智能纳米水凝胶的刺激响应性研究进展

智能纳米水凝胶在药物输送与可控释放、医学诊断、生物传感器、微反应器、催化剂载体等方面有良好的应用前景。结合本课题组近年来的研究成果,分别介绍了具有温度刺激响应性、pH刺激响应性、光刺激响应性、磁场刺激响应性、分子识别刺激响应性和多重刺激响应性智能纳米水凝胶的研究进展。另外,对这几种智能纳米水凝胶目前存在的问题和今后的发展方向提出了一些粗浅的看法。     

PEP与阴离子表面活性剂复配体系泡沫性能的研究

研究了PEP型非离子表面活性剂分别与十二烷基苯磺酸钠（DBS）,十二烷基硫酸钠（SDS）形成复配体系的泡沫性能,讨论了浓度及配比的变化对泡沫性能的影响,结果表明起泡性和稳泡性皆随混合表面活性剂的浓度的上升而增强;在一定浓度下,随着PEP比例下降,起泡性和稳泡性也随着增大,并达到稳定值。     

智能性生物医用高分子研究进展

智能高分子材料能够响应外界环境的微小刺激,引起自身构象,极性,相结构,组成结构等物理化学变化,表现出“智能”的特性,已被广泛应用于生物医学和纳米技术领域．文中将以智能水凝胶体系,智能载药体系和智能识别体系为例,综述智能高分子材料在生物医学上的研究进展,并展望其应用前景．     

基于胆固醇的有机超分子智能凝胶

胆固醇分子具有特色的多环、多手性碳结构,因此可用于构筑有机超分子凝胶智能材料。该凝胶体系除了对温度有良好的感知响应性外,对其他的外界刺激,如光、pH、超声等也能够感知并响应。由于胆固醇分子是生命体中普遍存在的生物分子,基于胆固醇的有机超分子智能凝胶在生命现象模拟、药物输运等方面具有天然的优势。本文先根据胆固醇凝胶体系的不同种类,包括光响应型、氧化还原响应型、酸碱响应型、超声响应型,金属离子响应型以及触变响应型等,对该体系的结构与性能进行了介绍,然后介绍了对凝胶因子的修饰方法,最后结合目前的研究现状,探讨了胆固醇有机超分子凝胶的应用方向及前景。     

刺激响应性聚合物载药纳米胶束研究进展

刺激响应性聚合物纳米胶束是目前药物控制释放体系的研究热点之一,其原理是将疏水性药物以物理或化学方法包覆在具有核/壳结构的纳米微球中,通过环境刺激响应控制药物的包覆与释放,可增加疏水性药物溶解度、提高药物利用率、降低药物毒副作用,具有显著的研究价值和应用前景.本文中我们主要介绍了不同类型刺激响应性聚合物纳米胶束在药物控制释放体系的研究进展.     

刺激响应纳米碳杂化材料

碳纳米管和石墨烯是碳纳米材料的典型代表,其纳米尺度赋予了其优异的光、电、热以及机械性能。然而,这些碳纳米材料间存在较强的范德华力,导致其溶解性差,后续加工处理困难。为提高碳纳米材料的溶解性,通常利用聚合物或其它小分子物质对其进行修饰。而利用刺激响应性聚合物或化合物功能化碳纳米材料,不仅可以提高其溶解性,还可以赋予其环境刺激响应功能。本文主要综述了近年来利用温度、pH、光以及CO2响应聚合物或小分子化合物对碳纳米管和石墨烯进行共价键、非共价键修饰并赋予其环境刺激响应特性的方法、功能和相关应用,展望了修饰得到的纳米碳杂化材料的应用前景及下一步发展方向。     

刺激响应性水凝胶在肿瘤治疗中的研究进展

恶性肿瘤的治疗在临床中一直备受关注,由于肿瘤细胞的浸润性和顽固性,常规治疗通常会产生严重的毒副作用。相较于全身化疗,局部载药水凝胶的使用显著降低了全身毒性并可实现药物在肿瘤部位的持续递送。此外,经物理掺杂或化学修饰的刺激响应性水凝胶,还可响应环境条件变化(如温度、pH、光等),实现原位交联和药物可控释放,大大提高了临床顺应性和药物递送效率。本综述分类讨论了用于肿瘤治疗的刺激响应性水凝胶的设计策略;汇总了近年来此类水凝胶的研究进展及其药物递送方案;并针对该领域存在的实际问题提出了可能的发展方向。     

基于环糊精的智能刺激响应型药物载体

智能药物载体凭借其独特的刺激-响应机制控制药物的释放速度和转运部位,已成为当前化学与药学领域的研究热点之一。由于具有提高药物在体内的生物利用度和降低其毒副作用等优点,智能药物载体将在未来的临床治疗中起到越来越重要的作用。近年来,环糊精作为药物载体材料的研究取得了巨大进步,其在药物控释的时间、空间和剂量上更为准确。环糊精具有大环结构,可自组装、易于功能化、天然无毒且价格低廉,已被广泛应用于构筑智能药物载体。凭借其自组装、分子识别和动态可逆性能力,环糊精可以同其他生物相容性材料构筑具有不同性能的智能药物载体。这种载体可在外界刺激下做出相关理化性质改变的反馈调节,包括通过内源性刺激(pH值、氧化还原物质和酶浓度等)和外源性刺激(温度、光、磁场、超声和电压等),进而控制药物的释放。本文综述了面向不同刺激因素的基于环糊精智能刺激响应型药物载体的作用机理、特点和应用的最新研究进展,并对其发展前景作了进一步的展望。     

氧化石墨烯/聚合物复合水凝胶的研究进展

氧化石墨烯是一种具有单原子厚度的二维材料, 具有优异的力学性能和良好的水分散性, 其表面有大量的含氧官能团. 将氧化石墨烯引入水凝胶体系中可以提高水凝胶的机械性能, 丰富其刺激响应的类型. 目前, 氧化石墨烯水凝胶在高强度、 吸附、 自愈合及智能材料等很多领域均有出色的表现. 氧化石墨烯水凝胶的研究已有10年的历史. 本文总结了氧化石墨烯水凝胶的制备方法, 归纳了智能氧化石墨烯水凝胶在光热响应、 pH响应和自愈合3个方面的响应机理和研究进展, 并综合评述了其在高强度水凝胶、 生物医学、 智能材料和污水处理等方面的应用前景.     

pH-Responsive Aqueous Foams of Oleic Acid/Oleate Solution

Aqueous foams of oleic acid/oleate solution were found to be pH-responsive with pH changes. Detailed characterization of the aqueous foams of oleic acid/oleate solution was conducted with respect to their stability, structure, and pH response. The pH values required for foam circulation were studied through pH adjustment. The foaming and defoaming activities of oleic acid/oleate solution were explained by microscopic analysis and oil defoaming mechanisms. Because of the reversibility of oleic acid losing or receiving protons, the foaming and defoaming cycles could be readily repeated many times.      

Experimental Investigation on Flow Characteristics of Aqueous Foams through the Jet Device and Horizontal Pipe

Aqueous foam is regarded as a versatile medium in numerous scientific and engineering applications due to its high viscosity and low density. The objective of this study is to investigate the flow characteristics of aqueous foams through the jet device and horizontal pipe. The pressure distribution and foam production capacity are measured at different operating conditions. Experimental results show that the pressure fluctuations reduce significantly by increasing the foam liquid concentration, especially in the downstream of jet device. The bubble flow turns into homogeneous foams gradually when the concentration increases from 0.025% to 0.35%, while the foam behaviors take little change at a higher concentration, and the foamability reaches a limit. Subjected to the large pressure difference produced between the top and bottom of horizontal pipe, aqueous foams undergo a gas–liquid separation at a high terminal pressure, resulting in bubbles at the top and liquid at the bottom. Therefore, the terminal pressure should be kept less than a critical value to hold a good foam pattern. Based on the above contributions, it is believed that the study laid an important foundation for the widespread application of foam technology.     

Hydrophobicity Enhances the Formation of Protein-Stabilized Foams

Screening proteins for their potential use in foam applications is very laborious and time consuming. It would be beneficial if the foam properties could be predicted based on their molecular properties, but this is currently not possible. For protein-stabilized emulsions, a model was recently introduced to predict the emulsion properties from the protein molecular properties. Since the fundamental mechanisms for foam and emulsion formation are very similar, it is of interest to determine whether the link to molecular properties defined in that model is also applicable to foams. This study aims to link the exposed hydrophobicity with the foam ability and foam stability, using lysozyme variants with altered hydrophobicity, obtained from controlled heat treatment (77 °C for 0–120 min). To establish this link, the molecular characteristics, interfacial properties, and foam ability and stability (at different concentrations) were analysed. The increasing hydrophobicity resulted in an increased adsorption rate constant, and for concentrations in the protein-poor regime, the increasing hydrophobicity enhanced foam ability (i.e., interfacial area created). At higher relative exposed hydrophobicity (i.e., ~2–5 times higher than native lysozyme), the adsorption rate constant and foam ability became independent of hydrophobicity. The foam stability (i.e., foam collapse) was affected by the initial foam structure. In the protein-rich regime—with nearly identical foam structure—the hydrophobicity did not affect the foam stability. The link between exposed hydrophobicity and foam ability confirms the similarity between protein-stabilized foams and emulsions, and thereby indicates that the model proposed for emulsions can be used to predict foam properties in the future.     

Smart Foams: Switching Reversibly between Ultrastable and Unstable Foams

Smart foams: Ultrastable foams with an optimal foamability are obtained using hydroxy fatty acids tubes. The stabilization results from the adsorption of monomers at the air-water interface and from the presence of tubes in the plateau borders. Upon heating, tubes transform to micelles, leading to foam destabilization and thus to the first foams to exhibit temperature-tuneable stability.     

Effect of Lipid Phase State and Foam Film Type on the Properties of DMPG Stabilized Foams

The drainage and stability of DMPG (l-α-phosphatidyl-dl-glycerol dimyristoyl) foams were studied by a microconductivity method under conditions where three different foam film types could be formed—thin foam films (TFF), common black foam films (CBF), and Newton black foam films (NBF). Foaming properties were investigated at 20 and 28°C where DMPG is in the gel and liquid-crystalline states. Higher conductivity signals were observed at the higher temperature where DMPG was in the liquid-crystalline state, which is indicative of wetter or more stable foams under these conditions. This effect was observed independent of foam film type. However, for a given phase state, the type of foam films formed significantly influenced the stability and rate of drainage of the foam. Indeed, the water content of the foams, obtained under conditions for formation of different foam films, is ranked in the order TFF > CBF > NBF. When the temperature was increased to 28°C (i.e., in the liquid-crystalline state), CBF and NBF showed a slight decrease in film thickness and an increase in film lifetime and surface molecular diffusion coefficient in the adsorbed layer. It is likely that the fluidity of the interfacial layer is an important factor contributing to DMPG foam stabilization.     

基于不同刺激源的刺激响应聚合物体系的构建

刺激响应聚合物是一类具有"智能"行为的大分子体系. 它可以接收外部环境的刺激信号, 如pH值、 光、 温度、 电压、 氧化还原剂和气体等, 使自身大分子结构或状态发生较大改变, 从而影响其物理化学性质, 进而体现出相应的功能. 大量的研究结果表明, 刺激响应聚合物在纳米材料科学、 生命科学及临床医学领域中有着广泛的应用前景. 本文主要介绍了我们课题组在基于不同刺激源的刺激响应性大分子体系研究方面的一些进展.     

Effects of Oil on Aqueous Foams: Electrical Conductivity of Foamed Emulsions

Three‐phase foams containing dispersed oils (also called foamed emulsion) are usually encountered in such areas as enhanced oil recovery, food foams, and in foams containing antifoams. The presence of oil causes these complex fluids to exhibit extraordinary properties in contrast to aqueous foams. We experimentally investigated, for the first time, the conductive properties of the foamed emulsions and found that the electrical conductivity increases monotonically with the volumetric liquid fraction, presenting a linear relationship. Combined with the analysis on the foaming capacity and microstructure of this complex fluid, the conductive mechanism is revealed. In these foamed emulsions, the whole conductive network is comprised of two levels of structural hierarchy, which displays a different mechanism from those of the conventional aqueous foams. The lamella of emulsions is taken as primary electrical channel, whereas the secondary electrical channel occurs in the lamella between two bubbles. This conductive behaviour is attributed to the microstructure properties of the foamed emulsions. We believe that such findings are potentially important for a better understanding of the fundamentals of these tri‐phase dispersion systems.     

Effect of Xanthan Gum on the Performance of Aqueous Film-Forming Foam

Solution properties of aqueous film-forming foam (AFFF) formulations containing different xanthan gum contents were investigated first by varying the mass fraction of xanthan gum in the range of 0.1–0.5%. Foam properties and fire-extinguishing performance of the AFFF formulations were then evaluated. Results indicated that xanthan gum content slightly affected surface tension of foam solutions. However, xanthan gum significantly affected viscosity of AFFF concentrates. Foaming of the AFFF formulations was hardly affected by xanthan gum, but foam stability of the compounds was obviously enhanced with the addition of xanthan gum. Optimal xanthan gum content was determined as 0.3%, which resulted in the shortest 90% control time and fire extinguishment time. Burnback time of foams increased with the addition of xanthan gum because of the enhanced foam stability.