一种高透明、可拉伸导电水凝胶的制备及其在电容传感器中的应用

导电水凝胶由于具备良好的电学特性、可调节的机械性能、易于加工性和生物相容性等,是制备柔性电子设备的理想基材。本文使用马来酸与丙烯酰胺作为共聚单体,氯化锂作为导电离子,N,N'-二甲基双丙烯酰胺作为交联剂,使用光引发剂,采用原位光聚合的方式制备了一种导电水凝胶。制得的水凝胶可见光透过率高达93%,最大拉伸形变~380%,导电率最大为12 S/m。鉴于其优异的综合性能,实验中使用导电水凝胶制备了电容传感器并应用于人体活动监测。结果表明,制备的导电水凝胶电容传感器对不同程度的手指弯曲形变和不同力度的手指触碰均表现出灵敏的响应行为,为未来可穿戴柔性电子产品的发展起到了一定的推动作用。     

PANI导电水凝胶的制备及其进展

导电水凝胶结合了水凝胶和导电高分子电性能的独特特性,并且具有特殊三维网络结构。其中聚苯胺(PANI)由于其独特的导电性能得到了广泛应用,因此PANI导电水凝胶是导电水凝胶中研究最为广泛的。本文综述了PANI导电水凝胶的制备方法及其发展,详述了PANI导电水凝胶的四种制备方法:直接填充、原位聚合、化学交联和物理交联。其中,利用直接填充和原位聚合方法制得PANI水凝胶是较传统的方法,获得的PANI水凝胶是由绝缘的水凝胶组分和导电的PNAI组分组合在一起,电化学性能不高。化学交联法的应用提高了导电水凝胶的电化学性能,物理交联法应用较少。最后,对导电水凝胶材料的应用以及未来发展方向进行了展望。     

Hofmeister效应辅助的蛋白质基水凝胶应变传感器

以酪蛋白酸钠和明胶为原料, 通过简单的在硫酸铵溶液中浸泡的方法, 借助Hofmeister效应制备了一种强韧导电的酪蛋白酸钠/明胶水凝胶, 克服了蛋白质基水凝胶柔软、 易碎的问题. 测试结果表明, 该水凝胶具有优异的机械性能, 最大拉伸应力为3.55 MPa, 最大拉伸应变为1375%; 水凝胶的最大电导率为0.0954 S/cm, 导电灵敏因子为0.53. 用该水凝胶制备的传感器对不同大小及不同速率的应变均具有分辨能力, 能够监测人体不同部位的运动, 且传感器的信号传输具有稳定性和准确性, 表明该水凝胶是监测人体健康和运动的理想材料. 该水凝胶还具有良好的形状记忆性能. 这一策略为制备全天然蛋白质基水凝胶开辟了新的思路, 扩展了水凝胶在生物医学和电子传感等相关领域的应用前景.     

Ultrastretchable and conductive core/sheath hydrogel fibers with multifunctionality

Conductive hydrogels with ionic compounds possess great potential for the development of soft smart devices. A dielectric scarfskin is typically required for these devices to prevent short circuiting, leading to devices with lower stretchability than the hydrogel. Henceforth, commonly used dielectric materials, such as PDMS and Ecoflex, cannot be largely stretched. Hydrogel devices with ultrastretchability are required to accommodate hostile application environments. Herein, we propose a hydrogel fiber coated with a dielectric layer that can be stretched to over 2000% of its initial length. The fiber remains conductive when stretched to ~1300%. In addition, the core/sheath hydrogel fiber can be endowed with a variety of functional properties, such as electroluminescence (EL), photoluminescence (PL), and magnetic‐responsiveness, demonstrating scalability of the resultant fiber. The present work can pave the way for numerous next‐generation soft devices, such as smart textiles and wearable electronics. © 2019 Wiley Periodicals, Inc. J. Polym. Sci., Part B: Polym. Phys. 2019 , 57, 272–280     

导电水凝胶的制备

作为一种新型的功能材料,导电水凝胶已经引起广泛的关注。本文根据目前的研究现状,将导电水凝胶大致分为聚电解质导电水凝胶,酸掺杂导电水凝胶,无机物添加导电水凝胶以及导电高分子基导电水凝胶等几大类,并综述了它们的制备方法。另外,由于大分子体系的导电高分子和水凝胶都有着独特和重要的性能,这使得它们具有广阔的应用价值。所以,本文在综述导电水凝胶制备进展的同时着重综述了导电高分子基导电水凝胶的制备进展。     

Recent progress in polymer hydrogel bioadhesives

Adhesive hydrogels have broad applications in tissue adhesives, hemostatic agents, and biomedical sensors. Various bio-inspired glues and synthetic adhesives are clinically used as conventional hemostatic agents and auxiliary tools for wound closure. Medical adhesives are needed to effectively and quickly control bleeding, thereby reducing the risk of complications caused by severe blood loss. Medical sensors need to have excellent skin compliance, mechanical properties, sensitivity, and biological safety. This review focuses on recent progress in adhesive hydrogel systems, their structures, adhesion mechanisms, construction strategies, and emerging applications in the biomedical field.     

Preparation of stable aqueous conductive ink with silver nanoflakes and its application on paper‐based flexible electronics

A new kind of stable aqueous conductive ink with silver nanoflakes was developed, which was also used to fabricate conductive patterns on weighing paper for flexible electronics by direct writing. Silver nanoflakes of different sizes were characterized by transmission electron microscopy. The physical properties of the conductive ink were investigated by a dynamic contact angle system, Ubbelohde viscometer, and a surface tension instrument. Conductive properties of paper‐based conductive patterns were also investigated by 4‐point probe, scanning electron microscopy, X‐ray diffraction and Uscan explorer with a 3D profilometer system. It is demonstrated how the formulation of conductive ink affects the surface morphology, microstructure conductivity, and line width of conductive patterns. It can be obtained that the paper‐based conductive patterns have low resistivity. Especially, when the sintering condition is 200 °C for 20 min, the resistivity can be down to 9.4 μΩ?cm. The application of the ink on an antenna for radio frequency identification was also studied. Copyright © 2011 John Wiley & Sons, Ltd.     

Influence of the Nature and Structure of Polyelectrolyte Cryogels on the Polymerization of (3,4-Ethylenedioxythiophene) and Spectroscopic Characterization of the Composites

Conductive hydrogels are polymeric materials that are promising for bioelectronic applications. In the present study, a complex based on sulfonic cryogels and poly(3,4-ethylenedioxythiophene) (PEDOT) was investigated as an example of a conductive hydrogel. Preparation of polyacrylate cryogels of various morphologies was carried out by cryotropic gelation of 3-sulfopropyl methacrylate and sulfobetaine methacrylate in the presence of functional comonomers (2-hydroxyethyl methacrylate and vinyl acetate). Polymerization of 3,4-ethylenedioxythiophene in the presence of several of the above cryogels occurred throughout the entire volume of each polyelectrolyte cryogel because of its porous structure. Structural features of cryogel@PEDOT complexes in relation to their electrochemical properties were investigated. It was shown that poly(3,4-ethylenedioxythiophene) of a linear conformation was formed in the presence of a cryogel based on sulfobetaine methacrylate, while minimum values of charge-transfer resistance were observed in those complexes, and electrochemical properties of the complexes did not depend on diffusion processes.     

磺化聚苯乙炔/多壁碳纳米管复合材料导电特性和机理的研究

将磺化聚苯乙炔(SPPA)与多壁碳纳米管(MWCNTs)超声共混制备得到SPPA/MWCNTs复合材料. 用X光电子能谱仪、固体紫外-可见分光光度计、X射线衍射仪、四探针、场发射扫描电镜等对复合材料导电特性及机理进行研究. 结果表明: SPPA/MWCNTs 复合材料中SPPA与MWCNTs发生电荷转移而被掺杂, 并且由于SPPA与MWCNTs间的电荷转移, 彼此间存在一定的相互作用力; 复合材料电阻呈负温度系数效应; SPPA/MWCNTs复合材料电导率发生两次突跃. 可能的导电机理为, 复合材料中SPPA不仅被MWCNTs物理填充, 同时还被MWCNTs掺杂, 复合材料中存在两种导电通路, 一是SPPA与MWCNTs的碳原子发生电荷转移而被掺杂, 彼此之间存在一定的相互作用力, 导致SPPA包裹MWCNTs形成独立导体单元, 这种独立单元相互接触形成导电通路; 二是MWCNTs彼此之间相互接触形成导电通路, 并建立了该导电机理的理论模型.     

Self-healing mineralized hydrogel scaffolds for stretch-triggered dye release

Hydrogels, with self-healing properties that can self-repair spontaneously when subjected to mechanical stress, are gaining popularity in the biomedical field. Numerous attempts have been made to create distinctive hydrogels with self-healing properties, along with stimuli-responsiveness and biocompatibility. Several techniques exist for fabricating hydrogels, including physical and chemical crosslinking via the creation of covalent bonds, and so on. Here, we prepared self-healing, stimuli-responsive, mineralized hydrogel by simply dissolving Kollidon 90-F, sodium chloride (NaCl), and potassium carbonate (K₂CO₃) in an aqueous solution. The dissociated CO₃²⁻ replaces the water molecules from the Kollidon 90-F polymer backbone and facilitates the cross-linking of the polymer chain, resulting in hydrogel formation. In addition, the in-situ produced sodium carbonate (Na₂CO₃) strengthens the hydrogel network. We optimized the mineralized hydrogels by taking various metal salts and different concentrations of K₂CO₃. The optimized hydrogel showed good stability over a period of time, was able to maintain viscoelastic properties, possessed good self-healing ability, and showed a shape retention ability. The shear-thinning property demonstrated by the optimized hydrogel could open a ray of hope in the bioprinting or 3D printing industry. Further, the stretch-responsive release of dye from the Self-healing mineralized hydrogel (SHMH) matrix confirms the mechanoresponsive behavior of the hydrogel. Overall, the findings could be utilized in the future to fabricate a stable drug delivery system that can autonomously release the drug molecules when stretched by daily processes such as joint movements.     

Overview of Polyvinyl Alcohol Nanocomposite Hydrogels for Electro‐Skin,Actuator, Supercapacitor and Fuel Cell

The properties of polyvinyl alcohol (PVA) nanocomposite hydrogels influenced by nanoparticles are reviewed. Various kinds of nanoparticles with excellent mechanical and electrical properties have been introduced into PVA hydrogel to produce stretchable and conductive PVA nanocomposite hydrogel. Understanding the mechanism between the matrix of PVA hydrogel and nanoparticles is therefore critical for the development of PVA nanocomposite hydrogels. This review focuses on the nanoparticles include carbon nanotubes, graphene oxide and metal nanoparticles, and describes the effects of nanoparticles on the mechanical and conductive properties of PVA nanocomposite hydrogels. A new promising area of soft stretchable PVA nanocomposite hydrogel is highlighted for possible applications. Finally, a brief outlook for future research is presented.     

导电高分子的最近进展

因为导电高分子结合了金属与塑料的优点,他们一直受到很大的关注。但是他们的应用受到一些因素的影响,包括他们的电学性质,稳定性和可加工性。近来,导电高分子的性能得到很大的提高。他们在许多领域的重要应用被论证,比如透明电极,可拉伸电极,神经界面,热电转换和能量储存。这篇文章简单综述了导电高分子的电导提高和它们在热电转换,超级电容器和电池的应用。     

导电聚合物的纳米结构及其在生物医学领域的应用

由于表面效应、小尺寸效应和量子效应,使纳米结构的导电聚合物材料与传统聚合物材料相比,显示出更优越的性能。基于神经组织对电场和电刺激敏感性,使得导电聚合物纳米材料在生物医学应用方面很有前景。本文综述了纳米结构的导电聚合物的合成方法,及其在生物医学领域的应用。合成方法主要关注于硬模板法、软模板法和无模板自组装法,以及这些方法中导电聚合物纳米结构的形成机理。总结了具有纳米结构的导电聚合物,如纳米颗粒、纳米纤维和纳米管等作为神经电极涂层材料和生物传感器等方面的应用。     

Oxidized Xanthan Gum Crosslinked NOCC: Hydrogel System and Their Biological Stability from Oxidation Levels of the Polymer

Dynamic hydrogel systems from N,O-carboxymethyl chitosan (NOCC) are investigated in the past years, which has facilitated their widespread use in many biomedical engineering applications. However, the influence of the polymer's oxidation levels on the hydrogel biological properties is not fully investigated. In this study, chitosan is converted into NOCC and introduced to react spontaneously with oxidized xanthan gum (OXG) to form several injectable hydrogels with controlled degradability. Different oxidation levels of xanthan gum, as well as NOCC/OXG volume ratios, are trialed. The infrared spectroscopy spectra verify chemical modification on OXG and successful crosslinking. With increasing oxidation levels, more dialdehyde groups are introduced into the OXG, resulting in changes in physical properties including gelation, swelling, and self-healing efficiency. Under different volume ratios, the hydrogel shows a stable structure and rigidity with higher mechanical properties, and a slower degradation rate. The shear-thinning and self-healing properties of the hydrogels are confirmed. In vitro assays with L929 cells show the biocompatibility of all formulations although the use of a high amount of OXG15 and OXG25 limited the cell proliferation capacity. Findings in this study suggested a suitable amount of OXG at different oxidation levels in NOCC hydrogel systems for tissue engineering applications.     

PVA-clay nanocomposite hydrogels for wound dressing

Polymer gels as soft biomaterials have found diverse applications in biomedical field, e.g. in management and care of wound as wound dressing.The recent researches on nanocomposite materials have shown that some properties of polymers and gels significantly improve by adding organoclay into polymeric matrix. In this work, in order to obtain wound dressing with better properties, nanocomposite hydrogel wound dressing was prepared using combination of polyvinyl alcohol hydogel and organoclay, i.e. Na-montmorillonite, via the freezing-thawing method. The effect of organoclay quantity on the structural, swelling, physical and mechanical properties of nanocomposite hydrogel wound dressing was investigated. The results showed that the nanocomposite hydrogels could meet the essential requirements for the reasonable wound dressing with some desirable characteristics such as relatively good swelling, appreciated vapour transmission rate, excellent barrierity against microbe penetration and mechanical properties. The results also indicated that the quantity of the clay added to the nanocomposite hydrogel is the key factor in obtaining such suitable properties required for wound dressing.     

Comprehensive Examination of Mechanical and Diffusional Effects on Cell Behavior Using a Decoupled 3D Hydrogel System

Hydrogels possess several physical and chemical properties suitable for engineering cellular environments for biomedical applications. Despite recent advances in hydrogel systems for cell culture, it is still a significant challenge to independently control the mechanical and diffusional properties of hydrogels, both of which are well known to influence various cell behaviors when using hydrogels as 3D cell culture systems. Controlling the crosslinking density of a hydrogel system to tune the mechanical properties inevitably affects their diffusional properties, as the crosslinking density and diffusion are often inversely correlated. In this study, a polymeric crosslinker is demonstrated that allows for the adjustment of the degree of substitution of reactive functional groups. By using this polymeric crosslinker, the rigidity of the resulting hydrogel is controlled in a wide range without changing the polymer concentration. Furthermore, their diffusional properties, as characterized by their swelling ratios, pore diameters, and drug release rates, are not significantly affected by the changes in the degree of substitution. 3D cell studies using this hydrogel system successfully demonstrate the varying effects of mechanical properties on different cell types, whereas those in a conventional hydrogel system are more significantly influenced by changes in diffusional properties.     

Injectable hydrogels for targeted delivering of therapeutic molecules for tissue engineering and disease treatment

Hydrogels are cross‐linked three‐dimensional polymeric networks that play a vital role in solving the pharmacological and clinical limitations of the existing systems due to their unique physical properties such as affinity for biological fluids, tunable porous nature, high water content, ease of preparation, flexibility, and biocompatibility. Hydrogel also mimics the living natural tissue, which opens several opportunities for its use in biomedical areas. Injectable hydrogel allows temporal control and exceptional spatial arrangements and can offset hitches with established hydrogel‐based drug delivery systems. Here, we review the recent development of injectable hydrogels and their significance in the delivery of therapeutics such as cells, genes, and drug molecules and how these innovatory systems can complement the current delivery systems.     

Progress on intelligent hydrogels based on RAFT polymerization: Design strategy,fabrication and the applications for controlled drug delivery

Although intelligent hydrogels have shown bright potential application in biomedical fields,they were prepared by conventional methods and still face many serious challenges,such as uncontrollable stimulus-response and low response sensitivity.Recently,RAFT polymerization provides a versatile strategy for the fabrication of intelligent hydrogels with improved stimulus-response properties,owing to the ability to efficiently construct hydrogel precursors with well-defined structure,such as block copolymer,graft copolymer,star copolymer.In this review,we summarized the recent progress on intelligent hydrogels based on RAFT polymerization with emphasis on their fabrication strategies and applications for controlled drug delivery.     

智能水凝胶研究最新进展

综述了近几年国内外智能水凝胶研究现状,重点介绍了对pH、温度、光、电、磁和特定生物分子敏感的水凝胶的研究创新以及智能水凝胶在药物控释载体、组织工程支架、血红蛋白氧栽体、生物传感器、蛋白质检验等生物医学领域应用的最新进展.