[1]A simple and sensitive competitive bio-barcode immunoassay for triazophos based on multi-modified gold nanoparticles and fluorescent signal amplification. Zhang, Chan,Jiang, Zejun,Jin, Maojun,Chen, Ge,Cao, Xiaolin,Cui, Xueyan,Zhang, Yudan,Li, Ruixing,Wang, Jing,Zhang, Chan,Jiang, Zejun,Jin, Maojun,Chen, Ge,Cao, Xiaolin,Cui, Xueyan,Zhang, Yudan,Li, Ruixing,Wang, Jing,Du, Pengfei,Du, Pengfei,Du, Pengfei,Abd El-Aty, A. M.,Abd El-Aty, A. M.. 2018

[2]Highly sensitive detection of triazophos pesticide using a novel bio-bar-code amplification competitive immunoassay in a micro well plate-based platform. Du, Pengfei,Jin, Maojun,Zhang, Chan,Chen, Ge,Cui, Xueyan,Zhang, Yudan,Zhang, Yanxin,Zou, Pan,Jiang, Zejun,Cao, Xiaolin,She, Yongxin,Jin, Fen,Wang, Jing. 2018

[3]Enhanced Competitive Chemiluminescent Enzyme Immunoassay for the Trace Detection of Insecticide Triazophos. Jin, Maojun,Shao, Hua,Jin, Fen,Shi, Xiaomei,Wang, Jing,Gui, Wenjun. 2012

[4]Expression and Functional Properties of an Anti-Triazophos High-Affinity Single-Chain Variable Fragment Antibody with Specific Lambda Light Chain. Liu, Rui,Liang, Xiao,Xiang, Dandan,Guo, Yirong,Zhu, Guonian,Liang, Xiao,Liu, Yihua. 2016

[5]Competitive colorimetric triazophos immunoassay employing magnetic microspheres and multi-labeled gold nanoparticles along with enzymatic signal enhancement. Du, Pengfei,Jin, Maojun,Chen, Ge,Zhang, Chan,Cui, Xueyan,Zhang, Yudan,Zhang, Yanxin,Zou, Pan,Jiang, Zejun,Cao, Xiaolin,She, Yongxin,Jin, Fen,Wang, Jing.

[6]Mutation in acetylcholinesterase1 associated with triazophos resistance in rice stem borer, Chilo suppressalis (Lepidoptera: Pyralidae). Jiang, Xiaojing,Jiang, Weihua,Han, Zhaojun,Qu, Mingjing,Denholm, Ian,Fang, Jichao. 2009

[7]Cloning of Two Acetylcholinesterase Genes and Analysis of Point Mutations Putatively Associated with Triazophos Resistance in Chilo auricilius (Lepidoptera: Pyralidae). Li, Xiao-Huan,Zhang, Zhi-Chun,Liu, Bao-Sheng,Fang, Ji-Chao,Li, Xiao-Huan,Fang, Ji-Chao,Huang, Shui-Jin.

[8]Identification of Metabolites and Transcripts Involved in Salt Stress and Recovery in Peanut. Cui, Feng,Liu, Yiyang,Han, Yan,Wan, Shubo,Li, Guowei,Cui, Feng,Liu, Yiyang,Han, Yan,Wan, Shubo,Li, Guowei,Sui, Na,Liu, Shanshan,Duan, Guangyou. 2018

[9]Nonylphenol Toxicity Evaluation and Discovery of Biomarkers in Rat Urine by a Metabolomics Strategy through HPLC-QTOF-MS. Zhang, Yan-Xin,Yang, Xin,Zou, Pan,Du, Peng-Fei,Wang, Jing,Jin, Fen,Jin, Mao-Jun,She, Yong-Xin,Du, Peng-Fei,Wang, Jing,Jin, Fen,Jin, Mao-Jun,She, Yong-Xin. 2016

[10]Serum Metabolic Profiling of Oocyst-Induced Toxoplasma gondii Acute and Chronic Infections in Mice Using Mass-Spectrometry. Zhou, Chun-Xue,Chen, Xiao-Qing,Zhu, Xing-Quan,Zhou, Chun-Xue,He, Shen-Yi,Cong, Wei,Chen, Xiao-Qing,Elsheikha, Hany M.. 2018

[11]Comparative metabolomics in vanilla pod and vanilla bean revealing the biosynthesis of vanillin during the curing process of vanilla. Gu, Fenglin,Hong, Yinghua,Fang, Yiming,Tan, Lehe,Chen, Yonggan,Gu, Fenglin,Fang, Yiming,Tan, Lehe. 2017

[12]Metabolite profiles of rice cultivars containing bacterial blight-resistant genes are distinctive from susceptible rice. Huang, Xin,Zhu, Shuifang,Wu, Jiao,Yu, Haichuan,Wu, Jiao,Dai, Haofu,Mei, Wenli,Peng, Ming. 2012

[13]Comparison of Salt Tolerance in Soja Based on Metabolomics of Seedling Roots. Li, Mingxia,Jiao, Yang,Zhang, Haiyan,Shi, Lianxuan,Guo, Rui,Jin, Xiaofei. 2017

[14]Utilization of UPLC/Q-TOF-MS-Based Metabolomics and AFLP-Based Marker-Assisted Selection to Facilitate/Assist Conventional Breeding of Polygala tenuifolia. Li, Juan,Wang, Dan-Dan,Bai, Lu,Pu, Ya-Jie,Qin, Xue-Mei,Zhang, Fu-Sheng,Wang, Dan-Dan,Bai, Lu,Pu, Ya-Jie,Xu, Xiao-Shuang,Peng, Bing,Tian, Hong-Ling,Ma, Cun-Gen. 2017

[15]The Antagonistic Effect of Mycotoxins Deoxynivalenol and Zearalenone on Metabolic Profiling in Serum and Liver of Mice. Ji, Jian,Cui, Fangchao,Pi, Fuwei,Zhang, Yinzhi,Li, Yun,Wang, Jiasheng,Sun, Xiulan,Zhu, Pei,Ji, Jian,Zhu, Pei,Cui, Fangchao,Pi, Fuwei,Zhang, Yinzhi,Sun, Xiulan,Li, Yun,Wang, Jiasheng. 2017

[16]Nontargeted Analysis Using Ultraperformance Liquid Chromatography-Quadrupole Time-of-Flight Mass Spectrometry Uncovers the Effects of Harvest Season on the Metabolites and Taste Quality of Tea (Camellia sinensis L.). Dai, Weidong,Qi, Dandan,Yang, Ting,Lv, Haipeng,Guo, Li,Zhang, Yue,Zhu, Yin,Peng, Qunhua,Xie, Dongchao,Tan, Junfeng,Lin, Zhi.

[17]Effect of the DGAT1 K232A genotype of dairy cows on the milk metabolome and proteome. Lu, Jing,van Hooijdonk, Toon,Hettinga, Kasper,Lu, Jing,Boeren, Sjef,Vervoort, Jacques,Lu, Jing.

[18]Complex molecular mechanisms underlying seedling salt tolerance in rice revealed by comparative transcriptome and metabolomic profiling. Wang, Wen-Sheng,Zhao, Xiu-Qin,Li, Min,Huang, Li-Yu,Xu, Jian-Long,Zhang, Fan,Cui, Yan-Ru,Fu, Bin-Ying,Li, Zhi-Kang,Li, Min,Xu, Jian-Long,Fu, Bin-Ying,Li, Zhi-Kang.

[19]Metabolomic Analyses Reveal Distinct Change of Metabolites and Quality of Green Tea during the Short Duration of a Single Spring Season. Liu, Jianwei,Liu, Jianwei,Zhang, Qunfeng,Liu, Meiya,Ma, Lifeng,Shi, Yuanzhi,Ruan, Jianyun,Liu, Jianwei,Zhang, Qunfeng,Liu, Meiya,Ma, Lifeng,Shi, Yuanzhi,Ruan, Jianyun.

[20]Metabolic responses and "omics" technologies for elucidating the effects of heat stress in dairy cows. Min, Li,Zhao, Shengguo,Tian, He,Zhou, Xu,Zhang, Yangdong,Li, Songli,Zheng, Nan,Wang, Jiaqi,Min, Li,Yang, Hongjian.