光交联水凝胶材料的研究与生物医学应用进展

光交联制备水凝胶技术具有非物理接触以及时空精确可控等优势,在细胞3D培养/打印以及组织工程和再生医学领域具有广阔的应用前景.当前,光交联水凝胶的制备主要基于光引发自由基交联反应、光点击交联反应或光偶联交联反应.本文分别介绍了以上交联反应各自的技术发展史、应用现状以及相关的优势和技术瓶颈.还着重介绍了本课题组在光交联水凝胶领域开展的研究与转化工作,主要包括提出了利用光笼分子的光剪切释放活性基团触发偶联交联的非自由基光交联策略,即光偶联反应交联策略.该策略实现了光交联水凝胶的低毒、可控构筑,同时赋予了光交联水凝胶技术的原位组织黏附特性,为该技术的最终临床转化奠定了基础.     

具生物活性的快速光交联生物可降解水凝胶的设计合成

采用开环聚合方法合成了一系列水溶性生物可降解的低聚(丙交酯-co-丙烯酸酯碳酸酯)-b-聚乙二醇-b-低聚(丙交酯-co-丙烯酸酯碳酸酯)(OLAC-PEG-OLAC)三嵌段共聚物,并通过光交联方法方便制备得到具生物活性的新型生物可降解水凝胶.流变测试表明水凝胶储存模量(170～10000 Pa)和凝胶时间(0.8～8min)均可通过调节丙烯酸酯碳酸酯(AC)单元数、聚合物浓度及光引发剂浓度等得到控制.降解实验表明水凝胶的降解速率可通过改变AC和丙交酯(LA)单元数进行调控.含巯基的生物活性分子如RGDC短肽可通过迈克尔加成反应直接链接到OLAC-PEG-OLAC上,由此可方便制备可注射性的具生物活性的生物可降解水凝胶.MG63成骨细胞实验表明RGDC短肽功能化的OLAC-PEG-OLAC水凝胶可很好地促进细胞黏附和生长.该快速光交联生物可降解水凝胶以其优异的凝胶、降解和生物功能化等性能可望为生物组织工程提供理想的三维活性多孔支架.     

氧化石墨烯对聚乙烯醇/硼酸水凝胶流变性能的影响

研究了氧化石墨烯(GO)对聚乙烯醇(PVA)/硼酸(borate)水凝胶线性及非线性流变性能的影响。 通过扫描电子显微镜、硼谱核磁共振波谱以及流变研究了水凝胶的流变性能。 结果表明,GO质量浓度在稀溶液区时,GO片层与PVA链间通过硼酸根离子形成了具有弹性活性的缔合点,有效地提高了水凝胶的平台模量、松弛时间和零切粘度;当GO进一步增加到亚浓溶液区,部分的交联剂被GO的团聚体捕获并处于非弹性活性的缔合状态,处于有效缔合状态的交联剂变少,导致平台模量、松弛时间和零切粘度降低。 稳态剪切测试下,样品在剪切增稠区的粘度增加随着GO添加量的增加明显加强,这与剪切场下取向的氧化石墨烯片层参与网络结构的重排有关。     

光交联法合成水凝胶的研究

合成了一种新型光敏性功能单体N -肉桂酰氧甲基丙烯酰胺 (CMMAM)及其与丙烯酸 (AA)的共聚物(CMMAM -AA) ,通过光交联法进一步合成水凝胶 .测定了CMMAM和CMMAM -AA聚合物的红外光谱 ,测定了水凝胶的DSC并对它的溶胀性能进行了初步研究     

PLG-g-TA/RGD酶催化交联水凝胶用于透明软骨细胞黏附和三维细胞培养

制备了一种基于聚谷氨酸-g-酪胺/cRGDfk(PLG-g-TA/RGD)的新型酶催化交联水凝胶, 用于兔透明软骨细胞黏附和三维细胞的培养. PLG-g-TA/RGD聚合物材料在辣根过氧化物酶(HRP)和过氧化氢(H₂O₂)存在下, 能够通过酪氨基团的自交联快速形成水凝胶. 环状多肽(cRGDfk)的引入能够显著提高材料的溶液-凝胶转变速率和凝胶强度. 透明软骨细胞在水凝胶表面黏附3 d后, 在PLG-g-TA/RGD水凝胶表面有更多的细胞黏附; 将透明软骨细胞包裹在水凝胶内培养1, 4, 7 d后, 细胞在PLG-g-TA/RGD水凝胶内增殖效率明显高于对照组PLG-g-TA水凝胶. 细胞实验结果表明, 该水凝胶材料具有良好的生物相容性. cRGDfk的引入, 促进了透明软骨细胞的黏附和增殖, 显示了PLG-g-TA/RGD水凝胶材料在三维细胞培养方面的应用潜力.     

光交联法合成水凝胶的研究

合成了一种新型光敏性功能单体N -肉桂酰氧甲基丙烯酰胺 (CMMAM)及其与丙烯酸 (AA)的共聚物(CMMAM -AA) ,通过光交联法进一步合成水凝胶 .测定了CMMAM和CMMAM -AA聚合物的红外光谱 ,测定了水凝胶的DSC并对它的溶胀性能进行了初步研究     

丝素蛋白-聚氨酯复合水凝胶的制备及性能研究

以聚乙二醇(PEG)、聚氧化丙烯二醇(PPG)、异弗尔酮二异氰酸酯(IPDI)为主要原料制备聚氨酯预聚体(PU),与丝素蛋白水溶液(SF)交联制得丝素蛋白-聚氨酯(SF-PU)复合水凝胶.分别利用ATR、SEM对水凝胶组成、结构及微观形貌进行表征;DSC、吸水溶胀测试探讨了丝素蛋白与聚氨酯的质量比(SF/PU)以及聚氨酯中不同软段质量比(PEG/PPG)对SF-PU水凝胶热性能、溶胀性能的影响.结果表明,SF-PU水凝胶具有多孔结构;样品中不同的SF/PU、PEG/PPG均对材料的玻璃化转变温度、结晶度及溶胀性能产生影响,且当水凝胶组分为SF/PU=1/25、PEG/PPG=2/1时,平衡溶胀比(ESR)可达到440%;水凝胶在溶胀初始阶段符合菲克扩散模型,整个溶胀过程遵循溶胀动力学2级方程.     

α-环糊精主客体识别超分子水凝胶的制备及其宏观流变性能构建过程研究

采用7 wt%的α-环糊精(α-CD)溶液和5 wt%的甲氧基聚乙二醇甲基丙烯酸酯均聚物(PMPEGA-2000)溶液制备了α-CD/PMPEGA-2000超分子水凝胶,并对其形貌、结构、形成条件和宏观流变学性能构建过程进行了表征和研究。结果表明,体积比不低于1.5:1是两种溶液混合后形成凝胶的必要条件;当体积比为2:1时,形成的凝胶黏度最大。热重分析、X射线粉末衍射分析和扫描电镜结果表明,该凝胶是基于α-CD与PMPEGA-2000之间的主客体识别所形成,具有三维网络结构。光学微流变分析结果显示,该凝胶宏观流变性能的构建过程实则是凝胶内部主客体识别交联点不断增多,网络结构强度不断增强的过程。该过程始于α-CD溶液与PMPEGA-2000溶液混合后的8′36′′,在64′00′′后基本完成,耗时约55′24′′。     

3D打印聚酰亚胺研究进展

聚酰亚胺(PI)是一种综合性能优异的特种工程塑料,已经被广泛应用于航天航空、汽车制造、微电子等重要技术领域;因其难溶难熔特性,PI加工成形尤其是复杂结构件的制造严重受限。然而,3D打印技术(也称“增材制造”)是一种以数字模型文件为基础,通过逐层打印的方式来构造复杂物体的技术,具有控形控性的特点,为PI智能制造的发展和应用提供新的技术路径。因此,本文就近年来国内外针对PI的3D打印研究现状,综述PI材料3D打印制造的研究进展和发展趋势,重点介绍了熔融成型3D打印热塑性PI和热固性PI、光固化3D打印PI及直写挤出3D打印PI的研究进展。     

会变形的水凝胶

本实验是关于可变形水凝胶的制备及其复杂形变的设计和调控的新创综合实验。首先,利用自由基聚合交联法制备含有聚丙烯酸钠(PNaAAc)的聚乙烯基吡咯烷酮-聚丙烯酰胺(PVP-PAAm)水凝胶。该凝胶具有优良的力学性能,其中PNaAAc可与Fe3+等金属离子络合,从而增加水凝胶的交联密度,降低其溶胀程度。使用离子转移印花技术和新开发的离子墨水打印技术在凝胶单面或双面不同位置引入Fe3+交联,改变水凝胶局部表面的交联密度和溶胀性能。处理后的凝胶样品在溶胀或去溶胀时可发生由一维到二维、二维到三维以及简单三维到复杂三维的复杂可控形变。     

Comparative Study of Silk Fibroin-Based Hydrogels and Their Potential as Material for 3-Dimensional (3D) Printing

Three-dimensional (3D) printing is regarded as a critical technology in material engineering for biomedical applications. From a previous report, silk fibroin (SF) has been used as a biomaterial for tissue engineering due to its biocompatibility, biodegradability, non-toxicity and robust mechanical properties which provide a potential as material for 3D-printing. In this study, SF-based hydrogels with different formulations and SF concentrations (1–3%wt) were prepared by natural gelation (SF/self-gelled), sodium tetradecyl sulfate-induced (SF/STS) and dimyristoyl glycerophosphorylglycerol-induced (SF/DMPG). From the results, 2%wt SF-based (2SF) hydrogels showed suitable properties for extrusion, such as storage modulus, shear-thinning behavior and degree of structure recovery. The 4-layer box structure of all 2SF-based hydrogel formulations could be printed without structural collapse. In addition, the mechanical stability of printed structures after three-step post-treatment was investigated. The printed structure of 2SF/STS and 2SF/DMPG hydrogels exhibited high stability with high degree of structure recovery as 70.4% and 53.7%, respectively, compared to 2SF/self-gelled construct as 38.9%. The 2SF/STS and 2SF/DMPG hydrogels showed a great potential to use as material for 3D-printing due to its rheological properties, printability and structure stability.     

丝素蛋白修饰改性的聚羟基脂肪酸酯支架上人体平滑肌细胞的生长

聚三羟基丁酸脂和聚三羟基己酸脂的共聚物(PHBHH_x)是一种具有良好强度和韧性的生物可降解高分子材料, 可作为组织工程心脏瓣膜支架的选择材料之一. 但其生物相容性尚不甚理想. 为此, 本工作利用丝素蛋白修饰改性高分子多孔支架, 以提高支架的生物相容性. 并将人体平滑肌细胞接种在该复合支架上进行体外培养, 以证实改性效果. 其中, 用3-(4,5-二甲基噻唑-2)-2,5-二苯基四氮唑溴盐(MTT)方法测试细胞生长, 评估复合支架的细胞相容性. 并用扫描电子显微镜观察细胞在支架上的生长形态. 结果显示, 丝素蛋白修饰改性后的复合支架更有利于细胞的粘附与生长, 平滑肌细胞在支架上表现出良好的生长形态. 这表明, 丝素能够改善多孔支架的生物相容性, 使PHBHH_x/丝素蛋白复合物能更适宜作为组织工程心脏瓣膜的支架材料. 结果对于进一步研究细胞外间质在复合支架上的生长以及体外培养的组织重建有重要的参考意义.     

Polylactic acid/silk fibroin composite hollow fibers as excellent controlled drug release systems

Polylactic acid (PLA) and silk fibroin (SF) have been widely used in biomedical applications because of their excellent biocompatibility and degradability. In this study, PLA and SF were used as raw materials to prepare hollow fibers with a skin-core structure by wet spinning technology. Scanning electron microscopy observations revealed that the structure of hollow fibers became increasingly uniform with increasing silk fibroin mass fraction. Tensile test results showed that with the increase of silk fibroin content, the elastic modulus of hollow fibers decreased and their tensile properties improved. The results of hollow fibers degradation experiments revealed that increasing the content of silk fibroin can effectively shorten the degradation time of hollow fibers. Ultraviolet spectrophotometry was used to measure the absorbance of tetracycline hydrochloride in phosphate buffer saline and calculate its release rate in hollow fibers with different silk fibroin contents, the result is HFs-9 > HFs-7 > HFs-0 > HFs-5 > HFs-3. The PLA/SF controlled drug release system has precise controlled release of the drug, realizes the separation of the drug from the controlled release system, and solves the problem of sudden drug release. In addition, the controlled release system is non-toxic, degradable, and has excellent mechanical properties.     

溶酶体靶向吲哚氟硼二吡咯光敏剂的合成、 双光子荧光成像及光动力治疗

通过Knoevenagel缩合反应制备了一个具有溶酶体靶向的近红外光敏剂IMBDP-Lys, 用于双光子荧光成像和光动力治疗. IMBDP-Lys由2个吲哚吗啉功能团连接到氟硼二吡咯(BODIPY)母核的3?位和8?位构筑而成, 是一种重原子诱导的光敏剂. 采用高斯09W理论计算光敏剂S₁态和T₂态能量值相差0.12 eV, 可以有效地发生系间窜越. 在二氯甲烷溶液中, 光敏剂IMBDP-Lys的最大吸收波长为631 nm, 最大发射波长为684 nm. 在 660 nm的光照下, 以亚甲基蓝为参比, 单线态氧量子产率经计算为48.3%. 此外, 含有2个吗啉基团的光敏剂IMBDP-Lys具有良好的生物相容性和精准的靶向能力, 可以快速地进入斑马鱼体内进行双光子荧光成像, 并且与溶酶体绿色染料Lyso-Tracker Green共定位系数为0.95. 溴化噻唑蓝四氮唑(MTT)实验结果表明, 光敏剂具有低的暗毒性(≥85%)和高的光毒性(IC₅₀=0.52 μmol/L). 在660 nm的光照下, 利用活性氧荧光探针2’,7’-二氯二氢荧光素二乙酸酯（DCFH-DA）证明光敏剂可以产生活性氧, 同时吖啶橙/溴化乙锭(AO/EB)染色实验和细胞迁移实验表明产生的活性氧不仅能诱导A549细胞凋亡, 还能有效地抑制肿瘤细胞迁移. 因此, 近红外光敏剂IMBDP-Lys在双光子荧光成像和溶酶体靶向的光动力治疗中具有重要的应用价值.     

3D Printing of Silk Protein Structures by Aqueous Solvent‐Directed Molecular Assembly

Hierarchical molecular assembly is a fundamental strategy for manufacturing protein structures in nature. However, to translate this natural strategy into advanced digital manufacturing like three‐dimensional (3D) printing remains a technical challenge. This work presents a 3D printing technique with silk fibroin to address this challenge, by rationally designing an aqueous salt bath capable of directing the hierarchical assembly of the protein molecules. This technique, conducted under aqueous and ambient conditions, results in 3D proteinaceous architectures characterized by intrinsic biocompatibility/biodegradability and robust mechanical features. The versatility of this method is shown in a diversity of 3D shapes and a range of functional components integrated into the 3D prints. The manufacturing capability is exemplified by the single‐step construction of perfusable microfluidic chips which eliminates the use of supporting or sacrificial materials. The 3D shaping capability of the protein material can benefit a multitude of biomedical devices, from drug delivery to surgical implants to tissue scaffolds. This work also provides insights into the recapitulation of solvent‐directed hierarchical molecular assembly for artificial manufacturing.     

固定丝素蛋白膜中的联吡啶钌电化学发光行为的研究与应用

基于苯海拉明对联吡啶钌(Ru(bpy)2+3)的电化学发光的增敏作用和丝素蛋白-联吡啶钌复合膜修饰玻碳电极稳定好的特点,建立了一种以丝素蛋白多孔膜-联吡啶钌复合物修饰的玻碳电极电化学发光检测苯海拉明的新方法.结果表明,该修饰电极具有很好的电化学活性和电化学发光(ECL)响应.在最佳实验条件下,苯海拉明浓度在1.0×10-4～1.0×10-7 mol/L范围内与其相对发光强度呈良好的线性关系(r=0.9989); 检出限为2.3×10-7 mol/L(S/N=3).连续平行测定3.78×10-5 mol/L苯海拉明5次,发光强度的RSD为1.76%. 用于实际样品中苯海拉明的测定,结果满意.     

Chinese Oak Tasar Silkworm Antheraea pernyi Silk Proteins: Current Strategies and Future Perspectives for Biomedical Applications

Chinese nonmulberry temperate oak tasar/tussah, Antheraea pernyi (Ap) silk is a natural biopolymer that has attracted considerable attention as a biomaterial. The proteinaceous components of Ap silk proteins, namely fibroin and sericin may represent an alternative over mulberry Bombyx mori silk proteins. In fact, the silk fibroin (SF) of Ap is rich in Arginyl‐Glycyl‐Aspartic acid (RGD) peptides, which facilitate the adhesion and proliferation of various cell types. The possibility of processing Ap silk proteins into different distinct 2D‐ and 3D‐based matrices is described in earlier studies, such as membranes, nanofibers, scaffolds, and micro/nanoparticles, contributing to a different rate of degradation, mechanical properties, and biological performance useful for various biomedical applications. This review summarizes the current advances and developments on nonmulberry Chinese oak tasar silk protein (fibroin and sericin)‐based biomaterials and their potential uses in tissue engineering, regenerative medicine, and therapeutic delivery strategies.     

Silk Fibroin Combined with Electrospinning as a Promising Strategy for Tissue Regeneration

The development of tissue engineering scaffolds is of great significance for the repair and regeneration of damaged tissues and organs. Silk fibroin (SF) is a natural protein polymer with good biocompatibility, biodegradability, excellent physical and mechanical properties and processability, making it an ideal universal tissue engineering scaffold material. Nanofibers prepared by electrospinning have attracted extensive attention in the field of tissue engineering due to their excellent mechanical properties, high specific surface area, and similar morphology as to extracellular matrix (ECM). The combination of silk fibroin and electrospinning is a promising strategy for the preparation of tissue engineering scaffolds. In this review, the research progress of electrospun silk fibroin nanofibers in the regeneration of skin, vascular, bone, neural, tendons, cardiac, periodontal, ocular and other tissues is discussed in detail.     

Porous 3‐D scaffolds from regenerated Antheraea pernyi silk fibroin

In this study, porous three‐dimensional (3‐D) materials were prepared with the regenerated Antheraea pernyi (A. pernyi) silk fibroin by freeze‐drying from a lithium thiocyanate solution of its fibers. The relationship between preparation conditions and morphological structures of 3‐D materials was also studied. We concluded that with the decrease in A. pernyi silk fibroin solution concentration and the increase in the freezing temperature, the porosity and the average pore diameter of the 3‐D materials were increased while the pore density was decreased. By adjusting the freezing temperature and the silk fibroin solution concentration, the 3‐D materials having the average pore diameter of 75–260 µm and the porosity of 70–90% can efficiently be produced. As a kind of new material with excellent biocompatibility and bioactivity, the material is expected to be applied to tissue regeneration scaffolds. Copyright © 2007 John Wiley & Sons, Ltd.     

A molecular light-driven water oxidation catalyst

Two mononuclear Ru(II) complexes, [Ru(ttbt)(pynap)(I)]I and [Ru(tpy)(Mepy)(2)(I)]I (tpy = 2,2';6,2"-terpyridine; ttbt = 4,4',4"-tri-tert-butyltpy; pynap = 2-(pyrid-2'-yl)-1,8-naphthyridine; and Mepy = 4-methylpyridine), are effective catalysts for the oxidation of water. This oxidation can be driven by a blue (λ(max) = 472 nm) LED light source using [Ru(bpy)(3)]Cl(2) (bpy = 2,2'-bipyridine) as the photosensitizer. Sodium persulfate acts as a sacrificial electron acceptor to oxidize the photosensitizer that in turn drives the catalysis. The presence of all four components, light, photosensitizer, sodium persulfate, and catalyst, are required for water oxidation. A dyad assembly has been prepared using a pyrazine-based linker to join a photosensitizer and catalyst moiety. Irradiation of this intramolecular system with blue light produces oxygen with a higher turnover number than the analogous intermolecular component system under the same conditions.