酶促开环聚合与自缩合乙烯基共聚合相结合制取超支化聚合物

在Novozyme 435脂肪酶催化下, 甲基丙烯酸羟乙酯(HEMA)引发己内酯(ε-CL)开环聚合反应, 得到一端为双键, 另一端为羟基的直链聚己内酯(PCL)产物; 将其端羟基官能化得到大分子AB*型单体, 与苯乙烯以原子转移自由基聚合(ATRP)反应形式进行自缩合乙烯基共聚合, 得到超支化结构聚苯乙烯-b-聚己内酯产物.     

“线性-超支化”超分子聚合物的制备及光响应性自组装行为研究

报道了一种"线性-超支化"超分子聚合物的制备、自组装及其光响应性解组装过程.分别通过可控阴离子开环聚合(ROMBP)和原子转移自由基聚合(ATRP)的方法,制备了以β-环糊精为中心的超支化聚缩水甘油醚(CD-g-HPG)和一端带有偶氮苯基团的线性聚苯乙烯(AZO-PS).两者通过β-环糊精和偶氮苯基团之间的主客体识别作用形成"线性-超支化"超分子聚合物PS-b-HPG.该聚合物可以在水中自组装形成囊泡结构.通过紫外滴定法表征了CD-g-HPG和AZO-PS之间的主客体复合能力,通过SEM和TEM表征了组装体的形貌.最后基于偶氮苯在紫外光照射下发生顺反异构化的性质,用紫外光照射组装体成功实现了组装体的解组装.     

基于炔类单体的点击聚合制备超支化聚合物

超支化聚合物由于其独特的树枝状结构和物理化学性质,已经得到了广泛关注及应用.而基于炔类单体的点击聚合作为一类简单、高效的聚合反应已被广泛用于超支化聚合物的制备.本文对近5年利用叠氮-炔和巯基-炔点击聚合制备超支化聚合物的工作进行了简要综述.其中,Cu(I)催化的叠氮-炔点击聚合可制备1?4-立构规整的超支化聚三唑;Ru(II)催化的叠氮-炔点击聚合可制备1?5-立构规整的超支化聚三唑;活化的炔类单体和叠氮单体的无金属催化点击聚合可得到1?4-异构体含量高(高达91.7%)的超支化聚合物;而光引发?热引发及自发的巯基-炔点击聚合可制备含硫的超支化聚合物.此外,对所制备的超支化聚合物的功能和应用进行了简单介绍,最后还简单讨论了点击聚合制备超支化聚合物方面的可能发展方向.     

通过大分子单体的“点击”反应合成超支化聚苯乙烯

用一端带有一个叠氮基,另一端带有两个炔基的聚苯乙烯(PSt)大分子单体,通过"点击"化学反应,成功制备了结构规整的超支化聚苯乙烯。首先,L-天冬氨酸经过溴化和酯化两步反应得到含有两个炔基的原子转移自由基聚合(ATRP)引发剂——2-溴代琥珀酸双炔丙基酯(BPBS),然后引发苯乙烯的ATRP,并通过NaN3的取代反应把末端溴转化为叠氮基,得到AB2型大分子单体(CH≡C)2-PS-N3。这种大分子单体通过"点击"反应聚合得到超支化聚苯乙烯,根据多角度激光光散射(MALLS)测试结果,最终产物重均聚合度DPw可达53,分子量分布Mw/Mn=1.53。     

超支化聚苯乙烯-线型聚苯乙烯-超支化聚甲基丙烯酸甲酯三嵌段聚合物的合成与表征

合成了超支化聚苯乙烯-线型聚苯乙烯-超支化聚甲基丙烯酸甲酯三嵌段聚合物(HPS-b-LPS-b-HPMMA). 首先分别合成了带有炔基和溴的三硫代碳酸酯(ATC和BTC), 然后通过苯乙烯(St)的可逆加成-断裂链转移(RAFT)聚合, 制得端炔基和端基溴的线型聚苯乙烯大分子RAFT试剂, 然后将大分子RAFT试剂的溴末端转化为叠氮末端. 接着在大分子RAFT试剂存在情况下, 通过自缩合原子转移自由基共聚合(SCATRCP)分别制得端炔基超支化聚苯乙烯-线型聚苯乙烯(HPS-b-LPS)和端叠氮基超支化聚甲基丙烯酸甲酯-线型聚苯乙烯(HPMMA-b-LPS)两嵌段聚合物. 最后将两种两嵌段聚合物通过点击(click)反应偶合, 得到不对称的超支化-线型-超支化三嵌段聚合物HPS-b-LPS-b-HPMMA. 核磁共振氢谱(¹H NMR)、凝胶渗透色谱(GPC)结果表明, 所得产物分子量可控, 得到了预期结构的聚合物.     

新型双功能性超支化聚合物的制备及表征

首先以烯丙基缩水甘油醚与N-氨乙基哌嗪反应合成新型B3单体,然后分别以六亚甲基二异氰酸酯和1,6-己二硫醇为A2单体与上述B3单体反应,利用异氰酸-羟基以及巯基-烯的反应,合成了同时含有羟基和烯丙基的双功能性超支化聚(氨酯-胺)和聚(硫醚-胺)。研究了单体种类及投料比与合成的超支化聚合物的化学与拓扑结构的关系。通过红外吸收光谱、核磁共振氢谱和凝胶渗透色谱表征了超支化聚合物的分子结构和化学组成。结果表明:该B3单体同时带有3个羟基与3个烯丙基,当A2和B3单体投料比(物质的量之比)为0.825∶1时,可以成功制备较高分子量的双功能性超支化聚合物。     

以四重氢键结合的超支化聚合物及其涂层材料

合成了以Upy(2-ureido-4[1H]-pyrimidone)封端的超支化聚合物并研究其涂层材料性能.首先在哌嗪与三羟甲基丙烷三丙烯酸酯摩尔比2.25∶1条件下,合成了端仲胺基超支化聚(酯-胺)(HPEA),进而在仲胺基/异氰酸酯基官能团比1∶0.3、1∶0.4和1∶0.5下,通过HPEA与单异氰酸酯基甲基异胞嘧啶反应,合成了一系列带有Upy基元的改性超支化聚合物.由于Upy基元间形成了自识别四重氢键,改性聚合物比HPEA具有更高的玻璃化转变温度和热分解温度,并且改性聚合物涂层具有优良的力学性能,这表明分子间强氢键相互作用可有效改善超支化聚合物的性能.     

由苯-1，2，4-三羧酸-1，2—酐和羟乙基哌嗪合成酰胺键、叔氨和酯键交替排列的水溶性超支化聚合物

基于官能团非等活性原理，由商品化多组分单体一步法合成了超支化聚合物． 用苯—1，2，4-三羧酸—1，2酐(BTAA)与羟乙基哌嗪(HEPZ)为原料，利用氨基和羟 基反应活性不同，制备了结构非对称超支化聚酰胺—酯．分别用红外、核磁共振确 定了所得聚合物的结构．该聚合物分子骨架中含有交替排列的酰胺键、叔氨和酯键 ，易溶于水．本合成方法原料易得、工艺简单，适合大量制备超支化聚合物．     

十八烷基三氯硅烷改性超支化聚(胺-酯)吸附亚硝胺的研究

以十八烷基三氯硅烷对超支化聚(胺-酯)进行改性,合成了改性的超支化聚(胺-酯)。将改性前后的超支化聚合物用于吸附二甲基亚硝胺和二苯基亚硝胺。吸附结果表明,聚合物对二甲基亚硝胺和二苯基亚硝胺的吸附率分别为51.3%和11.9%,而改性后的超支化聚合物对二甲基亚硝胺和二苯基亚硝胺的吸附率分别为67.3%和37.2%。     

超支化聚芳酰胺的合成

由3,5-二硝基苯甲酰氯和邻氨基苯甲酸合成了AB2型单体2-(3,5-二氨基苯甲酰氨基)苯甲酸。该单体进行自缩聚反应,合成了新型超支化聚酰胺(a),将其与酰氯反应,得到了7种封端的超支化聚合物(b~h)。用FT-IR1、H NMR、GPC、DSC测试技术对超支化聚合物进行了表征。封端改性后,聚酰胺的溶解性均得到了提高,聚合物的重均分子量(Mw)为3.36~3.96 kg/mol,特性粘度(ηinh)为0.061~0.078 dL/g,聚合物玻璃化转变温度(Tg)为56~185℃,随封端剂脂肪链增长而降低,随封端剂极性增加而升高。     

三氟化硼-乙醚络合物催化γ-戊内酯与ε-己内酯开环共聚的研究

以三氟化硼乙醚络合物为催化剂,进行了γ-戊内酯(γ-VL)与ε-己内酯(ε-CL)的本体开环共聚的研究.采用1H -NMR、13C- NMR证实了所得共聚物的结构,并对共聚物的分子量、组成、熔点等进行了表征.结果表明,在一定的条件下,难以均聚的γ-VL可与ε-CL发生共聚反应,从而在共聚物链结构中引入少量的γVL单元.γVL单元的引入使得共聚物的分子量和熔点下降.由K- T法估算出两种单体共聚的竞聚率分别为r(ε-CL)=17.6,r(γ-VL)=0.0078.     

两亲性嵌段共聚物mPEG-b-PCL/FA的合成及其药物释放性能

以苯甲醇为引发剂,在辛酸亚锡催化下引发ε-环己内酯(ε-CL )开环聚合,合成了聚己内酯(PCL).分别利用端甲氧基聚乙二醇(mPEG)、PCL及叶酸(FA)与三氯三嚎中不同的氯反应,得到两亲性嵌段共聚物mPEG-b-PCL/FA;采用傅立叶变换红外光谱仪和核磁共振谱仪等表征了mPEG-b-PCL/FA的组成和结构;采...     

Copolymer of lactide and ε-caprolactone catalyzed by bimetallic Schiff base aluminum complexes

A series of copolymers of lactide(LA) and e-caprolactone(ε-CL) with different monomer feed ratios were achieved using three kinds of bimetallic Schiff aluminum complexes as catalysts. The ratios of LA and ε-CL units in different copolymers and the average segments length were determined by NMR analysis. The comparative kinetic study of L-LA/ε-CL and rac-LA/ε-CL copolymerization systems showed that the polymerization rate of LA was faster than ε-CL, and L-LA showed polymerization rate slightly faster than rac-LA. It was inferred that the copolymers achieved by these complexes were gradient copolymers with gradual change in distribution of LA and e-CL units. The thermal properties of these copolymers were characterized by DSC analysis, which showed that the glass transition temperature(Tg) of these copolymers changed regularly according to the pro-portion change of two structural units.     

Microwave-assisted Polymerization of ε-Caprolactone with Maleic Acid as Initiator and Drug Release Behavior of Ibuprofen-Poly(ε-caprolaetone) System

Poly(ε-caprolactone) (PCL) with weight-average molar mass over 10000 g/mol was synthesized by microwave-assisted ring-opening polymerization of ε-caprolactonc (ε-CL) with malcic acid (MA) as initiator (2.45 GHz, 360 W, 85 min). Ibuprofen-PCL controlled release system was prepared directly by the ROP of ε-CL in its mixture with ibuprofen. The release of ibuprofen from the system was sustained and steady.     

辛酸镁催化L-丙交酯与ε-己内酯共聚及其共聚物结构与性能研究

以无毒性的辛酸镁为催化剂催化L-丙交酯和ε-己内酯本体开环共聚合,制备了一系列不同单体配比的共聚物.首先用1H-NMR跟踪了共聚合单体转化率,显示L-LA聚合速率显著快于ε-CL.用13C-NMR分析共聚物微观结构和计算单体单元平均序列长度(LLLe和LCe),表明聚合过程中酯交换反应导致单元序列结构重新分布.随着反应进行,LLLe急剧下降而LCe逐渐增加后稍有降低,游程数逐渐增大,共聚物无规度提高.反应初期主要是一级酯交换反应,二级酯交换反应导致的CLC序列结构在反应后期才观察到.由Fineman-Ross法计算出L-丙交酯和ε-己内酯的竞聚率分别为rLA=23和rCL=0.22,表明在聚合反应初期L-LA单体优先插入聚合物增长链端,形成LL单元长嵌段结构.共聚物组成显著影响单元序列长度,各序列长度随相应单体加入量增加而增长.二级酯交换系数(TII[CLC])随ε-CL含量增加而增大.对于整个组成范围内,根据竞聚率计算的LLLr值始终要大于聚合产物的LLLe,而LCr计算值小于或接近LCe实验值.因此,共聚物单元序列分布随共聚物投料比和反应时间而改变,趋向于无规分布.以DSC和XRD分析了共聚物热性能和结晶性,表明共聚物结晶性与单元序列长度密切相关.所有共聚物只有一个玻璃化转变温度Tg,符合无规共聚物的Fox方程,说明所得共聚物为无规共聚物,或者说包含有相容性嵌段成分的共聚物.     

Synthesis of high-molecular-weight poly(ε-caprolactone) catalyzed by highly active bis(amidinate) tin(II) complexes

A series of bis(amidinate) tin(II) complexes is synthesized and shown to rapidly polymerize ε-caprolactone (ε-CL) in the presence and absence of benzyl alcohol giving high-molecular-weight poly(ε-CL) (M(n) up to 160,600 Da). Ligands having electron donating groups were found to accelerate the polymerization by making the complex more nucleophilic.     

Copolymerisation of ε-caprolactone and trimethylene carbonate catalysed by methanesulfonic acid

The copolymerisation of ε-caprolactone (ε-CL) and trimethylene carbonate (TMC) catalysed by methanesulfonic acid was investigated. Preliminary copolymerisation tests using a monofunctional initiator confirm that the side bidirectional propagation previously detected in the homopolymerisation of TMC is also present in the copolymerisation. The comonomers in the ε-CL/TMC system do not follow first order kinetics. The values of the reactivity ratios obtained by the Kellen–Tüdös method (r_ε-CL = 2.90; r_TMC = 0.62) suggest that random copolymerisation can be achieved, although the copolymer will be richer in ε-CL. Dihydroxyl-telechelic ε-CL/ TMC random copolymers were prepared using a bifunctional initiator. ¹H and ¹³C NMR, SEC and DSC measurements show that the poly(TMC-co-ε-CL) samples presented the expected microstructural characteristics, a unimodal molar-mass distribution and a very narrow polydispersity. Based on these features a novel route for the preparation of block copolyesters with tuned properties, and highly regarded in the development of materials for biomedicine, may be foreseen.     

In situ generated,tetrahydrosalen stabilized yttrium borohydride complex:Efficient initiator for the ring-opening polymerization of ε-caprolactone

In this paper,we report the preparation of a new tertrahydrosalen-stabilized yttrium complex which was employed as an initiator-precursor for the polymerization ofε-caprolactone(ε-CL) in the presence of NaBH_4 to give interesting hydroxytelechelic poly(ε-caprolactone)(PCL).The effect of[monomer]/[initiator]([CL]/[I]),temperature and time on the polymerization was investigated.It was found that under the condition:[CL]/[I]= 1200,55℃,toluene:0.5 mL,ε-CL:0.5 mL,PCL with M_w = 32,600 and PDI = 1.47 was obtai...     

Ring-opening polymerization of degradable polyesters

Medium to high molecular weight random copolymers of 1,5-dioxepan-2-one (DXO) and L-lactide (L-LA) or ε-caprolactone (ε-CL) of different compositions have been investigated. Polymerization was conducted in bulk at 110°C using stannous 2-ethylhexanoate as catalyst. Poly(DXO-co-L-LA) is a hydrolysable material with a glass transition temperature (T_g) ranging from −36 up to 58°C depending on the molar composition. The material exhibited crystallinity as long as the amount of DXO did not exceed 50 weight%. Reactivity ratios were determined to r_L-LA=10 and r_DXO=0.1, giving a more blocky structure than expected in a random copolymer. The copolymer between ε-CL and DXO was shown to be a truly random copolymer by ¹³C NMR, as expected from the reactivity ratios, r_DXO=1.6 and r_ε-CL=0.6. T_g of the material was ranging from −64 up to −39°C. The ability of the poly(DXO-co-ε-CL) to crystallize was retained up to a DXO content of 40 weight%. The melting temperature and crystallinity of both copolymers decrease with increasing amount of DXO. Incorporation of semicrystalline comonomers, L-LA or ε-CL, into the amorphous poly(DXO) creates materials with adjustable properties depending on the molar composition.     

Effect of microwave energy on chain propagation of poly(ε-caprolactone) in benzoic acid-initiated ring opening polymerization of ε-caprolactone

Microwave-assisted ring opening polymerization of ε-caprolactone (ε-CL) initiated by benzoic acid was investigated. The molar ratio of ε-CL to benzoic acid was 5, 15 and 25. The mixtures of ε-CL/benzoic acid were heated under microwave irradiation and the temperatures were self-regulated to equilibrium from 204 to 240 °C with microwave power ranging from 340 to 680 W. The polymer chain propagated fast between 160 and 230 °C, within which the higher the temperature, the faster the propagation. However, when the temperature was over 230 °C, the resultant poly-(ε-caprolactone) (PCL) degraded. The advantage of microwave-assisted polymerization was that the propagation of PCL chain was significantly enhanced but the formation of growing center at the beginning stage of the polymerization was greatly inhibited. With this metal-free method, PCL with weight-average molar mass (M_w) over 4×10⁴ g/mol was prepared.