PNIPAm@CMCS生物基水凝胶吸附染料研究

针对目前皮革废水处理剂难回收问题,以羧甲基壳聚糖(CMCS)和聚N-异丙基丙烯酰胺(PNIPAm)为原料,合成一种兼具优异吸附性和可重复利用且易回收的生物基水凝胶(PNIPAm@CMCS),并对该水凝胶的抗疲、亲水、溶胀、吸附及抗菌等性能进行了研究。结果表明,所制备的生物基水凝胶具有出色的抗疲性(耐循环压缩15次)、溶胀率(2034%)、吸附性(伊红Y=587 mg/g,罗丹明=444 mg/g,甲基橙=621 mg/g)和抗菌性能(抗菌率=100%)。该生物基水凝胶作为一类高效、环保的染料废水处理剂,展现了广阔的应用前景,有望为制革工业处理含染料污水提供新的思路。

PNIPAM温敏水凝胶诱导小鼠骨骼肌慢性炎症

目的探讨肌内注射PNIPAM温敏水凝胶诱导小鼠骨骼肌慢性炎症的可行性。方法将PNIPAM或其与重组人骨骼肌C蛋白的混合物注入C57BL/6小鼠胫骨前肌(TA),于注射后15、30及60 d分别检测TA肌内单核/巨嗜细胞渗出、肌肉自身抗原表达、MHC-I表达及肌内CD8+T细胞浸润。结果 PNIPAM温敏水凝胶可诱导TA肌内炎症持续达60 d,炎症反应的高峰出现于注射后30 d,随后逐渐减退。PNIPAM水凝胶与C蛋白混合液注射所诱发的肌内炎症较单纯的PNIPAM或C蛋白注射诱发的炎症反应更持久。免疫荧光分析证实,PNIPAM水凝胶注射后可见TA肌内出现CD8+T细胞浸润,部分新生肌纤维表达MHC-I。结论 PNIPAM温敏水凝胶肌内注射可诱导小鼠慢性骨骼肌损伤及炎症反应。

Finite deformation swelling of a temperature-sensitive hydrogel cylinder under combined extension-torsion

The swelling behavior of a temperature-sensitive poly-N-isopropylacrylamide(PNIPAM) hydrogel circular cylinder is studied subjected to combined extension-torsion and varied temperature. In this regard, a semi-analytical solution is proposed for general combined loading. A finite element(FE) analysis is conducted, subjecting a hydrogel cylinder to the combined extension-torsion and the varied temperature to evaluate the validity and accuracy of the solution. A user-defined UHYPER subroutine is developed and verified under free and constrained swelling conditions. The FE results illustrate excellent agreement with the semi-analytical solution. Due to the complexity of the problem, some compositions and applied loading factors are analyzed. It is revealed that for larger cross-linked density and larger ending temperature, the cylinder yields higher stresses and smaller radial swelling deformation. Besides, the radial and hoop stresses increase by applying larger twist and axial stretch. The hoop stresses intersect at approximately R/Rout = 0.58, where the hoop stress vanishes. Besides, the axial force has direct and inverse relationships with the axial stretch and the twist, respectively. However, the resultant torsional moment behavior is complex, and the position of the maximum point varies significantly by altering the axial stretch and the twist.

离子掺杂型复合导电水凝胶的制备

复合导电水凝胶是近几年导电水凝胶的一个重要研究分支。文章通过在聚N-异丙基丙烯酰胺中掺杂海藻酸钠得到海藻酸钠/聚N-异丙基丙烯酰胺(即SA/PNIPAM)复合水凝胶,在SA/PNIPAM复合水凝胶中掺杂金CuCl_(2)、FeCl_(3)进行进一步的改性,分别测试制备出的复合导电水凝胶的了其导电性能、机械性能、应力/应变传感性能测试。发现海藻酸钠与聚N-异丙基丙烯酰胺的复合导电水凝胶具有良好的机械性能。复合导电水凝胶对于压力反映明显,可用于制备不同传感器,满足不同需求。复合导电水凝胶可以导电,并且导电性能理想,可用于导电材料。

掺杂上转换纳米粒子的温敏性发光水凝胶的制备及性能

采用水热法,以聚乙烯亚胺(PEI)为表面改性剂,合成了水分散性较好的上转换纳米粒子(UC@PEI NPs)。考察了溶剂组成、反应时间、PEI分子量与加入量对UC@PEI NPs发光强度的影响,并进行了表征。结果显示:V(H2O)∶V(EG)=1∶1,PEI(Mw=10000)加入量为1.2 g,并于200℃反应8 h为最优合成条件。随后在UC@PEI NPs、聚N-异丙基丙烯酰胺(PNIPAM)存在下,丙烯酰胺、N,N’-亚甲基双丙烯酰胺发生自由基聚合,制备复合水凝胶,采用SEM、拉伸试验机、发光光谱仪进行形貌、机械强度和发光温度响应性的表征。结果表明:该互穿网络结构复合水凝胶反复脱水溶胀后,材料保持完好,平均脱水率和溶胀率为81.18%和61.38%;应力作用下的应变量达到251.10%,机械强度为22.92 kPa;在980 nm近红外光激发下,当温度从20℃升至48℃时,540 nm处(Er3+,4S3/2→4I15/2)的发光强度减少42.64%,而当温度下降,发光强度可逆回升。说明该复合水凝胶具有可逆的上转换发光温度响应性,材料稳定性和拉伸性良好,并且有一定的机械强度。

低场固体NMR研究纳米复合凝胶结构与动力学

纳米复合水凝胶复杂的微观结构和动力学决定了其宏观性能,阐明其结构和动力学的非均匀性对揭示凝胶相变机理、认识其宏观物理和化学性质和设计新型高分子凝胶都具有重要意义.通过合成不同粘土含量的系列聚异丙基丙烯酰胺(PNIPAm)/锂藻土纳米复合水凝胶,运用多种先进的低场固体NMR技术详细研究了凝胶微观结构和动力学的非均匀性.首先建立了分析多组分凝胶体系中刚性和柔性高分子组分相对含量的计算方法,然后在不同粘土含量下,通过测量凝胶FID信号和质子T1定量研究了凝胶中刚性和柔性高分子组分的相对含量;通过偶极滤波双量子NMR实验,研究了体系中与交联密度关联的残余偶极作用参数随黏土含量的变化.结果表明:在纳米复合水凝胶中,随着粘土含量的增加,凝胶中聚合物的刚性相增加,而柔性相下降,当粘土含量达到12%(Wclay/Wwater)时体系中的刚性相含量趋于平衡.多量子实验结果表明,随着粘土含量的增加,纳米复合水凝胶中高分子链的残余偶极作用参数逐渐增大,反映了体系中高分子链的受限运动和二维无机纳米片层形成的物理交联密度增大的趋势.

聚N-异丙基丙烯酰胺水凝胶的制备及热致聚集行为

以异丙基丙烯酰胺(NIPAM)为单体、N,N’-亚甲基双丙烯酰胺(MBA)为交联剂、过硫酸钾(KPS)为引发剂,采用无皂乳液聚合法制备聚N-异丙基丙烯酰胺(PNIPAM),考察了聚合时间、温度、浓度、pH值、共存NaCl和MgCl2浓度对PNIPAM热致聚集行为的影响,并通过扫描电镜(SEM)、红外光谱(FTIR)等手段对PNIPAM的形貌和分子结构进行了表征。结果表明:线型PNIPAM更易在水中稳定存在,采用无皂乳液聚合技术制备PNIPAM过程简单、易操作,产物温敏效应明显。PNIPAM的热致聚集行为随聚合时间的延长、PNIPAM悬浊液浓度的增加、pH值的减小、共存盐浓度的增大而更为显著。

交联剂和温度对聚(N-异丙基丙烯酰胺)水凝胶热致行为的影响

聚(N-异丙基丙烯酰胺)(PNIPAM)具有良好的两亲性,是一种热响应型水凝胶。系统考察了交联剂用量和反应温度对PNIPAM水凝胶热致行为的影响。研究发现,两个因素对PNIPAM水凝胶的低临界溶液温度(LCST)影响不大,但对其外观形态、溶胀率以及收缩和溶胀动力学有较大影响。动力学结果表明,PNIPAM水凝胶的收缩和溶胀是一个多步复杂的过程,相对于低温(4℃)和高温(45℃)下的反应,25℃下交联剂用量大于6 phr时可获得性能较稳定、热致行为近似一致的PNIPAM水凝胶。稳定的热响应性能使其在智能材料、智能机器人、控制药物释放等方面具有巨大的应用潜力。

EuF_3-NaYF_4纳米晶/PNIPAm三元复合凝胶的荧光温敏行为与影响机制

分别采用水热法制备EuF3与NaYF4纳米晶,与N-异丙基丙烯酰胺(NIPAm)混合后进行自由基聚合,一步法合成EuF3-NaYF4纳米晶/聚N-异丙基丙烯酰胺(PNIPAm)三元复合凝胶.对纳米晶与复合凝胶的结构与荧光性能进行了表征.重点研究了三元复合凝胶的荧光温敏行为,并对其影响机制进行了探讨.结果表明,EuF3与NaYF4纳米晶在PNIPAm凝胶基体中的体相掺杂,同样产生了明显的能量传递.两种纳米晶相对含量的变化,对复合凝胶的荧光温敏性能有重要影响.

温敏型Keratin/PNIPAM水凝胶的制备及其对重金属离子的吸附性能和机理研究

以羽毛中提取的角蛋白为原料,N-异丙基丙烯酰胺(NIPAM)为温敏性单体,采用一锅法制备了对温度敏感的双网络型角蛋白/PNIPAM水凝胶,并对其结构、膨胀性能、吸附特性、吸附选择性及吸附机理进行了研究。结果表明,温敏型角蛋白/PNIPAM水凝胶符合负向温敏凝胶的特征,在高于低临界转变温度时凝胶排水收缩,在低于低临界转变温度时凝胶迅速吸水膨胀;温敏型角蛋白/PNIPAM水凝胶随着pH的增大对重金属Pb(Ⅱ)的吸附容量逐渐增大,在pH 5时达到最大吸附容量78.63 mg/g。温敏型角蛋白/PNIPAM水凝胶在吸附重金属Pb(Ⅱ)的过程中仅用30 min即可达到吸附平衡,对Pb(Ⅱ)的最大吸附容量为415.73 mg/g。吸附模型拟合和吸附动力学分析结果表明温敏型角蛋白/PNIPAM水凝胶符合Langmuir吸附模型(R^(2)=0.992),属于单层吸附。吸附动力学模型分析显示该凝胶符合准二级动力学模型,以化学吸附为主,物理吸附为辅。

Multi-bond Network Hydrogels with Robust Mechanical and Self-healable Properties

Multi-bond network（MBN） which contains a single network with hierarchical cross-links is a suggested way to fabricate robust hydrogels. In order to reveal the roles of different cross-links with hierarchical bond energy in the MBN, here we fabricate poly（acrylic acid） physical hydrogels with dual bond network composed of ionic cross-links between carboxylFe3＋ interactions and hydrogen bonds, and compare these dually cross-linked hydrogels with singly and ternarily cross-linked hydrogels. Simple models are employed to predict the tensile property, and the results confirm that the multi-bond network with hierarchical distribution in the bond energy of cross-links endows hydrogel with effective energy-dissipating mechanism. Moreover, the dually cross-linked MBN gels exhibit excellent mechanical properties（tensile strength up to 500 k Pa, elongation at break ~ 2400%） and complete self-healing after being kept at 50 °C for 48 h. The factors on promoting self-healing are deeply explored and the dynamic multi-bonds are regarded to trigger the self-healing along with the mutual diffusion of long polymer chains and ferric ions.

PREFACE

Hydrogels are classical soft and wet materials that have been extensively studied over the past several decades. Recently, with the development of supramolecular science, nanotechnology and precisely synthetic chemistry, various novel hydrogels have been designed and fabricated, which show emerging applications in tissue engineering, drug delivery, anti-fouling coatings, flexible electronics and soft robotics. Through tailoring their two-dimensional surface structures and three- dimensional networks, unique properties such as ultra-high mechanical strength, responsiveness to various kinds of stimuli, biocompatibility, special wettability and adhesion can be achieved.