Miscibility, Crystallization, and Rheological Behavior of Solution Casting Poly（3-hydroxybutyrate）/poly（ethylene succinate） Blends Probed by Differential Scanning Calorimetry, Rheology, and Optical Microscope Techniques

The miscibility and crystallization of solution casting biodegradable poly（3-hydroxybuty- rate）/poly（ethylene succinate） （PHB/PES） blends was investigated by differential scanning calorimetry, rheology, and optical microscopy. The blends showed two glass transition temperatures and a depression of melting temperature of PHB with compositions in phase diagram, which indicated that the blend was partially miscible. The morphology observation supported this result. It was found that the PHB and PES can crystallize simultaneously or upon stepwise depending on the crystallization temperatures and compositions. The spherulite growth rate of PHB increased with increasing of PES content. The influence of compositions on the spherulitic growth rate for the partially miscible polymer blends was discussed.

Enzymatic Degradation of Poly(butylenesuccinate)/Thermoplastic Starch Blend

The degradation of thermoplastic starch blend in the presence of commerciala-amylase and unpurified amylase of microbial origin was investigated.The blends consisting of thermoplastic starch and poly(butylene succinate)have potential use in packaging applications thus,it is essential to establish susceptibility to degradation.Molar mass loss,gravimetric weight loss,and molecular structure were evaluated.The changes in the surface were observed with scanning electron microscopy.It was confirmed that there was a significant difference in gravimetric weight loss between the blends degraded in two different solutions.Unpurified enzymes of microbial origin,produced by Rhizopus oryzae cultures decomposed analyzed materials more efficiently than purified commercial ones.Moreover,it was proved that in applied conditions,the molar mass of PBS fraction did not change significantly.

Improving Polylactide Toughness by Plasticizing with Low Molecular Weight Polylactide-Poly(Butylene Succinate)Copolymer

A low-molecular-weight polylactide-poly(butylene succinate)(PLA-PBS)copolymer was synthesized and incorporated into polylactide(PLA)as a novel toughening agent by solvent casting.The copolymer had the same chemical structure and function as PLA and it was used as a plasticizer to PLA.The copolymer was blended with PLA at a weight ratio from 2 to 10 wt%.Phase separation between PLA and PLA-PBS was not observed from their scanning electron microscopy(SEM)images and the crystal structure of PLA almost remained unchanged based on the X-ray diffraction(XRD)measurement.The melt flow index(MFI)of the blends was higher as the amount of PLA-PBS increased,indicating that the block copolymer did improve the mobility of the PLA chains.Moreover,tensile tests revealed that PLA with greater PLA-PBS copolymer exhibited higher elongation at break and it reached the maximum at 8 wt%of PLA-PBS in PLA,which was around 6 times higher than that of pure PLA.Furthermore,the glass transition temperature,measured by differential scanning calorimetry(DSC),markedly decreased with an increasing amount of the copolymer as it decreased from 61.2℃ for pure PLA to 41.3℃when it was blended with 10 wt%PLA-PBS copolymer.Therefore,the PLA-PBS copolymer was shown to be a promising plasticizer for fully biobased and toughened PLA.

Delivery of docetaxel using pH-sensitive liposomes based on D-α-tocopheryl poly(2-ethyl-2-oxazoline) succinate:Comparison with PEGylated liposomes

This study aimed to investigate the ability of the novel materials D-α-tocopheryl poly(2-ethyl-2-oxazoline) succinate(TPOS) to construct pH-sensitive liposomes. TPOS was initially synthesized and characterized by TLC, FTIR, and ~1H-NMR. The buffering capacity of polyethylene glycol-distearoyl phosphatidylethanolamine(PEG-DSPE) and TPOS was determined by acid-base titration, and TPOS displayed a slower downtrend and gentler slope of titration curve than PEG-DSPE within pH 7.4–5.0. Studies on the in vitro drug release demonstrated that TPOS modified docetaxel(DOC) liposomes(TPOS-DOC-L) had a slower drugrelease rate at pH 7.4 similar to PEGylated-DOC liposomes(PEG-DOC-L), whereas the release rate reached approximately 86.92% ± 1.69% at pH 6.4. In vitro cellular uptake assays by microplate reader, and flow cytometry revealed that TPOS modified coumarin 6 liposomes(TPOS-C6-L) had stronger cellular uptake at pH 6.4 than that at pH 7.4( P < 0.01). Conversely, for PEGylated C6 liposomes(PEG-C6-L) and conventional C6 liposomes(C6-L), very similar cellular uptakes were exhibited at different pH values. Confocal laser scanning microscopy images showed that PEG-C6-L and C6-L were mainly located in lysosomes. By contrast, TPOS-C6-L showed broader cytoplasmic release and distribution at 4 h. MTT assay showed that the cytotoxicity of TPOS-DOC-L was similar to that of PEG-DOC-L and conventional DOC liposomes(DOC-L) at the same DOC concentration and at pH 7.4, but was much lower than those at pH 6.4 after 48 h of incubation. The apoptosis of PEG-DOC-L and DOC-L had no remarkable improvement with decreased pH from 7.4 to 6.4. Meanwhile, TPOS-DOC-Lsignificantly induced the apoptosis of HeLa cells with decreased pH. Therefore, TPOS can be a biomaterial for the construction of a pH-sensitive drug delivery system.

Construction and evaluation of co-electrospun poly (butylene succinate)/gelatin materials as potential vascular grafts

In this study,a series of poly(butylene succinate)(PBSU)/gelatin composites were prepared by electrospinning.The morphology,physicochemical analysis,biomechanical properties,biocompatibility,and biodegradability of the materials were evaluated.The results showed that the ultimate tensile stress of the vascular PBSU/gelatin grafts at(95/5),(90/10),(85/15),and(80/20)was(4.17±0.54)MPa,(3.81±0.44)MPa,2.94±0.69 MPa and 2.11±0.72 MPa respectively,and the burst pressure was(282.7±22.3)kPa,(295.3±3.9)kPa,(306.8±13.9)kPa and(307.6±9.0)kPa respectively,which met the requirements of tissue-engineered blood vessels.Furthermore,the addition of gelatin improved the hydrophilicity and degradation properties of PBSU,thus enhancing cell adhesion and promoting the inward growth of vascular smooth muscle cells.In summary,the research in this paper provides a useful reference for the preparation and optimization of vascular scaffolds.

Influencing Factors and Process on <i>in Situ</i>Degradation of Poly(<i>Butylene Succinate</i>) Film by Strain <i>Bionectria ochroleuca</i>BFM-X1 in Soil

This is the first report on the PBS film degraded by any Bionectria ochroleuca fungal strain. The fungal strain BFM-X1 was isolated from an air environment on a vegetable field and was capable of degrading poly(butylene succinate) (PBS). The taxonomic identity of the strain BFM-X1 was confirmed to be Bionectria ochroleuca (showing a 99% similarity to B. ochroleuca in a BLAST search) through an ITS rRNA analysis. The bio-degradation of the PBS film by strain BFM-X1 was studied. Approximately 97.9% of the PBS film was degraded after strain BFM-X1 was inoculated at 28?C for 14 days. The degradation efficiency of BFM-X1 against PBS film under different soil environmental conditions was characterized. The results indicated that 62.78% of the PBS film loss was recorded in a 30-d experimental run in a sterile soil environment indoors. On adding strain BFM-X1 to a soil sample, the PBS degradation rate accelerated approximately fivefold. Furthermore, both temperature and humidity influenced the in situ degradation of the PBS by strain BFM-X1, and temperature may be the major regulating factor. The degradation was particularly effective in the warm season, with 90% of weight loss occurring in July and August. Scanning electron microscope observations showed surface changes to the film during the degradation process, which suggested that strain BFM-X1preferentially degraded an amorphous part of the film from the surface. These results suggested that the strain B. ochroleuca BFM-X1 was a new resource for degrading PBS film and has high potential in the bioremediation of PBS-plastic-contaminated soil

Crystallization and Dynamic Mechanical Behavior of Coir Fiber Reinforced Poly(Butylene Succinate)Biocomposites

The crystallization behavior,crystal morphology and form,and viscoelastic behavior of poly(butylene succinate)(PBS)and coir fiber/PBS composites(CPB)were investigated by differential scanning calorimetry(DSC),polarized optical microscopy(POM),X-ray diffraction(XRD)and dynamic mechanical analysis(DMA).The results of DSC measurement show that the crystallization temperature increases with the filling of coir fibers.POM images reveal that the spherulitic size and crystallization behavior of PBS are influenced by the coir fibers in the composites.XRD curves show that the crystal form of pure PBS and CPB are remaining almost identical.In addition,the storage modulus of CPB significantly increases comparing with the pure PBS.This predicted the dimensional stability and improved load-deformation temperature.In conclusion,the addition of coir fibers has a significant effect on the thermal properties of the matrix.

Unlocking the Potential of Poly(butylene succinate)through Incorporation of Vitrimeric Network Based on Dynamic Imine Bonds

Poly(butylene succinate)(PBS)exhibits many advantages,such as renewability,biodegradability,and impressive thermal and mechanical properties,but is limited by the low melt viscosity and strength resulted from the linear structure.To address this,vitrimeric network was introduced to synthesize PBS vitrimers(PBSVs)based on dynamic imine bonds through melt polymerization of hydroxyl-terminated PBS with vanillin derived imine containing compound and hexamethylene diisocyanate using trimethylolpropane as a crosslinking monomer.PBSVs with different crosslinking degrees were synthesized through changing the content of the crosslinking monomer.The effect of crosslinking degree on the thermal,theological,mechanical properties,and stress relaxation behavior of the PBSVs was studied in detail.The results demonstrated that the melt viscosity,melt strength,and heat resistance were enhanced substantially without obvious depression in crystallizability,thermal stability,and mechanical properties through increasing crosslinking degree.In addition,the PBSVs exhibit thermal reprocessability with mechanical properties recovered by more than 90%even after processing for three times.Furthermore,PBSV with improved melt properties shows significantly improved foamability compared to commercial PBS.This research contributes to the advancement of polymer technology by successfully developing PBS vitrimers with improved properties,showcasing their potential applications in sustainable and biodegradable materials.

聚丁二酸丁二醇酯熔融缩聚增黏特性

为解决生物可降解聚丁二酸丁二醇酯(PBS)长期正常储存过程中易发生降解而导致分子量下降的难题,通过熔融缩聚增黏方法实现了PBS分子量的提升。研究了反应温度、反应时间、初始特性黏度以及熔体膜厚等对PBS特性黏度、分子量、热性能和流变性能的影响。结果表明:PBS分子量随熔融缩聚增黏温度升高而升高;220℃反应60min,PBS特性黏度即可从1.049dL/g升至2.072dL/g;PBS初始黏度越低其增黏速率越高;而PBS的熔体膜厚与其增黏反应速率呈反比;PBS特性黏度的升高导致结晶困难,进而使其熔点下降。流变测试结果表明随着特性黏度升高,PBS熔体强度与热稳定性均提升,能满足重新加工和使用的需求,通过熔融再聚合方法可有效解决PBS因降解而无法满足其后续加工和使用需求的难题。

木质素在合成可降解高分子材料中的应用研究进展

简述了木质素的结构、特性和分类情况,并综述了近年来国内外使用木质素来增强和改善聚对苯二甲酸-己二酸丁二酯、聚乳酸、聚己内酯和聚丁二酸丁二酯等合成可降解高分子材料性能的研究进展。指出木质素与合成可降解高分子材料复合可以赋予复合材料多种功能特性,如紫外屏蔽、抗菌、阻隔等,并能改善材料的生物降解性能,同时实现降本增效的目标。最后提出当前木质素与合成可降解高分子材料复合材料工业化生产应用存在的问题,并对木质素基全生物降解复合材料的未来研究趋势进行展望。

静电纺丝HNTs/PBST复合纳米纤维膜的制备及其空气过滤性能研究

采用静电纺丝工艺,以可生物降解的聚丁二酸丁二醇-共-对苯二甲酸丁二醇酯(PBST)为原料,改性埃洛石纳米管(HNTs)为驻极体,制备了HNTs/PBST复合纳米纤维膜,探讨了HNTs对PBST纳米纤维膜的形貌、结构及空气过滤性能的影响。实验结果表明,改性HNTs添加量为10%(w)即可使PBST纳米纤维直径细化,协同增强了纳米纤维膜的物理筛分效应及静电吸引能力,显著提升了材料的综合过滤性能,HNTs/PBST复合纳米纤维膜对PM0.3的过滤效率高达96.67%,且过滤阻力仅为90.5 Pa。

酰肼类成核剂己二酸二苯基二酰肼对PBS复合材料性能的影响

聚丁二酸丁二酯(PBS)是近些年兴起的一类绿色环保高分子材料,具有良好的生物可降解性和生物相容性,是最具发展潜力的环境友好材料之一。然而PBS冲击强度较低,结晶性能较差,限制了其进一步的发展和应用。针对以上不足,采用酰肼类成核剂己二酸二苯基二酰肼(TMC-306)对PBS树脂进行改性,研究了酰肼类成核剂的添加量对PBS复合材料力学性能、结晶性能、加工性能以及微观形貌的影响。结果表明,TMC-306的引入明显改善了PBS/TMC-306复合材料的力学性能和结晶性能,当TMC-306添加量为15份时,PBS复合材料的冲击强度从41 J/m提高至102 J/m,提升了149%,结晶度从48.40%提高至62.01%,提升了28.12%。X射线衍射测试结果表明,成核剂TMC-306使复合材料晶面的衍射峰面积略微增大,与纯PBS晶型基本一致。流变测试结果发现,随着成核剂添加量的增加,PBS复合材料的储能模量、损耗模量和复数黏度均逐步增大,熔体强度得到了提高,这说明成核剂同时也改善了复合材料的加工性能。扫描电子显微镜测试结果表明,随着TMC-306的增加,PBS复合材料的断面由平整光滑变为“阶梯”式结构,且在添加量为15份时最为明显,这与力学测试结果相一致。

阻燃聚丁二酸丁二醇酯的研究进展

综述了近年来聚丁二酸丁二醇酯(PBS)复合材料阻燃改性技术的研究进展,并分析了其阻燃机理。常用于PBS复合材料的阻燃剂以磷氮系阻燃剂、纳米阻燃剂、生物基阻燃剂及其复配体系为主。其中磷氮系阻燃剂的开发和改性方案最多,尤其是基于聚磷酸铵(APP)的阻燃体系是目前研究最多也是最有效的体系,包括APP和纳米阻燃剂的复配体系以及APP和生物基阻燃剂的复配体系。本文同时对各种阻燃体系的阻燃性能及典型阻燃机理进行了总结。

聚丁二酸-共-对苯二甲酸丁二醇酯/氧化镁复合薄膜的制备及性能

以聚丁二酸-共-对苯二甲酸丁二醇酯(PBST)为基体,纳米氧化镁(MgO NPs)为抗菌剂,通过溶剂挥发法制备了PBST/MgO纳米复合薄膜,并探讨了复合薄膜在食品包装中的应用。研究了MgO NPs对纳米复合薄膜的机械性能、水蒸汽透过率(WVP)、氧气透过率(OTR)和紫外阻隔性能的影响。结果表明:MgO NPs的加入改善了PBST基体的力学性能和阻隔性能。与PBST薄膜相比,复合膜的拉伸强度和断裂伸长率分别提高了43.7%和32.2%,水蒸汽透过率和氧气透过率分别降低了28.1%和23.6%,并具有良好的紫外阻隔性能。当MgO NPs质量含量为5%时,复合膜的性能最佳。

PLA/PBST/EBS复合膜的制备及其性能研究

聚乳酸(PLA)是可生物降解的聚合物材料,但其韧性较差,因而应用受到限制。为改善PLA的力学性能,选用具有良好生物降解性和高柔韧性的聚丁二酸-共-对苯二甲酸丁二醇酯(PBST)与其进行共混。同时,通过添加乙撑双硬脂酰胺(EBS)作为相容剂,以优化PLA与PBST之间的相容性。研究结果表明:通过引入EBS,PLA和PBST在复合膜中的玻璃化转变温度更为接近;复合膜中海岛相结构的分散相尺寸减小,表明PLA与PBST的相容性得到改善。此外,增容改性后PLA/PBST/EBS复合膜的拉伸强度和断裂伸长率分别提高了4.67%和21.29%,水蒸气透过率下降了12.92%,复合膜的疏水性有所提高。

PPC/PBS复合生物膜的屏障功能及其对兔胫骨骨缺损模型的促成骨作用

目的:探讨聚碳酸1,2-丙二酯(PPC)/聚丁二酸丁二醇酯(PBS)复合生物膜在兔胫骨骨缺损模型中的空间支撑能力及其对成骨效果的影响,阐明其屏障功能的可靠性和体内促成骨作用。方法:制备PPC/PBS和PPC/PBS/Ⅰ型胶原(Col-Ⅰ)(PPC/PBS/Co)复合生物膜。选用18只日本大耳白兔,于兔每侧胫骨制备2处骨缺损,随机选择6只兔于骨缺损处放置PPC/PBS复合生物膜,术后4、8和12周各处死2只兔,扫描电子显微镜(SEM)观察兔骨缺损区PPC/PBS复合生物膜表面微观结构。实验分为空白对照组、PPC/PBS复合生物膜组、BME-10X胶原膜组和PPC/PBS/Co复合生物膜组,分别行手术将上述生物膜放置于兔相应骨缺损处,空白对照组兔不放置复合生物膜,于术后2、4、8和12周时分别处死3只兔,采用软X线检测各组兔骨缺损区再生骨组织灰度值,荧光标记后采用激光共聚焦显微镜观察各组兔骨缺损区再生骨组织荧光强度,采用HE染色和改良Gomori三色染色法观察各组兔骨缺损区再生骨组织病理形态表现,免疫组织化学染色法检测各组兔骨缺损区再生骨组织中骨形态发生蛋白2(BMP-2)和骨桥蛋白(OPN)蛋白表达水平。结果:大体观察,PPC/PBS复合生物膜紧密覆盖于骨缺损区,未见移位及塌陷。SEM观察,PPC/PBS复合生物膜多孔面随时间延长表面出现微孔结构并数量增多,而光滑面基本未形成微孔样结构。软X线检测,各组兔骨缺损区再生骨组织灰度值均随时间延长而升高,12周时PPC/PBS/Co复合生物膜组兔骨缺损区再生骨组织灰度值明显高于其他各组(P<0.05)。共聚焦显微镜观察,4、8和12周时PPC/PBS/Co复合生物膜组兔骨缺损区再生骨组织荧光强度与空白对照组相近;与PPC/PBS复合生物膜组和BME-10X胶原膜组比较,4周时PPC/PBS/Co复合生物膜组兔骨缺损区再生骨组织荧光强度升高(P<0.05),8和12周时PPC/PBS/Co复合生物膜组兔骨缺损区再生骨组织荧光强度降低(P<0.05)。HE染色和改良Gomori染色,与PPC/PBS复合生物膜组和BME-10X胶原膜组比较,2和4周时PPC/PBS/Co复合生物膜组和空白对照组兔骨缺损区形成新骨的速度较快,在12周时骨缺损区形成的层板状骨矿化程度较高。免疫组织化学染色,2和4周时,与空白对照组、PPC/PBS复合生物膜组和BME-10X胶原膜组比较,PPC/PBS/Co复合生物膜组兔骨缺损区再生骨组织中BMP-2和OPN蛋白表达水平升高(P<0.05或P<0.01);与空白对照组和PPC/PBS复合生物膜组比较,BME-10X胶原膜组兔骨缺损区再生骨组织中BMP-2和OPN蛋白表达水平均降低(P<0.05或P<0.01)。结论:PPC/PBS复合生物膜具有较好的空间支撑能力,物理屏障功能可靠,且PPC/PBS/Co复合生物膜具有良好的体内促成骨作用。

聚丁二酸丁二醇酯和聚辛二酸丁二醇酯及聚(丁二酸-co-辛二酸丁二醇)共聚酯的酶促降解

以1,4-丁二醇与不同链长二元酸单体为原料,合成了聚丁二酸丁二醇酯(PBS)和聚辛二酸丁二醇酯(PBSub)2种均聚酯和4种不同比例聚(丁二酸-co-辛二酸丁二醇)共聚酯。以上述6种聚酯为降解底物,利用角质酶对其进行降解研究。通过衰减全反射傅里叶变换红外光谱、核磁共振波谱仪、差示扫描量热仪、X射线衍射仪和热重分析仪等对聚酯及其降解产物进行表征分析。6种聚酯的晶体结构、熔点、结晶度和热稳定性变化不大。研究表明,聚酯的结晶度和熔点温度是影响其酶降解的重要因素。角质酶降解共聚酯的结晶区和非结晶区,但优先降解非结晶区。丁二酸/辛二酸投料摩尔比为4/6和6/4的降解效果最好,但摩尔比为6/4的样品熔点较高,为最佳比例。

超临界流体发泡制备生物可降解塑料泡沫应用进展

塑料制品的不规范生产、使用以及回收不当等,会造成能源资源浪费和环境污染。推广可降解塑料替代产品是解决塑料污染问题的重要途径之一。目前,生物可降解塑料仅用于薄膜、吸管等一次性制品,需求量更大的缓冲包装领域尚未有规模化应用。近年来,绿色环保的超临界流体发泡技术制备的生物可降解塑料泡沫成为了学术界和工业界关注的热点,基于此,笔者总结了超临界流体发泡制备生物可降解塑料泡沫方面的应用进展,简述了间歇发泡、挤出发泡、注塑发泡、珠粒发泡制备生物可降解塑料泡沫的发泡工艺和结构性能,重点综述了聚乳酸、聚对苯二甲酸-己二酸丁二酯、聚丁二酸丁二酯泡沫材料的研究现状。

后道拉伸对聚丁二酸丁二醇酯/丝胶蛋白共混纤维结构与性能的影响

为提高纤维的力学性能,采用后道拉伸处理聚丁二酸丁二醇酯(poly(butylene succinate),PBS)/丝胶蛋白(silk sericin,SS)共混纤维,研究拉伸倍数和拉伸温度对纤维形态结构、化学结构、热性能、力学性能与降解性能的影响。结果表明,随着拉伸倍数增加,PBS与丝胶蛋白发生相对位移,纤维表面沿拉伸方向出现明显条纹;随着拉伸温度增加,纤维表面的条纹减少,表明温度的增加提高了PBS分子链的运动能力,使纤维保持致密结构。随着拉伸倍数和拉伸温度的提高,共混纤维的力学性能和结晶度呈现先增加后减小的趋势,在后道拉伸倍数为4倍,拉伸温度为75℃时,纤维的结晶度可达61.30%,此条件下的纤维断裂强度最大为2.0 cN/dtex,接近粘胶纤维的力学强度,可满足纺纱、非织造等纺织加工工艺的要求。

乙酸氧钛催化酯化缩聚法合成聚丁二酸乙二醇酯及其性能研究

聚丁二酸乙二醇酯(PES)作为一种脂肪族聚酯,具有良好的力学性能和全生物降解特性,在降解塑料领域具有广阔的应用前景。以溶剂热法制备了一种乙酸氧钛化合物,将其作为催化剂用于催化丁二酸(SA)和乙二醇(EG)酯化缩聚合成高分子量PES。系统考察了催化剂用量(催化剂占反应物料的质量分数,下同)、反应温度和反应时间对PES分子量的影响,采用^(1)H-NMR和^(13)C-NMR对PES的结构进行了表征,并对其热性能、热稳定性和力学性能进行了测试。结果表明,当催化剂用量为0.6%,在230℃下聚合8 h时,合成的PES的特性黏度[η]为0.78,数均分子量(Mn)为47500,对应的聚合物分散性指数(PDI)为2.66。合成的PES熔点为102.4℃,最大热分解温度为420.2℃,断裂伸长率为505%±5%,拉伸应力为(48.3±0.6)MPa,拉伸弹性模量高达358.8 MPa。以煤制乙二醇为单体合成PES不但可以实现全生物降解聚合物的低成本制备,而且对煤化工产业的高质量发展有重要的现实意义。