Chinese Journal of Clinical Pharmacology and Therapeutics ›› 2026, Vol. 31 ›› Issue (6): 764-773.doi: 10.12092/j.issn.1009-2501.2026.06.005
Xiao XU1(
), Shuailin WANG1, Xin QIAN1, Yi YAO2, Zhangyu WANG2, Xiaoyi ZHU2, Qing MAO3, Qi GUO1,*(
)
Received:2025-06-06
Online:2026-06-26
Published:2026-07-06
Contact:
Qi GUO
E-mail:1000003358@ujs.edu.cn;guoqi608@126.com
CLC Number:
Xiao XU, Shuailin WANG, Xin QIAN, Yi YAO, Zhangyu WANG, Xiaoyi ZHU, Qing MAO, Qi GUO. Research progress on the treatment of diabetic cardiomyopathy with traditional Chinese medicine[J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(6): 764-773.
| Drug | Model | n (minimal) | Target | Mechanism | Reference |
| Curcumin | DCM rats | 6 | PI3K/AKT/mTOR signaling pathway | ↓MDA ↑SOD, PI3K, mTOR, p-AKT | [ |
| DCM mice | 5 | SIRT3/FOXO3a signaling pathway | ↓MDA, ROS, Bax, Cleaved caspase-3 ↑SOD, GSH-Px, SIRT3, FOXO3a, Bcl-2 | [ | |
| DCM rats | 10 | CYP2J2/PPARs signaling pathway | ↑PPARα, PPARβ, PPARγ, CYP2J2 | [ | |
| DCM mice | 6 | Nrf2/HO-1/GPX4 signaling pathway | ↓CK-MB, cTNT, LDH, MDA, ROS, Fe2? ↑SOD, GSH-Px, Nrf2, HO-1, GPX4 | [ | |
| DCM rats | 20 | AMPK/mTOR signaling pathway | ↓Cleaved caspase-3, C-PARP, p62, p-mTOR ↑LC3, Beclin-1, p-AMPK | [ | |
| Astragalus polysaccharide | DCM rats | 10 | AMPK/mTOR signaling pathway | ↓LVEDD, LVESD, mTOR, p-mTOR ↑LVEF, LVFS, AMPK, p-AMPK | [ |
| DCM rats | 10 | LC3, p62 | ↓p62 ↑LC3 | [ | |
| SOD2?/KO mice | 6 | Nitrosine, 8-OH-dG, SOD2 | ↓ROS, Nitrosine, 8-OH-dG ↑SOD2 | [ | |
| Berberine | H9c2 cells | — | CCNA2, PLK1, RRM2 | ↓ROS, CCL2, CCL7, NRBP2, SOX9 ↑BIRC5, CCNA2, CCNB1, CDC20, MYBL2, PLK1, RRM2 | [ |
| DCM mice, H9c2 cells | 6 | SIRT3/lipophagy axis | ↓CK, CK-MB, Plin5 ↑Beclin1, Sirt3, LC3Ⅱ/LC3Ⅰ, Opa1, Drp1, Mfn2, Mff | [ | |
| DCM mice, H9c2 cells | 6 | mTOR/mtROS signaling pathway | ↓CollagenⅠ, CollagenⅢ, NLRP3, Caspase-1, IL-1β, IL-18, GSDMD, p-mTOR, TGF-β | [ | |
| DCM mice, H9c2 cells | 6 | AMPK/mTOR signaling pathway | ↓ROS, MFF, p-Drp1Ser616, Parkin, p-mTORSer2481/mTOR ↑ATP, MMP, Mfn2, p-Drp1Ser637, LC3-Ⅱ, PGC-1α, Nrf1, Nrf2, Tfam, Tfb1m, Tfb2m | [ | |
| Astragaloside IV | DCM mice | 10 | IL-17 signaling pathway | ↓CK-MB, TG, LDL-C, IL-1β, IL-6, CXCL-10, IL-17, IL-17R, TRAF6, MAPKs, c-Jun, NF-κB p65 ↑HDL-C | [ |
| Astragaloside IV | DCM mice, H9c2 cells | 6 | NLRP3/Caspase-1/GSDMD signaling pathway | ↓TC, TG, IL-1β, IL-18, IL-6, TNF-α, NLRP3, ASC, Caspase-1, GSDMD, GSDMD-N, pro-IL-1β, IL-1β ↑LDH, CK-MB | [ |
| DCM mice | 6 | AMPK/ULK1 signaling pathway | ↓TG, LDL-C, p62 ↑Beclin-1, LC3, p-AMPK | [ | |
| DCM mice | 15 | PI3K/Akt signaling pathway | ↓LDH, CK-MB, cTnT, MDA, TNF-α, IL-1β, IL-6, MCP-1 mRNA ↑GSH, GSH-Px, p-PI3K/PI3K, p-Akt/Akt | [ | |
| Resveratrol | DCM mice | 8 | SIRT3 | ↓TC, TG, LDL-C, Bax, Cleaved caspase-3 ↑HDL-C, Bcl-2, p-AMPK, PGC-1α, p-FOXO-1, SIRT3 | [ |
| DCM mice | 10 | Mst1/SIRT3 | ↓Bax, Bax/Bcl-2, p62, p-Mst1 ↑Bcl-2 mRNA, Sirt3, LC3Ⅱ/LC3Ⅰ | [ | |
| DCM mice | 6 | AMPK-P53 | ↓P62, P53 ↑Parkin, p-AMPK | [ |
Table 1 Targets and mechanisms of TCM monomers in the treatment of DCM
| Drug | Model | n (minimal) | Target | Mechanism | Reference |
| Curcumin | DCM rats | 6 | PI3K/AKT/mTOR signaling pathway | ↓MDA ↑SOD, PI3K, mTOR, p-AKT | [ |
| DCM mice | 5 | SIRT3/FOXO3a signaling pathway | ↓MDA, ROS, Bax, Cleaved caspase-3 ↑SOD, GSH-Px, SIRT3, FOXO3a, Bcl-2 | [ | |
| DCM rats | 10 | CYP2J2/PPARs signaling pathway | ↑PPARα, PPARβ, PPARγ, CYP2J2 | [ | |
| DCM mice | 6 | Nrf2/HO-1/GPX4 signaling pathway | ↓CK-MB, cTNT, LDH, MDA, ROS, Fe2? ↑SOD, GSH-Px, Nrf2, HO-1, GPX4 | [ | |
| DCM rats | 20 | AMPK/mTOR signaling pathway | ↓Cleaved caspase-3, C-PARP, p62, p-mTOR ↑LC3, Beclin-1, p-AMPK | [ | |
| Astragalus polysaccharide | DCM rats | 10 | AMPK/mTOR signaling pathway | ↓LVEDD, LVESD, mTOR, p-mTOR ↑LVEF, LVFS, AMPK, p-AMPK | [ |
| DCM rats | 10 | LC3, p62 | ↓p62 ↑LC3 | [ | |
| SOD2?/KO mice | 6 | Nitrosine, 8-OH-dG, SOD2 | ↓ROS, Nitrosine, 8-OH-dG ↑SOD2 | [ | |
| Berberine | H9c2 cells | — | CCNA2, PLK1, RRM2 | ↓ROS, CCL2, CCL7, NRBP2, SOX9 ↑BIRC5, CCNA2, CCNB1, CDC20, MYBL2, PLK1, RRM2 | [ |
| DCM mice, H9c2 cells | 6 | SIRT3/lipophagy axis | ↓CK, CK-MB, Plin5 ↑Beclin1, Sirt3, LC3Ⅱ/LC3Ⅰ, Opa1, Drp1, Mfn2, Mff | [ | |
| DCM mice, H9c2 cells | 6 | mTOR/mtROS signaling pathway | ↓CollagenⅠ, CollagenⅢ, NLRP3, Caspase-1, IL-1β, IL-18, GSDMD, p-mTOR, TGF-β | [ | |
| DCM mice, H9c2 cells | 6 | AMPK/mTOR signaling pathway | ↓ROS, MFF, p-Drp1Ser616, Parkin, p-mTORSer2481/mTOR ↑ATP, MMP, Mfn2, p-Drp1Ser637, LC3-Ⅱ, PGC-1α, Nrf1, Nrf2, Tfam, Tfb1m, Tfb2m | [ | |
| Astragaloside IV | DCM mice | 10 | IL-17 signaling pathway | ↓CK-MB, TG, LDL-C, IL-1β, IL-6, CXCL-10, IL-17, IL-17R, TRAF6, MAPKs, c-Jun, NF-κB p65 ↑HDL-C | [ |
| Astragaloside IV | DCM mice, H9c2 cells | 6 | NLRP3/Caspase-1/GSDMD signaling pathway | ↓TC, TG, IL-1β, IL-18, IL-6, TNF-α, NLRP3, ASC, Caspase-1, GSDMD, GSDMD-N, pro-IL-1β, IL-1β ↑LDH, CK-MB | [ |
| DCM mice | 6 | AMPK/ULK1 signaling pathway | ↓TG, LDL-C, p62 ↑Beclin-1, LC3, p-AMPK | [ | |
| DCM mice | 15 | PI3K/Akt signaling pathway | ↓LDH, CK-MB, cTnT, MDA, TNF-α, IL-1β, IL-6, MCP-1 mRNA ↑GSH, GSH-Px, p-PI3K/PI3K, p-Akt/Akt | [ | |
| Resveratrol | DCM mice | 8 | SIRT3 | ↓TC, TG, LDL-C, Bax, Cleaved caspase-3 ↑HDL-C, Bcl-2, p-AMPK, PGC-1α, p-FOXO-1, SIRT3 | [ |
| DCM mice | 10 | Mst1/SIRT3 | ↓Bax, Bax/Bcl-2, p62, p-Mst1 ↑Bcl-2 mRNA, Sirt3, LC3Ⅱ/LC3Ⅰ | [ | |
| DCM mice | 6 | AMPK-P53 | ↓P62, P53 ↑Parkin, p-AMPK | [ |
| Drug | Model | n (minimal) | Target | Mechanism | Reference |
| Buyang Huanwu Decoction | DCM mice | 10 | AKT, GSK3β | ↓GSK3β, p-GSK3β ↑INSR, p-PI3K, p-AKT | [ |
| DCM mice | 8 | TNF-α, DRP1, MFN2 | ↓LDH, CK-MB, IL-2, TNF-α, MDA, DRP1, MFF ↑SOD, MFN2 | [ | |
| DCM mice | 10 | TLR4/NF-κB | ↓CK-MB, IL-6, MCP-1, TNF-α, TG, LDL-C, TLR4, NF-κB p65, Cleaved caspase-3, Cleaved PARP, CollagenⅠ, Collagen Ⅲ ↑HDL-C | [ | |
| Zhigancao Decoction | DCM rats | 10 | miR-181a-5p, SPHK2 | ↓α-SMA, CollagenⅠ, CollagenⅢ, SPHK2 ↑miR-181a-5p | [ |
| DCM rats | 10 | LC3-Ⅰ, LC3-Ⅱ, Beclin-1, P62 | ↓BNP, Bax, P62 ↑Bcl-2, Beclin-1, LC3-Ⅱ/LC3-Ⅰ | [ | |
| Shengmai Decoction | DCM mice | 10 | Alkbh5-Atg7 | ↓LDH, CK-MB, cTN1 ↑ANP mRNA, BNP mRNA, Alkbh5, Lc3, Atg7 | [ |
| DCM rats | 10 | CaMKII/PLB/p-PLB/SERCA2a | ↓PLB, CaMKII ↑p-PLB, SERCA2a, NCX1, PPAR-α, SERCA2a/PLB, PLBSer16+Thr17/PLB | [ | |
| DCM rats | 10 | PPARα/CD36 | ↓MDA, PPARα, CD36 ↑SOD, GSH-Px, miR-19a | [ | |
| Didang Decoction | DCM mice | 12 | Mfn2, Opal, Drp1, Fis-1 | ↓Mfn2, Opa1, ROS ↑Drp1, Fis-1 | [ |
| DCM mice | 8 | NLRP3 | ↓TC, TG, ROS, NLRP3, TXNIP, Caspase-1, IL-1β | [ |
Table 2 Targets and mechanisms of single TCM and traditional TCM compounds in the treatment of DCM
| Drug | Model | n (minimal) | Target | Mechanism | Reference |
| Buyang Huanwu Decoction | DCM mice | 10 | AKT, GSK3β | ↓GSK3β, p-GSK3β ↑INSR, p-PI3K, p-AKT | [ |
| DCM mice | 8 | TNF-α, DRP1, MFN2 | ↓LDH, CK-MB, IL-2, TNF-α, MDA, DRP1, MFF ↑SOD, MFN2 | [ | |
| DCM mice | 10 | TLR4/NF-κB | ↓CK-MB, IL-6, MCP-1, TNF-α, TG, LDL-C, TLR4, NF-κB p65, Cleaved caspase-3, Cleaved PARP, CollagenⅠ, Collagen Ⅲ ↑HDL-C | [ | |
| Zhigancao Decoction | DCM rats | 10 | miR-181a-5p, SPHK2 | ↓α-SMA, CollagenⅠ, CollagenⅢ, SPHK2 ↑miR-181a-5p | [ |
| DCM rats | 10 | LC3-Ⅰ, LC3-Ⅱ, Beclin-1, P62 | ↓BNP, Bax, P62 ↑Bcl-2, Beclin-1, LC3-Ⅱ/LC3-Ⅰ | [ | |
| Shengmai Decoction | DCM mice | 10 | Alkbh5-Atg7 | ↓LDH, CK-MB, cTN1 ↑ANP mRNA, BNP mRNA, Alkbh5, Lc3, Atg7 | [ |
| DCM rats | 10 | CaMKII/PLB/p-PLB/SERCA2a | ↓PLB, CaMKII ↑p-PLB, SERCA2a, NCX1, PPAR-α, SERCA2a/PLB, PLBSer16+Thr17/PLB | [ | |
| DCM rats | 10 | PPARα/CD36 | ↓MDA, PPARα, CD36 ↑SOD, GSH-Px, miR-19a | [ | |
| Didang Decoction | DCM mice | 12 | Mfn2, Opal, Drp1, Fis-1 | ↓Mfn2, Opa1, ROS ↑Drp1, Fis-1 | [ |
| DCM mice | 8 | NLRP3 | ↓TC, TG, ROS, NLRP3, TXNIP, Caspase-1, IL-1β | [ |
| Drug | Model | n (minimal) | Target | Mechanism | Reference |
| Tongxinluo Capsule | H9c2 cells | — | AMPK-mTOR signaling pathway | ↓ROS, LDH, MDA, P62, p-mTOR ↑Beclin-1, LC3Ⅱ/Ⅰ, p-AMPK | [ |
| DCM rats | 8 | TGF-β1-p38MAPK-CREB signaling pathway | ↓TGF-β1, p-p38MAPK, Caspase-3 ↑Bcl-2, p-CREB | [ | |
| Zuogui Jiangtang Shuxin Formula | DCM mice | 6 | Foxo1-ANP-β-MHC signaling pathway | ↓Foxo1, ANP, β-MHC | [ |
| DCM mice | 10 | TLR4/NF-κB signaling pathway | ↓TNF-α, IL-1β, TLR4, NF-κB p56, p-NF-κB p56/NF-κB p56, CollagenⅠ, CollagenⅢ, α-SMA | [ | |
| Zhilong Huoxue Tongyu Capsule | DCM mice | 8 | P38MAPK signaling pathway | ↓TG, TC, p-P38MAPK, TNF-α, α-SMA, Collagen-Ⅰ | [ |
| DCM rats | 10 | PI3K, AKT1, FoxO3a | ↓GHb, TC, TG, LDL-C ↑HDL-C, PI3K, AKT1, FoxO3a, p-PI3K, p-AKT1, p-FoxO3a | [ | |
| DCM rats | 9 | Adiponectin | ↓ICAM-1, VCAM-1 ↑Adiponectin | [ | |
| Shexiang Tongxin Dropping Pill | DCM rats | 6 | AGE-RAGE | ↓p-p38, p-JNK, Cleaved caspase-3 | [ |
| DCM mice | 6 | VEGF, ZO-1, Occludin, VE-Cadherin, Claudin-5, JAM-A | ↓TC, TG, LDL-C ↑VEGF, VEGFR2, PI3K, AKT, eNOS, ZO-1, Occludin, VE-Cadherin, Claudin-5, JAM-A | [ | |
| Zicui Tongmai Decoction | DCM rats | 9 | TGF-β1/Smads signaling pathway | ↓TGF-β1, Smads3 ↑Smads7 | [ |
| DCM rats | 9 | PKC-βⅡ | ↓FPG, FINS, HOMA-IR, TG, T-CHO, LDL-C, HbAlc, MDA, PKC-βⅡ, VEGF ↑SOD, VE-cadherin, VEGFR2 | [ |
Table 3 Targets and mechanisms of TCM modern formulations in DCM models
| Drug | Model | n (minimal) | Target | Mechanism | Reference |
| Tongxinluo Capsule | H9c2 cells | — | AMPK-mTOR signaling pathway | ↓ROS, LDH, MDA, P62, p-mTOR ↑Beclin-1, LC3Ⅱ/Ⅰ, p-AMPK | [ |
| DCM rats | 8 | TGF-β1-p38MAPK-CREB signaling pathway | ↓TGF-β1, p-p38MAPK, Caspase-3 ↑Bcl-2, p-CREB | [ | |
| Zuogui Jiangtang Shuxin Formula | DCM mice | 6 | Foxo1-ANP-β-MHC signaling pathway | ↓Foxo1, ANP, β-MHC | [ |
| DCM mice | 10 | TLR4/NF-κB signaling pathway | ↓TNF-α, IL-1β, TLR4, NF-κB p56, p-NF-κB p56/NF-κB p56, CollagenⅠ, CollagenⅢ, α-SMA | [ | |
| Zhilong Huoxue Tongyu Capsule | DCM mice | 8 | P38MAPK signaling pathway | ↓TG, TC, p-P38MAPK, TNF-α, α-SMA, Collagen-Ⅰ | [ |
| DCM rats | 10 | PI3K, AKT1, FoxO3a | ↓GHb, TC, TG, LDL-C ↑HDL-C, PI3K, AKT1, FoxO3a, p-PI3K, p-AKT1, p-FoxO3a | [ | |
| DCM rats | 9 | Adiponectin | ↓ICAM-1, VCAM-1 ↑Adiponectin | [ | |
| Shexiang Tongxin Dropping Pill | DCM rats | 6 | AGE-RAGE | ↓p-p38, p-JNK, Cleaved caspase-3 | [ |
| DCM mice | 6 | VEGF, ZO-1, Occludin, VE-Cadherin, Claudin-5, JAM-A | ↓TC, TG, LDL-C ↑VEGF, VEGFR2, PI3K, AKT, eNOS, ZO-1, Occludin, VE-Cadherin, Claudin-5, JAM-A | [ | |
| Zicui Tongmai Decoction | DCM rats | 9 | TGF-β1/Smads signaling pathway | ↓TGF-β1, Smads3 ↑Smads7 | [ |
| DCM rats | 9 | PKC-βⅡ | ↓FPG, FINS, HOMA-IR, TG, T-CHO, LDL-C, HbAlc, MDA, PKC-βⅡ, VEGF ↑SOD, VE-cadherin, VEGFR2 | [ |
| 1 |
Seferovic PM, Paulus WJ, Rosano G, et al. Diabetic myocardial disorder. A clinical consensus statement of the heart failure association of the ESC and the ESC working group on myocardial & pericardial diseases[J]. Eur J Heart Fail, 2024, 26 (9): 1893- 1903.
doi: 10.1002/ejhf.3347 |
| 2 |
Tan Y, Zhang ZG, Zheng C, et al. Mechanisms of diabetic cardiomyopathy and potential therapeutic strategies: preclinical and clinical evidence[J]. Nat Rev Cardiol, 2020, 17 (9): 585- 607.
doi: 10.1038/s41569-020-0339-2 |
| 3 |
刘伟, 顾秀竹, 吴筱霓, 等. 姜黄素药理作用的研究进展[J]. 华西药学杂志, 2021, 36 (3): 336- 340.
doi: 10.13375/j.cnki.wcjps.2021.03.022 |
| 4 |
李菊, 曲智海, 张晓蕾, 等. 姜黄素对2型糖尿病大鼠心肌组织PI3K/AKT/mTOR信号通路的影响[J]. 锦州医科大学学报, 2024, 45 (5): 43- 47.
doi: 10.13847/j.cnki.lnmu.2024.05.006 |
| 5 | 李星, 钟毅, 陈雪. 姜黄素通过调节SIRT3/FOXO3a通路改善糖尿病心肌病的机制研究[J]. 海南医学院学报, 2024, 30 (6): 401- 406. |
| 6 | 陈洁. 姜黄素对糖尿病心肌病大鼠心脏的保护作用及机制研究[J]. 武汉职业技术学院学报, 2023, 22 (6): 110- 116. |
| 7 | 陈雪. 姜黄素通过Nrf2/HO-1/GPX4途径抑制铁死亡改善糖尿病性心肌病小鼠的研究 [D]. 泸州: 西南医科大学, 2023. |
| 8 | 尧青, 李勇, 陈晓, 等. 姜黄素对糖尿病大鼠心肌自噬凋亡及AMPK-mTOR信号通路的影响[J]. 中国医院药学杂志, 2022, 42 (10): 1004- 1008. |
| 9 |
杨乾方, 王帆, 叶婷, 等. 黄芪多糖提取工艺、化学结构及药理作用的研究进展[J]. 中草药, 2023, 54 (12): 4069- 4081.
doi: 10.7501/j.issn.0253-2670.2023.12.033 |
| 10 | 叶婷, 马国庆, 魏明慧, 等. 黄芪多糖对糖尿病心肌病大鼠AMPK-mTOR通路的调控机制研究[J]. 世界中医药, 2022, 17 (7): 977- 982. |
| 11 | 侯赛红, 孙树芹, 徐万群, 等. 黄芪多糖对糖尿病心肌病大鼠心肌细胞凋亡的影响[J]. 青岛大学学报(医学版), 2020, 56 (3): 293- 296. |
| 12 | 孙奇林, 鞠婧, 王浩, 等. 黄芪多糖干预糖尿病心肌氧化应激的实验研究[J]. 中国中西医结合杂志, 2020, 40 (2): 196- 203. |
| 13 |
Cai Y, Xin QQ, Lu JJ, et al. A new therapeutic candidate for cardiovascular diseases: Berberine[J]. Front Pharmacol, 2021, 12, 631100.
doi: 10.3389/fphar.2021.631100 |
| 14 |
李明亮, 韩超, 白学鹏, 等. 基于RNA-seq研究小檗碱对糖尿病心肌缺血再灌注损伤基因表达的影响[J]. 临床医学研究与实践, 2025, 10 (9): 1- 5.
doi: 10.19347/j.cnki.2096-1413.202509001 |
| 15 | 陈文贤. 小檗碱调控脂噬改善糖尿病心肌病的机制研究 [D]. 深圳: 深圳大学, 2023. |
| 16 | 钟长生. 小檗碱抑制心肌细胞焦亡改善糖尿病心肌病小鼠心脏功能 [D]. 深圳: 深圳大学, 2023. |
| 17 | 莫苒. 小檗碱靶向AMPK维持线粒体稳态对糖尿病心肌病心肌损伤的保护作用及机制研究 [D]. 武汉: 华中科技大学, 2023. |
| 18 | 蒋微, 蒋式骊, 刘平. 黄芪甲苷的药理作用研究进展[J]. 中华中医药学刊, 2019, 37 (9): 2121- 2124. |
| 19 |
田小超, 刘玉, 方敬, 等. 黄芪甲苷通过抑制IL-17信号通路改善糖尿病心肌病小鼠心功能[J]. 中草药, 2024, 55 (21): 7335- 7346.
doi: 10.7501/j.issn.0253-2670.2024.21.014 |
| 20 | 秦依然. 黄芪甲苷通过抑制细胞焦亡改善糖尿病心肌病的机制研究 [D]. 济南: 山东大学, 2023. |
| 21 | 代雪宁. 黄芪甲苷通过AMPK-ULK1信号通路调控自噬减轻糖尿病心肌病心肌损伤 [D]. 济宁: 济宁医学院, 2023. |
| 22 |
杨嫒萍, 张磊, 李炜, 等. 黄芪甲苷对糖尿病心肌病小鼠的治疗作用及其机制[J]. 山东医药, 2022, 62 (23): 19- 24.
doi: 10.3969/j.issn.1002-266X.2022.23.005 |
| 23 |
陈小林, 张子龙, 高天慧, 等. 白藜芦醇药理作用及机制研究进展[J]. 中国野生植物资源, 2022, 41 (12): 67- 76.
doi: 10.3969/j.issn.1006-9690.2022.12.013 |
| 24 | 杨立群. 白藜芦醇通过调节SIRT3通路改善糖脂代谢紊乱所致心肌病变的研究 [D]. 石家庄: 河北医科大学, 2024. |
| 25 | 马振旺, 姜德友, 袁星星, 等. 白藜芦醇通过Mst1/Sirt3信号通路介导的细胞自噬改善糖尿病心肌损伤的机制研究[J]. 海南医学院学报, 2022, 28 (4): 251- 257. |
| 26 |
吴冰, 刘睿, 黄慧, 等. 白藜芦醇通过AMPK-P53途径调节糖尿病心肌线粒体自噬的研究[J]. 兰州大学学报(医学版), 2020, 46 (1): 67- 71+76.
doi: 10.13885/j.issn.1000-2812.2020.01.013 |
| 27 | 张燕. 补阳还五汤对糖尿病小鼠心肌的保护机制研究 [D]. 长春: 长春中医药大学, 2023. |
| 28 | 訾雪, 周凯旋, 鲍慧玮, 等. 补阳还五汤改善糖尿病心肌损伤的配伍作用研究[J]. 时珍国医国药, 2024, 35 (4): 831- 835. |
| 29 | 田小超, 杨帆, 马赟, 等. 补阳还五汤通过抑制炎症和凋亡改善糖尿病小鼠心肌损伤[J]. 中华中医药杂志, 2024, 39 (12): 6700- 6706. |
| 30 |
王天宇, 丁君灿, 程心怡, 等. 炙甘草汤通过miR-181a-5p靶向SPHK2调控心肌纤维化改善糖尿病心肌病[J]. 浙江中西医结合杂志, 2024, 34 (1): 14- 20+33.
doi: 10.3969/j.issn.1005-4561.2024.01.004 |
| 31 |
胡鹏飞, 陆明, 杨明, 等. 炙甘草汤对糖尿病性心肌病模型大鼠心功能的影响[J]. 浙江中西医结合杂志, 2020, 30 (6): 444- 448.
doi: 10.3969/j.issn.1005-4561.2020.06.005 |
| 32 | 成春锋. 生脉饮通过Alkbh5-Atg7通路介导脂自噬抗糖尿病心肌病的机制研究 [D]. 广州: 广州中医药大学, 2023. |
| 33 |
翟取, 孙明杰, 崔海峰, 等. 生脉散对糖尿病大鼠心脏钙转运蛋白的调节作用[J]. 中国中医基础医学杂志, 2020, 26 (5): 601- 604+665.
doi: 10.3969/j.issn.1006-3250.2020.05.017 |
| 34 | 李莺莺, 王卫, 王欣, 等. 生脉散对2型糖尿病大鼠心肌氧化应激的作用及miR-19a、PPARα、CD36因子的影响[J]. 中华中医药杂志, 2022, 37 (4): 2218- 2222. |
| 35 | 任晓霞, 尚鑫, 陈栋, 等. 基于线粒体分裂与融合探讨抵挡汤对糖尿病心肌病的影响[J]. 辽宁中医杂志, 2022, 49 (1): 195- 198+222-223. |
| 36 | 尚鑫, 任晓霞, 陈栋, 等. 抵挡汤对糖尿病心肌病小鼠NLRP3炎症小体的作用及机制[J]. 中国实验方剂学杂志, 2021, 27 (9): 19- 25. |
| 37 | 但俊. 通心络通过AMPK-mTOR通路调节自噬改善高糖环境下H9c2心肌细胞损伤的实验研究 [D]. 锦州: 锦州医科大学, 2022. |
| 38 | 张常喜, 张亚平, 张晓晋, 等. 基于“络脉”理论的通心络胶囊对糖尿病大鼠心肌TGF-β1-p38MAPK-CREB信号通路的影响[J]. 中国老年学杂志, 2025, 45 (2): 340- 344. |
| 39 | 廖心悦, 向琴, 皱骏驹, 等. 左归降糖舒心方对糖尿病心肌病MKR鼠Foxo1/β-MHC的影响[J]. 时珍国医国药, 2023, 34 (6): 1302- 1305. |
| 40 | 黄娟, 王一阳, 肖凡, 等. 左归降糖舒心方调控TLR4/NF-κB通路抑制糖尿病心肌病小鼠心肌纤维化的机制研究[J]. 湖南中医药大学学报, 2024, 44 (5): 729- 736. |
| 41 | 杨方. 基于网络药理学探讨蛭龙活血通瘀胶囊防治糖尿病心肌病的作用机制研究 [D]. 泸州: 西南医科大学, 2024. |
| 42 |
曾奇虎, 刘孟楠, 李小林, 等. 基于PI3K/AKT1/FoxO3a信号通路探讨蛭龙活血通瘀胶囊对糖尿病心肌病大鼠的影响[J]. 中药材, 2023, 46 (1): 197- 201.
doi: 10.13863/j.issn1001-4454.2023.01.034 |
| 43 | 董丽, 潘洪, 江云东, 等. 蛭龙活血通瘀胶囊对db/db小鼠心肌组织中脂联素、ICAM-1、VCAM-1的影响[J]. 中药药理与临床, 2019, 35 (6): 139- 144. |
| 44 | 白亚利, 崔鑫钰, 袁悦莹, 等. 基于网络药理学和动物实验研究麝香通心滴丸防治糖尿病心肌病的作用机制[J]. 中国中药杂志, 2024, 49 (7): 1905- 1914. |
| 45 | 崔鑫钰. 麝香通心滴丸治疗糖尿病心肌病冠脉微循环障碍机制研究 [D]. 北京: 北京中医药大学, 2023. |
| 46 |
吴刚强, 熊春红, 毛叶, 等. 滋膵通脉饮对糖尿病心肌病大鼠心肌纤维化和转化生长因子β1/Smads信号通路的影响[J]. 中药新药与临床药理, 2021, 32 (1): 29- 35.
doi: 10.19378/j.issn.1003-9783.2021.01.004 |
| 47 |
李汶珊, 易晓利, 卜献春, 等. 滋膵通脉饮对糖尿病心肌病大鼠糖脂代谢及氧化应激的影响[J]. 中医药导报, 2023, 29 (1): 12- 18.
doi: 10.13862/j.cn43-1446/r.2023.01.003 |
| 48 |
李汶珊, 黄昌锐, 易晓利, 等. 滋膵通脉饮对糖尿病心肌病大鼠心肌微血管损伤的影响[J]. 中医药导报, 2024, 30 (10): 20- 26+31.
doi: 10.13862/j.cn43-1446/r.2024.10.004 |
| [1] | Xiaoman XU, Lei ZHOU. Cardiovascular protective effects of GLP-1 receptor agonists in diabetic cardiomyopathy: mechanisms and clinical prospects [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(6): 729-734. |
| [2] | Xiaoyan GAO, Juan GUO, Sheng HUANG, Qiaoyun WANG, Yujia HUANG, Jinyuan LI, Xiaoqiang LIU. Mechanism of Qinggan Ershiqiwei Wan on non-alcoholic steatohepatitis based on network pharmacology and in vivo experiments [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(5): 596-606. |
| [3] | Qun LI, Xinyue ZHANG, Shuo QI, Jin TAN. Research progress on the mechanism of TGF-β1/Smads signaling pathway in oral submucous fibrosis and regulation of traditional Chinese medicine [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(5): 666-674. |
| [4] | Mina GAO, Liya YANG, Shangying DUAN, Xinlu CHEN, Xiaoya LI, Bo QIAO, Yueying WU. Research progress on the prevention and treatment of high-altitude diseases by traditional Chinese medicine based on the "lung-brain axis" [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(5): 675-682. |
| [5] | Haodong YANG, Long LI, Jingxuan LUO, Jinglei LI. Research progress of Hippo pathway effector YAP/TAZ in idiopathic pulmonary fibrosis [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(5): 709-715. |
| [6] | Ying ZHOU, Juntong LIU, Qingfeng WANG, Yufeng YANG, Yan SHI. Research progress on pharmacological mechanism of traditional Chinese medicine targeting type 2 diabetes related pathways [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(4): 500-508. |
| [7] | Liya SUN, Jiaxin LI, Guiyan SUN, Zhichao CHEN, Qingfeng WANG, Yufeng YANG, Yan SHI. Research progress of traditional Chinese medicine in the prevention and treatment of diabetic nephropathy based on intestinal flora and branched-chain amino acids [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(4): 527-535. |
| [8] | Yajie BAI, Liuqing YANG, Qin FAN, Xuwei LIU, Yuchen HE, Jiamao CHENG, Haiyan CHEN. The anti-hepatic fibrosis mechanism of Dendrobium officinale poly saccharides in vitro through epithelial-mesenchymal transition and Notch signaling pathway [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(3): 337-343. |
| [9] | Yuanyuan HUANG, Lingzhun WANG. Research progress in the intervention of myocardial fibrosis by regulating signal pathways with traditional Chinese medicine [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(3): 372-381. |
| [10] | Zhiwei LIU, Shuqing CHEN, Youjun CHEN, Yiming LI, Fangrong YAN, Yang ZHAO, Hua SUN, Haitang XIE, Ling WANG. Current application of P-value: challenges and optimization strategies [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(2): 240-246. |
| [11] | Tao WANG, Xiaowen CHENG, Zhirui ZHANG, Hao JIAO. Shikonin restrains TGF-β1/Smad signaling pathway to improve renal fibrosis [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(1): 48-54. |
| [12] | Jianqiang DU, Qi ZHANG, Enpeng GU, Chen XU, Yuan GUO, Menglong ZHANG, Jinke GUO, Si WU, Haibo XIE. Advances in the modulation of Nrf2 signaling by natural compounds for the treatment of intervertebral disc degeneration [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(1): 116-124. |
| [13] | JING Jiawen, MENG Qingbo, BI Zheng, WANG Fanjing, LI Yufan, FANG Zhaohui. Advances in animal models of diabetic erectile dysfunction based on therapeutic approaches [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2025, 30(9): 1224-1232. |
| [14] | SONG Cong, GAO Jinglin, BAN Feng, MENG Meng, WANG Mingxia. Research progress of PARP inhibitors in the treatment of brain glioma [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2025, 30(9): 1281-1289. |
| [15] | WEI Xiaocheng, LI Xinrong, HE Jungang, LI Xu, QIANG Zhengze, WANG Yan, WANG Mingwei, LI Chengyi. Research progress on antitumor effects of Hedysari radix and active components [J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2025, 30(8): 1112-1121. |
| Viewed | ||||||
|
Full text |
|
|||||
|
Abstract |
|
|||||