壳聚糖及其衍生物在口腔疾病防治中的研究进展

壳聚糖是一种天然高分子多糖,在食品、纺织、美容、医疗等行业被广泛应用。在口腔医学领域,壳聚糖及其衍生物因多种优良的生物学性能,如抗菌性能、载药功能、再矿化性能和成骨作用等,被广泛应用于多种口腔常见疾病的预防和治疗。文中介绍了壳聚糖的生物学性能、壳聚糖常见衍生物,与壳聚糖及其衍生物在口腔疾病防治方面的最新应用研究进展。     

壳聚糖及其衍生物在医药上的应用

本文着重对壳聚糖及其衍生物的抗菌特性,降低血清胆甾醇和抑制高血压的特性及其作为肝素材料在医药上的应用进行综述,并展望了其在医药上的发展前景。     

低聚壳聚糖美拉德衍生物抑菌性能研究

本文研究了基于与葡萄糖、麦芽糖和木糖进行美拉德反应的低聚壳聚糖衍生物的抑菌性.测定低聚壳聚糖及其衍生物对大肠杆菌和金黄色葡萄球菌的抑制效果.结果显示:壳聚糖及其衍生物对金黄色葡萄球菌的抑制作用强于对大肠杆菌的抑制作用,且随着浓度增加,对两种菌的抑菌效果增强.大多数壳聚糖衍生物的抑菌效果优于壳聚糖本身,其中CG 1∶1 8 h(低聚壳聚糖的氨基与葡萄糖的羰基的物质量比为1∶1,反应8h)的抑菌效果最好,CM 1∶3 8 h(低聚壳聚糖的氨基与麦芽糖的羰基的物质量比为1∶3,反应8 h)抑菌性最差,这可能与参加反应的还原糖种类、反应物比例以及反应时间相关.     

壳聚糖及其衍生物抗肿瘤作用研究进展

壳聚糖为天然多糖甲壳素脱除部分乙酰基的产物,是自然界存在的唯一碱性多糖,无毒,可生物降解,具有免疫功能和良好的生物相容性。近年发现,壳聚糖具有抗肿瘤作用,却因其难溶于水及中性溶剂而影响其应用,壳聚糖衍生物改善了壳聚糖的这个缺点,也具有更广泛的药理作用。本文对壳聚糖及其壳聚糖衍生物在抗肿瘤方面的研究情况做了综述。     

壳聚糖及其衍生物在生物医药中的应用与研究进展

随着科学、医疗技术的不断发展,自然界中很多有用的化学物质都被提炼出来,并广泛运用于生物、医疗、美容、化学等方面,壳聚糖就是其中的一种,壳聚糖具有天然高分子的生物官能性和相容性、血液相容性、安全性、微生物降解性,这些特性使得其被各行各业广泛关注并应用。本文系统地介绍了壳聚糖极其衍生物发展史、性质、以及其生物医药中的具体应用。     

益生菌抑制致病菌作用的机制研究进展

致病菌引起的各种胃肠道疾病对人类健康造成危害,应用益生菌制剂防治致病菌感染,具有安全和减少耐药性等优点,为控制致病菌感染性疾病提供了新的途径。主要从益生菌与致病菌竞争黏附位点、与致病菌的共聚作用及其产生的抗菌物质三个方面综述益生菌抑制致病菌的作用机制。     

壳聚糖衍生物及其胶束：特性、功能化修饰和在药物传递系统中的应用

壳聚糖是一种天然多糖,具有无毒、可生物降解、生物相容性等诸多优点,但水溶性差的自身特点限制了其在药剂学中的应用,而其经合理的结构设计、修饰和优化,可获得性能良好的两亲性壳聚糖衍生物,这些衍生物在水溶液中能自组装成具有良好药物传输性能（如载药量、稳定性、刺激敏感性、靶向性等）的胶束,并被广泛应用于构建药物传递系统,以改善药物的溶解性、靶向性、生物利用度及耐药性,降低药物的毒副作用。综述壳聚糖衍生物结构对其胶束药物传输性能的影响以及壳聚糖衍生物及其胶束的功能化修饰和在药物传递系统中的应用。     

壳聚糖对植物病原细菌的抑制作用研究

本文通过测定最小抑制浓度和相对抑制率,观察了分子量和脱乙酰度对壳聚糖抑制植物病原细菌(胡萝卜软腐欧文氏菌Erwinia cartovara Var carotovara、油菜黄单孢菌绒毛草致病菌Xanthamonas campestris Pv holcicola、丁香假单孢菌黍致病变种Pseudomonas spyings Pv panici)作用的影响。结果表明：在一定范围内,随分子量和脱乙酰度的增大,壳聚糖的抑菌效果相应降低,而且各种病原细菌对不同,壳聚糖的敏感性也有很大差异。     

壳聚糖及其衍生物作为药物载体研究进展

壳聚糖是甲壳素脱乙酰化的衍生物,是自然界中唯一的碱性多糖.壳聚糖及其衍生物是一类资源丰富、可生物降解的天然聚合物,具有生物相容性、高电荷密度、无毒性和粘膜粘附性,广泛应用于生物医学和药物制剂领域.壳聚糖作为药物载体可以控制药物释放、提高药物疗效、降低药物毒副作用,可以提高疏水性药物对细胞膜的通透性和药物稳定性及改变给药途径,还可以加强制刑的靶向给药能力.本文分别从壳聚糖及其衍生物在大分子药物载体、缓控释系统及不同部位给药系统中的应用进行了综述,以说明壳聚糖及其衍生物是一种优良的药物传递载体和新型药用辅料.     

壳聚糖的结构修饰及其应用

壳聚糖是甲壳素的衍生物,其水溶性较差。为了改善其溶解性,拓宽其应用范围,根据其结构特点对其进行化学修饰,制得多种衍生物。该就其在羧基化、酰基化、烷基化、醚化等方面的修饰及其应用进行综述。     

Membrane fluidity determines sensitivity of filamentous fungi to chitosan

The antifungal mode of action of chitosan has been studied for the last 30 years, but is still little understood. We have found that the plasma membrane forms a barrier to chitosan in chitosan‐resistant but not chitosan‐sensitive fungi. The plasma membranes of chitosan‐sensitive fungi were shown to have more polyunsaturated fatty acids than chitosan‐resistant fungi, suggesting that their permeabilization by chitosan may be dependent on membrane fluidity. A fatty acid desaturase mutant of Neurospora crassa with reduced plasma membrane fluidity exhibited increased resistance to chitosan. Steady‐state fluorescence anisotropy measurements on artificial membranes showed that chitosan binds to negatively charged phospholipids that alter plasma membrane fluidity and induces membrane permeabilization, which was greatest in membranes containing more polyunsaturated lipids. Phylogenetic analysis of fungi with known sensitivity to chitosan suggests that chitosan resistance may have evolved in nematophagous and entomopathogenic fungi, which naturally encounter chitosan during infection of arthropods and nematodes. Our findings provide a method to predict the sensitivity of a fungus to chitosan based on its plasma membrane composition, and suggests a new strategy for antifungal therapy, which involves treatments that increase plasma membrane fluidity to make fungi more sensitive to fungicides such as chitosan.     

Dependence on the Preparation Procedure of the Polymorphism and Crystallinity of Chitosan Membranes

Differences in the polymorphism and crystallinity of chitosan were found in membranes prepared by different procedures when examined by X-ray diffraction measurements for four samples of chitosan differing in the degree of polymerization. When an acetic acid solution of chitosan was dried in air and then soaked in an alkaline solution (method A), both hydrated and anhydrous polymorphs of chitosan were present in the resulting membranes; the latter polymorph made chitosan insoluble in common solvents of chitosan, and its crystallinity increased with decreasing chitosan molecular weight. When a highly concentrated chitosan solution in aqueous acetic acid was neutralized with an alkaline solution (method B), no anhydrous polymorphs were detected in the membrane because of incomplete drying. When aqueous formic acid was used as the solvent, behavior basically similar to that in aqueous acetic acid was observed. In contrast, even with method A, aqueous hydrochloric acid gave a chitosan membrane having very little anhydrous crystallinity. The crystalline polymorph called “1–2”, which has been proposed to be one of four chitosan polymorphs, is considered to be a mixture of hydrated and anhydrous crystals.     

Conformational Behavior of Chitosan in the Acetate Salt: An X-Ray Study

A well-defined X-ray fiber pattern of chitosan acetate was obtained by immersing a tendon chitosan, prepared from a crab tendon chitin by a solid-state N-deacetylation, in an aqueous acetic acid-isopropanol solution at 110°C. This pattern was very similar to that of chitosan salts with some inorganic acids, such as HF, HCl, and H₂SO₄, in which chitosan chains form an 8/5 helix, indicating that chitosan acetate also take up this conformation. This information may give an influential clue to the chitosan conformation in the aqueous acetic acid solution, the most popular solvent for chitosan. However, after one month of storage of the chitosan acetate, the fiber pattern, the density and its IR spectrum changed to those of the anhydrous polymorph of chitosan, suggesting that the acetic acid was removed accompanied with water molecules from the crystal during storage and that the polymorph can be obtained not only by annealing chitosan, but also through the chitosan acetate.     

壳聚糖作为基因药物载体的研究进展

以壳聚糖及其衍生物作为基因的载体的转染效率受到许多因素的影响, 如复合物粒子大小、壳聚糖/DNA的比值、壳聚糖的分子量、脱乙酰度、转染过程中血清的浓度、介质的pH值等。对壳聚糖进行一定程度的修饰, 可以改变壳聚糖的转染效率。介绍了壳聚糖作为基因转移载体的转染条件, 转染效率和转染机制的研究情况及研究进展。     

Adhesion and growth of HUVEC endothelial cells on films of enzymatically functionalized chitosan with phenolic compounds

Human Umbilical Vein Endothelial Cell (HUVEC) growth on chitosan films and its enzymatically functionalized derivatives films with ferulic acid (FA) and ethyl ferulate (EF) was assessed by evaluating cell adhesion, morphology and cell viability. The results indicated that chitosan derivative films improved protein adsorption properties compared to chitosan films. The HUVEC cell morphology showed well attachment and spread phenotype on chitosan derivative films compared to those growing on chitosan films which did not spread and remained round. Evaluation of cell viability revealed improvement of cell adhesion on chitosan derivative films compared to chitosan film depending on the quantity of oxidized phenols grafted on chitosan. In addition, FA-/EF-chitosan films allowed almost similar cell adhesion. Furthermore, cell adhesion was increased with the film thickness. These results suggested that the oxidized phenols grafting on chitosan is a promising process to enhance cell adhesion, growth and creating useful functional biomaterials.     

Effect of abiotic factors on the antibacterial activity of chitosan against waterborne pathogens

To assess the adaptability of chitosan (from agricultural waste) as a natural disinfectant, its antibacterial activity against bacteria associated with waterborne diseases was investigated by varying such abiotic conditions, as pH and ionic strength and by adding different amounts of acid solvent, metal ions, and EDTA. Two major waterborne pathogens, Escherichia coli and Staphylococcus aureus, were examined. Results showed that organic acids with low carbon number were better solvents for chitosan than were inorganic acids. The effect of pH below 6 on the antibacterial activity of chitosan was significant. The antibacterial activity of chitosan increased with ionic strength but decreased with the addition of metal ions. The addition of Zn(2+) ions inhibited the antibacterial activity of chitosan the most, while the addition of Mg(2+) ions inhibited the antibacterial activity of chitosan the least. This was due to the chelating capacity of chitosan toward metal ions. The antibacterial activity of chitosan against E. coli was enhanced by EDTA. However, the antibacterial activity of chitosan against S. aureus was partially suppressed by EDTA. The antibacterial activity of chitosan was also dependent on its charges and solubility. The antibacterial mechanism of chitosan has currently been hypothesized as being related to surface interference. The results show that the chitosan is a potential bactericide under various environmental conditions.     

Green synthesis approach: extraction of chitosan from fungus mycelia

Chitosan, copolymer of glucosamine and N-acetyl glucosamine is mainly derived from chitin, which is present in cell walls of crustaceans and some other microorganisms, such as fungi. Chitosan is emerging as an important biopolymer having a broad range of applications in different fields. On a commercial scale, chitosan is mainly obtained from crustacean shells rather than from the fungal sources. The methods used for extraction of chitosan are laden with many disadvantages. Alternative options of producing chitosan from fungal biomass exist, in fact with superior physico-chemical properties. Researchers around the globe are attempting to commercialize chitosan production and extraction from fungal sources. Chitosan extracted from fungal sources has the potential to completely replace crustacean-derived chitosan. In this context, the present review discusses the potential of fungal biomass resulting from various biotechnological industries or grown on negative/low cost agricultural and industrial wastes and their by-products as an inexpensive source of chitosan. Biologically derived fungal chitosan offers promising advantages over the chitosan obtained from crustacean shells with respect to different physico-chemical attributes. The different aspects of fungal chitosan extraction methods and various parameters having an effect on the yield of chitosan are discussed in detail. This review also deals with essential attributes of chitosan for high value-added applications in different fields.     

Purification and characterization of chitosanase from Bacillus sp. strain KCTC 0377BP and its application for the production of chitosan oligosaccharides

For the enzymatic production of chitosan oligosaccharides from chitosan, a chitosanase-producing bacterium, Bacillus sp. strain KCTC 0377BP, was isolated from soil. The bacterium constitutively produced chitosanase in a culture medium without chitosan as an inducer. The production of chitosanase was increased from 1.2 U/ml in a minimal chitosan medium to 100 U/ml by optimizing the culture conditions. The chitosanase was purified from a culture supernatant by using CM-Toyopearl column chromatography and a Superose 12HR column for fast-performance liquid chromatography and was characterized according to its enzyme properties. The molecular mass of the enzyme was estimated to be 45 kDa by means of sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme demonstrated bifunctional chitosanase-glucanase activities, although it showed very low glucanase activity, with less than 3% of the chitosanase activity. Activity of the enzyme increased with an increase of the degrees of deacetylation (DDA) of the chitosan substrate. However, the enzyme still retained 72% of its relative activity toward the 39% DDA of chitosan, compared with the activity of the 94% DDA of chitosan. The enzyme produced chitosan oligosaccharides from chitosan, ranging mainly from chitotriose to chitooctaose. By controlling the reaction time and by monitoring the reaction products with gel filtration high-performance liquid chromatography, chitosan oligosaccharides with a desired oligosaccharide content and composition were obtained. In addition, the enzyme was efficiently used for the production of low-molecular-weight chitosan and highly acetylated chitosan oligosaccharides. A gene (csn45) encoding chitosanase was cloned, sequenced, and compared with other functionally related genes. The deduced amino acid sequence of csn45 was dissimilar to those of the classical chitosanase belonging to glycoside hydrolase family 46 but was similar to glucanases classified with glycoside hydrolase family 8.     

Synthesis of diamine maleyl chitosans, and in vitro transfection studies

Three novel diamine-modified chitosan derivatives were synthesized from N-maleyl chitosan via Michael addition reaction with 1,2-diaminoethane, 1,4-diaminobutane, and 1,6-diaminohexane, respectively. These chitosan derivatives exhibited well binding ability of condensing plasmid DNA to form complexes with size ranging from 150 to 500 nm when the chitosan derivative/DNA weight ratios were above 10. The complexes observed by scanning electron microscopy (SEM) exhibited a compact and spherical morphology. The cytotoxicity of the chitosan derivatives presented a dependence on their side-chain structures. The gene transfection experiments were evaluated in 293 T and HeLa cells. The data obtained demonstrated that the gene transfection efficiencies of these chitosan derivatives were better than that of chitosan, suggesting these chitosan derivatives as potential gene vectors in vitro.     

Chitosan-induced restructuration of a mica-supported phospholipid bilayer: an atomic force microscopy study

Chitosan has emerged as a promising material for biomedical applications. However, the effect of chitosan adsorption on the structure of model biomembrane is not known. In this study, atomic force microscopy (AFM) is employed to investigate the interaction between chitosan and mica-supported dipalmitoylphosphocholine (DPPC) bilayer. First, in situ AFM measurement indicates that nucleation of chitosan occurs around the membrane defects at the initial stage of chitosan incubation. Eventually, DPPC-chitosan binding and chitosan intermolecular association lead to chitosan aggregation on the membrane surface which is quantified by average height measurement and RMS roughness analysis. Lateral force microscopy (LFM) confirms that the adsorbed chitosan has distinct material properties. Furthermore, the trend of surface pressure-area isotherms supports the condensation of DPPC monolayer induced by chitosan in the aqueous subphase. Surface coverage and surface roughness analysis show that the extent of chitosan aggregation on the supported membrane is affected by the incubation time during long-term chitosan incubation.