👤 Xuejie Li

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Also published as: A Li, Ai-Jun Li, Ai-Qin Li, Ailing Li, Aimin Li, Aixin Li, Alexander H Li, Alexander Li, Amy Li, An-Qi Li, AnHai Li, Anan Li, Andrew C Li, Ang Li, Anna Fen-Yau Li, Annie Li, Anqi Li, Anyao Li, Ao Li, Aowen Li, Aoxi Li, Audrey Li, Bai-Qiang Li, Baichuan Li, Baiqiang Li, Baixing Li, Baizhou Li, Bang-Yan Li, Bao Li, Bao-Shan Li, Baoguang Li, Baoguo Li, Baohong Li, Baohua Li, Baolin Li, Baoqi Li, Baoqing Li, Baosheng Li, Baoting Li, Bei Li, Bei-Bei Li, Beibei Li, Beixu Li, Ben Li, Ben-Shang Li, Benyi Li, Biao Li, Bichun Li, Bin Li, Bin-Kui Li, Binbin Li, Bing Li, Bing-Heng Li, Bing-Hui Li, Bing-Mei Li, Bingbing Li, Binghu Li, Binghua Li, Bingjie Li, Bingjue Li, Bingkun Li, Binglan Li, Bingong Li, Bingshan Li, Bingsheng Li, Bingsong Li, Bingxin Li, Binjun Li, Binkui Li, Binru Li, Binxing Li, Biyu Li, Bizhi Li, Bo Li, BoWen Li, Bohao Li, Bohua Li, Bolun Li, Boru Li, Botao Li, Boxuan Li, Boya Li, Boyang Li, Bugao Li, C H Li, C Li, C X Li, C Y Li, Caesar Z Li, Cai Li, Cai-Hong Li, Caihong Li, Caili Li, Caixia Li, Caiyu Li, Caiyun Li, Can Li, Cang Li, Caolong Li, Chang Li, Chang-Da Li, Chang-Ping Li, Chang-Sheng Li, Chang-Yan Li, Chang-hai Li, Changcheng Li, Changgui Li, Changhong Li, Changhui Li, Changjiang Li, Changkai Li, Changqing Li, Changwei Li, Changxian Li, Changyan Li, Changyu Li, Changzheng Li, Chanjuan Li, Chanyuan Li, Chao Bo Li, Chao Li, Chaochen Li, Chaojie Li, Chaonan Li, Chaoqian Li, Chaowei Li, Chaoying Li, Chen Li, Chen-Chen Li, Chen-Lu Li, Chen-Xi Li, Chenfeng Li, Cheng Li, Cheng-Lin Li, Cheng-Tian Li, Cheng-Wei Li, Chengbin Li, Chengcheng Li, Chenghao Li, Chenghong Li, Chengjian Li, Chengjun Li, Chenglan Li, Chenglong Li, Chengnan Li, Chengping Li, Chengqian Li, Chengquan Li, Chengsi Li, Chenguang Li, Chengwen Li, Chengxin Li, Chengyun Li, Chenhao Li, Chenjie Li, Chenli Li, Chenlin Li, Chenlong Li, Chenlu Li, Chenmeng Li, Chenrui Li, Chensheng Li, Chenwen Li, Chenxi Li, Chenxiao Li, Chenxin Li, Chenxuan Li, Chenyang Li, Chenyao Li, Chenyu Li, Cheung Li, Chi-Ming Li, Chi-Yuan Li, Chia Li, Chia-Yang Li, Chien-Feng Li, Chien-Hsiu Li, Chien-Te Li, Chih-Chi Li, Chitao Li, Chiyang Li, Chong Li, Chongyang Li, Chongyi Li, Chris Li, Chu-Qiao Li, Chuan F Li, Chuan Li, Chuan-Hai Li, Chuan-Yun Li, Chuanbao Li, Chuanfang Li, Chuang Li, Chuangpeng Li, Chuanning Li, Chuanyin Li, Chumei Li, Chun Li, Chun-Bo Li, Chun-Lai Li, Chun-Mei Li, Chun-Quan Li, Chun-Xiao Li, Chun-Xu Li, Chung-Hao Li, Chung-I Li, Chunhong Li, Chunhui Li, Chunjie Li, Chunjun Li, Chunlan Li, Chunlian Li, Chunliang Li, Chunlin Li, Chunmei Li, Chunmiao Li, Chunqing Li, Chunqiong Li, Chunshan Li, Chunsheng Li, Chunting Li, Chunxia Li, Chunxiao Li, Chunxing Li, Chunxue Li, Chunya Li, Chunyan Li, Chunyi Li, Chunying Li, Chunyu Li, Chunzhu Li, Chuzhong Li, Cien Li, Cong Li, Congcong Li, Congfa Li, Conghui Li, Congjiao Li, Conglin Li, Congxin Li, Congye Li, Cui Li, Cui-lan Li, Cuicui Li, Cuiguang Li, Cuilan Li, Cuiling Li, Cun Li, Cunxi Li, Cyril Li, D C Li, Da Li, Da-Hong Li, Da-Jin Li, Da-Lei Li, Da-wei Li, DaZhuang Li, Dacheng Li, Dai Li, Daiyue Li, Dalei Li, Dali Li, Dalin Li, Dan C Li, Dan Li, Dan-Dan Li, Dan-Ni Li, Dandan Li, Daniel Tian Li, Danjie Li, Danni Li, Danxi Li, Danyang Li, Daoyuan Li, Dapei Li, Dawei Li, Dayong Li, Dazhi Li, De-Jun Li, De-Tao Li, Dechao Li, Defa Li, Defeng Li, Defu Li, Dehai Li, Deheng Li, Dehua Li, Dejun Li, Demin Li, Deming Li, Dengfeng Li, Dengke Li, Dengxiong Li, Deqiang Li, Desen Li, Desheng Li, Dexiong Li, Deyu Li, Dezhi Li, Di Li, Di-Jie Li, Dianjie Li, Dijie Li, Ding Li, Ding Yang Li, Ding-Biao Li, Ding-Jian Li, Dingchen Li, Dingshan Li, Diyan Li, Dong Li, Dong Sheng Li, Dong-Jie Li, Dong-Ling Li, Dong-Run Li, Dong-Yun Li, Dong-fei Li, Dongbiao Li, Dongdong Li, Dongfang Li, Dongfeng Li, Donghe Li, Donghua Li, Dongliang Li, Dongmei Li, Dongmin Li, Dongnan Li, Dongtao Li, Dongyang Li, Dongye Li, Duan Li, Duanbin Li, Duanxiang Li, Dujuan Li, Duo Li, Duoyun Li, Ellen Li, En Li, En-Min Li, Enhao Li, Enhong Li, Enxiao Li, F Li, Fa-Hong Li, Fa-Hui Li, Fadi Li, Fan Li, Fang Li, Fangqi Li, Fangyan Li, Fangyong Li, Fangyuan Li, Fangzhou Li, Fei Li, Fei-Lin Li, Fei-feng Li, Feifei Li, Feilong Li, Fen Li, Feng Li, Feng-Feng Li, Fengfeng Li, Fengjuan Li, Fengli Li, Fengqi Li, Fengqiao Li, Fengqing Li, Fengxia Li, Fengxiang Li, Fengyi Li, Fengyuan Li, Fu-Rong Li, Fugen Li, Fuhai Li, Fujun Li, Fulun Li, Fuping Li, Fusheng Li, Fuyu Li, Fuyuan Li, G Li, G-P Li, Gaijie Li, Gaizhen Li, Gaizhi Li, Gan Li, Gang Li, Ganggang Li, Gao-Fei Li, Gaoyuan Li, Ge Li, Gen Li, Gen-Lin Li, Gerard Li, Gong-Hua Li, Gongda Li, Guanbin Li, Guandu Li, Guang Li, Guang Y Li, Guang-Li Li, Guang-Xi Li, Guangda Li, Guangdi Li, Guanghua Li, Guanghui Li, Guangjin Li, Guangli Li, Guanglu Li, Guanglve Li, Guangming Li, Guangping Li, Guangpu Li, Guangqiang Li, Guangquan Li, Guangwen Li, Guangxi Li, Guangxiao Li, Guangyan Li, Guangzhao Li, Guangzhen Li, Guannan Li, Guanqiao Li, Guanyu Li, Gui Lin Li, Gui-Bo Li, Gui-Hua Li, Gui-Rong Li, Gui-xing Li, Guigang Li, Guihua Li, Guilan Li, Guisen Li, Guixia Li, Guixin Li, Guiyang Li, Guiying Li, Guiyuan Li, Guo Li, Guo-Chun Li, Guo-Jian Li, Guo-Li Li, Guo-Ping Li, Guo-Qiang Li, Guobin Li, Guoge Li, Guohong Li, Guohua Li, Guohui Li, Guojin Li, Guojun Li, Guoli Li, Guoping Li, Guoqin Li, Guoqing Li, Guowei Li, Guoxi Li, Guoxiang Li, Guoxing Li, Guoyan Li, Guoyin Li, H J Li, H Li, H-F Li, H-H Li, H-J Li, Hai Li, Hai-Yun Li, Haibin Li, Haibo Li, Haifeng Li, Haihong Li, Haihua Li, Haijun Li, Hailong Li, Haimin Li, Haiming Li, Hainan Li, Haipeng Li, Hairong Li, Haitao Li, Haitong Li, Haixia Li, Haiyan Li, Haiyang Li, Haiying Li, Haiyu Li, Han Li, Han-Bing Li, Han-Bo Li, Han-Ni Li, Han-Ru Li, Han-Wei Li, Hanbin Li, Hanbing Li, Hanbo Li, Handong Li, Hang Li, Hangwen Li, Hanjun Li, Hankun Li, Hanlu Li, Hanmei Li, Hanqi Li, Hanqin Li, Hansen Li, Hanting Li, Hanxiao Li, Hanxue Li, Hao Li, Hao-Fei Li, Haojing Li, Haolong Li, Haomiao Li, Haoqi Li, Haoran Li, Haotong Li, Haoxian Li, Haoyu Li, Haying Li, He Li, He-Zhen Li, Hecheng Li, Hegen Li, Hehua Li, Heng Li, Heng-Zhen Li, Hengguo Li, Hengtong Li, Hengyu Li, Hening Li, Hewei Li, Hexin Li, Heying Li, Hong Li, Hong-Chun Li, Hong-Lan Li, Hong-Lian Li, Hong-Mei Li, Hong-Tao Li, Hong-Wen Li, Hong-Yan Li, Hong-Yu Li, Hong-Zheng Li, Hongbo Li, Hongchang Li, Hongde Li, Honggang Li, Hongguo Li, Honghua Li, Honghui Li, Hongjia Li, Hongjiang Li, Hongjuan Li, Honglei Li, Hongli Li, Honglian Li, Hongliang Li, Honglin Li, Hongling Li, Honglong Li, Hongmei Li, Hongmin Li, Hongming Li, Hongqin Li, Hongquan Li, Hongru Li, Hongsen Li, Hongwei Li, Hongxia Li, Hongxin Li, Hongxing Li, Hongxue Li, Hongyan Li, Hongye Li, Hongyi Li, Hongyu Li, Hongyun Li, Hongzhe K Li, Hongzheng Li, Hongzhi Li, Hsiao-Fen Li, Hsiao-Hui Li, Hsin-Hua Li, Hsin-Yun Li, Hu Li, Hua Li, Hua-Zhong Li, Huabin Li, Huafang Li, Huafu Li, Huaixing Li, Huaiyuan Li, Hualian Li, Hualing Li, Huamao Li, Huan Li, Huanan Li, Huang Li, Huangbao Li, Huangyuan Li, Huanhuan Li, Huanjun Li, Huanqing Li, Huanqiu Li, Huaping Li, Huashun Li, Huawei Li, Huayao Li, Huayin Li, Huaying Li, Hui Li, Hui-Jun Li, Hui-Long Li, Hui-Ping Li, Huibo Li, Huifang Li, Huifeng Li, Huihuang Li, Huihui Li, Huijie Li, Huijuan Li, Huijun Li, Huilan Li, Huili Li, Huiliang Li, Huilin Li, Huilong Li, Huimin Li, Huiping Li, Huiqin Li, Huiqing Li, Huiqiong Li, Huiting Li, Huixia Li, Huixue Li, Huiying Li, Huiyou Li, Huiyuan Li, Huizi Li, Hujie Li, Hulun Li, Hung Li, Hung-Yuan Li, Ivan Li, J Li, J T Li, Jason Li, Jen-Ming Li, Jenny J Li, Ji Li, Ji Xia Li, Ji-Cheng Li, Ji-Feng Li, Ji-Liang Li, Ji-Lin Li, Ji-Min Li, Jia Li, Jia Li Li, Jia-Da Li, Jia-Huan Li, Jia-Peng Li, Jia-Ru Li, Jia-Xin Li, Jiabei Li, Jiachen Li, Jiacheng Li, Jiafang Li, Jiafei Li, Jiahao Li, Jiahui Li, Jiajia Li, Jiajie Li, Jiajing Li, Jiajun Li, Jiajv Li, Jiali Li, Jialin Li, Jialing Li, Jialun Li, Jiaming Li, Jian Li, Jian'an Li, Jian-Jun Li, Jian-Mei Li, Jian-Qiang Li, Jian-Shuang Li, Jianan Li, Jianang Li, Jianbin Li, Jianbo Li, Jianchun Li, Jiandong Li, Jianfang Li, Jianfeng Li, Jiang Li, Jiangan Li, Jiangbo Li, Jiangchao Li, Jiangfeng Li, Jianglin Li, Jianglong Li, Jiangtao Li, Jiangui Li, Jianguo Li, Jiangxia Li, Jiangya Li, Jianhai Li, Jianhua Li, Jiani Li, Jianing Li, Jianliang Li, Jianlin Li, Jianmin Li, Jiannan Li, Jianping Li, Jianrong Li, Jianrui Li, Jiansheng Li, Jianshuang Li, Jianwei Li, Jianxin Li, Jianxiong Li, Jianye Li, Jianyi Li, Jianyong Li, Jianyu Li, Jianzhong Li, Jiao Li, Jiao-Jiao Li, Jiaomei Li, Jiaping Li, Jiaqi Li, Jiawei Li, Jiaxi Li, Jiaxin Li, Jiaxuan Li, Jiayan Li, Jiayang Li, Jiayi Li, Jiaying Li, Jiayu Li, Jiayuan Li, Jiazhou Li, Jicheng Li, Jie Li, Jie-Pin Li, Jie-Shou Li, Jiehan Li, Jiejia Li, Jiejie Li, Jiejing Li, Jieming Li, Jiequn Li, Jieshou Li, Jiexi Li, Jiexin Li, Jiezhen Li, Jifang Li, Jihua Li, Jin Li, Jin-Jiang Li, Jin-Liang Li, Jin-Long Li, Jin-Mei Li, Jin-Ping Li, Jin-Qiu Li, Jin-Wei Li, Jin-Xiu Li, Jinchen Li, Jinfang Li, Jinfeng Li, Jing Li, Jing-Jing Li, Jing-Ming Li, Jing-Yao Li, Jing-Yi Li, Jing-gao Li, Jingcheng Li, Jingchun Li, Jingfeng Li, Jinghao Li, Jinghui Li, Jingjing Li, Jingke Li, Jinglin Li, Jingmei Li, Jingming Li, Jingping Li, Jingqi Li, Jingshang Li, Jingshu Li, Jingtong Li, Jingui Li, Jingwen Li, Jingxia Li, Jingxiang Li, Jingxin Li, Jingya Li, Jingyi Li, Jingyong Li, Jingyu Li, Jingyun Li, Jinhua Li, Jinhui Li, Jinjie Li, Jinku Li, Jinlan Li, Jinliang Li, Jinlin Li, Jinman Li, Jinming Li, Jinping Li, Jinsong Li, Jinwei Li, Jinxia Li, Jinxin Li, Jinzhi Li, Jiong Li, Jiong-Ming Li, Jipeng Li, Jiqing Li, Jisen Li, Jisheng Li, Jiuke Li, Jiuyi Li, Jiwei Li, Jiwen Li, Jixi Li, Jixuan Li, Jiyang Li, Jiyuan Li, John Zhong Li, Jonathan Z Li, Joyce Li, Ju-Rong Li, Juan Li, Juan-Juan Li, Juanjuan Li, Juanling Li, Juanni Li, Jufang Li, Julia Li, Jun Li, Jun Z Li, Jun-Cheng Li, Jun-Jie Li, Jun-Ling Li, Jun-Ru Li, Jun-Yan Li, Jun-Ying Li, JunBo Li, Junfeng Li, Junhong Li, Junhui Li, Junjie Li, Junjun Li, Junming Li, Junping Li, Junqin Li, Junru Li, Junsheng Li, Juntong Li, Junxian Li, Junxin Li, Junxu Li, Junya Li, Junyi Li, Junying Li, Justin Li, Jutang Li, Juxue Li, K-L Li, Ka Li, Ka Wan Li, Kai Li, Kai-Wen Li, Kaibin Li, Kaibo Li, Kaifeng Li, Kailong Li, Kaimi Li, Kainan Li, Kaiwei Li, Kaixin Li, Kaiyi Li, Kaiyuan Li, Kang Li, Kangli Li, Kangyuan Li, Karen Li, Kathy H Li, Kawah Li, Ke Li, KeZhong Li, Keanning Li, Kecheng Li, Kechun Li, Keguo Li, Kejuan Li, Keke Li, Kening Li, Kenli Li, Kenneth Kai Wang Li, Keqing Li, Keshen Li, Keying Li, Keyuan Li, Kezhen Li, Kongdong Li, Kuan Li, Kui Li, Kuiliang Li, Kun Li, Kun-Peng Li, Kun-Ping Li, Kun-Xin Li, Kunlin Li, Kunlong Li, Kunlun Li, Kunpeng Li, L I Li, L K Li, L Li, L P Li, L-Y Li, Lai K Li, Laiqing Li, Lamei Li, Lan Li, Lan-Juan Li, Lan-Lan Li, Lanfang Li, Lang Li, Lanjuan Li, Lanlan Li, Lanzhou Li, Le Li, Le-Le Li, Le-Ying Li, Lei Li, Leilei Li, Leipeng Li, Letai Li, Leyao Li, Li Li, Li-Min Li, Li-Na Li, Lian Li, Lianbing Li, Liang Li, Liangdong Li, Liangji Li, Liangkui Li, Liangqian Li, Lianhong Li, Lianjian Li, Lianyong Li, Liao-Yuan Li, Lieyou Li, Liguo Li, Lihong Li, Lihua Li, Lijia Li, Lijuan Li, Lijun Li, Lili Li, Liliang Li, Liling Li, Liming Li, Lin Li, Lin-Feng Li, Linchuan Li, Linfeng Li, Ling Li, Ling-Jie Li, Ling-Ling Li, Ling-Zhi Li, Lingjiang Li, Lingjie Li, Lingjun Li, Lingling Li, Lingxi Li, Lingyan Li, Lingyi Li, Lingzhi Li, Linhong Li, Linke Li, Linlin Li, Linqi Li, Linqing Li, Linsheng Li, Linting Li, Linxin Li, Linyan Li, Linying Li, Lipeng Li, Liping Li, Liqin Li, Liqun Li, Lirong Li, Lisha Li, Litao Li, Liuzheng Li, Liwei Li, Lixi Li, Lixia Li, Lixiang Li, Liyan Li, Long Li, Long Shan Li, Long-Yan Li, Longhui Li, Longxuan Li, Longyu Li, Lu Li, Lu-Yun Li, Lucia M Li, Lucy Li, Luhan Li, Lujiao Li, Lujie Li, Lulu Li, Luquan Li, Luxuan Li, Luyao Li, Luying Li, M D Li, M Li, M V Li, M-J Li, Man Li, Man-Xiang Li, Man-Zhi Li, Mangmang Li, Manjiang Li, Manna Li, Manru Li, Manxia Li, Mao Li, Maogui Li, Maolin Li, Maoquan Li, Maosheng Li, Marilyn Li, Mei Li, Mei-Lan Li, Mei-Ya Li, Mei-Zhen Li, Meifang Li, Meifen Li, Meijia Li, Meilan Li, Meiqing Li, Meitao Li, Meiting Li, Meiyan Li, Meiying Li, Meiyue Li, Meizi Li, Melody M H Li, Meng Li, Meng-Hua Li, Meng-Jun Li, Meng-Meng Li, Meng-Miao Li, Meng-Yang Li, Meng-Yao Li, Meng-Yue Li, MengGe Li, Mengfan Li, Menghua Li, Mengjiao Li, Mengjuan Li, Mengling Li, Menglu Li, Mengmeng Li, Mengqing Li, Mengqiu Li, Mengsen Li, Mengshi Li, Mengxi Li, Mengxia Li, Mengxuan Li, Mengyang Li, Mengyao Li, Mengying Li, Mengyuan Li, Mengyun Li, Mengze Li, Mi Li, Mian Li, Miao Li, Miao X Li, Miaoxin Li, Michelle Li, Mimi Li, Min Li, Min-Dian Li, Min-Rui Li, Min-jun Li, Minerva X Li, Ming D Li, Ming Li, Ming V Li, Ming Xing Li, Ming Zhou Li, Ming-Han Li, Ming-Hao Li, Ming-Jiang Li, Ming-Kai Li, Ming-Qing Li, Ming-Wei Li, Ming-Xing Li, Ming-Yang Li, Mingdan Li, Mingfang Li, Mingfei Li, Minghao Li, Minghua Li, Minghui Li, Mingjiang Li, Mingjie Li, Mingjun Li, Mingke Li, Mingkun Li, Mingli Li, Minglong Li, Minglun Li, Mingna Li, Mingqiang Li, Mingquan Li, Mingrui Li, Mingwei Li, Mingxi Li, Mingxia Li, Mingxing Li, Mingxu Li, Mingxuan Li, Mingyang Li, Mingyao Li, Mingyue Li, Mingzhe Li, Mingzhou Li, Minhui Li, Minle Li, Minmin Li, Minqi Li, Minyue Li, Minze Li, Minzhe Li, Miyang Li, Mo Li, Mohan Li, Monica M Li, Moyi Li, Mufan Li, Mulin Jun Li, Muzi Li, N Li, Na Li, Naishi Li, Nan Li, Nan-Nan Li, Nana Li, Nanjun Li, Nanlong Li, Nanxing Li, Nanzhen Li, Ni Li, Nianfu Li, Nianyu Li, Nien Li, Nien-Chen Li, Nien-Chi Li, Ning Li, Ningyan Li, Ningyang Li, Niu Li, Nuomin Li, O Li, P H Li, P Li, Pan Li, Panlong Li, Panyuan Li, Pei Li, Pei-Lin Li, Pei-Qin Li, Pei-Shan Li, Pei-Ying Li, Pei-Zhi Li, PeiQi Li, Peibo Li, Peifen Li, Peifeng Li, Peihong Li, Peihua Li, Peilin Li, Peilong Li, Peining Li, Peipei Li, Peiqin Li, Peiran Li, Peiwu Li, Peixin Li, Peiyu Li, Peiyuan Li, Peiyun Li, Peng Li, Peng Peng Li, Peng-li Li, Pengcui Li, Penghui Li, Pengjie Li, Pengju Li, Pengsong Li, Pengyang Li, Pengyu Li, Pengyun Li, Pik Yi Li, Pilong Li, Pindong Li, Ping Li, Ping'an Li, Pinghua Li, Pingping Li, Pu Li, Pu-Yu Li, Q Li, Qi Li, Qi-Fu Li, Qi-Jing Li, Qian Li, Qian-Qian Li, Qiang Li, Qiang-Ming Li, Qiankun Li, Qianqian Li, Qiao Li, Qiao-Xin Li, Qiaolian Li, Qiaoqiao Li, Qibing Li, Qifang Li, Qihang Li, Qihua Li, Qiji Li, Qijun Li, Qilan Li, Qilong Li, Qin Li, Qiner Li, Qing Li, Qing Run Li, Qing-Chang Li, Qing-Fang Li, Qing-Min Li, Qing-Wei Li, Qingchao Li, Qingfang Li, Qingfeng Li, Qinggang Li, Qinghe Li, Qinghong Li, Qinghua Li, Qingjie Li, Qinglan Li, Qingli Li, Qinglin Li, Qingling Li, Qingqin S Li, Qingrun Li, Qingshang Li, Qingsheng Li, Qingxian Li, Qingyang Li, Qingyu Li, Qingyuan Li, Qingyun Li, Qinqin Li, Qinrui Li, Qintong Li, Qiong Li, Qionghua Li, Qipei Li, Qiqiong Li, Qiu Li, Qiufeng Li, Qiuhong Li, Qiusheng Li, Qiuxuan Li, Qiuya Li, Qiuyan Li, Qiwei Li, Qiyong Li, Qizhai Li, Quan Li, Quan-Zhong Li, Quanpeng Li, Quanshun Li, Quanzhang Li, Qun Li, R H L Li, R Li, Ran Li, Ranchang Li, Ranran Li, Ranwei Li, Ren Li, Ren-Ke Li, Rena Li, Roger Li, Ronald Li, Rong Li, Rong-Bing Li, Ronggui Li, Rongkai Li, Rongling Li, Rongqing Li, Rongsong Li, Rongxia Li, Rongyao Li, Rosa J W Li, Ru Li, Ru-Hao Li, Rui Li, Rui-Fang Li, Rui-Han Li, Rui-Jún Eveline Li, Ruibing Li, Ruidong Li, Ruifang Li, Ruihuan Li, Ruijia Li, Ruijin Li, Ruikai Li, Ruitong Li, Ruiwen Li, Ruixi Li, Ruixia Li, Ruixue Li, Ruiyang Li, Rujia Li, Rulin Li, Rumei Li, Runbing Li, Runwen Li, Runzhao Li, Runzhen Li, Runzhi Li, Ruobing Li, Ruolin Li, Ruonan Li, Ruotai Li, Ruotian Li, Ruotong Li, Ruyi Li, Ruyue Li, S A Li, S E Li, S L Li, S Li, S S Li, S-C Li, Sai Li, Saijuan Li, Sainan Li, San-Feng Li, Sanqiang Li, Senlin Li, Senmao Li, Sha Li, Sha-Sha Li, Shan Li, Shan-Shan Li, Shangjia Li, Shanglai Li, Shangming Li, Shanhang Li, Shanpeng Li, Shanshan Li, Shanyi Li, Shao-Dan Li, Shaobin Li, Shaodan Li, Shaofei Li, Shaoguang Li, Shaojian Li, Shaojing Li, Shaoliang Li, Shaomin Li, Shaoqi Li, Shaoyong Li, Shasha Li, Shawn S C Li, Shawn Shun-Cheng Li, Shen Li, Sheng Li, Sheng-Fu Li, Sheng-Jie Li, Sheng-Qing Li, Sheng-Tien Li, Shengbiao Li, Shengbin Li, Shengchao A Li, Shenghao Li, Shengjie Li, Shengli Li, Shengliang Li, Shengsheng Li, Shengwen Li, Shengxian Li, Shengxu Li, Shengze Li, Sherly X Li, Shi Li, Shi-Fang Li, Shi-Guang Li, Shi-Hong Li, Shi-Ying Li, Shibao Li, Shibo Li, Shichao Li, Shigang Li, Shihao Li, Shiheng Li, Shihong Li, Shijie Li, Shijun Li, Shikang Li, Shilan Li, Shili Li, Shiliang Li, Shilin Li, Shilun Li, Shiqi Li, Shiquan Li, Shisheng Li, Shishi Li, Shitao Li, Shiya Li, Shiyan Li, Shiyang Li, Shiyi Li, Shiying Li, Shiyu Li, Shiyue Li, Shiyun Li, Shu Li, Shu-Fang Li, Shu-Fen Li, Shu-Feng Li, Shu-Hong Li, Shu-Qi Li, Shu-Xin Li, Shuai Li, Shuaicheng Li, Shuang Li, Shuang-Ling Li, Shuangding Li, Shuangfei Li, Shuanglong Li, Shuangmei Li, Shuangshuang Li, Shuangxiu Li, Shubo Li, Shude Li, Shufen Li, Shugang Li, Shuguang Li, Shuhao Li, Shuhua Li, Shuhui Li, Shujiao Li, Shujie Li, Shujin Li, Shujing Li, Shulin Li, Shun Li, Shunhua Li, Shunle Li, Shunqin Li, Shunqing Li, Shunwang Li, Shuo Li, Shupeng Li, Shuqiang Li, Shuwei Li, Shuwen Li, Shuying Li, Shuyu D Li, Shuyu Dan Li, Shuyuan Li, Shuyue Li, Si Li, Si-Wei Li, Si-Xing Li, Si-Ying Li, Si-Yuan Li, Sibing Li, Sichen Li, Sichong Li, Side Li, Siguang Li, Sijie Li, Simin Li, Siming Li, Sin-Lun Li, Siqi Li, Sitao Li, Siting Li, Siwen Li, Siyi Li, Siyu Li, Siyue Li, Song Li, Song-Chao Li, Songhan Li, Songlin Li, Songtao Li, Songyu Li, Songyun Li, Stephen Li, Su Li, SuYun Li, Suchun Li, Suheng Li, Suhong Li, Suiyan Li, Sujing Li, Suk-Yee Li, Sumei Li, Sunan Li, Sung-Chou Li, Supeng Li, Suping Li, Suran Li, Suwei Li, Suwen Li, Suyan Li, T Li, Taibo Li, Taiwen Li, Taixu Li, Tao Li, Taoyingnan Li, Teng Li, Tengyan Li, Thomas Li, Tian Li, Tian-Yi Li, Tian-chang Li, Tian-wang Li, Tianchang Li, Tiandong Li, Tianfeng Li, Tiange Li, Tianjiao Li, Tianjun Li, Tianming Li, Tiansen Li, Tiantian Li, Tianxiang Li, Tianyao Li, Tianye Li, Tianyi Li, Tianyou Li, Tie Li, Tiegang Li, Tiehua Li, Tiewei Li, Timmy Li, Ting Li, Tingguang Li, Tinghao Li, Tinghua Li, Tingsong Li, Tingting Li, Tong Li, Tong-Ruei Li, Tongyao Li, Tongzheng Li, Tsai-Kun Li, Tuojian Li, Tuoping Li, Vivian Li, Vivian S W Li, W H Li, W J Li, W Li, W W Li, W Y Li, W-B Li, Wan Jie Li, Wan Li, Wan-Hong Li, Wan-Shan Li, Wan-Xin Li, Wang Li, Wanling Li, Wanni Li, Wanqian Li, Wanru Li, Wanshi Li, Wanshun Li, Wanting Li, Wanwan Li, Wanxin Li, Wanyan Li, Wanyi Li, Wei Li, Wei-Bo Li, Wei-Dong Li, Wei-Jun Li, Wei-Li Li, Wei-Ming Li, Wei-Na Li, Wei-Ping Li, Wei-Qin Li, Wei-Yang Li, Weidong Li, Weifeng Li, Weiguang Li, Weiguo Li, Weihai Li, Weiheng Li, Weihua Li, Weijian Li, Weijie Li, Weijun Li, Weike Li, Weiling Li, Weimin Li, Weina Li, Weining Li, Weiping Li, Weiqin Li, Weirong Li, Weisong Li, Weiyang Li, Weiye Li, Weiyong Li, Weizu Li, Wen Lan Li, Wen Li, Wen-Chao Li, Wen-Jie Li, Wen-Ting Li, Wen-Wen Li, Wen-Xi Li, Wen-Xing Li, Wen-Ya Li, Wen-Ying Li, Wen-juan Li, Wenbo Li, Wenchao Li, Wende Li, Wendeng Li, Wenfang Li, Wenfeng Li, Wenge Li, Wenguo Li, Wenhao Li, Wenhong Li, Wenhua Li, Wenhui Li, Wenjia Li, Wenjian Li, Wenjie Li, Wenjing Li, Wenjuan Li, Wenjun Li, Wenke Li, Wenlei Li, Wenli Li, Wenlong Li, Wenming Li, Wenqi Li, Wenqiang Li, Wenqing Li, Wenqun Li, Wenrui Li, Wensheng Li, Wentao Li, Wenwen Li, Wenxi Li, Wenxia Li, Wenxiang Li, Wenxin Li, Wenxiu Li, Wenxue Li, Wenyan Li, Wenyang Li, Wenyi Li, Wenying Li, Wenyong Li, Wenyu Li, Wenzhe Li, Wenzhuo Li, Wu-Jun Li, Wuguo Li, Wulan Li, Wuyan Li, X B Li, X L Li, X Li, X Y Li, X-H Li, X-L Li, Xi Li, Xi-Hai Li, Xi-Xi Li, Xia Li, Xian Li, Xiancheng Li, Xiang Li, Xiang-Dong Li, Xiang-Jun Li, Xiang-Ping Li, Xiang-Yu Li, Xiangcheng Li, Xiangchun Li, Xiangdong Li, Xiangfei Li, Xiangjun Li, Xiangling Li, Xianglong Li, Xiangnan Li, Xiangpan Li, Xiangping Li, Xiangqi Li, Xiangrui Li, Xiangwei Li, Xiangyan Li, Xiangyang Li, Xiangyun Li, Xiangzhe Li, Xiankai Li, Xiankun Li, Xianlin Li, Xianlong Li, Xianlu Li, Xianlun Li, Xianrui Li, Xianyong Li, Xiao Li, Xiao-Cheng Li, Xiao-Dong Li, Xiao-Feng Li, Xiao-Gang Li, Xiao-Guang Li, Xiao-Hong Li, Xiao-Hui Li, Xiao-Jiao Li, Xiao-Jing Li, Xiao-Jun Li, Xiao-Kang Li, Xiao-Li Li, Xiao-Lin Li, Xiao-Long Li, Xiao-Min Li, Xiao-Na Li, Xiao-Qiang Li, Xiao-Qin Li, Xiao-Qiu Li, Xiao-Sa Li, Xiao-Tong Li, Xiao-Yao Li, Xiao-Yun Li, Xiao-kun Li, Xiao-mei Li, Xiao-xu Li, Xiao-yu Li, XiaoQiu Li, Xiaobai Li, Xiaobin Li, Xiaobing Li, Xiaobo Li, Xiaochen Li, Xiaochun Li, Xiaocun Li, Xiaodong Li, Xiaofang Li, Xiaofei Li, Xiaofeng Li, Xiaoguang Li, Xiaohan Li, Xiaoheng Li, Xiaohong Li, Xiaohu Li, Xiaohua Li, Xiaohuan Li, Xiaohui Li, Xiaojiao Li, Xiaojiaoyang Li, Xiaojing Li, Xiaoju Li, Xiaojuan Li, Xiaokun Li, Xiaolei Li, Xiaoli Li, Xiaolian Li, Xiaoliang Li, Xiaolin Li, Xiaoling Li, Xiaolong Li, Xiaoman Li, Xiaomei Li, Xiaomeng Li, Xiaomin Li, Xiaoming Li, Xiaona Li, Xiaonan Li, Xiaoning Li, Xiaopeng Li, Xiaoping Li, Xiaoqi Li, Xiaoqiang Li, Xiaoqin Li, Xiaoqing Li, Xiaoqiong Li, Xiaoquan Li, Xiaoran Li, Xiaorong Li, Xiaotian Li, Xiaoting Li, Xiaotong Li, Xiaowei Li, Xiaoxia Li, Xiaoxiao Li, Xiaoxiong Li, Xiaoxuan Li, Xiaoya Li, Xiaoyan Li, Xiaoyao Li, Xiaoyi Li, Xiaoying Li, Xiaoyong Li, Xiaoyu Li, Xiaoyuan Li, Xiaoyun Li, Xiaozhao Li, Xiaozhen Li, Xiaozheng Li, Xiatian Li, Xiawei Li, Xiaxia Li, Xiayu Li, Xidan Li, Xihao Li, Xihe Li, Xijing Li, Xikun Li, Xiliang Li, Ximei Li, Xin Li, Xin-Chang Li, Xin-Jian Li, Xin-Ping Li, Xin-Tao Li, Xin-Ya Li, Xin-Yu Li, Xin-Yue Li, Xin-Zhu Li, Xinbin Li, Xing Li, Xing-Wang Li, Xingchen Li, Xingcheng Li, Xingfang Li, Xinghuan Li, Xinghui Li, Xingli Li, Xinglong Li, Xingwang Li, Xingxing Li, Xingya Li, Xingye Li, Xingyu Li, Xingyuan Li, Xinhai Li, Xinhua Li, Xinhui Li, Xining Li, Xinjia Li, Xinjian Li, Xinke Li, Xinle Li, Xinli Li, Xinlin Li, Xinmei Li, Xinmiao Li, Xinmin Li, Xinming Li, Xinpeng Li, Xinping Li, Xinrong Li, Xinrui Li, Xinsheng Li, Xinwei Li, Xinxin Li, Xinxiu Li, Xinyan Li, Xinyang Li, Xinyao Li, Xinye Li, Xinyi Li, Xinyu Li, Xinyuan Li, Xinzhi Li, Xinzhong Li, Xiong Bing Li, Xiong Li, Xiongfeng Li, Xionghao Li, Xionghui Li, Xiu-Ling Li, Xiucui Li, Xiufeng Li, Xiujuan Li, Xiuli Li, Xiuling Li, Xiumei Li, Xiuqi Li, Xiurong Li, Xiushen Li, Xiushi Li, Xiuzhen Li, Xixi Li, Xiying Li, Xiyue Li, Xiyun Li, Xu Li, Xu-Bo Li, Xu-Wei Li, Xu-Zhao Li, Xuan Li, Xuan-Ling Li, Xuanfei Li, Xuanxuan Li, Xuanzheng Li, Xudong Li, Xue Cheng Li, Xue Li, Xue-Er Li, Xue-Fei Li, Xue-Hua Li, Xue-Lian Li, Xue-Min Li, Xue-Nan Li, Xue-Peng Li, Xue-Yan Li, Xue-Ying Li, Xue-jing Li, Xue-zhi Li, Xuebiao Li, Xueer Li, Xuefei Li, Xuefeng Li, Xuehua Li, Xuejun Li, Xuekun Li, Xuelian Li, Xuelin Li, Xueling Li, Xuemei Li, Xuemin Li, Xuening Li, Xuepeng Li, Xueqin Li, Xueren Li, Xueshan Li, Xuesong Li, Xueting Li, Xuewang Li, Xuewei Li, Xuewen Li, Xueyang Li, Xueyi Li, Xueying Li, Xuezhong Li, Xuhang Li, Xuhong Li, Xuhua Li, Xujun Li, Xun Li, Xunjia Li, Xuri Li, Xutong Li, Xuyi Li, Xuze Li, Y H Li, Y L Li, Y Li, Y M Li, Y X Li, Y-Y Li, Ya Li, Ya-Feng Li, Ya-Ge Li, Ya-Jun Li, Ya-Li Li, Ya-Pei Li, Ya-Qiang Li, Ya-Ting Li, Ya-Zhou Li, YaJie Li, Yadong Li, Yahui Li, Yajiao Li, Yajing Li, Yajuan Li, Yajun Li, Yakui Li, Yalan Li, Yali Li, Yalin Li, Yan Bing Li, Yan Li, Yan Ning Li, Yan-Chun Li, Yan-Guang Li, Yan-Hong Li, Yan-Hua Li, Yan-Li Li, Yan-Nan Li, Yan-Xue Li, Yan-Yan Li, Yan-Yu Li, Yanan Li, Yanbin Li, Yanbing Li, Yanbo Li, Yanchang Li, Yanchuan Li, Yanchun Li, Yandong Li, Yanfeng Li, Yang Li, Yangxue Li, Yangyang Li, Yanhui Li, Yani Li, Yanjiao Li, Yanjie Li, Yanjing Li, Yanjun Li, Yanli Li, Yanlin Li, Yanling Li, Yanlong Li, Yanmei Li, Yanmin Li, Yanming Li, Yanni Li, Yanping Li, Yanqing Li, Yansen Li, Yanshu Li, Yansong Li, Yantao Li, Yanwei Li, Yanwu Li, Yanxi Li, Yanxiang Li, Yanxin Li, Yanyan Li, Yanying Li, Yanze Li, Yanzhong Li, Yao Li, Yaobo Li, Yaochen Li, Yaodong Li, Yaofu Li, Yaojia Li, Yaokun Li, Yaoqi Li, Yaoyao Li, Yaqi Li, Yaqiang Li, Yaqiao Li, Yaqin Li, Yaqing Li, Yaqiong Li, Yarong Li, Yawei Li, Yaxi Li, Yaxian Li, Yaxiong Li, Yaxuan Li, Yaying Li, Yayu Li, Yazhou Li, Ye Li, Yehong Li, Yeshan Li, Yetian Li, Yi Li, Yi-Heng Li, Yi-Ling Li, Yi-Ning Li, Yi-Shuan J Li, Yi-Ting Li, Yi-Wen Li, Yi-Yang Li, Yi-Ying Li, Yi-Yun Li, YiPing Li, YiQing Li, Yibo Li, Yiche Li, Yicun Li, Yifan Li, Yifei Li, Yifeng Li, Yige Li, Yihan Li, Yihao Li, Yiheng Li, Yihong Li, Yijian Li, Yijie Li, Yijing Li, Yiju Li, Yikang Li, Yike Li, Yilang Li, Yiliang Li, Yilong Li, Yimei Li, Yimeng Li, Yiming Li, Yin Li, Yinan Li, Ying Li, Ying-Bo Li, Ying-Lan Li, Ying-Qin Li, Ying-Qing Li, Ying-na Li, Yinggao Li, Yinghao Li, Yinghua Li, Yinghui Li, Yingjian Li, Yingjie Li, Yingjun Li, Yinglin Li, Yingnan Li, Yingpu Li, Yingqin Li, Yingrui Li, Yingshuo Li, Yingxi Li, Yingxia Li, Yingyi Li, Yingying Li, Yinhao Li, Yining Li, Yinliang Li, Yinxiong Li, Yinyan Li, Yinzhen Li, Yipeng Li, Yiqiang Li, Yirun Li, Yitong Li, Yiwei Li, Yiwen Li, Yixi Li, Yixiang Li, Yixiao Li, Yixin Li, Yixing Li, Yixuan Li, Yixue Li, Yiyang Li, Yizhe Li, Yong Li, Yong-Jian Li, Yong-Jun Li, Yong-Liang Li, Yongchao Li, Yonghao Li, Yonghe Li, Yongjia Li, Yongjiang Li, Yongjin Li, Yongjing Li, Yongjun Li, Yongkai Li, Yongle Li, Yongli Li, Yongmei Li, Yongnan Li, Yongpeng Li, Yongping Li, Yongqi Li, Yongqiang Li, Yongqiu Li, Yongsen Li, Yongsheng Li, Yongting Li, Yongxiang Li, Yongxin Li, Yongxue Li, Yongze Li, Yongzhe Li, Yongzhen Li, Yongzheng Li, You Li, You Ran Li, You-Mei Li, Youchen Li, Youjun Li, Youming Li, Youran Li, Yousheng Li, Youwei Li, Yu Li, Yu-Cheng Li, Yu-Chia Li, Yu-Hang Li, Yu-Hao Li, Yu-He Li, Yu-Hui Li, Yu-I Li, Yu-Jin Li, Yu-Jui Li, Yu-Kun Li, Yu-Lin Li, Yu-Sheng Li, Yu-Xiang Li, Yu-Ye Li, Yu-Ying Li, Yu-quan Li, Yuan Hao Li, Yuan Li, Yuan-Hai Li, Yuan-Jing Li, Yuan-Tao Li, Yuan-Yuan Li, Yuan-hao Li, Yuanchang Li, Yuanchuang Li, Yuancong Li, Yuandong Li, Yuanfang Li, Yuanfei Li, Yuanhao Li, Yuanhe Li, Yuanheng Li, Yuanhong Li, Yuanhua Li, Yuanjing Li, Yuanmei Li, Yuanyou Li, Yuanyuan Li, Yuanze Li, Yubin Li, Yubo Li, Yuchan Li, Yuchao Li, Yucheng Li, Yuchuan Li, Yuchun Li, Yudong Li, Yue Li, Yue-Chun Li, Yue-Jia Li, Yue-Ming Li, Yue-Rui Li, Yue-Ting Li, Yue-Ying Li, YueQiang Li, Yuefei Li, Yuefeng Li, Yueguo Li, Yuehua Li, Yuemei Li, Yueping Li, Yueqi Li, Yueting Li, Yuezheng Li, Yufan Li, Yufen Li, Yufeng Li, Yuguang Li, Yuhan Li, Yuhang Li, Yuhong Li, Yuhua Li, Yuhuang Li, Yuhui Li, Yujie Li, Yujun Li, Yukun Li, Yuli Li, Yulin Li, Yuling Li, Yulong Li, Yumao Li, Yumei Li, Yumiao Li, Yumin Li, Yun Li, Yun-Da Li, Yun-Lin Li, Yun-Peng Li, Yun-tian Li, Yuna Li, Yunan Li, Yunchu Li, Yunfeng Li, Yunjiu Li, Yunlong Li, Yunlun Li, Yunman Li, Yunmin Li, Yunpeng Li, Yunqi Li, Yunrui Li, Yunshen Li, Yunsheng Li, Yunting Li, Yunxi Li, Yunxiao Li, Yunxu Li, Yunyun Li, Yunze Li, Yuping Li, Yuqi Li, Yuqian Li, Yuqing Li, Yuqiu Li, Yuquan Li, Yushan Li, Yutang Li, Yutian 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articles

Exploring the Effect of Genetic Testing on Personalised Treatment Plans for Depression.

Shichao Li, Liang Peng, Yuting Wang · 2026 · Actas espanolas de psiquiatria · added 2026-04-24
As a result of individual genetic variations, some patients show no response to initial antidepressant medications. This study aims to investigate the association between specific genetic polymorphism Show more
As a result of individual genetic variations, some patients show no response to initial antidepressant medications. This study aims to investigate the association between specific genetic polymorphisms and the efficacy of antidepressant drugs and to improve the accuracy and effectiveness of treatment under the guidance of genetic testing. A retrospective screening was conducted on medical records from, Suixian People's Hospital between January 2022 and December 2024. A total 202 patients with depression carrying the CYP2C19 gene were selected after the application of exclusion criteria. They were assigned to three groups in accordance with their genetic metabolism types: the rapid metabolism group (Group A, n = 65), the intermediate metabolism group (Group B, n = 94) and the poor metabolism group (Group C, n = 43). All three groups were treated with sertraline for a six-week treatment cycle. The observation indicators included scores on the Hamilton Depression Scale (HAMD); onset time of drug effect; rates of response and remission; scores on the Clinical Global Impression-Improvement (CGI-I) scale; levels of the neurotransmitter factors 5-hydroxytryptamine (5-HT), γ-aminobutyric acid (GABA) and brain-derived neurotrophic factor (BDNF); incidence of adverse events; and scores on the Morisky Medication Adherence Scale-8 (MMAS-8). The baseline data of the three groups of patients were comparable before medication (p > 0.05). Compared with those in Groups A and B, patients in Group C showed a significantly greater reduction in HAMD scores (all p < 0.05), along with higher response rates (all p < 0.05) and remission rates (all p < 0.05). Amongst the three groups, Group C had a shorter onset time of drug effect (all p < 0.05); more significant improvement in CGI-I scores (all p < 0.05); and more prominent upregulation of neurotransmitter factors, namely, 5-HT (all p < 0.05), GABA (all p < 0.05) and BDNF (all p < 0.05). Regarding the incidence of adverse events, Group C had the highest rate, whereas Group A had the lowest (10.8% vs. 24.5% vs. 41.9%). Compared with other groups, Group B exhibited a more significant increase in MMAS-8 scores (all p < 0.05). Metabolic phenotype exerts substantial effects on the therapeutic outcome of sertraline in patients with depression carrying the CYP2C19 gene. Amongst groups, Group C showed better therapeutic efficacy but an elevated incidence of adverse events and lower medication adherence; Group A had relatively poor efficacy; and Group B demonstrated superior adherence. In clinical practice, individualised treatment can be implemented on the basis of CYP2C19 metabolic typing to improve therapeutic efficacy and reduce adverse events and medical burden. Show less
📄 PDF DOI: 10.62641/aep.v54i1.2098
BDNF

Therapeutic Effect of Human Umbilical Cord Mesenchymal Stromal Cells Loaded With miR-9-5p on Hypoxic-Ischemic Brain Damage in Neonatal Rats.

Bin Li, Yang Hu, Lan Wang +5 more · 2026 · Brain and behavior · Wiley · added 2026-04-24
To investigate the therapeutic mechanisms of miR-9-5p-overexpressing human umbilical cord mesenchymal stromal cells (hUC-MSCs) in neonatal rat models of hypoxic-ischemic brain damage (HIBD). Fresh neo Show more
To investigate the therapeutic mechanisms of miR-9-5p-overexpressing human umbilical cord mesenchymal stromal cells (hUC-MSCs) in neonatal rat models of hypoxic-ischemic brain damage (HIBD). Fresh neonatal umbilical cords were collected to isolate and culture human umbilical cord mesenchymal stromal cells (hUC-MSCs). Recombinant adenovirus was used to amplify miR-9-5p and transduce hUC-MSCs, generating miR-9-5p-overexpressing cells. Functional assessments included: ELISA to evaluate secretory function (e.g., neurotrophic and anti-inflammatory factors), real-time cell analysis to measure proliferation capacity, Transwell and Dunn chamber assays to assess chemotactic migration ability. Healthy 7-day-old Sprague-Dawley (SD) rats of both sexes were randomly allocated into four groups (n = 12/group, with 4 rats per group assigned to TTC staining, Western blot, or Morris water maze assay, respectively): Sham-operated control group (mock surgery), Hypoxic-ischemic brain damage (HIBD) model group, miR-9-5p-hUC-MSCs treatment group, and Adenovirus-transduced hUC-MSCs (Ad-hUC-MSCs) treatment group. The HIBD model was induced in groups 2-4. At 24 h post-modeling, 1×10 Spindle-shaped and polygonal adherent cells emerged within 3-5 days following umbilical cord tissue block inoculation, with flow cytometric analysis confirming their identity as mesenchymal stromal cells (MSCs). Compared to the Ad-hUC-MSCs treatment group, miR-9-5p enhanced the secretion of neuroreparative and anti-inflammatory factors (e.g., NGF, BDNF, IL-6) in hUC-MSCs while suppressing pro-inflammatory cytokines (e.g., IL-1, IL-2) (p < 0.05). Furthermore, miR-9-5p significantly promoted hUC-MSCs proliferation and augmented the chemotactic migratory capacity of miR-9-5p-hUC-MSCs. At 48 h post-transplantation in the miR-9-5p-hUC-MSCs group, the sham-operated controls showed no detectable cerebral infarction, whereas the model group exhibited distinct pale infarct foci occupying 33.15% ± 4.38% of total brain volume (vs. controls, p < 0.05), indicating severe cerebral injury. Both miR-9-5p-hUC-MSCs and Ad-hUC-MSCs treatments markedly reduced infarct volumes to 14.85% ± 2.79% and 19.11% ± 4.57%, respectively, with the miR-9-5p-hUC-MSCs group demonstrating a statistically superior therapeutic effect compared to Ad-hUC-MSCs (p < 0.05). Transplantation of either Ad-hUC-MSCs or miR-9-5p-hUC-MSCs significantly improved short- and long-term neurobehavioral outcomes in hypoxic-ischemic brain damage (HIBD) rats. At 48 h post-HIBD induction, upregulated expression of Beclin-2 and Caspase-3 proteins was observed in brain tissue. Notably, these elevated protein levels were attenuated following treatment with miR-9-5p-hUC-MSCs or Ad-hUC-MSCs. MiR-9-5p enhances the secretion of immunomodulatory factors and improves the migratory and proliferative capacities of hUC-MSCs. Overexpression of miR-9-5p promotes in vivo homing of hUC-MSCs, which mitigate cerebral injury and exert neuroprotective and reparative effects through dual mechanisms: modulating immune responses and providing neurotrophic support. Furthermore, hUC-MSCs significantly reduce cerebral infarct volume in hypoxic-ischemic brain damage (HIBD) rats and downregulate levels of apoptotic proteins (Beclin-2 and Caspase-3) in brain tissue, demonstrating potent cerebroprotective effects. Show less
📄 PDF DOI: 10.1002/brb3.71282
BDNF

The timing of arterial thrombectomy on neurological recovery in patients with acute ischemic stroke: A retrospective observational study.

Guiguo Yan, Weihai Li, Baihai Guo +5 more · 2026 · Medicine · added 2026-04-24
Arterial thrombectomy (AT) is a cornerstone in the treatment of acute ischemic stroke (AIS) due to large vessel occlusion. However, the optimal therapeutic time window and the best management strategy Show more
Arterial thrombectomy (AT) is a cornerstone in the treatment of acute ischemic stroke (AIS) due to large vessel occlusion. However, the optimal therapeutic time window and the best management strategy for patients presenting beyond the conventional 4.5-hour timeframe remain areas of active investigation and debate. This retrospective cohort study aimed to analyze the effect of timing of AT on recovery in AIS. We retrospectively analyzed 117 AIS patients admitted between January 2021 and January 2023. Participants were categorized into 3 groups: early AT (onset-to-AT < 4.5 hours), late AT (onset-to-AT ≥ 4.5 hours), and late AT + intravenous thrombolysis (IT). Outcomes compared included clinical efficacy, National Institutes of Health Stroke Scale (NIHSS) scores, serum levels of neurotrophic factors, brain-derived neurotrophic factor, vascular endothelial growth factor, residual stenosis, vessel reocclusion, 3-month mortality, and 1-month complications. The total effective rate was higher in the early AT and late AT + IT groups than in the late AT group. Pretreatment NIHSS scores and serum neurological marker levels were comparable across all groups. After treatment, the early AT and late AT + IT groups showed significantly lower NIHSS scores, higher serum levels of neurological markers, and improved treatment efficiency compared to the late AT group. Prognosis-related markers also indicated better outcomes in these 2 groups. Additionally, complications such as mucocutaneous ecchymosis, gastrointestinal bleeding, and intracranial bleeding were significantly reduced in the early AT and late AT + IT groups. AT within 4.5 hours of stroke onset improves efficacy, reduces neurological injury, and decreases complications. For patients presenting beyond 4.5 hours, combining AT with IT achieves comparable therapeutic benefits. Show less
📄 PDF DOI: 10.1097/MD.0000000000047634
BDNF

Stem Cell-Derived Exosomes Improve Neurological Dysfunction in a Rat Model of Moderate-to-Severe Cerebral Palsy.

Tingting Peng, Huijuan Lin, Xiaoli Zeng +16 more · 2026 · Stem cell reviews and reports · Springer · added 2026-04-24
Cerebral palsy (CP), the most prevalent pediatric motor disorder with significant cognitive comorbidity (> 50%), lacks therapies addressing both impairments in moderate-to-severe cases. This study dem Show more
Cerebral palsy (CP), the most prevalent pediatric motor disorder with significant cognitive comorbidity (> 50%), lacks therapies addressing both impairments in moderate-to-severe cases. This study demonstrates that human umbilical cord mesenchymal stem cell-derived exosomes (hUCMSC-Exos) exert profound therapeutic effects in a rat model of moderate-to-severe CP established via bilateral carotid artery occlusion with hypoxia. Intravenously administered hUCMSC-Exos displayed sustained brain retention and significantly restored motor coordination and cognitive function. The recovery was primarily mediated through enhanced remyelination driven by promoted oligodendrocyte maturation and differentiation (elevated oligodendrocyte lineage transcription factor 2 and myelin basic protein). Concurrently, the treatment attenuated key pathological processes involving sustained neuroinflammatory responses (reduced ionized calcium-binding adapter molecule 1, tumor necrosis factor-α, and interleukin-6) while elevating brain-derived neurotrophic factor. Our findings establish hUCMSC-Exos as a promising dual-modality therapy for moderate-to-severe CP, mechanistically linked to robust remyelination and coordinated modulation of core disease mechanisms. Show less
no PDF DOI: 10.1007/s12015-026-11072-1
BDNF cerebral palsy exosomes mesenchymal stem cells neurological disorders neuroscience pediatric motor disorder stem cells

4-MEC potentially triggers CAV1 via the BDNF-TrkB signaling pathway.

Wangping Zhang, Fangqi Cao, Ming Li +4 more · 2026 · Molecular and cellular neurosciences · Elsevier · added 2026-04-24
4-Methylethcathinone (4-MEC), a synthetic cathinone with psychostimulant properties, is increasingly abused as a "designer drug". However, its molecular mechanisms, particularly those related to neuro Show more
4-Methylethcathinone (4-MEC), a synthetic cathinone with psychostimulant properties, is increasingly abused as a "designer drug". However, its molecular mechanisms, particularly those related to neuroplasticity regulation, remain poorly understood. Caveolin-1 (CAV1) is a scaffolding protein of membrane lipid rafts and has been confirmed to organize multiple synaptic signaling proteins to regulate synaptic signaling and neuroplasticity. Herein, we investigated whether CAV1 modulates 4-MEC-induced alterations in the BDNF-TrkB signal pathway and neuroplasticity markers in human SH-SY5Y neuroblastoma cells and a mouse-conditioned place preference (CPP) model. Using qRT-PCR and Western blotting, we demonstrated that 4-MEC significantly upregulated CAV1 mRNA and protein levels, as well as components of the BDNF-TrkB signaling pathway and neuroplasticity markers (GAP43, MAP2, SYP). siRNA-mediated CAV1 knockdown abolished 4-MEC-induced increases in these proteins and neuroplasticity-related mRNAs, whereas CAV1 overexpression potentiated these effects. Additionally, molecular docking predicted potential binding sites between 4-MEC and CAV1. Meanwhile, protein docking also predicted the potential binding sites between CAV1 and TrkB, and co-immunoprecipitation confirmed their physical interactions in SH-SY5Y cells. In the mice exposed to 4-MEC in the CPP paradigm, we observed similar upregulation of CAV1, BDNF-TrkB signaling pathway components, and neuroplasticity markers in the brain. These findings identify CAV1 as a potential critical mediator of 4-MEC's neuroadaptive effects through the BDNF-TrkB signal pathway to regulate neuroplasticity. It suggests a possible novel molecular target for synthetic cathinone toxicity, with potential implications for forensic research. Show less
no PDF DOI: 10.1016/j.mcn.2026.104074
BDNF bdnf cav1 lipid rafts neuroplasticity psychostimulant signaling pathway synaptic signaling

Effect of pterostilbene on cognitive function, and histone deacetylase and BDNF/CREB pathway following ischemia reperfusion injury in mice.

Shilai Tian, Yingxia Li, Junlin Kang +3 more · 2026 · Behavioural brain research · Elsevier · added 2026-04-24
To investigate the effect of pterostilbene (PTE), a natural dimethyl ether analog of resveratrol with higher bioavailability, on cognitive recovery after cerebral ischemia reperfusion (IR) injury and Show more
To investigate the effect of pterostilbene (PTE), a natural dimethyl ether analog of resveratrol with higher bioavailability, on cognitive recovery after cerebral ischemia reperfusion (IR) injury and its potential mechanisms. Mice were subjected to middle cerebral artery occlusion and assigned to Sham, IR, PTE+IR, and PTE+Zinc Protoporphyrin (ZnPP)+IR groups. Cognitive function was assessed using the Morris water maze. Cerebral infarct volume was evaluated by 2,3,5-triphenyltetrazolium chloride (TTC) staining, and neuronal apoptosis was determined via TUNEL assay. The protein levels of postsynaptic density protein 95 (PSD-95), phosphorylated cAMP response element-binding protein (p-CREB), brain-derived neurotrophic factor (BDNF), and histone deacetylases (HDACs) in the hippocampus were measured by western blot. PTE treatment significantly reduced cerebral infarct volume, alleviated cognitive deficits, and inhibited neuronal apoptosis in the hippocampus. At the molecular level, PTE up-regulated the expression of PSD-95, p-CREB, and BDNF, while down-regulating HDAC (1, 2, 3, 4, 7) levels. The beneficial effects of PTE were partially reversed by the HO-1 inhibitor ZnPP. PTE ameliorates cognitive impairment induced by cerebral IR injury, potentially through activating the BDNF/CREB pathway and inhibiting HDAC expression. This suggests PTE as a promising neuroprotective agent for post-stroke cognitive recovery. Show less
no PDF DOI: 10.1016/j.bbr.2026.116112
BDNF bdnf/creb pathway cerebral ischemia cognitive function histone deacetylase ischemia reperfusion injury neuroprotection resveratrol

Negative effects of microcystin-LR on larval zebrafish: Focus on visual function, behavior, and circadian rhythm regulation.

Wei Liu, Zi Wei, Zhicong Jiang +3 more · 2026 · Comparative biochemistry and physiology. Toxicology & pharmacology : CBP · Elsevier · added 2026-04-24
Microcystin-LR (MC-LR) is the most prevalent and toxic microcystin congeners, posing a significant threat to aquatic organisms as well as humans; however, its underlying toxic mechanisms remain incomp Show more
Microcystin-LR (MC-LR) is the most prevalent and toxic microcystin congeners, posing a significant threat to aquatic organisms as well as humans; however, its underlying toxic mechanisms remain incompletely elucidated. In this study, the negative impacts of MC-LR and the underlying mechanisms in zebrafish larvae were investigated. The results demonstrated that MC-LR could penetrate zebrafish larvae and induce developmental toxicity, characterized by reduced heart rate, decreased body length, and smaller eye area. H&E staining revealed that MC-LR exposure significantly reduced the thickness of retinal layers. qPCR analysis showed altered expression levels of phototransduction and retinoic acid metabolism related genes (rho, gnat1, gnat2, opn1sw1, opn1lw1, opn1mw1, rdh1, rbp4, cyp26a1, and aldh1a2). These findings suggest that MC-LR may disrupt retinal structure and impair normal visual function in larvae. Behavioral analyses indicated that MC-LR exposure weakened spontaneous movements in embryos and impaired swimming ability in larvae, potentially due to significant alterations in the levels of glutamate, γ-aminobutyric acid, and brain-derived neurotrophic factor. Additionally, MC-LR exposure reduced visuomotor responses, delayed reactions to external stimuli, and disrupted circadian rhythms, which may be attributed to altered expression levels of circadian rhythm-related genes (clock1a, bmal1a, per1b, cry1a, and per2), as well as changes in melatonin and arylalkylamine N-acetyltransferase 2 levels. Overall, these findings indicate that MC-LR exposure induces developmental neurotoxicity in zebrafish, and that impaired visual function and disrupted circadian rhythm may serve as key contributing factors to MC-LR-induced behavioral abnormalities, which warrant further emphasis in future ecological and health risk assessments. Show less
no PDF DOI: 10.1016/j.cbpc.2026.110488
BDNF aquatic organisms behavior circadian rhythm developmental toxicity microcystin toxicity visual function

BDNF Val66Met protects oxaliplatin-induced peripheral neuropathy in patients with colorectal cancer.

Li-Hsien Chen, Peng-Chan Lin, Yu-Min Yeh +4 more · 2026 · Science translational medicine · Science · added 2026-04-24
Chemotherapy-induced peripheral neuropathy (CIPN) remains a major unmet challenge in oncology, affecting treatment adherence and patient quality of life. Despite its prevalence, reliable predictive bi Show more
Chemotherapy-induced peripheral neuropathy (CIPN) remains a major unmet challenge in oncology, affecting treatment adherence and patient quality of life. Despite its prevalence, reliable predictive biomarkers and targeted neuroprotective strategies remain elusive. This study integrates clinical data, whole-genome sequencing, and translational research to identify genetic determinants of CIPN susceptibility and validate therapeutic approaches. Through comprehensive analysis of patients with colorectal cancer, including neurophysiological evaluations and CIPN-specific quality-of-life assessments, we identified the Show less
no PDF DOI: 10.1126/scitranslmed.adx1436
BDNF bdnf chemotherapy colorectal cancer genetics neuroprotection oncology oxaliplatin

Mitochondrial fusion targeted supramolecular peptide hydrogel for gut neuroprotection.

Wei Sun, Lu Han, Yanyu Bi +6 more · 2026 · Biomaterials · Elsevier · added 2026-04-24
Oxidative stress-induced enteric neuropathy is a key driver of slow-transit constipation (STC), primarily through disrupted mitochondrial dynamics and neuronal degeneration. To address this, we develo Show more
Oxidative stress-induced enteric neuropathy is a key driver of slow-transit constipation (STC), primarily through disrupted mitochondrial dynamics and neuronal degeneration. To address this, we developed a bioengineered oral delivery system that supports neuronal recovery and actively enhances mitochondrial membrane fusion. A self-assembling amphiphilic peptide (GFF) was synthesized to encapsulate rhein (RH), a natural anthraquinone with antioxidant, anti-inflammatory, and microbiota-regulating properties. A BDNF-derived tetrapeptide was integrated to further potentiate neurotrophic effects. These components were co-assembled into a therapeutic nanofiber (RFI), which was embedded in a chitosan/sodium alginate hydrogel for sustained oral delivery. In vitro and in vivo studies demonstrated that RFI significantly improved neuronal viability and gastrointestinal motility. Mechanistic investigations revealed that RFI is associated with activation of the AKT signaling pathway and enhancement of mitochondrial membrane fusion, collectively contributing to the restoration of mitochondrial network integrity and neuronal protection. This multifunctional nanoplatform offers a promising therapeutic approach to STC by combining targeted delivery with direct modulation of mitochondrial function. Show less
no PDF DOI: 10.1016/j.biomaterials.2026.124061
BDNF bioengineered delivery system gut health mitochondrial dynamics mitochondrial fusion neuronal degeneration neuroprotection oxidative stress

S-nitrosylation of Dexras1 attenuates fear memory generalization in the infralimbic cortex.

Cheng Qin, Ke Chen, Yu-Yang Chen +3 more · 2026 · Brain research · Elsevier · added 2026-04-24
Fear memory generalization is a fundamental hallmark of post-traumatic stress disorder (PTSD) that enables animals to use past experience to adapt to changing conditions. The infralimbic cortex (IL) i Show more
Fear memory generalization is a fundamental hallmark of post-traumatic stress disorder (PTSD) that enables animals to use past experience to adapt to changing conditions. The infralimbic cortex (IL) is implicated in suppressing generalized fear, but the underlying molecular mechanisms remain unknown. Here, we demonstrate that S-nitrosylation of Dexras1 (SNO-Dexras1) in the IL drives fear generalization. Dexras1 is activated by nitric oxide (NO) donors as well as by N-methyl-D-aspartic acid (NMDA) receptor-stimulated NO synthesis in cortical neurons. It is found that the level of SNO-Dexras1 is significantly increased in the IL of generalized mice and downregulation of SNO-Dexras1 attenuates fear generalization. Mechanistically, inhibition of SNO-Dexras1 increases the expression of phosphorylated extracellular regulated protein kinases (pERK) and brain derived neurotrophic factor (BDNF), implicating synaptic remodeling in the IL. Our study reveals a key role of SNO-Dexras1 in the fear generalization, which may provide a potential therapeutic strategy for PTSD. Show less
no PDF DOI: 10.1016/j.brainres.2026.150209
BDNF dexras1 fear memory infralimbic cortex nitric oxide nmda post-traumatic stress disorder s-nitrosylation

Formononetin attenuates corticosterone-induced depressive-like behaviors and neuronal damage via ERα/ERK-CREB-BDNF signaling pathway.

Baoying Wang, Hui Liu, Changjing Zhang +4 more · 2026 · The Journal of pharmacy and pharmacology · Oxford University Press · added 2026-04-24
Formononetin (FMN) is known for its significant neuroprotective effects, this study aims to investigate the antidepressant potential and underlying mechanisms of FMN. Antidepressant efficacy was evalu Show more
Formononetin (FMN) is known for its significant neuroprotective effects, this study aims to investigate the antidepressant potential and underlying mechanisms of FMN. Antidepressant efficacy was evaluated in corticosterone (CORT)-induced depression models. In vivo, CORT-exposed mice received FMN to assess behavioral and hippocampal changes (dendritic spine density, synaptic markers: MAP-2/GAP-43). In silico, network pharmacology and molecular docking predicted FMN's binding affinity and enriched pathways. In vitro, HT22 cells pretreated with FMN (10 μM, 6 h) were subjected to CORT injury, with mechanistic validation via ERα antagonist (MPP) and ERK inhibitor (PD98059). FMN alleviated depressive-like behaviors and preserved hippocampal integrity in mice. Bioinformatics analysis revealed FMN's strong binding to ER subtypes and enrichment in estrogen/MAPK pathways. In vitro, FMN pretreatment activated the ERK-CREB-BDNF axis in CORT-injured HT22 cells, enhancing neuronal survival and synaptic function. The activation was ERα/ERK-dependent, as evidenced by the abolition of protective effects following pharmacological inhibition with MPP (ERα antagonist) or PD98059 (ERK inhibitor). Concomitantly, in vivo FMN treatment restored hippocampal p-ERK/ERK ratios in mice, directly corroborating the ERK-CREB-BDNF pathway activation and highlighting its efficacy in reversing CORT-induced signaling deficits. FMN exerts antidepressant effects via ERα-mediated neurotrophic signaling (ERK-CREB-BDNF), offering a mechanistic foundation for natural antidepressant development. Show less
no PDF DOI: 10.1093/jpp/rgag010
BDNF antidepressant corticosterone creb depression erk neural damage neuroprotection

Microbiota-driven therapeutic efficacy of Hyperoside in ulcerative colitis and associated anxiety.

Li Yin, Lin Xu, Yu-Nan Shan +3 more · 2026 · Frontiers in cellular and infection microbiology · Frontiers · added 2026-04-24
Ulcerative colitis (UC) is subtype of inflammatory bowel disease that is frequently comorbid with anxiety disorders. However, effective dual-targeting therapies are still lacking. Hyperoside (HYP), a Show more
Ulcerative colitis (UC) is subtype of inflammatory bowel disease that is frequently comorbid with anxiety disorders. However, effective dual-targeting therapies are still lacking. Hyperoside (HYP), a natural flavonoid, exhibits anti-inflammatory and neuroprotective properties, yet its potential therapeutic effects on UC and associated anxiety, as well as the underlying mechanisms, remain largely unexplored. A murine model of DSS-induced colitis was established and treated with HYP. Disease activity was assessed through body weight, colon length, and histopathology. Anxiety-like behaviors were evaluated using open field and elevated plus maze tests. Neuroinflammation was examined through immunohistochemistry of BDNF expression and microglial activation. Gut microbiota composition was profiled by metagenomic sequencing, and metabolomic profiling was conducted using the Q300 Kit. Network pharmacology and molecular docking were employed to predict signaling pathways, which were further validated by Western blotting. Additionally, antibiotic depletion experiments were conducted to determine microbiota dependency. HYP administration significantly ameliorated DSS-induced colitis, as evidenced by attenuated weight loss, restored colon length, and improved histopathology. It suppressed pro-inflammatory cytokines (TNF-α, IL-6, IL-1β) and restored intestinal barrier integrity by upregulating Mucin-2 and ZO-1. Furthermore, HYP also alleviated anxiety-like behaviors and mitigated neuroinflammation by increasing BDNF levels and suppressing microglial activation. HYP treatment also restored gut microbial homeostasis, enriching beneficial bacteria such as Our findings demonstrate that HYP effectively alleviates DSS-induced colitis and comorbid anxiety-like behaviors. Its efficacy is dependent on the gut microbiota and is associated with the restoration of microbial homeostasis, enhancement of arginine metabolism, and modulation of the MAPK/PI3K-Akt/NF-κB signaling pathways. HYP represents a promising microbiota-targeting therapeutic candidate for UC and its neuropsychiatric comorbidities. Show less
📄 PDF DOI: 10.3389/fcimb.2026.1734356
BDNF

T7 peptide-engineered liposomal Irisin mitigates PND progression through AMPK/PGC-1α signaling: multi-omic evidence of metabolic and epigenetic modulation.

Huisheng Wu, Wenlong Dai, Jun Cheng +4 more · 2026 · Journal of nanobiotechnology · BioMed Central · added 2026-04-24
This study explored the molecular mechanisms by which T7 peptide-modified liposomal irisin (T7@Lipo@Irisin) alleviates perioperative neurocognitive disorders (PND) via regulation of the AMPK/PGC-1α me Show more
This study explored the molecular mechanisms by which T7 peptide-modified liposomal irisin (T7@Lipo@Irisin) alleviates perioperative neurocognitive disorders (PND) via regulation of the AMPK/PGC-1α metabolic pathway. T7@Lipo@Irisin nanoparticles were prepared by thin-film hydration and ultrasonic dispersion and showed favorable physicochemical performance, with an encapsulation efficiency of approximately 85%. Serum analysis of healthy donors (n = 10) and PND patients (n = 6) showed higher IL-6 and TNF-α and lower brain-derived neurotrophic factor (BDNF) in PND. In vitro, T7@Lipo@Irisin restored mitochondrial membrane potential, reduced reactive oxygen species (ROS) accumulation, enhanced Neuro-2a hippocampal neuron viability, and activated the AMPK/PGC-1α axis under oxidative stress. In a PND mouse model, it improved Garcia neurological scores, preserved neuronal morphology, and decreased apoptosis. Multi-omic integration of scATAC-seq/scRNA-seq and TMT-based proteomics demonstrated enhanced neuro-glial crosstalk, epigenetic activation of metabolic/antioxidant genes (e.g., Sirt1, Nfe2l2), and upregulated pathways (mitochondrial function, NAD-dependent metabolism, synaptic homeostasis). Proteomics confirmed upregulation of SIRT1, NDUFS2, and BDNF, forming a network linked to energy metabolism and neural repair. Collectively, T7@Lipo@Irisin mitigates PND by activating AMPK/PGC-1α to enhance mitochondrial function and stabilize the neuro-microenvironment. Show less
📄 PDF DOI: 10.1186/s12951-026-04109-7
BDNF

Short-duration electrical pulse stimulation induces myokines and mitochondrial adaptations in C2C12 myotubes.

Shih-Hua Fang, Ming-Ru Chiang, Chia-Yang Li +3 more · 2026 · Journal of muscle research and cell motility · Springer · added 2026-04-24
📄 PDF DOI: 10.1007/s10974-026-09722-5
BDNF

Plant-derived bioactive compounds modulate the gut microbiota in Alzheimer's disease: Metabolite signaling, neuroimmune circuits, and systems-level regulation.

Dong Xue, Xixi Hu, Ranchang Li +6 more · 2026 · Phytomedicine : international journal of phytotherapy and phytopharmacology · Elsevier · added 2026-04-24
Alzheimer's disease (AD) is increasingly recognized as a multisystem disorder shaped not only by central neurodegeneration but also by peripheral metabolic and immune dysregulation. Growing evidence h Show more
Alzheimer's disease (AD) is increasingly recognized as a multisystem disorder shaped not only by central neurodegeneration but also by peripheral metabolic and immune dysregulation. Growing evidence highlights the gut microbiota and its metabolites as key modulators of amyloid accumulation, tau phosphorylation, neuroinflammation, and microglial dysfunction. This review aims to synthesize current advances on how plant-derived bioactive compounds modulate AD pathophysiology through microbiota-dependent metabolic and neuroimmune mechanisms, and to establish a systems-level framework linking botanical interventions to gut microbiota remodeling and metabolite signaling. A comprehensive literature survey was conducted using PubMed, Web of Science, ScienceDirect, and Google Scholar, covering publications from 2010 to 2026. Studies investigating gut microbiota, microbial metabolites, and plant-derived bioactive compounds in AD-related metabolic, immune, and neurodegenerative pathways were systematically reviewed and integrated. Plant-derived bioactive compounds, including phytochemicals, polysaccharides, and multi-herb formulations, interact extensively with the gut microbiota, undergoing microbial biotransformation to yield more active metabolites while simultaneously reshaping microbial community structure and metabolite profiles. These bidirectional interactions position the microbiota as a central mediator of plant-derived therapeutic activity. We summarize current evidence on how plant-derived compounds influence AD pathophysiology through microbiota-dependent metabolic and neuroimmune pathways. Major microbial metabolites, including short-chain fatty acids (SCFAs), trimethylamine N-oxide (TMAO), bile acids (BAs), and indole derivatives, are discussed, together with their regulatory roles in signaling networks such as nuclear factor κB (NF-κB), phosphatidylinositol 3-kinase/Akt (PI3K/Akt), cAMP response element-binding protein/brain-derived neurotrophic factor (CREB/BDNF), and triggering receptor expressed on myeloid cells 2 (TREM2)-associated microglial states. We further summarize evidence for synergistic strategies combining plant bioactives with probiotics and highlight advances in microbial biotransformation, precision metabolite modulation, and engineered microbial systems. Finally, future directions integrating multi-omics, personalized microbiota-guided interventions, and synthetic biology are outlined to support the development of targeted, mechanism-based therapies. By framing AD through a gut microbiota-centered perspective, this review provides a unified mechanistic foundation for the development of next-generation interventions based on plant-derived compounds and microbiota regulation. Show less
no PDF DOI: 10.1016/j.phymed.2026.157919
BDNF alzheimer's disease bioactive compounds gut microbiota metabolite signaling microglial dysfunction neuroimmune circuits neuroinflammation

Mapping the Regulatory Landscape of Sheep Pituitary Gland Associated With Puberty at Single-Cell Resolution.

Shanglai Li, Bingru Zhao, Yu Cai +5 more · 2026 · FASEB journal : official publication of the Federation of American Societies for Experimental Biology · added 2026-04-24
The pituitary gland plays a pivotal role in regulating puberty and reproductive physiology; however, the precise cellular and molecular mechanisms driving the pubertal transition in large animal, such Show more
The pituitary gland plays a pivotal role in regulating puberty and reproductive physiology; however, the precise cellular and molecular mechanisms driving the pubertal transition in large animal, such as ewes, remain poorly understood. Here, we generated a comprehensive single-cell transcriptomic atlas of the ovine anterior pituitary, specifically comparing the pre-pubertal (3 month) and post-pubertal (6 month) stages. We identified 30 335 cells classified into ten distinct clusters. Comparative analysis revealed a global transcriptional reprogramming during puberty, characterized by a marked upregulation of genes associated with ribosome biogenesis, unfolded protein response, and hormone secretion across endocrine cells, reflecting an expanded biosynthetic capacity. Specifically, we identified SCG2 as a critical regulator of gonadotroph maturation. Functional validation demonstrated that SCG2 facilitates the biogenesis of secretory granules, thereby promoting FSH synthesis and secretion. Furthermore, intercellular communication analysis uncovered a distinct shift in the pituitary microenvironment: the 6 month pituitary exhibited enhanced regulatory networks, including IGF signaling mediated by non-endocrine cells and NT signaling (e.g., BDNF-NTRK2) driven by multiple cell types. These findings suggest that the onset of puberty relies on a coordinated "endocrine-to-endocrine" and "non-endocrine-to-endocrine" crosstalk. This study provides a high-resolution molecular blueprint of the pubertal transition, highlighting the key roles of biosynthetic machinery upgrades and microenvironmental remodeling in establishing the high reproductive performance of Hu sheep. Show less
no PDF DOI: 10.1096/fj.202503749RR
BDNF molecular biology ovine pituitary gland puberty regulatory mechanisms reproductive physiology single-cell transcriptomics

Tianwangbuxiandan decoction alleviates constipation and associated emotional disorders via regulating the brain-gut axis: Involving MAPK/ERK/JNK signaling pathways.

Shaoliang Li, Pengning Wu, Yue Wang +3 more · 2026 · Journal of ethnopharmacology · Elsevier · added 2026-04-24
Tianwang Buxin Dan (TWBXD) is a classical Chinese formula traditionally prescribed to "nourish Yin, calm the mind and relieve bowel stagnation" in disorders characterized by heart-kidney disharmony, i Show more
Tianwang Buxin Dan (TWBXD) is a classical Chinese formula traditionally prescribed to "nourish Yin, calm the mind and relieve bowel stagnation" in disorders characterized by heart-kidney disharmony, insomnia, anxiety, and constipation. However, the mechanistic basis associating its gut-regulating and emotion-modulating effects along the gut-brain axis remains unclear. To investigate whether TWBXD ameliorates functional constipation comorbid with emotional disturbances by modulating mitogen-activated protein kinase/Extracellular Signal-Regulated Kinase/c-Jun N-terminal Kinase (MAPK/ERK/JNK) signaling, hypothalamic-pituitary-adrenal (HPA)-axis activity, and autophagy-related mitochondrial integrity in the colon and hippocampus. A diphenoxylate-induced rat model of functional constipation with anxiety/depression-like behavior was treated with low, medium, or high doses of TWBXD. Intestinal transit, fecal parameters, and distal colonic transit were also assessed. Emotional behaviors were evaluated using open-field and elevated plus-maze tests. Colonic and hippocampal histopathology and ultrastructure were examined using hematoxylin and eosin staining, Nissl staining, and transmission electron microscopy. Serum corticotropin-releasing factor (CRF), adrenocorticotropic hormone (ACTH), and corticosterone (CORT) levels were measured using enzyme-linked immunosorbent assay. MAPK/ERK/JNK-related proteins and brain-derived neurotrophic factor (BDNF) were analyzed by Western blotting. The major chemical constituents of TWBXD were characterized using ultra-high-performance liquid chromatography-tandem mass spectrometry(UHPLC-MS/MS). TWBXD dose-dependently improved intestinal transit, fecal moisture, and body weight gain, and alleviated anxiety-/depression-like behaviors. TWBXD preserved colonic mucosal architecture and hippocampal neuronal integrity, mitigated mitochondrial swelling and excessive autophagic vacuole formation, downregulated colonic phosphorylated ERK (p-ERK), phosphorylated JNK, and phosphorylated p38, restored hippocampal BDNF expression while normalizing p-ERK levels, and reduced serum CRF, ACTH, and CORT levels. TWBXD exerts multi-target therapeutic effects on functional constipation with emotional disturbances by suppressing MAPK/ERK/JNK overactivation, normalizing HPA-axis hyperactivity, and protecting mitochondrial structure and autophagy along the gut-brain axis, providing mechanistic support for its traditional use in gut-brain-related disorders. Show less
no PDF DOI: 10.1016/j.jep.2026.121308
BDNF brain-gut axis constipation emotional disorders gut-brain axis mapk/erk/jnk signaling pathways mitogen-activated protein kinase

Bidirectional association between immune-mediated diseases and major depressive disorder: evidence from cohort, genome-wide pleiotropic, and experimental studies.

Xiaohua Chen, Huan Liu, Yurong Liu +16 more · 2026 · Molecular psychiatry · Nature · added 2026-04-24
Although immune-mediated diseases (IMDs) and major depressive disorder (MDD) commonly co-occur, the bidirectional relationship between them remains to be fully elucidated. Using data from the prospect Show more
Although immune-mediated diseases (IMDs) and major depressive disorder (MDD) commonly co-occur, the bidirectional relationship between them remains to be fully elucidated. Using data from the prospective UK Biobank cohort, we evaluated the bidirectional associations by time-varying Cox proportional hazards regression models and assessed shared genetic architecture using genome-wide association study summary statistics. Additionally, we employed collagen-induced arthritis (CIA) and chronic social defeat stress (CSDS) mouse models to investigate the relationship between rheumatoid arthritis (RA) and depression. Over 5,226,841 person-years of follow-up, 23,534 incident MDD cases were identified. The presence of any IMD was associated with higher MDD risk (hazard ratio [HR]: 1.95; 95% CI: 1.89-2.01). Conversely, 59,742 incident cases of IMD were documented. MDD was associated with increased IMD risk (HR: 1.47; 95% CI: 1.40-1.54). We observed significant global genetic correlations between IMDs and MDD (r Show less
📄 PDF DOI: 10.1038/s41380-026-03459-w
BDNF

The discovery of multiregional neurotoxicity-associated metabolic alterations induced by Aconiti Lateralis Radix Praeparata in brain of rat using LC-MS metabolomics.

Hongrui Ma, Xin Ding, Junli Liang +4 more · 2026 · Journal of ethnopharmacology · Elsevier · added 2026-04-24
Aconiti Lateralis Radix Praeparata (Fuzi in Chinese) is an herbal medicine for restoring yang from collapse. However, the multiregional neurotoxicity of Fuzi was unclear. This work was designed to dis Show more
Aconiti Lateralis Radix Praeparata (Fuzi in Chinese) is an herbal medicine for restoring yang from collapse. However, the multiregional neurotoxicity of Fuzi was unclear. This work was designed to discover the multiregional neurotoxicity-associated metabolic alterations induced by Fuzi in brain of rat. Fuzi-distributed components in cerebrospinal fluid and multiple brain regions were analyzed by using ultra-high performance liquid chromatography coupled with quadrupole-time-of-flight mass spectrometry (UHPLC-QTOF-MS). The multiregional neurotoxicity including hippocampus, striatum and cerebellum was evaluated by behavioral tests, biochemical examinations, Hematoxylin/eosin (H&E), Nissl staining, TUNEL staining, reactive oxygen species and metabolomic analyses. Both cerebrospinal fluid metabolomics and the multiregional target tissue (hippocampus, striatum and cerebellum) metabolomics of the brain, based on UHPLC-QTOF-MS, were conducted to reveal the metabolic changes associated with Fuzi neurotoxicity. 13, 11, 11 and 8 ingredients of Fuzi were distributed into the cerebrospinal fluid, hippocampus, striatum, and cerebellum, respectively. Fuzi exposure could cause motor dysfunction and anxiety-like behaviors and decrease the level of brain derived neurotrophic factor (BDNF) and increase the level of neuron specific enolase (NSE). Fuzi exposure produced oxidative stress, neuronal lesions, neuronal apoptosis and metabolic alterations, which produced the multiregional neurotoxicity in the brain. The differentially expressed metabolites associated with Fuzi exposure in the cerebrospinal fluid, hippocampus, striatum and cerebellum predominantly involved glycerophospholipid metabolism, sphingomyelin metabolism, arachidonic acid metabolism, purine metabolism, amino acid metabolism, TCA cycle and fatty acid β-oxidation. Fuzi exposure produced the multiregional neurotoxicity in the hippocampus, striatum and cerebellum of the brain. Show less
no PDF DOI: 10.1016/j.jep.2026.121316
BDNF herbal medicine lc-ms mass spectrometry metabolic alterations metabolomics neurotoxicity neurotoxicity-associated metabolic alterations

The potential of human milk oligosaccharides in ameliorating traumatic brain injury-induced cognitive impairment in mice.

Dongliang He, Renli He, Wei Duan +2 more · 2026 · Future science OA · Taylor & Francis · added 2026-04-24
To investigate the ameliorative effect and underlying mechanisms of human milk oligosaccharides (HMOs) on cognitive impairment induced by traumatic brain injury (TBI) in mice. Forty-eight C57BL/6 mice Show more
To investigate the ameliorative effect and underlying mechanisms of human milk oligosaccharides (HMOs) on cognitive impairment induced by traumatic brain injury (TBI) in mice. Forty-eight C57BL/6 mice were randomly divided into the sham-operated group, TBI group, and TBI+HMOs group. The TBI model was established via controlled cortical impact (CCI). Mice in the TBI+HMOs group received daily HMOs administration by gavage, while other groups were given normal saline. Relevant indicators were detected using behavioral tests, pathological staining, Western blot, and other methods. HMOs significantly improved cognitive function in TBI mice, inhibited hippocampal oxidative stress and the expression of proinflammatory cytokines (IL-1β, IL-6, TNF-α), alleviated intestinal barrier injury, and regulated the expression of synaptophysin, BDNF, and pro-BDNF. HMOs exert neuroprotective effects by targeting central inflammation, oxidative stress, synaptic function, and intestinal barrier integrity, providing a novel natural therapeutic candidate for TBI treatment. Show less
📄 PDF DOI: 10.1080/20565623.2026.2622241
BDNF

Blood-based biomarkers and early diagnosis of Alzheimer's disease.

Zhikang Cui, Guixia Li, Shuyong Wei +9 more · 2026 · Neural regeneration research · added 2026-04-24
Alzheimer's disease is a common neurodegenerative disease characterized by progressive memory loss, cognitive decline, and behavioral changes. Blood-based biomarkers have recently gained significant a Show more
Alzheimer's disease is a common neurodegenerative disease characterized by progressive memory loss, cognitive decline, and behavioral changes. Blood-based biomarkers have recently gained significant attention due to their accessibility and cost-effectiveness. This review highlights the latest progress in multiple key areas of bloodbased biomarkers for Alzheimer's disease. For early diagnosis, blood-based biomarkers such as amyloid-β and phosphorylated tau can identify Alzheimer's disease even before clinical symptoms emerge. Dynamic changes in blood-based biomarkers, including p-tau217 and neurofilament light chain, reflect disease progression and correlate with cognitive decline, enabling continuous monitoring of Alzheimer's disease progression. Additionally, bloodbased biomarkers such as p-tau181 and glial fibrillary acidic protein aid in differential diagnosis by distinguishing Alzheimer's disease from other dementias such as frontotemporal dementia. Blood-based biomarkers related to nerve repair have opened up new avenues for tracking nerve regeneration and therapeutic response, especially brain-derived neurotrophic factor. Furthermore, advanced detection technologies such as single-molecule array and immunoprecipitation-mass spectrometry have significantly improved the sensitivity and specificity of bloodbased biomarkers, facilitating their clinical translation. In summary, blood-based biomarkers hold strong potential to improve early diagnosis, monitor progression, differential diagnosis, and evaluate therapies in Alzheimer's disease. This review provides a comprehensive and updated evaluation of the translational potential of bloodbased biomarkers, emphasizing their practical utility in clinical settings and offering insights into future directions for large-scale application. This review emphasizes the need to prioritize the allocation of scientific resources, expedite the transition of blood-based biomarkers to clinical implementation, and ultimately achieve precise treatment of Alzheimer's disease using these biomarkers. Show less
no PDF DOI: 10.4103/NRR.NRR-D-25-00759
BDNF alzheimer's disease amyloid-β blood-based biomarkers cognitive decline early diagnosis neurodegenerative disease phosphorylated tau

Effect of a digital-based integrated exercise and sleep intervention for older adults with depression: study protocol for a stepped-wedge cluster randomized controlled trial.

Nan Zhang, Cui Wang, Yuling Ga +11 more · 2026 · BMC geriatrics · BioMed Central · added 2026-04-24
Geriatric depression affects 12.95-28.4% of adults aged ≥ 60, yet treatment rates remain critically low globally. Lifestyle factors, particularly exercise and sleep demonstrate therapeutic potential, Show more
Geriatric depression affects 12.95-28.4% of adults aged ≥ 60, yet treatment rates remain critically low globally. Lifestyle factors, particularly exercise and sleep demonstrate therapeutic potential, integrated interventions may exert synergistic effects on geriatric depression, though such interventions remain scarce. The Geriatric Exercise-Sleep Optimization (GESO) project aims to evaluate the clinical efficacy and cost-effectiveness of a combined exercise and sleep health intervention in alleviating depressive symptoms among community-dwelling older adults with depression, and exploring the potential underlying mechanisms. This is a stepped-wedge cluster-randomized trial (SW-CRT). A 12-week integrated exercise and sleep intervention will be implemented to all eligible participants during the study period. The primary aim is to evaluate the clinical efficacy in alleviating depressive symptoms. Secondary aims are to evaluate the additional health outcomes (i.e., quality of life, physical activity level, daily step count, sleep quality, and anxiety symptom), cost-effectiveness, and potential mechanisms. Costs will be aggregated and analyzed for economic evaluation. Costs will be aggregated and analyzed for economic evaluation. Salivary measured BDNF and irisin levels, and EEG-based brain function connectivity will be collected to assess potential intervention mechanisms. Mixed-effect linear regression models will be used to evaluate the effects of the integrated exercise-sleep intervention on primary and secondary outcomes. This study is expected to provide an effective and practical mode for an integrated exercise and sleep intervention among community-dwelling older adults with depression. Intended outcomes of the trial will facilitate changes in best practice to improve outcomes for this population.Trial registration Chinese Clinical Trail Registry ChiCTR2500107641, Registration date: 15 August 2025. Show less
📄 PDF DOI: 10.1186/s12877-026-07071-z
BDNF

A phenolic acid glyceride dimer isolated from Lilium brownii exerts neuroprotective effects in Parkinson's disease by modulating the p62-Keap1-Nrf2 signalling pathway.

Yuxiao Feng, Hengyun Tian, Chengcheng Hui +7 more · 2026 · European journal of pharmacology · Elsevier · added 2026-04-24
Lilium brownii is a plant that can be used for medicinal and food purposes. 1-O-p-coumaroyl-3-O-feruloyl glycerol (CF) is a phenolic acid glycerol dimer isolated from Lilium brownii. This study aims t Show more
Lilium brownii is a plant that can be used for medicinal and food purposes. 1-O-p-coumaroyl-3-O-feruloyl glycerol (CF) is a phenolic acid glycerol dimer isolated from Lilium brownii. This study aims to evaluate the neuroprotective effects of CF and elucidate the possible molecular mechanisms underlying its neuroprotective effects through in vivo and in vitro models of Parkinson's disease. 1-methyl-4-phenylpyridinium ions (MPP Following CF administration, the apoptosis rate and reactive oxygen species (ROS) levels in PC12 cells were significantly reduced. CF markedly upregulated the expression of proteins including dopamine, tyrosine hydroxylase, brain-derived neurotrophic factor (BDNF), while simultaneously downregulating the expression of proteins such as α-synuclein. Molecular docking results demonstrated favorable affinity between CF and proteins including p62. This compound not only ameliorated motor and cognitive impairments in Parkinson's disease mice but also markedly increased neuronal numbers within the substantia nigra region of these animals. CF exerts a neuroprotective effect in Parkinson's disease by modulating the p62-Keap1-Nrf2 signalling pathway. Show less
no PDF DOI: 10.1016/j.ejphar.2026.178618
BDNF biochemistry molecular biology neuroprotection neuroscience parkinson's disease phenolic acid signalling pathway

miR-322-5p mediates maternal immune activation-induced schizophrenia-like behaviors via regulation of the BDNF/TrkB/AKT signaling pathway.

Qiang Fu, Yaobo Li, Xiaodong Li +3 more · 2026 · Brain, behavior, and immunity · Elsevier · added 2026-04-24
Maternal immune activation (MIA) is a key environmental risk factor for neurodevelopmental disorders such as schizophrenia. MicroRNAs are critical regulators of brain development, yet their role in MI Show more
Maternal immune activation (MIA) is a key environmental risk factor for neurodevelopmental disorders such as schizophrenia. MicroRNAs are critical regulators of brain development, yet their role in MIA-induced pathology remains unclear. We found that miR-322-5p was significantly upregulated in the prefrontal cortex of MIA-exposed offspring and directly targeted the 3' untranslated region of brain-derived neurotrophic factor (BDNF), inhibiting its expression. This upregulation impaired BDNF/TrkB/AKT signaling and reduced the synaptic protein PSD95, leading to hypoactivity, cognitive deficits, social impairments, and disrupted sensorimotor gating. Inhibition of miR-322-5p or overexpression of BDNF in the prefrontal cortex restored signaling and reversed both behavioral and molecular abnormalities. These results identify miR-322-5p as a key mediator of MIA-induced neuropathology via repression of BDNF signaling and suggest its potential as a therapeutic target in neurodevelopmental disorders. Show less
no PDF DOI: 10.1016/j.bbi.2026.106298
BDNF akt signaling pathway bdnf maternal immune activation micrornas neurodevelopmental disorders schizophrenia trkb

Plasma Brain-Derived Neurotrophic Factor Levels, Brain-Derived Neurotrophic Factor Val66Met Polymorphism, and Their Association with Phenoconversion in Isolated REM Sleep Behavior Disorder.

Yajie Zang, Hui Zhang, Zheng Ruan +6 more · 2026 · European neurology · added 2026-04-24
Brain-derived neurotrophic factor (BDNF) plays an important role in the survival of dopaminergic neurons. Clinical studies have suggested that serum BDNF levels are reduced in patients with Parkinson' Show more
Brain-derived neurotrophic factor (BDNF) plays an important role in the survival of dopaminergic neurons. Clinical studies have suggested that serum BDNF levels are reduced in patients with Parkinson's disease (PD). However, no study has investigated peripheral BDNF levels and BDNF Val66Met polymorphism in the prodromal stage of PD and their relationship with disease conversion. In total, 120 patients with video-polysomnography confirmed isolated REM sleep behavior disorder (iRBD) and 120 healthy controls (HCs) were enrolled. Genetic analyses were performed, and plasma levels of BDNF were measured. All patients with iRBD underwent comprehensive clinical testing, and 107 iRBD patients were prospectively followed up. Plasma BDNF levels were significantly lower in the iRBD group than in HCs (18,878.85 pg/mL vs. 24,649.85 pg/mL, p = 0.002), but no differences were observed in BDNF Val66Met carrier rates between the two groups. Plasma BDNF levels did not differ significantly between BDNF Val66Met carriers and noncarriers. Notably, higher plasma BDNF levels were associated with an increased risk of short-term disease conversion (hazard ratio = 3.418, 95% CI: 1.520-7.684, p = 0.003), whereas BDNF Val66Met carrier rates showed no such association. Our findings suggest that plasma BDNF is significantly associated with iRBD and may likely serve as a prognostic biomarker for the development of neurodegenerative disease. However, the BDNF Val66Met polymorphism may not be involved in the pathogenesis of iRBD as well as phenoconversion in the studied population. Show less
no PDF DOI: 10.1159/000550711
BDNF bdnf dopaminergic neurons neurotrophic factor parkinson's disease rem sleep behavior disorder val66met polymorphism

Roseburia intestinalis Offers Vagus-Dependent Neuroprotection Against Parkinson's Disease.

Mengyun Li, Jie Wu, Junjie Xiang +7 more · 2026 · Molecular neurobiology · Springer · added 2026-04-24
Parkinson's disease (PD) is characterized by dopaminergic neurodegeneration and increasingly associated with gut microbiota alterations. Roseburia intestinalis (R. intestinalis) is consistently reduce Show more
Parkinson's disease (PD) is characterized by dopaminergic neurodegeneration and increasingly associated with gut microbiota alterations. Roseburia intestinalis (R. intestinalis) is consistently reduced in PD; however, its functional contribution remains unknown. We performed two complementary mouse experiments using a 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-induced PD model. In the primary intervention experiment, mice received live or heat-killed R. intestinalis, followed by behavioral assessments and multi-layer analyses, including immunofluorescence, western blotting, enzyme-linked immunosorbent assay, quantitative polymerase chain reaction, 16S rRNA sequencing, metabolomics, and transcriptomics. In a separate mechanistic experiment, subdiaphragmatic vagotomy was introduced to interrogate vagus-dependent gut-brain communication, with key behavioral and inflammatory endpoints assessed. Live R. intestinalis improved rotarod, pole, and grip strength performance and preserved tyrosine hydroxylase-positive neurons in the substantia nigra; however, these effects were not observed in the heat-killed group. Live R. intestinalis treatment also reduced glial reactivity, restored brain-derived neurotrophic factor expression, and maintained blood-brain barrier integrity. Systemically, R. intestinalis lowered serum lipopolysaccharide, tumor necrosis factor-α, and interleukin-6 levels; preserved colonic structure; and restored mucin-secreting goblet cell function. MPTP-induced dysbiosis was partially corrected. Metabolomic profiling revealed restoration of several acyl-carnitines and higher acetic acid levels. Transcriptomic analysis showed increased immediate early genes after MPTP, and the elevated c-Fos in the substantia nigra was partially normalized by R. intestinalis. Importantly, vagotomy abolished the central neuroprotective and anti-inflammatory effects but did not affect peripheral cytokine suppression, indicating both vagus-dependent and vagus-independent pathways. R. intestinalis supplementation alleviated motor impairments, reduced neuroinflammation, preserved dopaminergic neurons, and improved intestinal and metabolic alterations in mice with an MPTP-induced PD model. Its protective actions may involve both central and peripheral mechanisms, potentially including gut-brain communication pathways. R. intestinalis may be a promising candidate for microbiota-based strategies against PD. Show less
📄 PDF DOI: 10.1007/s12035-026-05707-0
BDNF

Sinomenine inhibits oxidative stress to attenuate Alzheimer's disease pathology via α7 nicotinic acetylcholine receptor.

Haojie Ni, Yiyi Xiong, Min Liu +14 more · 2026 · Phytomedicine : international journal of phytotherapy and phytopharmacology · Elsevier · added 2026-04-24
The pathological mechanism of Alzheimer's disease (AD) is complex. The binding of Aβ to α7 nicotinic acetylcholine receptor (α7nAChR) contributes to neuronal damage. Sinomenine (SIN) is an alkaloid ex Show more
The pathological mechanism of Alzheimer's disease (AD) is complex. The binding of Aβ to α7 nicotinic acetylcholine receptor (α7nAChR) contributes to neuronal damage. Sinomenine (SIN) is an alkaloid extracted from the traditional Chinese medicine Qingfengteng (Sinomenium acutum). The anti-inflammatory, antioxidant, and immunomodulatory effects of SIN were confirmed to be closely associated with the α7nAChR. This study aimed to investigate whether α7nAChR serves as a pharmacological target of SIN against AD, and to evaluate the neuroprotective effects of SIN both in vivo and in vitro, focusing on the α7nAChR/Nrf2/Keap1 signaling pathway. In this study, the effects of SIN in both APP/PS1 transgenic mice and SH-SY5Y cells subjected to Aβ1-42-induced injury were assessed. The selective antagonist α-bungarotoxin ‌(α-BTX), the agonist nicotine (Nic) of α7nAChR, and α7nAChR siRNA were employed. The cognitive function, Aβ deposition, synaptic plasticity markers, the tau protein phosphorylation, mitochondrial membrane potential, oxidative stress and the α7nAChR/Nrf2/Keap1 signaling pathway were analyzed in vivo and/or in vitro. SIN significantly enhanced learning and memory abilities in APP/PS1 mice, reduced Aβ plaque deposition and synaptic dysfunction, and inhibited hyperphosphorylation of tau protein and oxidative stress in the brain. In Aβ1-42-induced neuronal injury model, SIN alleviated apoptosis, increased BDNF and ACh levels, inhibited mitochondrial damage, stabilized calcium homeostasis, and suppressed oxidative stress. Meanwhile, SIN disrupted Nrf2-Keap1 binding to promote the Nrf2/HO-1 signaling pathway. Nevertheless, SIN effects above were inhibited by α-BTX. The knockdown of α7nAChR in vitro significantly promoted Nrf2/HO-1 pathway and BDNF expression. SIN exerts neuroprotective effect in APP/PS1 transgenic mice and Aβ1-42-induced neuronal injury by inhibiting oxidative stress via α7nAChR/Nrf2/Keap1 pathway. This study provides evidence for α7nAChR as a new target and the clinical application potential of SIN in AD treatment. Show less
no PDF DOI: 10.1016/j.phymed.2026.157779
BDNF alzheimer's disease antioxidant inflammation neuroprotection oxidative stress pathology sinomenine

The effect and mechanism of atrazine induced depression-like in mice.

Dandan Wang, Peng Li · 2026 · Ecotoxicology and environmental safety · Elsevier · added 2026-04-24
Depression is a prevalent mental disorder in modern society, with a complex and incompletely understood etiology. Accumulating evidence indicates that pesticide exposure is a potential risk factor for Show more
Depression is a prevalent mental disorder in modern society, with a complex and incompletely understood etiology. Accumulating evidence indicates that pesticide exposure is a potential risk factor for mental health disorders. Atrazine (ATR), a widely used herbicide with the highest global application rates and frequently detected in environmental media, has been confirmed to possess neurotoxicity. However, there are currently no reports examining its effects on depression. Therefore, this study aimed to investigate the effects of subchronic ATR exposure on depression-like phenotypes in mice through behavioral tests, pathological examinations, and molecular analyses. The results demonstrated that ATR exposure induced significant depressive-like behaviors and led to neuronal reductions in key brain regions associated with depression, such as the hippocampus and prefrontal cortex. These effects were mechanistically linked to oxidative damage and decreased expression levels of 5-hydroxytryptamine (5-HT) and brain-derived neurotrophic factor (BDNF). Collectively, this study not only reveals the potential role and mechanism of ATR as an environmental risk factor for depression, but also provides a theoretical basis for the prevention and treatment of its new neurotoxicological effects and future related research. Show less
no PDF DOI: 10.1016/j.ecoenv.2025.119658
BDNF atrazine depression etiology herbicide mental health neurotoxicity pesticide

Neuroprotective Effects of Desert Milk Exosomes in LPS-Induced Cognitive Decline: Role of Microglial M2 Polarization and AMPK Signaling.

Yujie Li, Wei Lu, Wentao Qian +9 more · 2026 · Nutrients · MDPI · added 2026-04-24
Hippocampal neuroinflammation (HNF) is a key pathological feature in neurodegenerative disorders. Milk-derived exosomes, as bioactive extracellular vesicles, have underexplored potential in regulating Show more
Hippocampal neuroinflammation (HNF) is a key pathological feature in neurodegenerative disorders. Milk-derived exosomes, as bioactive extracellular vesicles, have underexplored potential in regulating brain neuroinflammatory responses. This study aimed to characterize desert milk exosomes (D-Exo) and investigate their neuroprotective and anti-neuroinflammatory effects in LPS-induced HNF mice model and an LPS-stimulated BV2 microglia. Exosomes were isolated from desert and non-desert milk (ND-Exo) for proteomic analysis. After pretreating BV2 cells with exosomes and stimulating with LPS, their inflammatory responses and polarization were assessed by RT-PCR. Balb/c mice were orally gavaged with D-Exo or 0.9% NaCl for 28 days before LPS injection. Cognitive function was assessed via behavioral tests, with microglial/astrocyte activation analyzed by immunofluorescence. D-Exo exhibited superior stability and a unique proteomic profile enriched with proteins linked to neuroinflammation and blood-brain barrier (BBB) integrity, notably within the AMPK signaling pathway. In vitro, D-Exo shifted LPS-stimulated microglia from the M1 to the M2 phenotype. In vivo, it alleviated HNF and cognitive decline, reduced Aβ D-Exo is enriched with specific proteins, attenuates neuroinflammation and cognitive decline by regulating microglial M1/M2 polarization and AMPK pathway, highlighting its preventive potential. Show less
📄 PDF DOI: 10.3390/nu18020315
BDNF

Mechanism of Inosine from

Jianbo Tang, Qing Zhao, Hanying Tan +8 more · 2026 · Foods (Basel, Switzerland) · MDPI · added 2026-04-24
Gut microbial metabolites play a crucial role in modulating cognitive function. In a previous animal study, oral administration of
📄 PDF DOI: 10.3390/foods15020349
BDNF