Effect of Kartogenin combined with adipose-derived stem cells on tendon-bone healing after anterior cruciate ligament reconstruction_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

CHEN Gang , ZHENG Qian , LIU Mengfei , HE Haiyang ,  JU Xiaochen , JIANG Kan

Department of Joint Surgery, the Sixth Affiliated Hospital of Xinjiang Medical University, Urumqi Xinjiang, 830000, P. R. China;

Corresponding author：

JU Xiaochen, Email: 31841528@qq.com

Keywords：

Kartogenin; adipose-derived stem cells; anterior cruciate ligament reconstruction; tendon-bone healing; rabbit

DOI：

10.7507/1002-1892.202305011

Video：

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Objective To investigate the effect of Kartogenin (KGN) combined with adipose-derived stem cells (ADSCs) on tendon-bone healing after anterior cruciate ligament (ACL) reconstruction in rabbits. Methods After the primary ADSCs were cultured by passaging, the 3rd generation cells were cultured with 10 μmol/L KGN solution for 72 hours. The supernatant of KGN-ADSCs was harvested and mixed with fibrin glue at a ratio of 1∶1; the 3rd generation ADSCs were mixed with fibrin glue as a control. Eighty adult New Zealand white rabbits were taken and randomly divided into 4 groups: saline group (group A), ADSCs group (group B), KGN-ADSCs group (group C), and sham-operated group (group D). After the ACL reconstruction model was prepared in groups A-C, the saline, the mixture of ADSCs and fibrin glue, and the mixture of supernatant of KGN-ADSCs and fibrin glue were injected into the tendon-bone interface and tendon gap, respectively. ACL was only exposed without other treatment in group D. The general conditions of the animals were observed after operation. At 6 and 12 weeks, the tendon-bone interface tissues and ACL specimens were taken and the tendon-bone healing was observed by HE staining, c-Jun N-terminal kinase (JNK) immunohistochemical staining, and TUNEL apoptosis assay. The fibroblasts were counted, and the positive expression rate of JNK protein and apoptosis index (AI) were measured. At the same time point, the tensile strength test was performed to measure the maximum load and the maximum tensile distance to observe the biomechanical properties. Results Twenty-eight rabbits were excluded from the study due to incision infection or death, and finally 12, 12, 12, and 16 rabbits in groups A-D were included in the study, respectively. After operation, the tendon-bone interface of groups A and B healed poorly, while group C healed well. At 6 and 12 weeks, the number of fibroblasts and positive expression rate of JNK protein in group C were significantly higher than those of groups A, B, and D (P<0.05). Compared with 6 weeks, the number of fibroblasts gradually decreased and the positive expression rate of JNK protein and AI decreased in group C at 12 weeks after operation, with significant differences (P<0.05). Biomechanical tests showed that the maximum loads at 6 and 12 weeks after operation in group C were higher than in groups A and B, but lower than those in group D, while the maximum tensile distance results were opposite, but the differences between groups were significant (P<0.05). Conclusion After ACL reconstruction, local injection of a mixture of KGN-ADSCs and fibrin glue can promote the tendon-bone healing and enhance the mechanical strength and tensile resistance of the tendon-bone interface.

Citation： CHEN Gang, ZHENG Qian, LIU Mengfei, HE Haiyang, JU Xiaochen, JIANG Kan. Effect of Kartogenin combined with adipose-derived stem cells on tendon-bone healing after anterior cruciate ligament reconstruction. Chinese Journal of Reparative and Reconstructive Surgery, 2023, 37(8): 1002-1010. doi: 10.7507/1002-1892.202305011 Copy

1.	汤义民, 陶钧, 董斌, 等. 关节镜下前交叉韧带重建术的手术时机对患者膝关节功能恢复的影响. 现代生物医学进展, 2019, 19(4): 755-758, 788.
2.	Matsumoto T, Takayama K, Hayashi S, et al. Therapeutic potential of vascular stem cells for anterior cruciate ligament reconstruction. Ann Transl Med, 2019, 7(Suppl 8): S286.
3.	Tajima T, Yamaguchi N, Nagasawa M, et al. Early weight-bearing after anterior cruciate ligament reconstruction with hamstring grafts induce femoral bone tunnel enlargement: a prospective clinical and radiographic study. BMC Musculoskelet Disord, 2019, 20(1): 274.
4.	Dini F, Tecame A, Ampollini A, et al. Multiple ACL revision: Failure analysis and clinical outcomes. J Knee Surg, 2021, 34(8): 801-809.
5.	张培, 刘泉, 吴敏, 等. TGF-β₁、bFGF对自体腘绳肌腱重建前交叉韧带腱-骨愈合的影响. 中华全科医学, 2020, 18(1): 30-33.
6.	魏钰, 运行, 李众利, 等. 前交叉韧带重建失败的原因分析. 中国矫形外科杂志, 2021, 29(16): 1461-1465.
7.	孙畅, 郭亭, 李林涛, 等. 前交叉韧带重建术后腱骨愈合的生物学干预研究进展. 中华骨与关节外科杂志, 2020, 13(10): 863-869.
8.	辜刘伟, 周霖, 庹伟, 等. 促进膝关节前交叉韧带重建术后腱骨愈合方法的研究进展. 中国现代医学杂志, 2021, 31(23): 49-56.
9.	Feng W, Jin Q, Ming-Yu Y, et al. MiR-6924-5p-rich exosomes derived from genetically modified Scleraxis-overexpressing PDGFRα(+) BMMSCs as novel nanotherapeutics for treating osteolysis during tendon-bone healing and improving healing strength. Biomaterials, 2021, 279: 121242.
10.	熊波涵, 余洋, 卢晓君, 等. 促进前交叉韧带重建腱骨愈合的研究与进展. 中国组织工程研究, 2023, 27(5): 779-786.
11.	Mostafa S, Pakvasa M, Coalson E, et al. The wonders of BMP9: From mesenchymal stem cell differentiation, angiogenesis, neurogenesis, tumorigenesis, and metabolism to regenerative medicine. Genes Dis, 2019, 6(3): 201-223.
12.	Ma XF, Ma XB, Qian WJ, et al. Co-culture of adipose-derived stem cells and chondrocytes with transforming growth factor-beta 3 promotes chondrogenic differentiation. J Craniofac Surg, 2020, 31(8): 2355-2359.
13.	朱亮, 林享玉, 何晶. 脂肪干细胞在皮肤损伤再生及组织工程中的应用及进展. 解剖学杂志, 2021, 44(5): 433-437.
14.	张栋鑫, 肖丽玲. 脂肪干细胞联合水凝胶材料在组织工程中的研究进展及前景. 国际生物医学工程杂志, 2021, 44(4): 323-328.
15.	李庆标, 罗惠慈, 戴冠东. Kartogenin对肩袖止点腱骨愈合的干预作用及机制研究. 心电图杂志(电子版), 2017, 6(2): 179-182.
16.	Kosaka M, Nakase J, Hayashi K, et al. Adipose-derived regenerative cells promote tendon-bone healing in a rabbit model. Arthroscopy, 2016, 32(5): 851-859.
17.	徐文悦, 赵娜, 王燕, 等. 脂肪干细胞用于肌腱损伤修复研究进展. 动物医学进展, 2023, 44(3): 99-103.
18.	丁伟, 谭洪波. KGN修复软骨、促进腱-骨愈合作用的研究进展. 山东医药, 2017, 57(16): 102-104.
19.	Zhang J, Wang JH. Kartogenin induces cartilage-like tissue formation in tendon-bone junction. Bone Res, 2014, 2: 14008.
20.	杨德勇, 凯沙尔·百合提亚尔, 姜钧耀, 等. 局部注射肝细胞生长因子基因修饰的骨髓间充质干细胞对兔前交叉韧带重建后腱骨愈合的影响. 中国医药导报, 2022, 19(35): 28-31.
21.	马子越, 巨啸晨, 张磊, 等. 保留与不保留残端重建前交叉韧带后移植物腱骨愈合的比较. 中国组织工程研究, 2021, 25(4): 582-587.
22.	舒莉, 柴浩, 巨啸晨, 等. 鞘内保残重建术与牵张保残重建术对兔前交叉韧带残端成纤维细胞增殖、凋亡的影响. 山东医药, 2019, 59(13): 35-38.
23.	Oh JH, Chung SW, Kim SH, et al. 2013 Neer Award: Effect of the adipose-derived stem cell for the improvement of fatty degeneration and rotator cuff healing in rabbit model. J Shoulder Elbow Surg, 2014, 23(4): 445-455.
24.	赖文涛, 张晓璐, 张春阳, 等. 脂肪干细胞转染Bmp2后成骨能力变化的研究. 生物骨科材料与临床研究, 2022, 19(1): 15-19.
25.	张诗晨, 金丽鸥, 李跃, 等. kartogenin对骨关节炎的治疗作用机制及其在软骨组织工程学中应用的研究进展. 吉林大学学报 (医学版), 2021, 47(2): 519-527.
26.	Ren E, Chen H, Qin Z, et al. Harnessing bifunctional ferritin with Kartogenin loading for mesenchymal stem cell capture and enhancing chondrogenesis in cartilage regeneration. Adv Healthc Mater, 2022, 11(8): e2101715.
27.	Xu X, Shi D, Shen Y, et al. Full-thickness cartilage defects are repaired via a microfracture technique and intraarticular injection of the small-molecule compound kartogenin. Arthritis Res Ther, 2015, 17(1): 20.
28.	Advancements in the treatment options for shoulder problems [Z/OL]. [2023-07-26]. https: //biospectrumindia.com/ article/pdf/21372.
29.	Wang R, Xu B, Xu HG. Up-regulation of TGF-β promotes tendon-to-bone healing after anterior cruciate ligament reconstruction using bone marrow-derived mesenchymal stem cells through the TGF-β/MAPK signaling pathway in a New Zealand white rabbit model. Cell Physiol Biochem, 2017, 41(1): 213-226.
30.	Gimble JM, Katz AJ, Bunnell BA. Adipose-derived stem cells for regenerative medicine. Circ Res, 2007, 100(9): 1249-1260.
31.	Valencia Mora M, Antuña Antuña S, García Arranz M, et al. Application of adipose tissue-derived stem cells in a rat rotator cuff repair model. Injury, 2014, 45 Suppl 4: S22-S27.
32.	Skutek M, van Griensven M, Zeichen J, et al. Cyclic mechanical stretching of human patellar tendon fibroblasts: activation of JNK and modulation of apoptosis. Knee Surg Sports Traumatol Arthrosc, 2003, 11(2): 122-129.

1. 汤义民, 陶钧, 董斌, 等. 关节镜下前交叉韧带重建术的手术时机对患者膝关节功能恢复的影响. 现代生物医学进展, 2019, 19(4): 755-758, 788.
2. Matsumoto T, Takayama K, Hayashi S, et al. Therapeutic potential of vascular stem cells for anterior cruciate ligament reconstruction. Ann Transl Med, 2019, 7(Suppl 8): S286.
3. Tajima T, Yamaguchi N, Nagasawa M, et al. Early weight-bearing after anterior cruciate ligament reconstruction with hamstring grafts induce femoral bone tunnel enlargement: a prospective clinical and radiographic study. BMC Musculoskelet Disord, 2019, 20(1): 274.
4. Dini F, Tecame A, Ampollini A, et al. Multiple ACL revision: Failure analysis and clinical outcomes. J Knee Surg, 2021, 34(8): 801-809.
5. 张培, 刘泉, 吴敏, 等. TGF-β₁、bFGF对自体腘绳肌腱重建前交叉韧带腱-骨愈合的影响. 中华全科医学, 2020, 18(1): 30-33.
6. 魏钰, 运行, 李众利, 等. 前交叉韧带重建失败的原因分析. 中国矫形外科杂志, 2021, 29(16): 1461-1465.
7. 孙畅, 郭亭, 李林涛, 等. 前交叉韧带重建术后腱骨愈合的生物学干预研究进展. 中华骨与关节外科杂志, 2020, 13(10): 863-869.
8. 辜刘伟, 周霖, 庹伟, 等. 促进膝关节前交叉韧带重建术后腱骨愈合方法的研究进展. 中国现代医学杂志, 2021, 31(23): 49-56.
9. Feng W, Jin Q, Ming-Yu Y, et al. MiR-6924-5p-rich exosomes derived from genetically modified Scleraxis-overexpressing PDGFRα(+) BMMSCs as novel nanotherapeutics for treating osteolysis during tendon-bone healing and improving healing strength. Biomaterials, 2021, 279: 121242.
10. 熊波涵, 余洋, 卢晓君, 等. 促进前交叉韧带重建腱骨愈合的研究与进展. 中国组织工程研究, 2023, 27(5): 779-786.
11. Mostafa S, Pakvasa M, Coalson E, et al. The wonders of BMP9: From mesenchymal stem cell differentiation, angiogenesis, neurogenesis, tumorigenesis, and metabolism to regenerative medicine. Genes Dis, 2019, 6(3): 201-223.
12. Ma XF, Ma XB, Qian WJ, et al. Co-culture of adipose-derived stem cells and chondrocytes with transforming growth factor-beta 3 promotes chondrogenic differentiation. J Craniofac Surg, 2020, 31(8): 2355-2359.
13. 朱亮, 林享玉, 何晶. 脂肪干细胞在皮肤损伤再生及组织工程中的应用及进展. 解剖学杂志, 2021, 44(5): 433-437.
14. 张栋鑫, 肖丽玲. 脂肪干细胞联合水凝胶材料在组织工程中的研究进展及前景. 国际生物医学工程杂志, 2021, 44(4): 323-328.
15. 李庆标, 罗惠慈, 戴冠东. Kartogenin对肩袖止点腱骨愈合的干预作用及机制研究. 心电图杂志(电子版), 2017, 6(2): 179-182.
16. Kosaka M, Nakase J, Hayashi K, et al. Adipose-derived regenerative cells promote tendon-bone healing in a rabbit model. Arthroscopy, 2016, 32(5): 851-859.
17. 徐文悦, 赵娜, 王燕, 等. 脂肪干细胞用于肌腱损伤修复研究进展. 动物医学进展, 2023, 44(3): 99-103.
18. 丁伟, 谭洪波. KGN修复软骨、促进腱-骨愈合作用的研究进展. 山东医药, 2017, 57(16): 102-104.
19. Zhang J, Wang JH. Kartogenin induces cartilage-like tissue formation in tendon-bone junction. Bone Res, 2014, 2: 14008.
20. 杨德勇, 凯沙尔·百合提亚尔, 姜钧耀, 等. 局部注射肝细胞生长因子基因修饰的骨髓间充质干细胞对兔前交叉韧带重建后腱骨愈合的影响. 中国医药导报, 2022, 19(35): 28-31.
21. 马子越, 巨啸晨, 张磊, 等. 保留与不保留残端重建前交叉韧带后移植物腱骨愈合的比较. 中国组织工程研究, 2021, 25(4): 582-587.
22. 舒莉, 柴浩, 巨啸晨, 等. 鞘内保残重建术与牵张保残重建术对兔前交叉韧带残端成纤维细胞增殖、凋亡的影响. 山东医药, 2019, 59(13): 35-38.
23. Oh JH, Chung SW, Kim SH, et al. 2013 Neer Award: Effect of the adipose-derived stem cell for the improvement of fatty degeneration and rotator cuff healing in rabbit model. J Shoulder Elbow Surg, 2014, 23(4): 445-455.
24. 赖文涛, 张晓璐, 张春阳, 等. 脂肪干细胞转染Bmp2后成骨能力变化的研究. 生物骨科材料与临床研究, 2022, 19(1): 15-19.
25. 张诗晨, 金丽鸥, 李跃, 等. kartogenin对骨关节炎的治疗作用机制及其在软骨组织工程学中应用的研究进展. 吉林大学学报 (医学版), 2021, 47(2): 519-527.
26. Ren E, Chen H, Qin Z, et al. Harnessing bifunctional ferritin with Kartogenin loading for mesenchymal stem cell capture and enhancing chondrogenesis in cartilage regeneration. Adv Healthc Mater, 2022, 11(8): e2101715.
27. Xu X, Shi D, Shen Y, et al. Full-thickness cartilage defects are repaired via a microfracture technique and intraarticular injection of the small-molecule compound kartogenin. Arthritis Res Ther, 2015, 17(1): 20.
28. Advancements in the treatment options for shoulder problems [Z/OL]. [2023-07-26]. https: //biospectrumindia.com/ article/pdf/21372.
29. Wang R, Xu B, Xu HG. Up-regulation of TGF-β promotes tendon-to-bone healing after anterior cruciate ligament reconstruction using bone marrow-derived mesenchymal stem cells through the TGF-β/MAPK signaling pathway in a New Zealand white rabbit model. Cell Physiol Biochem, 2017, 41(1): 213-226.
30. Gimble JM, Katz AJ, Bunnell BA. Adipose-derived stem cells for regenerative medicine. Circ Res, 2007, 100(9): 1249-1260.
31. Valencia Mora M, Antuña Antuña S, García Arranz M, et al. Application of adipose tissue-derived stem cells in a rat rotator cuff repair model. Injury, 2014, 45 Suppl 4: S22-S27.
32. Skutek M, van Griensven M, Zeichen J, et al. Cyclic mechanical stretching of human patellar tendon fibroblasts: activation of JNK and modulation of apoptosis. Knee Surg Sports Traumatol Arthrosc, 2003, 11(2): 122-129.

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Effect of Kartogenin combined with adipose-derived stem cells on tendon-bone healing after anterior cruciate ligament reconstruction

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