[1]王 玲,杨文富,杨 应,等.水液相下依达拉奉消除羟自由基反应的密度泛函理论研究[J].江西师范大学学报(自然科学版),2023,(06):582-593.[doi:10.16357/j.cnki.issn1000-5862.2023.06.05]
 WANG Ling,YANG Wenfu,YANG Ying,et al.The Density Functional Theory Study on the Reaction of Edaravone Scavenging Hydroxyl Radical in Aqueous Solution[J].Journal of Jiangxi Normal University:Natural Science Edition,2023,(06):582-593.[doi:10.16357/j.cnki.issn1000-5862.2023.06.05]
点击复制

水液相下依达拉奉消除羟自由基反应的密度泛函理论研究()
分享到:

《江西师范大学学报》(自然科学版)[ISSN:1006-6977/CN:61-1281/TN]

卷:
期数:
2023年06期
页码:
582-593
栏目:
化学
出版日期:
2023-11-25

文章信息/Info

Title:
The Density Functional Theory Study on the Reaction of Edaravone Scavenging Hydroxyl Radical in Aqueous Solution
文章编号:
1000-5862(2023)06-0582-12
作者:
王 玲12杨文富2杨 应2黄筱珂3潘 宇2赵丽红4*王佐成24*
(1.白城师范学院计算机科学学院,吉林 白城 137000; 2.白城师范学院理论计算中心,吉林 白城 137000; 3.吉林省前郭县第三中学物理组,吉林 松原 138000; 4.白城医学高等专科学校基础医学院,吉林 白城 137000)
Author(s):
WANG Ling12YANG Wenfu2YANG Ying2HUANG Xiaoke3PAN Yu2ZHAO Lihong4WANG Zuocheng24*
(1.College of Computer Science,Baicheng Normal University,Baicheng Jilin 137000,China; 2.Theoretical Computing Center,Baicheng Normal University,Baicheng Jilin 137000,China; 3.Qianguo County of Jilin Province,Physics Group of No. 3 Middle School,Songyuan Jilin 138000,China; 4.School of Baisic Medicine,Baicheng Medical College,Baicheng Jilin 137000,China)
关键词:
依达拉奉 羟自由基 密度泛函理论 过渡态 电子转移 能垒
Keywords:
edaravone hydroxyl radical density functional theory transient state electron transfer energy barrier
分类号:
O 641.12
DOI:
10.16357/j.cnki.issn1000-5862.2023.06.05
文献标志码:
A
摘要:
该文采用密度泛函理论的M06-2X和MN15方法,结合自洽反应场理论的SMD模型方法,研究了在水液相下依达拉奉(Eda)消除羟自由基(OH)的反应机理.反应通道研究发现:Eda可通过给OH提供H原子、OH与其加成以及给OH提供单电子等3个途径消除OH.势能面计算结果表明:Eda给OH提供H原子的能垒为16.1~77.9 kJ·mol-1; OH加成反应的能垒为2.8~26.8 kJ·mol-1; Eda给OH提供单电子的能垒为32.1 kJ·mol-1.在水液相下Eda容易与OH发生反应,依达拉奉是极好的羟自由基清除剂.
Abstract:
The reaction mechanism of edaravone(Eda)scavenging hydroxyl radical in aqueous solution is studied by means of M06-2X and MN15 methods based on DFT(density functional theory)and SMD model method of self-consistent reaction field theory.The study of reaction channel finds that Eda can scavenge OH by providing H atom to OH,OH addition to it and providing single electron to OH.The potential energy surface calculations show that the energy barrier of Eda providing H atom to OH is between 16.1 and 77.9 kJ·mol-1,the energy barrier of OH addition reaction is between 2.8 and 26.8 kJ·mol-1,the energy barrier of Eda providing single electron to OH is 32.1 kJ·mol-1.The results show that Eda can easily react with OH in aqueous solution and Eda is an excellent hydroxyl radical scavenger.

参考文献/References:

[1] 金海峰,王月飞,郭林娜,等.依达拉奉通过抗炎、抗氧化对大鼠缺氧性肺动脉高压病理发展的抑制作用[J].中国老年学杂志,2022,42(21):5324-5328.
[2] 王娟,顾顺忠,陆洋,等.依达拉奉改善大鼠心肌缺血损伤和炎症反应[J].中南医学科学杂志,2022,50(4):495-498.
[3] 党若之.依达拉奉和Gpx4在慢性社会挫败应激所致小鼠抑郁样行为中的作用及机制[D].重庆:重庆医科大学,2022.
[4] SHEN Zhongying,SHEN Wenying,CHEN Minghua,et al.Mitochondria,calcium and nitric oxide in the apoptotic pathway of esophageal carcinoma cellsinduced by As2O3 [J].International Journal of Molecular Medicine,2002,9(4):385-390.
[5] KOBAYASHI T,KURODA S,TADA M,et al.Calcium-induced mitochondrial swelling and cytochrome c release in the brain: its biochemical characteristics and implication in ischemic neuronal injury[J].Brain Research,2003,960(1/2):62-70.
[6] 王蔚.依达拉奉对大鼠海马神经元损伤的影响效应及其作用机制的研究[D].南京:南京医科大学,2007.
[7] 吴晋,吴婷,丁新生.依达拉奉对沙土鼠缺血-再灌注损伤后的脑保护作用机制的探讨[J].南京医科大学学报,2006,26(3):156-160.
[8] 张霄瀚.应用依达拉奉治疗胶原诱导型关节炎的方案探究[D].南宁:广西医科大学,2020.
[9] 阿吉姑·阿布都热西提,买尔旦·马合木提,马合木提·乌斯满,等.维生素C清除自由基能力3种检测方法的比较[J].新疆医科大学学报,2008,149(5):578-579,582.
[10] DE ZWART L L,MEERMAN J H N,COMMANDEUR J N M, et al.Biomarkers of free radical damage: applications in experimental animals and in humans[J].Free Radical Biology & Medicine,1999,26(1/2):202-226.
[11] 罗香怡,高浩溟,姜丰,等.水液相下羟基自由基(水分子簇)诱导脯氨酸分子损伤的机理[J].复旦学报(自然科学版),2022,61(1):104-114.
[12] 喻小继,潘宇,黄煜纯,等.水液相下羟基自由基诱导半胱氨酸分子损伤的机理[J].武汉大学学报(理学版),2023,69(3):373-383.
[13] 马宏源,姜春旭,庄严,等.水环境下羟自由基致Asp分子损伤机理[J].吉林大学学报(理学版),2019,57(5):1246-1254.
[14] 李斌,黄筱珂,李双鹤,等.水液相下羟基自由基与两性Lys分子反应机理的量子化学研究[J].复旦学报(自然科学版),2023,62(2):263-272.
[15] 杨应,姜春旭,张雪娇,等.水液相下羟自由基诱导组氨酸分子损伤的密度泛函理论研究[J].南开大学学报(自然科学版),2023,56(3):108-119.
[16] 李冰,庄严,吴梓昊,等.水液相环境下羟自由基抽对异丙基苯基氢诱导布洛芬损伤的机理[J].中山大学学报(自然科学版),2020,59(4):24-32.
[17] 杨应,黄筱珂,赵丽红,等.水液相下Phe分子与Na+配合物对映异构的DFT研究[J].江西师范大学学报(自然科学版),2023,47(2):154-163.
[18] WANG Ying,VERMA P,ZHANG Lujia,et al.M06-SX screened-exchange density functional for chemistry and solid-state physics[J].Proceedings of the National Academy of Sciences,2020,117(5):2294-2301.
[19] 柳国洪,彭国强,张栩宾,等.水液相下赖氨酸钙(II)配合物旋光异构的DFT研究[J].江西师范大学学报(自然科学版),2022,46(6):558-567.
[20] 刘芳,姜春旭,杨晓翠,等.α-丙氨酸及其金属配合物的旋光异构理论研究进展[J].武汉大学学报(理学版),2022,68(6):665-679.
[21] GARRETT B C, TRUHLAR D G.Criterion of minimum state density in the transition state theory of、bimolecular reactions[J].The Journal of Chemical Physics,1979,70(4):1593-1598.
[22] HRATCHIAN H P, SCHLEGEL H B.Using hessian updating to increase the efficiency of a hessian based predictor-corrector reaction path following method[J].Journal of Chemical Theory and Computation,2005,1(1):61-69.
[23] YU Haoyu S,HE Xiao,LI Shaohong L,et al.MN15:a Kohn-Sham global-hybrid exchange-correlation density functional with broad accuracy for multi-reference and single-reference systems and noncovalent interactions[J].Chemical Science,2016,7(8):5032-5051.
[24] ALEKSANDR V,MARENICE C J,CRAMER,et al.Universal solvation model based on solute electron density and on a continuum model of the solvent defined by the bulk dielectric constant and atomic surface tensions[J].The Journal of Physical Chemistry B,2009,113(18):6378-6396.
[25] MARCUS R A.Electron transfer reactions in chemistry:theory and experiment[J].Pure and Applied Chemistry,1997, 69(1):13-30.
[26] MARCUS R A.Electron transfer reactions in chemistry: theory and experiment[J].Reviews of Modern Physics,1993,65(3):599-610.
[27] BIEGLER-KÖNIG F,SCHÖNBOHM J,DERDAU R,et al.AIM 2000:Version 2.0[M].Hamilton McMaster University,2002.
[28] GORB L,LESZCZYNSKI J.Intramolecular proton transfer in mono-and dihydrated tautomers of guanine: an ab initio post hartree-fock study[J].Journal of the American Chemical Society,1998,120(20):5024-5032.

备注/Memo

备注/Memo:
收稿日期:2023-06-01
基金项目:吉林省自然科学基金(20160101308C),白城医学高等专科学校科研平台重点课题(BYKPT202207)和白城医学高等专科学校高层次人才团队建设课题(BCYZ20220408)资助项目.
作者简介:王 玲(1980—),女,吉林松原人,讲师,主要从事计算机应用化学研究.E-mail: century51@163.com
通信作者:赵丽红(1970—),女,吉林大安人,教授,主要从事药物化学研究.E-mail: 1035213648@qq.com
王佐成(1963—),男,吉林蛟河人,教授,主要从事计算化学研究.E-mail: wzc188@163.com
更新日期/Last Update: 2023-11-25