前取代度随比例升高而增加。脱乙酰度和分子量越大的壳聚糖其季铵盐取代度越高。控制反应温度在30～90℃,反应时间3～10h,投抖比为1：1～4：1,可以得到取代度15％～909／6,分子量1万到100万的羟丙基三甲基氯化铵壳聚糖。     

羟丙基三甲基氯化铵壳聚糖的制备及其吸湿、保湿性能

抑菌活性;羟丙基三甲基氯化铵壳聚糖的制备及其吸湿、保湿性能     

Novel 2-Hydroxypropyltrimethyl Ammonium Chitosan Derivatives: Synthesis,Characterization, Moisture Absorption and Retention Properties

Recent years have seen a steady increase in interest and demand for the use of humectants based on biodegradable natural polymers in many fields. The aim of this paper is to investigate the moisture absorption and retention properties of 2-hydroxypropyltrimethyl ammonium chitosan derivatives which were modified by anionic compounds via ion exchange. FTIR, ¹H NMR, and ¹³C NMR spectroscopy were used to demonstrate the specific structures of chitosan derivatives. The degrees of substitution for objective products were calculated by the integral ratio of hydrogen atoms according to ¹H NMR spectroscopy. Meanwhile, moisture absorption of specimens was assayed in a desiccator at different relative humidity (RH: 43% and 81%), and all target products exhibited enhanced moisture absorption. Furthermore, moisture retention measurement at different relative humidity (RH: 43%, 81%, and drier silica gel) was estimated, and all target products possessed obviously improved moisture retention property. Specifically, after 48 h later, the moisture retention property of HACBA at 81% RH was 372.34%, which was much higher than HA (180.04%). The present study provided a novel method to synthesize chitosan derivatives with significantly improved moisture absorption and retention properties that would serve as potential humectants in biomedical, food, medicine, and cosmetics fields.     

甲壳素类液晶高分子的研究Ⅵ.邻苯二甲酰化壳聚糖中酰胺酸取代度对液晶性的影响

通过控制不同反应时间和邻苯二甲酸酐 壳聚糖的摩尔比制备不同取代度的邻苯二甲酰化壳聚糖(PHCS) .用FTIR研究了反应机理和产物结构 ,观察到PHCS含两类取代即酰胺酸取代和酰亚胺取代 .反应时间较短时主要为前者 ,取代度表示为DS1 ;反应时间较长时主要为后者 ,取代度表示为DS2 .对PHCS在二氯乙酸 (DCA)中的液晶行为观察 ,结果表明 ,PHCS的临界浓度随DS1 的增加而显著增加 .DS1 对PHCS临界浓度的影响明显大于DS2 的影响 .基本上为酰胺酸取代的PHCS的临界浓度高于溶解度 ,以至于观察不到     

Synthesis and characterization of amphiphatic carboxymethyl-hexanoyl chitosan hydrogel: water-retention ability and drug encapsulation

Carboxymethyl-hexanoyl chitosan (NOCHC) amphiphatic hydrogel with excellent water-absorption and water-retention abilities under neutral conditions was successfully synthesized for the first time and then employed as a carrier for delivering amphiphatic agents. NOCHC is a water-soluble chitosan derivative bearing the carboxymethyl (hydrophilic) group and the hexanoyl (hydrophobic) group, which was synthesized using N,O-carboxymethyl chitosan (NOCC) as the starting precursor. Water-absorption ability (W(c)), water-retention ability, and drug encapsulation efficiency of the NOCHC hydrogel were investigated in terms of the degree of carboxymethyl and hexanoyl substitution. It was found that the amount of moisture uptake was dependent on the relative humidity as well as degree and nature of such substitution. The hexanoyl substitution affected significantly the water-absorption ability by altering the number of water-binding sites and the state of water under low humidity and the fully swollen state, respectively. In addition, the presence of hydrophobic hexanoyl substitution significantly retards water mobility during deswelling, causing better water-retention ability. Moreover, compared with that of pristine chitosan and NOCC, the encapsulation efficiency of ibuprofen (partially hydrophobic agent) was significantly enhanced with the incorporation of the hexanoyl group. These results demonstrate that the newly developed NOCHC amphiphatic hydrogel showed enhanced water-absorption ability, water-retention ability, and amphiphatic drug encapsulation efficiency compared with NOCC and chitosan.     

N,N-Dilauryl Chitosan：Synthesis and Surface Pressure-area Isotherm

With sodium dodecyl sulfonate(SDS) as the phase transferring catalyst, N,N-Dilauryl chitosans with a high degree of alkyl group substitution were prepared and characterized by means of FTIR, ^1H NMR and elemental analyses. The results indicate that the average degree of alkyl group substitution on the chitosan increases with decreasing the molecular weight of the chitosan. The fully N,N-dilaurylated chitosan was found to be dissolvable in chloroform. The collapsed pressures of the samples derived from chitosan with 3000,5000 and 10000 dalton are 47.6, 48. 2 and 51.0 mN/m, respectively. The surface area occupied by the monomer unit(glucosamine) of all. those samples is 0:6 nm^2.     

阳离子改性壳聚糖的合成工艺

弱碱性条件下,在壳聚糖（CTS）上引入2-羟丙基三甲基氯化铵（CTA）基团,使其阳离子化。采用正交试验通过测定合成产物的取代度确定其最佳合成条件,再用红外光谱对产物结构进行表征。结果表明：CTS/CTA质量比=1∶5,溶胀时间60 min,碱化温度35℃,反应温度60℃,反应时间9 h为该工艺的优化条件,在此条件下合成...     

邻苯二甲酰化壳聚糖的合成与溶致液晶表征

从全脱乙酰化壳聚糖出发,在室温下合成了一系列不同取代度的邻苯二甲酰化壳聚糖(PhCS),由于反应条件温和,产物未发生进一步的酰亚胺化.X射线电子能谱(XPS)被用来测定PhCS的取代度.测定结果表明在N上和O上均发生取代,N上反应的取代度随酸酐用量的增加基本保持不变(0.26±0.03),而O上的取代度却不断变大(0.01～1.54),合成产物的总取代度为0.26～1.81.邻苯二甲酰化壳聚糖可溶解于普通的有机溶剂,如DMSO、二氯乙酸和甲酸,并形成溶致液晶.测定了PhCS在这些溶剂中的临界浓度(c),结果表明c基本上不受取代度变化的影响.     

Synthesis and Characterization of a Novel Liquid Crystalline Chitin — Quaternary Ammonium Chitosan Salt

N-Butyl chitosan(NBCS) derivatives were prepared by introducing butyl groups into the amine groups of chitosan via Schiff base intermediates. The quaternization of NBCS was carried out by using ethyl iodide to produce water-soluble cationic polyelectrolytes. The degree of the substitution of the products was measured by means of the electron spectroscopy for a successful chemical analysis. The quaternary ammonium chitosan salt(QACS) was proved to be a novel cholesteric liquid crystalline chitin, by means of the polarized optical microscopy and the circular dichroism spectropolarimetry. The critical mass fraction of the QACS/formic acid solution forming a lyotropic liquid crystal phase was 50%, which was almost the same as that of the NBCS/formic acid solution, but much hiuher than that of the chitosan in the same solvent.