聚乳酸共混物立构复合物的形成及其结构性能研究进展

聚乳酸立构复合物(SC-PLA)由左旋聚乳酸(PLLA)和右旋聚乳酸(PDLA)以31螺旋构象并排堆砌而成,由于分子链间的紧密堆积,SC-PLA具有更高的晶体稳定性、熔点(约比PLLA高50℃)以及良好的热、力学、降解等性能。PLLA和PDLA共混是目前制备SC-PLA的一类常用方法,包括溶液共混、熔融共混、微波辐射共混等,SC-PLA在形成过程中会受到PLLA和PDLA的分子量、光学纯度、混合比例等因素影响。本文综述了PLLA和PDLA通过共混形成SC-PLA的条件和机理,以及SC-PLA的微观结构、性能和应用现状。     

高耐热聚乳酸立体复合材料的制备

以等比例的聚L乳酸(PLLA)和聚D乳酸(PDLA)树脂为原料,先通过低温共混制备聚乳酸全立构粉末,然后将立构粉末与成核剂、玻璃纤维等混合,直接在注塑机中成型,注塑样品经热处理后,得到高耐热性能聚乳酸(PLA)样品,经测试,其维卡软化温度高达165 ℃以上,差示扫描量热分析(DSC)结果表明,处理后的样品富含立构物结晶,立构物结晶熔融焓高达27.6 J/g。 拉伸强度较纯PLA也有大幅提升,达到129 MPa。     

一种基于立构复合及自组装方法构筑的耐受性疏水表面

利用丙交酯开环聚合法制备了聚(D-乳酸)-聚二甲基硅氧烷-聚(D-乳酸)(PDLA-b-PDMS-b-PDLA)三嵌段聚合物,将其溶液涂覆至充斥着非溶剂蒸汽的聚(L-乳酸)(PLLA)表面,PDLA-b-PDMS-b-PDLA在缓慢沉积的过程中与PLLA发生立构复合及自组装,得到由立构复合的亚微米颗粒组装体形成的聚乳酸表面疏水层。 研究了聚合物溶液的质量浓度、组装温度以及溶剂对聚乳酸表面的微观形貌和疏水性能产生的影响。 结果表明,随着PDLA-b-PDMS-b-PDLA聚合物溶液质量浓度的增加,可以实现聚乳酸表面Wenzel-Cassie-Wenzel的疏水行为转变;在0 ℃下,可得到最大疏水角151°的疏水层;选择对聚合物溶解性、挥发速度不同的溶剂,得到的表面微观形貌和疏水性也不同。 由于聚乳酸制品表面的PLLA链段与亚微米颗粒中的PDLA链段也能够立构复合,因此该表面疏水层对刀刮、胶带剥离和手指擦拭测试均表现出良好的耐受性。     

立构复合化聚乳酸纳纤膜的制备及高效滤除PM2.5性能

聚乳酸(PLA)纳米纤维在环境友好型纤维过滤材料领域有良好的应用前景,但受制于其本征螺旋分子链构象和低介电常数的不足,导致其驻极性能差、过滤性能(过滤效率及压降)易衰减以及有效服役周期短.本文将高旋光性的聚L-乳酸(PLLA)和聚D-乳酸(PDLA)溶液共混,并通过静电纺丝过程的高压静电场诱导C=O基团加速取向极化,形成高电活性的立构复合晶体(SCs),显著提高聚乳酸纳纤膜的表面电位、介电常数及驻极效果等电活性特征,增大纤维表面静电斥力,促进PLA纳纤膜(PLA NFMs)的纤维细化,从而使其压降大幅降低(85 L/min, 209.2 Pa),过滤PM_2.5效率显著提高至96.32%(纯PLLA对比样为72.44%).更重要的是,立构复合化PLA纳纤膜(SC-PLA NFMs)的过滤性能受气体流量变化影响较小(10～85 L/min),当气流增大时,过滤效率的衰减远远低于纯PLLA,在高气流下的稳定性使其能更好地满足在空气过滤领域的实际应用需求.此外,提高PLA纳纤膜电活性可显著增强摩擦生电输出性能和呼吸振动激发电信号,为基于人体呼吸的生理特征监测奠定理论基础....     

界面立构复合化电活性聚乳酸纳纤膜的制备及高效过滤性能

聚乳酸纤维膜在可降解空气过滤材料领域具有巨大潜力,但低比例的电活性相导致纤维膜的介电性能较弱,难以满足高性能空气颗粒物(PMs)过滤材料的需要.本文利用聚L-乳酸(PLLA)和聚D-乳酸(PDLA)组成的立构复合物(SC)提供高比例电活性相,采用同轴静电纺丝策略构筑界面立构复合化的电活性聚乳酸纳纤膜.通过改变纺丝时的注射速度,调控纤维形貌以及羰基(C=O)偶极子、 β晶相和界面立构复合晶(SCs)的形成,得到的核壳(CS)结构纳纤膜具有改善的表面电势(9.3 kV)和介电常数(1.60 F/m).界面立构复合化的纤维膜力学性能提升显著,核部PLLA和壳部PDLA的注射速度分别为1.0和0.5 mL/h时获得的CS1.5纳纤膜的拉伸强度和杨氏模量分别达到17.2和351.1 MPa,明显优于纯聚乳酸纤维膜.更重要的是,提升的电活性显著增强了聚乳酸纳纤膜对PM0.3和PM2.5的过滤效率,界面立构复合化在应对高流速下捕尘时具有独特优势, CS1.5纳纤膜的过滤效率由10 L/min时的82.5%提升至85 L/min时的97.9%.本文提出了采用界面立构复合化激发聚乳酸电活性的策略,为解决...     

高耐热PLLA/PDLA共混物的热性能和结晶结构研究

通过熔融共混法制备了一系列等比例聚左旋乳酸(PLLA)/聚右旋乳酸(PDLA)共混试样,采用差示扫描量热法(DSC)、核磁共振(13C-NMR)及广角X射线衍射(WAXD)等方法对共混产物进行了表征和研究分析.结果表明,等比例PLLA和PDLA熔融共混生成了立构复合物(stereocomplex,sc),同时部分均聚物发生酯交换反应,生成了立体嵌段物(stereoblock,sb),从而在DSC升温曲线上sc晶体处出现特殊的熔融双峰现象;随着熔融共混温度升高,sc晶体的生成率和结晶度逐渐下降;聚乳酸立构复合物的加工稳定性较好,二次加工后,sc晶体熔点基本不变,生成率和结晶度提高;由于sc晶体的存在,PLLA/PDLA共混物的耐热性能提高,退火热处理后耐热性能得到进一步提高.这对于开发高耐热聚乳酸及其加工应用具有重要的应用价值.     

非手性席夫碱-异丙氧基铝引发外消旋丙交酯的立构选择性聚合

摘要以非手性的席夫碱-异丙氧基铝(Ⅱ)引发外消旋丙交酯(rac-LA)的立构选择性聚合. 其聚合动力学研究结果表明, 聚合反应对于单体符合一级反应动力学. 所得聚合物的数均分子量与单体转化率成正比, 并且分子量分布很窄， 表明该聚合反应具有良好的可控性. 此外所得的聚外消旋乳酸是tm为179 ℃的结晶性聚合物. 13C NMR和同核去偶1H NMR谱表明, 所得的聚乳酸是一种立构嵌段聚合物, 平均嵌段长度为11个乳酸单元.     

立构复合PL(D) LA-TMC无规共聚物的制备、结构与性能

以辛酸亚锡为催化剂,通过开环聚合法制备了聚左旋乳酸-三亚甲基碳酸酯(PLLA-TMC)和聚右旋乳酸-三亚甲基碳酸酯(PDLA-TMC)无规共聚物.利用共聚物中PLLA/PDLA链段形成立构复合体,通过溶液浇注法制备了PLLA-TMC/PDLA-TMC立构复合聚乳酸材料(sc-PLA-TMC).研究结果表明,聚合物链中的柔性TMC单元可以增强L(D)LA链段的运动能力,有助于不同旋光性的LA链段形成立构复合晶体,但也使得L(D)LA链段的规整度和序列长度降低.即随着共聚物链段中柔性TMC单元摩尔含量的增加,sc-PLA-TMC中同质结晶能力降低.当TMC含量≥5%时,仅生成熔点200℃的PLLA/PDLA立构复合结晶,表明sc-PLA-TMC的耐热性有所提高.蛋白酶K降解实验表明,PL(D)LA-TMC共聚物的降解速率不但比PLLA高,而且可通过共聚物中TMC含量进行调控.     

不断向自然与金属冶金学习的高分子加工

总结了高分子材料加工的发展趋势及发展历程,并指出过去很多加工新技术的出现都得益于从自然现象及其他材料行业中获得很好的借鉴,如从蜘蛛吐丝发展出溶液纺丝成型、从玻璃吹制发展出吹塑成型、从金属锻造发展出压延成型及固相拉拔成型等;随后针对生物基可生物降解的立构复合型聚乳酸难以采用传统熔融加工方法成型的问题,借鉴金属粉末冶金加工的思路,提出了一种通过低温烧结制备高性能立构复合型聚乳酸制品的新方法.通过这种加工方法不仅可以有效解决立构复合型聚乳酸在熔融加工过程中熔体稳定性差、易降解的问题,而且可以制得耐热性好、光学透明度高、耐水解降解性佳、综合力学性能优异的高性能聚乳酸制品.     

三臂PPO-PDLA-PLLA 嵌段共聚物的制备与结构及其立构复合体的结晶行为

以环氧丙烷聚醚三元醇(PPO)为起始剂, 开环聚合D 型丙交酯(DLA), 合成三臂环氧丙烷聚醚三元醇-聚右旋乳酸(PPO-PDLA)嵌段预聚体. 采用端基活化技术对预聚体进行端羟基活化, 再与L 型丙交酯(LLA)进行逐步开环聚合,合成了不同分子量的三臂环氧丙烷聚醚三元醇-聚右旋乳酸-聚左旋乳酸(PPO-PDLA-PLLA)嵌段共聚物. 采用红外(FTIR)、核磁(NMR)和凝胶渗透色谱(GPC)等对三臂PPO-PDLA-PLLA 嵌段共聚物的测试表明, 合成的嵌段共聚物分子链具有很高的立构规整度; 通过调节LLA 单体与PPO-PDLA 预聚体的投料比, 不仅可控制产物的分子序列结构, 而且样品的数均分子量可大于100 kDa. 差示扫描量热仪(DSC)和广角X 射线衍射(WAXD)结果显示, 三臂PPO-PDLAPLLA嵌段共聚物的异构体链段分子间生成立构复合晶体, 其熔点约为200 ℃, 且没有PLLA 均聚物链段结晶现象. 实验结果表明, 这是一类具有实际应用价值的新型耐热聚乳酸(PLA)材料.     

Shortening of Amino Acids from C-terminal of PZase as Basis of Pyrazinamide Resistance in P14 Isolate of Mycobacterium Tuberculosis Strain

Pyrazinamide (PZA) is one of the mainstays WHO-recommended drugs for therapy of tuberculosis (TB). The emergence of PZA resistance in clinical isolates of M. tuberculosis is often associated with pncA gene mutations encoding PZase. A local clinical isolate of Mycobacterium tuberculosis strain showed phenotipe resistant to PZA at concentration of 10 μg/mL. The ORF of pncA gene of the isolate showed deletion of guanine base at position 81, then followed by shortening of 70 amino acids from C-terminal of PZAse which has 186 amino acid residues. The mutant of PZase took frame shift of amino acids after the residue at position 27. The pncA gene mutation at the level of genotype, that produced a physical-chemical alteration of the active site or the metal-binding site of PZase, in this case perturbing or lossing its activity was proposed as trigering the PZA resistance in P14 clinical isolate of M. tuberculosis strain.     

Si-Zr-C-O纤维的耐高温抗氧化性能研究

以聚硅碳硅烷(PSCS)与乙酰丙酮锆为原料合成聚锆碳硅烷(PZCS),采用先驱体转化法制备了Si-Zr-C-O纤维.通过元素分析、扫描电镜(SEM)、X射线衍射(XRD)和俄歇电子能谱(AES)等分析测试手段研究了Si-Zr-C-O纤维的组成结构及其耐高温抗氧化性能.结果表明:Si-Zr-C-O纤维的元素组成为SiC1.24HxO0.56Zr0.0129,平均强度2.5GPa,平均直径11μm,纤维表面光滑平坦,没出现孔洞、裂纹、沟槽等缺陷,直径均匀.该纤维耐超高温性能良好,在1450和1600℃处理后,强度保留率分别为72%和36%,1800℃处理后Si-Zr-C-O纤维的化学式为SiC0.99HxO0.1Zry,纤维氧含量大大降低;纤维抗氧化性能良好,空气中1000℃热处理20h后,强度保留率为71.2%,热处理100h后,强度保留率为50%.     

A scratch-resistant single-layer antireflective coating by a low temperature sol-gel route

A novel quarterwave-thick narrow-bandwidth antireflective coating has been developed for both plastic and vitreous substrates by a sol-gel route. This coating has revealed pronounced scratch- and climatic-resistance under adverse conditions. The single-layer coating consists basically of a composite material made of silica as the discontinuous phase and of a polytetrafluoroethylene-derived (Teflon¹) organic polymer as the continuous phase. This leads to fluorine-containing colloidal silica product, or a so-called Flucosil coating. The coating is applied by spinning or dipping from specific solutions at room temperature followed by a mild and short heat treatment. In addition to remarkable abrasion and environmental resistance properties, such coatings have displayed excellent laser-induced damage threshold levels, surpassing uncoated substrates.We hope such a product might open new perspectives concerning household articles, architectural optical thin-films, ophthalmic uses, and so on.     

稀土添加剂对镍,铜刷镀层质量的影响

通过在刷镀镀液中加入稀土添加剂，研究稀土对刷镀层质量的影响。实验结果表明，稀土起到平整、光亮、细化镀层晶粒、减少镀层应力的作用，并增强镀层结合力，提高镀层的耐磨性、耐蚀性。     

Hybrid Drugs—A Strategy for Overcoming Anticancer Drug Resistance?

Despite enormous progress in the treatment of many malignancies, the development of cancer resistance is still an important reason for cancer chemotherapy failure. Increasing knowledge of cancers’ molecular complexity and mechanisms of their resistance to anticancer drugs, as well as extensive clinical experience, indicate that an effective fight against cancer requires a multidimensional approach. Multi-target chemotherapy may be achieved using drugs combination, co-delivery of medicines, or designing hybrid drugs. Hybrid drugs simultaneously targeting many points of signaling networks and various structures within a cancer cell have been extensively explored in recent years. The single hybrid agent can modulate multiple targets involved in cancer cell proliferation, possesses a simpler pharmacokinetic profile to reduce the possibility of drug interactions occurrence, and facilitates the process of drug development. Moreover, a single medication is expected to enhance patient compliance due to a less complicated treatment regimen, as well as a diminished number of adverse reactions and toxicity in comparison to a combination of drugs. As a consequence, many efforts have been made to design hybrid molecules of different chemical structures and functions as a means to circumvent drug resistance. The enormous number of studies in this field encouraged us to review the available literature and present selected research results highlighting the possible role of hybrid drugs in overcoming cancer drug resistance.     

Manipulating the Flow of Nanoconfined Water by Temperature Stimulation

The manipulation of a nanoconfined fluid flow is a great challenge and is critical in both fundamental research and practical applications. Compared with chemical or biochemical stimulation, the use of temperature as controllable, physical stimulation possesses huge advantages, such as low cost, easy operation, reversibility, and no contamination. We demonstrate an elegant, simple strategy by which temperature stimulation can readily manipulate the nanoconfined water flow by tuning interfacial and viscous resistances. We show that with an increase in temperature, the water fluidity is decreased in hydrophilic nanopores, whereas it is enhanced by at least four orders of magnitude in hydrophobic nanopores, especially in carbon nanotubes with a controlled size and atomically smooth walls. We attribute these opposing trends to a dramatic difference in varying surface wettability that results from a small temperature variation.     

氨乙基氨丙基聚二甲基硅氧烷改性水性聚酯型聚氨酯的研究

由聚酯二元醇、异佛尔酮二异氰酸酯和二羟甲基丙酸合成聚氨酯预聚体，以氨乙基氨丙基聚二甲基硅氧(AEAPS)为扩链剂，制备了AEAPS改性聚氨酯水分散液。与未改性的聚氨酯水分散液相比，AEAPS改性聚氨酯水分散液的粒径增大，但粒径分布和表面张力基本不变，说明疏水的聚二甲基硅氧烷侧链被包裹于分散颗粒的内部；此外，改性聚氨酯水分散液的冻融稳定性显著增强。AEAPS改性聚氨酯水分散液成膜后，吸水率明显下降，水在膜表面的接触角增加，400℃时热失重下降，具有良好的疏水性和耐热性。