透明质酸的制备及其应用

对透明质酸的制备及其在化妆品和医药领域中的应用进行了综述。透明质酸（hyaluronic acid,HA),又名玻璃酸,是一种大分子酸性粘多糖,广泛地存在于生物体的结缔组织中。1934年美国Meyer等^[1]首先从牛眼玻璃体中分离出该物质,Kendell等于1937年从细菌体内提取到HA。此后,人们对HA的分布,生理作用,化学结构,理化性质,制备工艺及其在医疗和化妆品方面的应用进行了广泛深入的研究。目前,它主要应用于临床治疗,诊断和化妆品基质等方面。据报道^[2],HA在国际市场上的价格为2000－100000美元／kg,1985年HA在国际市场上的总销售额为1亿美元,到1990年已达2亿多美元。我国从80年代开始研究HA的分离纯化制备工艺和临床应用^[3],90年代初已有HA制剂作为新药上市^[4],生产方法由提取法发展到微生物发酵法^[3],现将HA性能,用途和生产情况综述如下。     

煤炭腐植酸的温度滴定

温度滴定(thermometric titration)又称量热滴定(calorimetric titration),已应用于土壤有机质及高分子电解质等的研究。水体及土壤腐植酸(HA)的溶液热化学研究中亦有应用。但迄今未见在煤炭HA研究方面的报道。作者在应用电化学分析法对风化煤硝酸氧解产物(NHA)的酸性功能团进行表征的基础上,试图采用这一方法对HA酸性功能团含量、性质及热力学参数——△H_n(中和热)、△Ha(电离热)、△S_a(电离熵)等作进一步研究。同吋对热化学方法在HA化学研究中的应用作一些初步探讨。     

土壤胡敏酸的^13C核磁共振研究

胡敏酸(HA)是土壤有机质的重要组分,其结构性质与土壤形成和肥力特性有密切关系,长期以来一直是土壤化学研究的难点和重点之一。NMR是研究HA结构的有效手段。自Bar-ton和Schnitzer(1963)首次用~1H NMR研究土壤有机质以来,国外已先后应用~1H、~(13)C NMR和CP-MAS-~(13)C NMR等对土壤及其它来源的HA进行了许多研究,并取得引人注目的进展。但在国内,这方面研究还刚刚开始。本文应用~(13)C NMR方法对东北几种主要耕作土壤以及泥炭和猪粪的HA进行了结构表征,为土壤腐殖酸化学的基础研究提供了资料。     

腐植酸高吸水性树脂研究进展

腐植酸（HA）是土壤腐殖质的主要成分,含有多种功能基团。随着HA基础和应用研究的不断深入,将具有反应活性和生物活性的HA引入到高吸水性树脂中,既能发挥HA改良土壤、增效化肥、刺激生长、增强抗逆和改善品质的功效,又可改善高吸水性树脂的吸水和耐盐性能,同时大幅度降低高吸水性树脂的制备成本。本文综述了近年来HA高吸水性树脂的...     

透明质酸的改性及临床应用

透明质酸具有极高的保湿性、粘弹性、润滑性、生物相容性和生物降解性,在医药、组织工程及临床医学中得到广泛应用。但天然HA稳定性差,对强酸、强碱、热及透明质酸酶敏感等缺陷限制了其在临床上的应用,因此改性HA的研究越来越受到关注。本文综述了近年来国内外采用交联、酯化、复合／共聚等方法对HA的改性研究,介绍了HA及衍生物在眼科...     

羟基磷灰石微球的制备、应用和功能化

羟基磷灰石(HA)是人体和动物骨骼的主要无机矿物成分。近年来,因HA具有特殊的表面特性和理化性能,良好的生物相容性、生物活性和骨传导作用,制备各种形态的HA材料成为从事生物、医学和材料的科研人员的研究重点。本文首先介绍了HA微球的制备方法,重点讨论了以聚合物为软模板以及用各种球形材料作为硬模板合成HA微球的制备方法,列出了不同方法制备HA微球的直径、孔径、比表面等各种性能参数。由于HA微球具有比表面积大、流动性好、质量轻、强度大,注射性能好,团聚能力低等HA块材不具有的特点,其在载体、骨修复材料、环境保护和色谱分离上有广泛的应用。针对HA微球在应用过程中遇到的问题,可采用表面改性或包覆、掺杂和将HA分散在其他基体中等措施对HA微球进行功能化修饰。HA 微球在控释载体、蛋白质分离以及细胞支架等方面具有极大的应用前景。     

透明质酸的改性及在生物医用材料领域的应用研究

透明质酸(HA)是人体内最为常见的一种粘多糖,具有优良的生物相容性和可降解性,可广泛应用于药物输送、皮肤填充材料、组织工程、药物载体和3D仿生学等方面,是当前生物医用材料领域的研究热点之一。HA具有独特的结构使其显示出特定的物理化学性质,可通过物理或化学方法修饰,赋予其新功能和新应用。本文从HA的分子结构出发,重点综述了HA的官能团羧基、羟基和乙酰胺基的化学改性和物理改性,主要包括羧基的酰胺化反应和酯化反应,羟基与环氧化物的开环反应、与有机硫化物的反应、酯化反应、与卤化物的反应和氧化反应,以及HA脱乙酰基反应;介绍了HA在生物医用材料领域的应用,并对其前景进行展望。     

HDEHP萃取钙的动力学研究

近几年来萃取化学基础理论方面的研究不断深入,在广泛的热力学研究的基础上,萃取动力学的研究也日益增多。前文对HDEHP(二-(2·乙基已基)磷酸,用HA表示)萃钙的平衡与机理进行了研究,本文拟对Ca²⁺,NO₃⁼/HDEHP-萃体系萃取过程动力学加以探讨。     

可降解自固化类骨磷灰石支架的研究

0引言一直以来,钙磷生物材料如羟基磷灰石(hy-droxyapatite,HA)由于其成份与骨的无机成份相似,具有良好的生物相容性,作为骨修复材料引起了人们广泛的兴趣。磷酸钙骨水泥是一类可在生理条件下自固化的非陶瓷型类HA人工骨材料,这种由磷酸钙骨水泥(calcium phosphate cement,CPC)转变而成的HA,与天然骨磷灰石有类似的组成结构,植入人体后可参与新陈代谢,促进骨组织生长[1,2]。一些研究显示,CPC具有成骨活性和生物降解性,在体内被吸收的同时可引导新骨的生成,从而可克服自体骨、磷酸三钙陶瓷因吸收降解过快造成的局部缺陷以及陶瓷型HA长…     

Wittig反应合成共轭双金属钌配合物

共轭有机分子的光电性质已被广泛研究,在分子材料领域,一些器件已成功地利用了其所具有的光电功能.由于发展具有新颖性质材料的需要,近年来对共轭金属有机体系的合成、表征及材料性质的研究产生了巨大的兴趣.     

基于透明质酸的刺激响应纳米给药系统的研究进展

透明质酸(Hyaluronic acid, HA)是一种天然多糖,具有良好的生物相容性和生物降解性,利用 HA 构建的纳米载体自身就具有肿瘤靶向功能,可以作为抗癌药物载体将药物传递到肿瘤细胞内从而实现精准到达病患处。近年来透明质酸在应用于肿瘤靶向给药系统中的关注越来越多,成为了靶向治疗肿瘤的一大研究热点。基于透明质酸的基本特性和肿瘤靶向的生理学基础,在不同的刺激响应下,透明质酸型纳米给药系统能将药物集中释放于肿瘤的微环境内,更好地杀死肿瘤细胞,同时避免其他正常的组织受到药物损害。本文主要综述了透明质酸型纳米药物输送系统在各种刺激响应下释放药物的最新研究进展。     

Characterization of Composite Networks Made of Type I Collagen,Hyaluronic Acid and Decorin

Summary: To ultimately assess the ability of macromolecular medicines e.g. liposomes, non viral gene delivery systems, to penetrate one of the least studied physiological barriers, the extracellular matrix (ECM), composite networks made of different ECM components i.e. type I collagen, hyaluronic acid and a proteoglycan, decorin, were prepared. These composite networks were characterized by rheology, Confocal Reflection Microscopy, Fluorescence Recovery After Photobleaching and Transmission Electron Microscopy. While being at the low end of its physiological concentration, collagen appears to be the backbone of the composite networks as it provides the elastic modulus. On the other hand, 15 kDa and 1.1 MDa hyaluronic acid, when present at physiological levels interpenetrate the collagen network. When approaching their overlap concentration, hyaluronic acid chains lead to an increase of the population of collagen fibrils. Finally, while decorin increased the population of fibrils in pure collagen networks, its role in presence of hyaluronic acid remains unclear as it does not alter the diameter of fibrils nor their population.     

Capillary electrophoresis of complex natural polysaccharides

Complex natural polysaccharides, glycosaminoglycans (GAGs), are a class of ubiquitous macromolecules that exhibit a wide range of biological functions and participate and regulate multiple cellular events and (patho)physiological processes. They are generally present either as free chains (hyaluronic acid and bacterial acidic polysaccharides) or as side chains of proteoglycans (PGs; chondroitin/dermatan sulfate, heparin/heparan sulfate, and keratan sulfate) and are most often found in cell membranes and in the extracellular matrix. The recent emergence of modern analytical tools for their study has produced a virtual explosion in the field of glycomics. CE, due to its high resolving power and sensitivity, has been useful in the analysis of intact GAGs and GAG-derived oligosaccharides and disaccharides affording concentration and structural characterization data essential for understanding the biological functions of GAGs. In this review, novel off-line and on-line CE-MS and MS/MS methods for screening of GAG-derived oligosaccharides and disaccharides will be discussed.     

Elastin-Hyaluronan Bioconjugate as Bioactive Component in Electrospun Scaffolds

Hyaluronic acid or hyaluronan (HA) and elastin-inspired peptides (EL) have been widely recognized as bioinspired materials useful in biomedical applications. The aim of the present work is the production of electrospun scaffolds as wound dressing materials which would benefit from synergic action of the bioactivity of elastin peptides and the regenerative properties of hyaluronic acid. Taking advantage of thiol-ene chemistry, a bioactive elastin peptide was successfully conjugated to methacrylated hyaluronic acid (MAHA) and electrospun together with poly-D,L -lactide (PDLLA). To the best of our knowledge, limited reports on peptide-conjugated hyaluronic acid were described in literature, and none of these was employed for the production of electrospun scaffolds. The conformational studies carried out by Circular Dichroism (CD) on the bioconjugated compound confirmed the preservation of secondary structure of the peptide after conjugation while Scanning Electron Microscopy (SEM) revealed the supramolecular structure of the electrospun scaffolds. Overall, the study demonstrates that the bioconjugation of hyaluronic acid with the elastin peptide improved the electrospinning processability with improved characteristics in terms of morphology of the final scaffolds.     

Effect of hyaluronic acid encapsulation in a silica hydrogel matrix on drug penetration through the skin

It has been found that the encapsulation of high molecular weight hyaluronic acid in a biologically relevant silica hydrogel matrix provides its accelerated penetration into the skin compared to free acid. The developed hybrid hydrogels, in which high molecular weight hyaluronic acid retains its pronounced anti-inflammatory properties and strong hydrating effect, can become the basis for new, more effective soft formlations for the treatment of inflammatory skin diseases, as well as for products used in the beauty industry. It has been shown that the penetration of hyaluronic acid from the hybrid hydrogels depends on the conditions of their synthesis, the average molecular weight and the loading of the acid.     

基于透明质酸构筑的药物递送载体及其应用

传统纳米药物控释载体主要通过细胞胞吞作用实现药物递送,其主要过程为被动靶向机制,因此会影响纳米载体在肿瘤组织的富集和治疗效果.近年来生物大分子透明质酸因其优异的水溶性、生物相容性、可降解性和肿瘤靶向性备受科研工作者青睐,已被广泛用于药物控释载体的构筑中,并成为靶向肿瘤治疗纳米载体领域的研究热点.本文根据透明质酸基纳米载...     

Enhanced Transdermal Absorption of Hyaluronic Acid via Fusion with Pep-1 and a Hyaluronic Acid Binding Peptide

It is always big challenges for hyaluronic acid (HA) in transmembrane absorbing and efficient delivering to the skin. Pep-1, as one of the cell-penetrating peptides, has been documented to permeate various substances across cellular membranes without covalent binding. Here, a novel hyaluronic acid binding peptide (named HaBP) is designed, and then combined with Pep-1 to enhance the cell-penetrating efficiency of HA. The results of ELISA and immunofluorescence assay show that HaBP could bind with HA very well, and a combination of Pep-1 and HaBP could efficiently improve the transmembrane ability of HA. Furthermore, HA gradually enters the dermis from the surface of the skin in mice when it is administrated with both HaBP and Pep-1, while there are no obvious allergies or other adverse reactions during this process. This study finds a new method to promote the efficient transmembrane and transdermal absorption of HA, and throws some light on further research on the development of hyaluronic acid and its related cosmetics or drugs.     

Preparation and properties of Miramistin–hyaluronic acid coatings on the nanodiamond surface

Hyaluronic acid is a promising coating for imparting biocompatibility to nanodiamond–antibiotic composites. It has been found that the adsorption of Miramistin on nanodiamonds with an initial negative zeta-potential increases the adsorption of hyaluronic acid, which remains lower than on positively charged nanodiamonds that are not affected by the pre-adsorption of Miramistin. The highest adsorption of hyaluronic acid is observed when Miramistin neutralizes the surface charge of nanoparticles.     

Enzymatic polymerization to artificial hyaluronic acid using a transition state analogue monomer

Artificial hyaluronic acid has been synthesized in vitro via enzymatic polymerization catalyzed by testicular hyaluronidases, which is the first successful example of the hyaluronic acid synthesis via non-biosynthetic pathways. The novel GlcAβ(1→3)GlcNAc oxazoline derivative was designed and synthesized as a transition state analogue monomer for the hyaluronidase catalysis. The oxazoline monomer was efficiently recognized by the enzymes at pH 7.1 to 9.0 and the polymerization reaction proceeded in a regio- and stereo-selective manner to give rise to artificial hyaluronic acid with molecular weight higher than 15000. These results strongly suggest that the transition state of these testicular hyaluronidases catalysis corresponds to a sugar oxazolinium ion.