1,5-萘二异氰酸酯与1,4-丁二醇基为基质的多嵌段聚氨酯弹性体的合成与性能

利用 1 ,5_萘二异氰酸酯 (NDI)和 1 ,4_丁二醇 (BDO)为均匀硬质分子单体 ,与不同软质分子单体 (聚醚、聚酯、聚硅氧烷 )缩合制备多嵌段聚氨酯弹性体 ,详细研究了硬嵌段相 (NDI)弹性体的结构与性能间的关系 ,发现随着硬嵌段相长度的增加 ,或者氨基甲酸酯中胺基与聚醚、聚酯、聚硅氧烷中软段氧原子间氢键的减弱 ,都导致微相分离程度的增加 ,造成聚合物熔点和熔化热的升高。硬嵌段相熔化的多峰行为是由于形成了NDI/BDO半微晶区 ,在退火时转变为更加有序的结晶微区 ,当温度高于 1 80℃时 ,由于氢键的断裂 ,NDI/BDO硬嵌段发生分解反应 ,该过程源于不很有序的硬嵌段半结晶微区。当温度高于 2 5 0℃时 ,发生快速的分解。在动态力学行为方面 ,NDI基聚醚弹性体比其它硅氧烷基的弹性体展示了更高的硬嵌段区的稳定性 ,同时 ,在使用温度范围内 ,也显示出最高的储能模量值 ,表明刚性对温度的依赖性 ,以及NDI/BDO硬嵌段中活性填料的显著影响     

Preparation and Properties of Polyurethane Hydrogels Based on Hexamethylene Diisocyanate/Polycaprolactone-Polyethylene Glycol

Hydrogels are considered an optimum material for controlled release drug systems and tissue engineering scaffolds since they are tri-dimensional networks. In this work hexamethylene diisocyanate (HMDI), polycaprolactone (PCL) and polyethylene glycol (PEG) were used to prepare polyurethane prepolymers using diethylene glycol (DEG) as a chain-extender. Then the prepolymer was used to fabricate the HMDI/PCL-PEG/DEG polyurethane hydrogels by free radical polymerization using benzoyl peroxide (BPO) as a cross-linking agent. The influences of the ratio of polyol on the contact angle, swelling ratio, morphology and cytotoxicity in-vitro of the HMDI/PCL-PEG/DEG polyurethane hydrogel were investigated. The biological behavior of the polyurethane hydrogels was analyzed by studying the cell behavior using the standard biological MTT (3–4,5-dimethyl-2-thiazolyl)-2,5-diphenyl-2-H-tetrazolium bromide) test. The Fourier transform infrared (FTIR) spectra results showed that the polyurethane hydrogels were successfully synthesized. The change of the molar the ratio of the polyhydric alcohols (PEG and PCL) played important roles in the swelling degree, the contact angle and the pore size. The HMDI/PCL-PEG/DEG polyurethane hydrogel (PCL/PEG = 1:3) was hydrophilic with many more large pores while the polyurethane hydrogel with PCL/PEG = 3:1 had a dense structure. The fibroblastic cell proliferation improved with decreasing relative PEG content; however, there were insignificant differences (P > 0.05) on all days of observation of the samples with various PEG contents compared with the negative control group. The MTT assays revealed that the cells were able to grow and proliferate quite quickly in the extracts of the HMDI/PCL-PEG/DEG polyurethane hydrogels as well as the extract of the negative control.     

耐高温,耐腐蚀乙烯基酯树脂的研究

本文就乙烯基酯树脂进行了一些探讨,旨在提高其耐热、耐腐蚀性能,并着重研究了用异氰酸酯改性的乙烯基酯树脂。通过玻璃化转变温度、红外分析、静态试验样浸泡、透光率、介电损耗的变化,以及对其力学性能进行了考察。试验结果表明用甲苯二异氰酸酯对乙烯基酯树脂进行改性是有效的。     

Preparation and Properties of Polyurethane Hydrogels Based on Methylene Diphenyl Diisocyanate/Polycaprolactone-Polyethylene Glycol

Polyurethane (PU) hydrogel is an important biomedical material for drug controlled release systems, wound dressings and medical bandages. Three series of polyurethane prepolymers based on methylene diphenyl diisocyanate (MDI), polycaprolactone (PCL) and polyethylene glycol (PEG), using diethylene glycol (DEG), N-methyldiethanolamine (MDEA) or dimethylolpropionic acid (DMPA), as the chain-extender, were prepared. Then the polyurethane hydrogels were obtained from the prepolymers, using benzoyl peroxide (BPO) as a cross-linking agent, by free radical polymerization. The influences of the types of chain-extenders and polyols on the contact angle, swelling ratio and morphology of the polyurethane hydrogels were investigated. The effect of the variety of the chain-extenders in the PU hydrogel on the drug release behavior was also studied. The FT-IR results showed that the PU hydrogels were successfully synthesized. The introduction of PEG improved the hydrophilicity of the PU hydrogels. The MDI/PCL-PEG/DEG hydrogel was hydrophobic, and there were small micropores on its surface; while the MDI/PCL-PEG/DMPA and MDI/PCL-PEG/MDEA hydrogels had high hydrophilicity and a micropouous structure on their surface due to the existence of carboxyl and tertiary amino functional groups. The change of chain-extenders had no significant effect on the cumulative drug release of chloramphenicol from the PU hydrogels. However, the introduction of PEG increased the drug release rate. The chloramphenicol release kinetics from the MDI/PCL-PEG hydrogels indicated non-Fickian diffusion.     

甲苯二异氰酸酯与乙二胺沉淀聚合一步法制备聚脲多孔材料及其表征

以甲苯二异氰酸酯和乙二胺为单体,通过沉淀聚合一步到位制备了富含胺基的聚脲多孔材料.探讨了反应时间、溶剂种类及混合溶剂配比对聚脲多孔材料性能的影响.通过BET和压汞法对聚脲多孔材料的孔结构进行了表征,用扫描电子显微镜表征了材料的形貌,用X-射线衍射仪测试了材料的结晶性能.结果表明,聚合反应进行48 h后多孔材料的胺基含量不再变化,所得聚脲为典型多孔材料且部分结晶.与丙酮相比,以乙腈作反应介质制备的聚脲的比表面积和孔体积较大,孔径分布较宽.以乙腈和丙酮混合溶剂作反应介质,通过改变混合溶剂的配比可以改变材料的孔结构.     

Control of hard segment size in polyurethane formation

In general, segmented polyurethane elastomers are prepared by reacting an isocyanate-capped polyol prepolymer with a short-chain diol chain extender, yielding an elastomer with hard segments of uniform size. However, the hard segment size will not be uniform if the polyurethane polymer is prepared by forming the hard segment first, followed by soft segment formation. Because the mechanical properties of polyurethane elastomers depend on the relative ratio of the hard to soft segments as well as the effectiveness of the hard segment as a physical crosslinker, the control of the size distribution of the hard segment is a key factor in designing polyurethane elastomers. It was found that reaction conditions can affect the size distribution of hard segments derived from an aliphatic diisocyanate with differential reactivity between the two isocyanate groups. Lower reaction temperatures and simultaneous mixing of all reactants gave the preferred size distribution of hard segments. © 1995 John Wiley & Sons, Inc.     

Macromolecular synthesis from saccharic lactones. Polyaddition of D-glucaro- and D-mannaro- 1,4:6, 3-dilactones with diisocyanates and hydrolyzability of the resulting polyurethanes having dilactone rings in the main chains

Polyaddition of saccharic acid dilactones prepared from D-glucose and D-mannitol, D-glu-caro-, and D-mannaro-1,4:6,3-dilactones ( 1 and 2 , respectively), with hexamethylene di-isocyanate ( 3a ) and methyl (S)-2,6-diisocyanatocaproate ( 3b ) was carried out by using dibutyltin dilaurate as a catalyst at 50, 25, and 0°C to give polyurethanes ( 4 and 5 ) having dilactone moieties in the main chains. The resulting polymers were found to decompose easily in phosphate buffers under neutral or slightly basic conditions (pH 7 or 8). Therefore, the polyurethanes may be used as novel degradable polymeric materials. © 1995 John Wiley & Sons, Inc.     

Study of elastomeric polyurethane nanocomposites prepared from grafted organic–montmorillonite

4,4′-Diphenylmethane diisocyanate (MDI) was grafted on to organic–montmorillonite (OMMT) by reaction between hydroxyl groups (−OH) on surface of the montmorillonite and the isocyanate groups (−NCO) of MDI, thus forming grafted organic–montmorillonite (MOMMT). Intercalated nanocomposites based on polyurethane (PU) and MOMMT were prepared by solution intercalation technology. The interface interaction of PU/MOMMT nanocomposites was better than that of PU/MMT composites. The tensile strength, elongation at break, and tear strength of the PU/MOMMT nanocomposites increased for MOMMT content up to 5% w/w, and then decreased with further increase in MOMMT content. At the same filler content, the tensile strength and tear strength of PU/MOMMT nanocomposites were higher than those of PU/OMMT nanocomposites, whereas the elongations at break of PU/MOMMT nanocomposites were smaller than those of PU/OMMT nanocomposites. The initial temperatures of weight loss of PU/MOMMT nanocomposites were lower than for PU/MMT composites in the first step of thermal degradation, whereas in the second step initial temperatures of weight loss were higher for PU/MOMMT nanocomposites.     

DIBUTYLTIN DILAURATE-CATALYZED DIISOCYANATE COUPLING—GRAFTING OF POLY(ETHYLENE GLYCOL) ONTO NANO-SILICA SURFACE THROUGH A ONE-STEP PROCEDURE

Grafting polymer glycols onto nano-silica surface through one-step procedure was investigated. The major characteristic of this procedure is that all the materials and reagents (silica, PEG, TDI, DBTDL, solvent) required for grafting were added simultaneously into the reaction vessel. TDI and DBTDL were used as coupling agent and catalyst, respectively.The products were characterized by FTIR, TGA, elemental analyses and TEM, giving evidence for successful grafting of PEG. Possible mechanism of this grafting was studied and two grafting processes were proposed. The process through which the grafting proceeds depends on the reaction temperature. Effect of molecular weight of PEG on grafting was also investigated.     

Controlling the diffusion of micro-volume Pb solution on hydrophobic polyurethane membrane for quantitative analysis using laser-induced breakdown spectroscopy (LIBS)

This work reports a novel controlling mechanism of analyte diffusion in a micro volume solution (100 μL) into a hydrophobic membrane. This study was designed to facilitate the liquid–solid conversion using membrane for laser-induced breakdown spectroscopy (LIBS) in quantitatively analyzing aqueous lead (Pb) pollutant. Herein, we used the same analyte (Pb) solution applied on one side of the membrane (back side) to enhance the diffusion of the analyte administered from the other side (front side). The membrane was confirmed hydrophobic with contact angles ranged from 104.6°±1.3° to 106.28°±1.7°, where its morphology had smooth surface and randomly distributed small pores. We found the limit of detection (LOD) to reach 184.2 mg/L derived from a calibration curve with Pb I (405.7 nm) line intensity as the dependent variable, where the root-mean-square-errors (RMSE) and correlation (R²) were 1.08 M and 0.999, respectively. In comparison, the membrane back side with distilled water achieved LOD as low as 134.53 mg/L obtained from the similar calibration curve (RMSE = 5.8 M; R² = 0.986). Further analysis using the LIBS spectra confirmed the role of the analyte ion on the back side of the membrane in enhancing the analyte diffusion.