1-取代-2-氨基苯并咪唑化合物毒性和热力学性质的密度泛函理论研究

用密度泛函理论(DFT)B3LYP方法,在6-31G(d)基组水平上,对8个1-取代-2-氨基苯并咪唑化合物分子进行了全优化计算,得到其轨道能(ENHOMO、ENLUMO以及二者轨道能隙ΔE2)、原子电荷(Q)等量子化学参数,以及热能校正值Eth、恒容热容Cv、熵S等热力学性质,并计算了8种1-取代-2-氨基苯并咪唑化合物分子的电性拓扑状态指数Em。通过最佳变量子集回归建立这些化合物毒性的QSAR模型,以及热力学性质的QSPR模型。模型的相关系数R2和采用逐一剔除法得到的交叉验证相关系数R2cv均大于0.84和0.72,利用2个模型得到毒性的预测值与实验值的误差分别为0.11和0.20,3个热力学性质预测模型的误差分别为3.89%、4.03%和2.64%,吻合度较好,经检验证明所建模型具有良好的鲁棒性和预测能力。研究工作揭示了基团对毒性大小影响的变化规律、有利于对苯并咪唑类化合物在生态环境中的危害性进行评价,可为研发高效、低毒的苯并咪唑类新型药物提供理论依据。     

基于基团贡献法的有机化合物好氧生物降解预测模型研究

从MITI-Ⅰ试验中筛选出587种不同类型有机化合物的可用数据,通过对这些物质的结构进行拆分,随机选择其中50种化合物作为验证集,另外537种作为训练集,利用多元线性回归(MLR)和支持向量机(SVM)2种计算方法分别建立模型。结果表明,芳香酸、醛、芳香碘和叔胺等功能基团对有机化合物的好氧生物降解性影响较大;MLR模型总体预测正确率为81.43%,验证集正确率为82%,SVM模型总体预测正确率为87.90%,验证集正确率为86%。所建立的2种定量结构与生物降解性关系(QSBR)模型有效,可用于化学品的好氧生物降解性评价。     

过氧化物酶催化去除水体中酚类内分泌干扰物的研究进展

内分泌干扰物(EDCs)会干扰生物体的内分泌系统从而对人类、野生动物以及水生生物产生负面影响,这一问题已经引起了人们的广泛关注.广泛分布于自然环境中的辣根过氧化物酶(HRP)和木质素过氧化物酶(LiP),具有较强的催化氧化能力,能够催化去除雌激素、双酚A等多种具有内分泌干扰效应的污染物.本文在介绍辣根过氧化物酶(HRP)和木质素过氧化物酶(LiP)两种过氧化物酶的相关性质和催化氧化机理的基础上,从污染物结构与其催化去除效率关系的角度综述了过氧化物酶去除具有内分泌干扰效应的污染物的研究进展.为污水处理过程中过氧化物酶用于去除内分泌干扰物提供依据,并展望了其未来的发展方向.     

Comparative quantitative structure–activity relationship (QSAR) study on acute toxicity of triazole fungicides to zebrafish

We employed two-dimensional quantitative structure–activity relationship (2D-QSAR) and hologram QSAR (HQSAR) methods to quantitatively investigate the mechanism and active site of toxicity for Danio rerio exposed to triazole fungicides. Our results showed that 2D-QSAR models constructed using the energy of the lowest unoccupied molecular orbit, the net C atom charges, the octanol–water partition coefficient and the molecular shape factor had higher predictive abilities. HQSAR models containing the fragment distinctions atoms (As), bonds (Bs), chirality (Ch) and donors and acceptors (D&A) had higher reliability. It was found that 2D-QSAR results explaining the toxicity mechanism were consistent with HQSAR. In summary, the hydrophobicity and shape/size of the molecule were the important factors influencing the toxic effect of these chemicals against D. rerio. In addition, electron exchange may occur between these fungicides and the target. The study provided a method to evaluate the environmental risk of chemicals with a similar structure, based on the QSAR models obtained.     

Toxicity of substituted benzaldehydes to photobacterium phosphoreum and quantitative structure‐activity relationship

Acute toxicities (15min‐EC₅₀) of 21 substituted benzaldehydes to Photobacterium phosphoreum were determined. A quantitative structure‐activity relationship (QSAR) was developed using molecular connectivity indices and quantum chemical parameters, which show that the toxicity is influenced mainly by the difference of the simple and valence‐corrected fourth path molecular connectivity, polarizability, dipole moment, and the most negative net atomic charge on an atom. This study further shows that benzaldehydes are reactive chemicals, which exhibit bioreactive toxicity.     

Utility of the QSAR modeling system for predicting the toxicity of substances on the European inventory of existing commercial chemicals∗

Many chemicals are in common commercial use for which no information on the environmental fate or toxicity exists. Recent legislation requires that many substances be assessed for their toxicity to aquatic organisms within a very short time and determine which of these chemicals need to be studied in greater detail. It would be impossible to measure the acute and chronic effects of all of these compounds on a single organism, let alone a battery of different types of organisms, communities or ecosystems. Initially, the chemicals on the European Inventory of Existing Commercial Chemical Substances (EINECS) need to be screened and relative hazard to the environment determined. In response to OECD directives, there has been a great deal of activity by government and industry scientists. At the International Workshop on Advances in Environmental Hazard and Risk Assessment it was concluded that quantitative structure activity relationships (QSAR) could and should be used in the hazard assessment process. Papers published in that volume outline the advantages, disadvantages, limitations, advances and research requirements.

The QSAR, structure‐activity based chemical modeling and information system, which was developed by the US‐Environmental Protection Agency was used to predict the acute toxicity of 113 substances from the “Old Substances”; list of the German government to the four commonly used aquatic toxicity test organisms: Daphnia magna (DM), fathead minnow (FHM), rainbow trout (RBT), and blue‐gill sunfish (BG).

Of these compounds the QSAR system predicted the acute toxicity of 87 substances towards fathead minnow. For the other three species examined the QSAR system could be used to predict toxicity for 78 compounds.

The predicted toxicities were compared to observed toxicities of compounds which have been evaluated and stored in the “Aquire”; data base. Observed toxicity values were available for at least one species for 38 compounds. The toxicities of some compounds are well predicted while those of other compounds were not well predicted. Overall, the QSAR system accurately classified the acute toxicity ranges of 50%, 64%, 56% and 56% of the compounds investigated for DM, FHM, RBT and BG, respectively. Of the compounds studied 10 were very poorly predicted, of these the QSAR system overpredicted the toxicity of three, while underpredicting the toxicity of seven. Of these seven compounds, five contained amino groups.     

有机化学品的自相关拓扑指数与生物毒性的定量关系

针对目前化学品生物毒性评价和预测中存在的问题,采用以范德华体积（V）和电负性（E）为结构参数的自相关拓扑指数法,建立了54种有机化学品的分子结构与青锵鱼急性毒性（48h-LC₅₀）的定量构效关系数学模型。对模型采用的范德华体积进行了修正,使其更能准确地描述分子的结构信息,经逐步回归分析得到的线性关系良好的定量构效关系方程logLC₅₀＝0.03＋0.32V（1）＋13.33E（0）－6.83E（2）－4.48E（3）（R＝0.9513,F＝245.1）,有可能应用于不同结构化学品的生物毒性预测。     

取代苯对人体细胞的定量结构—遗传毒性研究

通过微核实验,测定了 36 种取代苯类化合物对人体外周血淋巴细胞的遗传毒性;并构建了遗传毒性与分子结构参数之间的 QSAR 模型.结果表明,有 34 种化合物显著地导致了微核的产生,具有明显的遗传毒性;遗传毒性的大小与分子结构描述符辛醇-水分配系数(MlogP)、x 轴主惯性矩(Principalx)、γ 极化率[Polar(γ)]等存在良好的结构-活性相关关系,所建模型的相关系数 R² =0.718,具有较高的预测能力,可用来预测取代苯类化合物的遗传毒性.     

氯代苯类化合物对江水细菌的毒性及QSAR研究

采用细菌生长抑制实验,测定了18种氯苯类化合物对长江水中混合细菌的毒性,得到24 hIC₅₀值,-1gIC₅₀为3.65～4.32,其中,毒性最弱的是氯苯,毒性最强的是1,2,4-三氯苯.选用分子连接性指数法对毒性数据进行定量结构活性关系(QSAR)研究.结果表明,氯苯类化合物对江水细菌的毒性与苯环上取代基的种类、数目和位置有关,价分子连接性指数0XV和7X_CHV能够很好地描述氯苯类化合物对江水细菌的毒性.方程-1gIC₅₀=0.8390XV-25.3727X_CHV+0.802的稳健性很好,该模型的预测值与毒性实测值之间的相关系数达0.948.      

62种杂环芳胺结构与致变活性关系的神经网络研究

应用自适应分子结构描述符生成方法和神经网络数值模式,研究62种烹调食品过程中产生的杂环芳胺结构与致变活性间的关系。该模式预报结果与实验测定结果符合良好;致变剂、非致变剂和勉强有致变活性剂三类间正确分类率超过90％。通过6次自适应分子结构描述符选择迭代,得到５种特征分子描述符为：芳环碳原子取代甲基数、芳环氮原子取代甲基数、母体共轭环数、端环增活结构数和端环抑活结构数。其中,增活结构为具有共轭烯烃碎片结构;抑活结构具有短共轭烯烃结构或不具有共轭烯烃结构。最后,对该构效关系的起因进行了定性解释。