大叶桉化学成分的研究 - 大叶桉酚乙和其它成分的分离和鉴定

从大叶桉叶的乙醇提取物中分离并鉴定出九种已知成分:5-羟基-4',7-二甲氧基6,8-二甲基黄酮,4',5-二羟基-7-甲氧基6,8-二甲基黄酮,3β-羟基-乌索-11-烯-28,13β-内酯,13β-乙酰氧基-乌索-11-烯-28,13β-内酯;3β,28-二羟基-乌索-12-烯,β-谷甾醇,2-甲基5,7-二羟基-苯骈吡喃酮-7β-葡萄糖苷,正卅烷醇和正卅烷酸,另外,分得一种新的酰基间苯三酚类成分,命名为大叶桉酚乙,其结构为2-甲氧基-4,6-二羟基异丁酰基苯,并进行化学合成确证,大叶桉酚乙在管碟法中对金黄色葡萄球菌和枯草杆菌有抑菌作用。     

β,β-二氯丁烯酮甲基上的反应

通过4,4-二氯-3-丁烯-2-酮的氯甲基化,Mannich反应和醇醛缩合制备了1,1,5-三氯-p-戊烯-3-酮(2),1,1-二氯-9-二乙胺基-1-戊烯-3-酮盐酸盐(3)和1,1-二氯-1,4-己二烯-3-酮(4).氯甲基化产品(2)与三乙胺在醚反应生成1,1-二氯-1,4-戊二烯-3-酮(6),在醇中生成1,1-二氯-5-乙氧基-1-戊烯-3-酮(6).与容易在室温中聚合.(2)和氨在醇中反应可得到环化产品N-(4-酮基-5H,6H-2-吡啶基)-3H,4H,5H-吡啶-2,4-二酮.     

4-取代苯次甲亚胺-5-(1-苯基-3-甲基-5-氯吡唑)-2H-1,2,4-三唑-3-硫酮的合成

以乙醇为溶剂,冰醋酸为催化剂,4-氨基-5-(1-苯基-3-甲基-5-氯吡唑)-1,2,4-三唑-3-硫酮(1)与芳醛经缩合反应合成了7个新型的4-取代苯次甲亚胺-5-(1-苯基-3-甲基-5-氯吡唑)-4H-1,2,4-三唑-3-硫酮(3a~3g),收率66%~74%,其结构经1H NMR,IR及元素分析表征。合成4-(苯次甲亚胺)-5-(1-苯基-3-甲基-5-氯吡唑)-2H-1,2,4-三唑-3-硫酮(3a)的最佳反应条件为:以乙醇为溶剂,乙酸为催化剂,1 10 mmol,n(苯甲醛)∶n(1)=1.2,于75℃反应3 h,产率74%。     

茉莉酮酸甲酯类似物的新方法

茉莉酮酸甲酯是茉莉花的主香成份。本文报道了另一类茉莉酮酸甲酯的类似物2-烃基-3-氧-环戊基-乙酸甲酯, 2-亚苄基-3-氧-环戊基-乙酸甲酯, 和2-(1-羟基-戊基)-3-氧-环戊基-乙酸甲酯, 及其合成的新方法。     

杂环光化学IV.1,2,4-三氮杂-双环[4.2.0]辛烷衍生物的光化学合成

通过1,3-二甲基-6-氮杂胸腺嘧啶与含极性取代基的烯类化合物的光环合加成反应,合成了1,2,4-三氮杂-2,4,6-三甲基-3,5-二氧-8-乙酰基-双环[4.2.0]辛烷的三个差异构体(6R,8S)-1a,(6S,8R)-2a和(6R,8R)-3a;1,2,4-三氮杂-2,4,6-三甲基-3,5-二氧-8-氰基-双环[4.2.0]辛烷的两个差相异构体(6S,8R)-2b和(6R,8R)-3b以及1,2,4-三氮杂-2,4,6-三甲基-3,5-二氧-8-羧甲酯基的两个差相异构体.讨论了该反应的区域选择性,以及产物的立体化学。     

3-乙酰基取代吡咯衍生物的合成及其晶体结构

本文通过Knorr合成法制备了四个3-位乙酰基取代的吡咯衍生物:1, 2-二甲基-4-异丙基-5-苯基-3-乙酰基-吡咯(5a); 1, 2, 4-三甲基-5-对甲氧苯基-3-乙酰基-吡咯(5b); 1, 2, 5-三甲基-4-苯基-3-乙酰基-吡咯(5c); 1, 2, 5-三甲基-4-对甲氧苯基-3-乙酰基-吡咯(5d)。通过红外, 质谱, 核磁等方法对其结构进行了表征。测定了其中三个化合物的晶体结构。对这类吡咯环上4或5-位有芳环取代基时化合物的晶体结构特征进行了扼要讨论, 晶体衍射实验结果表明,4, 5-位上的芳环与吡咯环本身处于非共平面结构。     

1-芳基-3-(5-氯-1,3-二苯基-1H-4-吡唑基)-2,3-环氧-1-丙酮的新重排反应

报导了1-芳基-3-(5-氯代-1,3-二苯基-1H-4-吡唑基)-2,3-环氧-1-丙酮的重排反应, 生成β-(4,5-二氢-1,3-二苯基-5-酮-1H-4-吡唑基)-α-羟基-α-P-甲苯基丙酸, 讨论了反应机理, 并用红外光谱, 核磁共振氢谱, 碳十三核磁共振和微量分析证实了结构.     

α-二酮的铟促水相烯丙基化研究

以6,7-十二烷二酮(或1,2-环烷基二酮)和3-碘-2-碘甲基-1-丙烯为原料,铟粉为催化剂,在水相中经烯丙基化反应合成了4个新型的单烯丙基化产物[7-羟基-7-(2-碘甲基-烯丙基)-十二烷-6-酮和2-羟基-2-(2-碘甲基-烯丙基)-环烷酮]和3个新型的双烯丙基化产物{4-亚甲基-1,2-二戊基-1,2-环戊二醇,2-羟基-2-[2-(1-羟基-2-羰基-环癸基甲基)-烯丙基]-环癸酮和2-羟基-2-[2-(1-羟基-2-羰基-环十二基甲基)-烯丙基]-环十二烷酮},其结构经1H NMR,IR和HR-MS表征。     

5-二氰亚甲基-4-二环丙亚甲基-3-[1-(2, 5-二甲基-3-呋喃基)亚乙基]四氢呋喃-2-酮的合成

报道俘精酸酐类化合物(E/Z)4-二环丙亚甲基-3-[1-(2, 5-二甲基-3-呋喃基)亚乙基]四氢呋喃-2, 5-酮的拆分, 及(E)和(Z)-5-二氰亚甲基-4-二环丙亚甲基-3-[1-(2, 5-二甲基-3-呋喃基)亚乙基]四氢呋喃-2-酮 4(E)和4(Z)的合成, 并对它们的光致变色特性进行了初步研究。     

千里光中四个新倍半萜的结构

从植物千里光中分得四个新艾里莫芬烷型倍半萜,经仔细的波谱分析和单晶X射线衍射,研究它们的结构分别为为：7β,11-环氧-9α,10α-环氧-8-羰基艾里莫芬烷(1),8-11-过氧-9α,10α-环氧-6-烯-8β-羟基艾里莫芬烷(2),7(11)-烯-9α,10α-环氧-8-羰基艾里莫芬烷(3),6-烯-9α,10α-环氧-11-羟基-8-羰基艾里莫芬烷(4)。活性筛选实验表明化合物1具有促进癌细胞生长作用,化合物2和3具有较好的抗癌活性。     

The negative biodegradation of poly(vinyl alcohol) modified by aldehydes

Due to the wide application of PVA acetals, the biodegradation of PVA modified by formaldehyde, n-butyraldehyde, glyoxaldehyde and glutaraldehyde was conducted in an intensive biodegradation environment. Spectrophotometric analysis and weight loss were used to determine the biodegradation of PVA, and the changes of the mechanical properties of PVA acetals were also studied.An obvious decrease in biodegradation levels of all the modified samples was found, and a decrease in biodegradation level with increasing degree of acetals of PVA. The biodegradation of poly(vinyl formal) is better than poly(vinyl butyral) with the same degree of acetals whereas the biodegradation levels of poly(vinyl glyoxal) are lower than poly(vinyl glutaral) which has the same degree of crosslinking. The difference between the FT-IR of the samples before and after biodegradation indicated scission of residual PVA chain during the process.     

A kinetic model for predicting biodegradation

Biodegradation plays a key role in the environmental risk assessment of organic chemicals. The need to assess biodegradability of a chemical for regulatory purposes supports the development of a model for predicting the extent of biodegradation at different time frames, in particular the extent of ultimate biodegradation within a ‘10?day window’ criterion as well as estimating biodegradation half-lives. Conceptually this implies expressing the rate of catabolic transformations as a function of time. An attempt to correlate the kinetics of biodegradation with molecular structure of chemicals is presented. A simplified biodegradation kinetic model was formulated by combining the probabilistic approach of the original formulation of the CATABOL model with the assumption of first order kinetics of catabolic transformations. Nonlinear regression analysis was used to fit the model parameters to OECD 301F biodegradation kinetic data for a set of 208 chemicals. The new model allows the prediction of biodegradation multi-pathways, primary and ultimate half-lives and simulation of related kinetic biodegradation parameters such as biological oxygen demand (BOD), carbon dioxide production, and the nature and amount of metabolites as a function of time. The model may also be used for evaluating the OECD ready biodegradability potential of a chemical within the ‘10-day window’ criterion.     

Aerobic biodegradability of hydroxypropyl-β-cyclodextrins in soil

Hydroxylpropyl-β-cyclodextrins (HP-β-CDs), hydroxyalkyl derivatives of β-CD, used in a broad range of applications in food, pharmaceutical, agriculture and bioremediation of soil because of their specific chemical properties. The possibility of varying the biodegradation rate of HP-β-CDs by changing the DS and substitution pattern makes HP-β-CDs suitable for various applications. Therefore, their biodegradation fate has been of great concern. In this study, the biodegradation of various HP-β -CDs, which have different degrees and patterns of substitution in different soil ecosystems, was investigated. The degree and pattern of substitution of HP-β-CDs were determined by the reductive-cleavage method and methylation analysis. Two common soils and a contaminated soil were used in the biodegradation test. All CDs were found to be more or less biodegradable. Increasing the degree of substitution (DS) had negative effect on the biodegradation rate of HP-β-CDs. The substitution pattern affected the biodegradation, too. The biodegradation rates of CDs in the contaminated soil were higher than that obtained in the uncontaminated soils. The contamination removing ability of CDs was highly affected by their own biodegradation fate in soil.     

A kinetic model for predicting biodegradation

Biodegradation plays a key role in the environmental risk assessment of organic chemicals. The need to assess biodegradability of a chemical for regulatory purposes supports the development of a model for predicting the extent of biodegradation at different time frames, in particular the extent of ultimate biodegradation within a '10 day window' criterion as well as estimating biodegradation half-lives. Conceptually this implies expressing the rate of catabolic transformations as a function of time. An attempt to correlate the kinetics of biodegradation with molecular structure of chemicals is presented. A simplified biodegradation kinetic model was formulated by combining the probabilistic approach of the original formulation of the CATABOL model with the assumption of first order kinetics of catabolic transformations. Nonlinear regression analysis was used to fit the model parameters to OECD 301F biodegradation kinetic data for a set of 208 chemicals. The new model allows the prediction of biodegradation multi-pathways, primary and ultimate half-lives and simulation of related kinetic biodegradation parameters such as biological oxygen demand (BOD), carbon dioxide production, and the nature and amount of metabolites as a function of time. The model may also be used for evaluating the OECD ready biodegradability potential of a chemical within the '10-day window' criterion.     

Spectral and chromatographic study of the effect of UV preirradiation on the biodegradation of phenols

The effect of UV radiation of a KrCl excilamp on the biodegradation of 4-nitrophenol, 2,5-dinitrophenol, and their mixture by a Penicillium tardum H-2 isolate strain and microbiocenosis of activated sludge was studied. It was shown that the efficiency of the successive photodegradation and biodegradation of nitrophenols depended on the initial concentration and the time of UV preirradiation. UV irradiation increased the efficiency of the biodegradation of 2,5-dinitrophenol with respect to the biodegradation alone. Preliminary UV irradiation inhibited the subsequent biodegradation of 4-nitrophenol by a Penicillium tardum H-2 isolate strain and activated sludge.     

Biodegradation of Chlorinated and Non-chlorinated VOCs from Pharmaceutical Industries

Biodegradation studies were conducted for major organic solvents such as methanol, ethanol, isopropanol, acetone, acetonitrile, toluene, chloroform, and carbon tetrachloride commonly used in pharmaceutical industries. Various microbial isolates were enriched and screened for their biodegradation potential. An aerobic mixed culture that had been previously enriched for biodegradation of mixed pesticides was found to be the most effective. All the organic solvents except chloroform and carbon tetrachloride were consumed as primary substrates by this mixed culture. Biodegradation rates of methanol, ethanol, isopropanol, acetone, acetonitrile, and toluene were measured individually in batch systems. Haldane model was found to best fit the kinetics of biodegradation. Biokinetic parameters estimated from single-substrate experiments were utilized to simulate the kinetics of biodegradation of mixture of substrates. Among the various models available for simulating the kinetics of biodegradation of multi-substrate systems, competitive inhibition model performed the best. Performance of the models was evaluated statistically using the dimensionless modified coefficient of efficiency (E). This model was used for simulating the kinetics of biodegradation in binary, ternary, and quaternary substrate systems. This study also reports batch experiments on co-metabolic biodegradation of chloroform, with acetone and toluene as primary substrates. The Haldane model, modified for inhibition due to chloroform, could satisfactorily predict the biodegradation of primary substrate, chloroform, and the microbial growth.     

Laser light-scattering studies of poly(caprolactone-b-ethylene oxide-b-caprolactone) nanoparticles and their enzymatic biodegradation

Water-insoluble triblock poly(caprolactone-b-ethylene oxide-b-caprolactone) (PCL-PEO-PCL) was micronized into narrowly distributed nanoparticles stable in water. Using a combination of static and dynamic laser light scattering (LLS), we characterized the resultant nanoparticles and studied their biodegradation in the presence of enzyme lipase PS. The results revealed that the biodegradation rate was mainly dependent on the enzyme concentration. The scattering intensity decreased as the degradation proceeded, but there was no change in size of the remaining nanoparticles, indicating that the degradation of each particle was fast and the enzyme consumed the nanoparticles individually. We also found that different copolymer compositions, i.e., different PCL–PEO molar ratios, led to different biodegradation rates. The pH and temperature dependence of the biodegradation rate were also studied. All results indicated that the biodegradation rate can be well controlled and the biodegradation essentially involves two processes: adsorption of lipase PS onto the nanoparticles, and enzymatic hydrolysis of the PCL blocks. The biomedical application of the enzymatic biodegradation of the copolymer nanoparticles is also envisioned. © 1999 John Wiley & Sons, Inc. J Polym Sci B: Polym Phys 37: 3288–3293, 1999     

PPDO/OMMT纳米复合材料在微生物环境下的降解行为

采用微生物水性培养液降解实验法对聚对二氧环己酮/有机蒙脱土(PPDO/OMMT)纳米复合材料的生物降解性能进行了研究.通过质量、特性黏数、pH、热分析和电子扫描显微镜(SEM)研究了试样的降解过程.结果表明,在本实验条件下,PPDO/OMMT纳米复合材料降解性随着OMMT含量的增加而增加.降解90天,在微生物水性培养液...     

Biodegradability of polylactide bottles in real and simulated composting conditions

As new biodegradable polymers and their packaging applications are emerging, there is a need to address their environmental performance. In particular, there is a need to understand the time required for their complete disintegration, before these materials are deployed in commercial composting processes. Standards developed by ASTM and ISO evaluate the biodegradation of biodegradable plastic materials in simulated controlled composting conditions. However, a more detailed understanding of the biodegradation of complete packages is needed in order to have a successful composting operation. This paper investigates the biodegradation performance of polylactide (PLA) bottles under simulated composting conditions according to ASTM and ISO standards, and these results are compared with a novel method of evaluating package biodegradation in real composting conditions. Two simulated composting methods were used in this study to assess biodegradability of PLA bottles: (a) a cumulative measurement respirometric (CMR) system and (b) a gravimetric measurement respirometric (GMR) system. Both CMR and GMR systems showed similar trends of biodegradation for PLA bottles and at the end of the 58th day the mineralization was 84.2±0.9% and 77.8±10.4%, respectively. PLA bottle biodegradation in real composting conditions was correlated to their breakdown and variation in molecular weight. Molecular weight of 4100 Da was obtained for PLA bottles in real composting conditions on the 30th day. The biodegradation observed for PLA bottles in both conditions explored in this study matches well with theoretical degradation and biodegradation mechanisms; however, biodegradation variability exists in both conditions and is discussed in this paper.