共固定化IFN-α和IFN-γ的抗宫颈癌作用

干扰素(Ⅰ型、Ⅱ型)是具有抗肿瘤作用的蛋白质型的细胞因子，与4-叠氮苯甲酸反应，经红外光谱确认生成物在约2118cm^-1处有叠氮基团的典型吸收，证明合成得到了光活性的干扰素。采用光固定法将光活性蛋白质固定到24孔组织培养聚苯乙烯板上，制成生物材料。实验通过扫描电子显微镜(SEM)，时光固定化细胞因子的微观形态进行观察。通过做细胞生长曲线，透射电镜观察两种细胞因子固定化抑制宫颈癌细胞生长、诱导细胞凋亡的情况。实验表明，共固定IFN-α和IFN-γ，能有效地抑制宫颈癌细胞的生长，在低剂量(60ng／孔)的情况下，抑制活性达到70％，而IFN-γ，具有明显的协同抑癌作用。     

光固定EGF对CHO—Kl细胞生长的促进

用活化的４－叠氮苯甲酸与上皮细胞生长因子ＥＧＦ反应,合成了具有光反应性的ＥＧＦ。将这种ＥＧＦ涂覆在组织培养聚苯乙烯基板上,通过紫外光照射。ＥＧＦ与聚苯乙烯基板通过共价键连接。在此材料上进行了中国仓鼠卵巢细胞ＣＨＯ－Ｋ１的无血清培养,并对细胞生长活性进行研究。     

光固定EGF对CHO-K1细胞生长的促进

用活化的4-叠氮苯甲酸与上皮细胞生长因子EGF反应,合成了具有光反应性的EGF。将这种EGF涂覆在组织培养聚苯乙烯基板上,通过紫外光照射,EGF与聚苯乙烯基板通过共价键连接。在此材料上进行中国仓鼠卵巢细胞CHO－K1的无血清培养,并对细胞生长活性进行研究。     

聚(N-对丙烯酰氧苯甲酰氧基)丁二酰亚胺的合成及其共聚物与血清蛋白的固定化

新的丙烯酸活性酯,N-(对甲基丙烯酰氧苯甲酰氧基)丁二酰亚胺(MBOSu)及N-(对丙烯酰氧苯甲酰氧基)丁二酰亚胺(ABOSu)单体分别由对甲基丙烯酰氧基苯甲酸(MBA)、对丙烯酰氧基苯甲酸(ABA)与N-羟基丁二酰亚胺(HOSu)在环已基羰二亚胺存在下经偶联反应合成。MBOSu及 ABOSu 容易进行均聚合及与MBA或ABA进行共聚合而得到相应的反应性聚合物。P(MBOSu-MBA)共聚物是一个较好的固定化蛋白质的载体。它极易与抗血清(驴抗人A·B·O混合血清)或正常人 A·B·O混合血清反应,形成一种具有较高免疫活性的固定化免疫吸附剂。     

氢键辅助光诱导N-乙基马来酰亚胺/甲基丙烯酸甲酯序列可控共聚物的聚合

在405 nm光源辐照下，采用二硫代羰基苯甲酸异丁腈酯(CPDB)作为光引发剂和链转移剂，对N-乙基马来酰亚胺(NEM)和甲基丙烯酸甲酯(MMA)的光诱导链转移共聚行为进行了研究。通过核磁共振氢谱(¹H-NMR)和基质辅助激光解吸电离飞行时间质谱(MALDI-TOFMS)对共聚物的结构进行了表征。利用1,1,1,3,3,3-六氟-2-丙醇(HFP)溶剂与单体构筑氢键，探究了HFP的最佳添加量，并通过单体在聚合物中的累计组成(Fcum)与其在聚合过程中的瞬间组成(Finst)之间的关系，对不同聚合条件下聚合物的组成和序列结构进行了探究。结果表明：在405 nm光照下，CPDB能够成功引发NEM和MMA的共聚，且聚合行为具有活性特征；当HFP与单体的物质的量之比为1∶1时，MMA单体会优先与HFP形成氢键，使NEM和MMA反应速率相近，形成交替结构共聚物；当不以HFP为溶剂或在加热条件下进行聚合时，NEM和MMA共聚得到的共聚物均为梯度共聚物。     

偶氮苯功能化两亲性共聚物的合成与其纳米聚集体光响应行为的研究

以4,4'-二羟乙氧基偶氮苯(BHEAZO)为引发剂引发对二氧环己酮(PDO)开环聚合,与羧基化的单羟甲基聚乙二醇(mPEG)偶联,制备了具有光响应性的两亲性三嵌段共聚物mPEG-BHEAZO-PPDO-mPEG,并对其纳米聚集体的光响应行为进行了研究.采用紫外可见光谱(UV-Vis Spectroscopy)研究了纳米聚集体水溶液的吸光度随着光照时间的变化;用动态光散射(DLS)研究了辐射波长对纳米聚集体的粒径及粒径分布的影响;结合透射电子显微镜(TEM)的研究结果,提出了对纳米聚集体在不同波长光照下聚集行为改变的机理,即反式结构共平面的共轭体系更易形成稳定的低能级电子离域状态,从而使得纳米聚集体之间通过π-π堆积作用形成微聚集现象.     

苯乙烯-NOx光照的二次有机气溶胶生成

在烟雾箱内研究了温度为(301±2) K时苯乙烯-NO_x-air光照体系生成的二次有机气溶胶(SOA). 分别探讨了高相对湿度(RH＝72%)对SOA的化学组分、数浓度、产率等的影响. 通过长光程傅立叶红外(FTIR)得到苯乙烯-NO_x光照体系的气相产物主要有甲醛、苯甲醛、甲酸和CO等. 采用聚四氟乙烯(PTFE)膜对SOA进行富集, 用FTIR对其化学组分进行分析, 推得SOA的主要物种有过氧苯甲酸硝酸酯、苯甲酸羟基苯基甲酯和苯甲酸. 高相对湿度时气相产物中甲酸量显著提高, 同时SOA红外谱图中新增加了苯甲酸, 而酯中的羰基吸收峰却比低相对湿度时降低了, 从而证实了H₂O与Criegee双自由基反应生成苯甲酸的路径, 同时也间接地说明了Criegee双自由基与苯甲醛反应生成苯甲酸羟基苯基甲酯的存在. 高相对湿度时SOA的数浓度比低相对湿度时降低了约36%～44%, 但根据在膜上的SOA质量得到高相对湿度时SOA产率比低相对湿度时提高了约40%, 说明高相对湿度增大了SOA的粒子尺度.     

含能叠氮高分子粘合剂的研究进展

含能叠氮类高分子粘合剂在固体推进剂领域具有广阔的应用前景,本文详细介绍了含能叠氮高分子粘合剂的合成方法和反应机理,对含叠氮基团的3,3-双叠氮甲基氧丁环(BAMO)、叠氮缩水甘油醚(GA)、3-叠氮甲基-3-甲基氧杂环丁烷(AMMO)的均聚物和共聚物的性能特点和合成方法进行了综述,最后对含能叠氮高分子粘合剂的未来发展趋势进行了展望。     

星形氢化苯乙烯-二烯烃共聚物结构分析方法

基于活性阴离子聚合方法,通过改变单体投料比例,成功制备了3种二乙烯基苯(DVB)偶联的星形结构苯乙烯-二烯烃共聚物S-IBS,其平均偶联臂数(AGN)达到7.0以上,偶联效率(CE)达到93%。进一步加氢得到氢化苯乙烯-二烯烃(HSD)型共聚物—氢化星形苯乙烯-异戊二烯-丁二烯(HS-IBS),氢化效率达到95%以上,同时对氢化前后的聚合物进行表征以及组成含量计算。将氢化后星形聚合物HS-IBS合理简化视为乙烯-丙烯-苯乙烯(E-P-St)三元共聚物后,结合~(13)C以及~1H-NMR进行组成含量计算。氢化后组成计算值与实际投料组成以及氢化前核磁计算值误差在1%以内,表明将氢化后聚合物简化视为E-P-St共聚物,进而推算组成的模拟计算方法具有非常好的精确度。这一方法为采用活性阴离子聚合-偶联-氢化的HSD类黏指剂产品剖析建立了可靠的分析和计算方法,能够准确地推断其组成结构,进而分析其合成方法,也便于国内研发人员对这一类产品的结构组成进行有效的解析。     

手性两亲超支化嵌段共聚物PG-b-PBTQMO-b-PG的合成

以叠氮基修饰的超支化共聚物PG-b-PBAMO-b-PG和10,11-二氢化奎宁为原料,通过"click"化学反应合成了一种新型侧链含有奎宁的光学活性两亲超支化嵌段共聚物PG-b-PBTQMO-b-PG。用傅里叶转变红外光谱(FT-IR)和核磁共振氢谱(1HNMR)对产物结构和组成进行了表征,并利用圆二色谱法研究了手性共聚物的光学活性。     

Novel synthesis of N(4)-substituted 1,4-benzodiazepine-2,5-diones using poly(ethylene glycol) as soluble polymer support

An efficient method for the liquid-phase combinatorial synthesis of N4-substituted 1,4-benzodiazepine-2,5-diones has been developed. Poly(ethylene glycol) (PEG) stepwise reacted with bromoacetyl bromide, a primary amine and 2-azidobenzoic acid to give a potential PEG-bound dipeptide, which was reduced by NaI / acetic acid, along with concurrent cyclization and cleavage of the seven-membered heterocycle from the PEG support.     

Synthesis and biological activity of C-4 and C-15 Aryl azide derivatives of anguidine

Potential trichothecene photoaffinity reagents were prepared by coupling either the C-4 or C-15 alcohols derived from anguidine with (3-azido-5-methoxyphenoxy) acetic acid, 4-(3-azido-5-methoxyphenoxy)butyric acid, or N-(3-azido-5-methoxyphenyl) N'-(carboxymethyl) urea. The C-15 anguidine deriviatives of (3-azido-5-methoxyphenoxy)acetic acid and (3-azido-4-iodo-5-methoxyphenoxy) acetic acid possessed protein synthesis inhibition activity comparable to that of anguidine itself in Chinese hamster ovary and African Green Monkey kidney cell lines.     

Preparation of a Lanthanide–Titanium Oxo Cluster–Polymer Composite by CuI-Catalyzed Click Chemistry

Incorporating metal clusters within the skeleton of the organic polymers through a click reaction cannot only effectively prepare cluster–polymer composites, but also effectively avoid the cluster aggregation. Herein, an azide-containing lanthanide–titanium oxo cluster of Eu₈Ti₁₀-N₃ ( Eu₈Ti₁₀-N₃ =[Eu₈Ti₁₀(μ₃-O)₁₄(H₂O)₄(OAc)₂(tbba)₃₀(paza)₄(THF)₂] ⋅ 4 THF ⋅ 8 H₂O ( 1 ), Htbba=4-tert-butylbenzoic acid, Hpaza=4-azidobenzoate, HOAc=acetic acid, THF=tetrahydrofuran) through an in situ solvothermal reaction of 4-azidobenzoic acid and 4-tert-butylbenzoic acid. Reaction of 1 with PEG ( PEG =methoxypoly(ethyleneglycol)alkyne, 2000 g mol⁻¹) through Cu^I-catalyzed click chemistry generates a lanthanide–polymer composite of Eu₈Ti₁₀-N₃@PEG ( 2 ). Investigation with IR, ¹H NMR and ICP-OES of 2 indicates that the structural integrity of 1 is maintained in 2 . Study of the luminescent properties of 1 and 2 reveals that the quantum yield of 1 itself basically remains unchanged in 2 . Significantly, the formation of 2 cannot only effectively prevent the cluster 1 from aggregation, but also greatly enhance its solubility and adhesion to the substrate. Owing to the solubility and adhesion of luminescent materials being the key to their practical application, present work is thus of great significance for the development of metal cluster–polymer composite luminescent materials.     

Modulating the catalytic activity of Au/micelles by tunable hydrophilic channels

Polymeric micelles with a polystyrene core, poly(acrylic acid)/poly(4-vinyl pyridine) (PAA/P4VP) complex shell and poly(ethylene glycol) & poly(N-isopropylacrylamide) (PEG & PNIPAM) mixed corona were synthesized and used as the supporter for the gold nanoparticles (GNs). It was concluded from the result of ¹H NMR characterization that hydrophilic channels formed around PEG chains when PNIPAM collapsed above its lower critical solution temperature. The density of the channels in the corona can be tuned by changing the weight ratios of PEG chains to PNIPAM chains. The GNs were set in the PAA/P4VP complex layer and the catalytic activity of the GNs can be modulated by the channels. The catalytic activity increased with increasing the density of the channels in the corona. Meanwhile, the whole Au/micelle nanoparticles were stabilized by the extended PEG chains.     

光亲和标记磷脂酸类似物的合成

合成了光敏基团位于sn-1脂肪酰基上的光亲和标记磷脂酸(PA)类似物,选用了有较高C-H插入效率的全氟苯基叠氮化合物作为光敏基团.用酶化学方法在PA类似物中引入了同位素标记³³P.初步实验表明,合成的PA类似物与天然PA一样对cAMP-磷酸二酯酶有激活作用,提示合成的PA类似物可进一步用于该酶的光亲和标记.     

PEGylation of an artificial O2 and CO receptor: synthesis, characterisation and pharmacokinetic study

A synthetic oxygen (O(2)) and carbon monoxide (CO) receptor (hemoCD) composed of 5,10,15,20-tetrakis(4-sulfonatophenyl)porphinatoiron(ii) and a per-O-methylated β-cyclodextrin dimer with a pyridine linker (Py3CD) was functionalised with poly(ethylene glycol) (PEG) to elongate the circulation time of the receptor in the bloodstream. α-PEG monocarboxylic acid (HOOC(CH(2))(3)(CO)O-PEG(mw)-OCH(3); mw = 750 or 5k) or α,ω-PEG dicarboxylic acid (HOOC(CH(2))(3)(CO)O-PEG(mw)-O(CO)(CH(2))(3)COOH; mw = 10k or 20k) was reacted with the amino group of 5-(4-aminophenyl)-10,15,20-tris(4-sulfonatophenyl)porphyrin to afford a porphyrin monomer having a PEG chain or a porphyrin dimer having a PEG linker, respectively. The ferrous complexes of these PEGylated porphyrins (PEG750-, PEG5k-, PEG10k- and PEG20k-hemoCDs) bound O(2) in aqueous solution, P(1/2) values being 6.5-8.1 Torr at pH 7.0 and 25 °C. Each PEG(mw)-hemoCD was infused into the femoral vein of a Wistar male rat. After 6 h of the infusions, 67, 82, 86 and 42% of PEG750-, PEG5k-, PEG10k- and PEG20k-hemoCD were excreted in the urine. PEG750-hemoCD with a hydrodynamic diameter (D(h)) of 3.4 nm seemed to partly leak from the blood vessels (pore size: 2-6 nm) before renal filtration (pore size: 4-14 nm). PEG5k- (D(h) = 6.2 nm) and PEG10k-hemoCDs (9.0 nm) hardly passed through the blood vessels but were fully filtered by the kidney, resulting in high excretion rates. A considerable amount of PEG20k-hemoCD (D(h) = 12.0 nm) was retained in the blood even at 6 h after administration. The present study demonstrates that the behaviour of hemoCD in blood after administration can be controlled by modification of hemoCD with PEG having an appropriate molecular weight.     

'Stealth' corona-core nanoparticles surface modified by polyethylene glycol (PEG): influences of the corona (PEG chain length and surface density) and of the core composition on phagocytic uptake and plasma protein adsorption

Nanoparticles possessing poly(ethylene glycol) (PEG) chains on their surface have been described as blood persistent drug delivery system with potential applications for intravenous drug administration. Considering the importance of protein interactions with injected colloidal dug carriers with regard to their in vivo fate, we analysed plasma protein adsorption onto biodegradable PEG-coated poly(lactic acid) (PLA), poly(lactic-co-glycolic acid) (PLGA) and poly(-caprolactone) (PCL) nanoparticles employing two-dimensional gel electrophoresis (2-D PAGE). A series of corona/core nanoparticles of sizes 160–270 nm were prepared from diblock PEG-PLA, PEG-PLGA and PEG-PCL and from PEG-PLA:PLA blends. The PEG Mw was varied from 2000–20 000 g/mole and the particles were prepared using different PEG contents. It was thus possible to study the influence of the PEG corona thickness and density, as well as the influence of the nature of the core (PLA, PLGA or PCL), on the competitive plasma protein adsorption, zeta potential and particle uptake by polymorphonuclear (PMN) cells. 2-D PAGE studies showed that plasma protein adsorption on PEG-coated PLA nanospheres strongly depends on the PEG molecular weight (Mw) (i.e. PEG chain length at the particle surface) as well as on the PEG content in the particles (i.e. PEG chain density at the surface of the particles). Whatever the thickness or the density of the corona, the qualitative composition of the plasma protein adsorption patterns was very similar, showing that adsorption was governed by interaction with a PLA surface protected more or less by PEG chains. The main spots on the gels were albumin, fibrinogen, IgG, Ig light chains, and the apolipoproteins apoA-I and apoE. For particles made of PEG-PLA45K with different PEG Mw, a maximal reduction in protein adsorption was found for a PEG Mw of 5000 g/mole. For nanospheres differing in their PEG content from 0.5 to 20 wt %, a PEG content between 2 and 5 wt % was determined as a threshold value for optimal protein resistance. When increasing the PEG content in the nanoparticles above 5 wt % no further reduction in protein adsorption was achieved. Phagocytosis by PMN studied using chemiluminescence and zeta potential data agreed well with these findings: the same PEG surface density threshold was found to ensure simultaneously efficient steric stabilization and to avoid the uptake by PMN cells. Supposing all the PEG chains migrate to the surface, this would correspond to a distance of about 1.5 nm between two terminally attached PEG chains in the covering ‘brush’. Particles from PEG5K-PLA45K, PEG5K-PLGA45K and PEG5K-PCL45K copolymers enabled to study the influence of the core on plasma protein adsorption, all other parameters (corona thickness and density) being kept constant. Adsorption patterns were in good qualitative agreement with each other. Only a few protein species were exclusively present just on one type of nanoparticle. However, the extent of proteins adsorbed differed in a large extent from one particle to another. In vivo studies could help elucidating the role of the type and amount of proteins adsorbed on the fate of the nanoparticles after intraveinous administration, as a function of the nature of their core. These results could be useful in the design of long circulating intravenously injectable biodegradable drug carriers endowed with protein resistant properties and low phagocytic uptake.     

对叠氮苯甲酸与β-环糊精的包合作用

合成了对叠氮苯甲酸与β-环糊精的包合物，并利用红外、热重、核磁和紫外 等测试方法进行了详细的表征与研究。包合后客体化合物的热稳定性有了明显的提 高，其分解温度提高了+115 ℃；此外还利用紫外光谱的数据计算了包合反应的平 衡常数，为(7933±192)L·mol~(-1)。     

Poly(maleic anhydride-co-acrylic acid)/poly(ethylene glycol) hydrogels with pH- and ionic-strength-responses

<正>Poly(maleic anhydride-coacrylic acid),P(MA-AA),was synthesized by the free-radical copolymerization of maleic anhydride with acrylic acid,and fast responsive pH-sensitive poly(maleic anhydride-co-acrylic acid)/polyethylene glycol,P(MA-AA)/PEG,hydrogels were prepared using PEG as macromolecular cross-linking agent.FT-IR and ~1H-NMR spectrometry were applied to characterize the structure of P(MA-AA).The influences of pH and ionic strength on the swelling behavior of P(MA-AA)/PEG hydrogels and the swelling-deswelling changes along with the repeated changes between acid and alkali conditions were studied.The results showed that there was a hundredfold difference in the swelling ratios between the conditions of acid and alkali,and the swelling capability could not be weakened after multiple swelling-deswelling cycles.The results of swelling kinetics demonstrated that the response rate of P(MA-AA)/PEG hydrogels was very fast,because the swelling transition points always occurred at 10 min.The pH-responsive hydrogels reported here might be a smart material for potentially applications in many areas,including biosensors,drug-delivery devices and tissue engineering.     

Formation of Core‐Shell‐Corona Micellar Complexes through Adsorption of Double Hydrophilic Diblock Copolymers into Core‐Shell Micelles

Summary: The complexation between polystyrene‐block‐poly(acrylic acid) (PS‐b‐PAA) micelles and poly(ethylene glycol)‐block‐poly(4‐vinyl pyridine) (PEG‐b‐P4VP) is studied, and a facile strategy is proposed to prepare core‐shell‐corona micellar complexes. Micellization of PS‐b‐PAA in ethanol forms spherical core‐shell micelles with PS block as core and PAA block as shell. When PEG‐b‐P4VP is added into the core‐shell micellar solution, the P4VP block is absorbed into the core‐shell micelles to form spherical core‐shell‐corona micellar complexes with the PS block as core, the combined PAA/P4VP blocks as shell and the PEG block as corona. A model is suggested to characterize the core‐shell‐corona micellar complexes.

Schematic formation of core‐shell‐corona (CSC) micellar complexes by adsorption of PEG‐b‐P4VP into core‐shell PS‐b‐PAA micelles.