EXPERIMENTAL STUDY ON DIFFERENT CONCENTRATION RATIOS OF OSTEOPROTEGERIN COMBINED WITH DEPROTEINIZED BONE ON BONE TUNNEL AFTER ANTERIOR CRUCIATE LIGAMENT RECONSTRUCTION_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

WEIBing ,  ZOUGuoyao , SONGEnhong , GUANLincong

Department of Spinal and Osteopathy Surgery, Affiliated Hospital, Guilin Medical College, Guilin Guangxi, 541001, P. R. China;

Corresponding author：

ZOUGuoyao, Email: zhouguoyao2000@aliyun.com

Keywords：

Anterior cruciate ligament; Osteoprotegerin; Deproteinized bone; Bone tunnel; Biomechanics; Rabbit

DOI：

10.7507/1002-1892.20150295

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Objective To investigate the effects of different concentrations of osteoprotegerin (OPG) combined with deproteinized bone (DPB) on the bone tunnel after the anterior cruciate ligament (ACL) reconstruction. Methods The femoral epiphyseal side was harvested from newborn calf, and allogenic DPB were prepared by hydrogen peroxide-chloroform/methanol method. Then, DPB were immersed in 3 concentrations levels of OPG (30, 60, 100 μg/mL) and 3 concentration ratios (30%, 60%, 100%) of the gel complex were prepared. Sixty healthy New Zealand white rabbits, male or female, weighing (2.7±0.4) kg, were divided randomly into 4 groups (n=15):control group (group A), 30% (group B), 60% (group C), and 100% (group D) OPG/DPB gel complex. The ACL reconstruction models were established by autologous Achilles tendon. Different ratios of OPG/DPB gel complex were implanted in the femoral and tibial bone tunnel of groups B, C, and D, but group A was not treated. The pathology observation (including the percentage of the femoral bone tunnel enlargement) and histological observation were performed and the biomechanical properties were measured at 4, 8, and 12 weeks after operation. Results One rabbit died of infection in groups A and D, 2 rabbits in groups B and C respectively, and were added. General pathology observation showed that the internal orifices of the femoral and tibia tunnels were covered by a little of scar tissue at 4 weeks in all groups. At 8 weeks, white chondroid tissues were observed around the internal orifices of the femoral and tibia tunnels, especially in groups C and D. At 12 weeks, the internal orifices of the femoral and tibia tunnels enlarged in groups A, B, and C, but it was completely closed in group D. At each time point, the rates of the femoral bone tunnel enlargement in groups B, C, and D were significantly lower than that in group A, and group D was significantly lower than groups B and C (P<0.05); group C was significantly lower than group B at 8 weeks, but no significant difference was found at 4 and 12 weeks (P<0.05). Hisological observation showed that fresh fibrous connective tissue was observed in 4 groups at 4 weeks; there was various arrangements of Sharpey fiber in all groups at 8 weeks and the atypical 4-layer structure of bone was seen in group D; at 12 weeks, Sharpey fiber arranged regularly in all groups, with typical 4-layer structure of bone in groups B, C, and D, and an irregular "tidal line" formed, especially in group D. Biomechanics measurement showed that the maximum tensile load in group D was significantly higher than that in groups A and B at 4 weeks (P<0.05), but no significant difference was shown among groups A, B, and C, and between groups C and D (P>0.05); at 8 weeks, it was significantly higher in groups C and group D than group A, and in group D than group B (P<0.05), but there was no significant difference between groups A, C and group B (P>0.05); at 12 weeks, it was significantly higher in groups C and D than groups A and B, and in group D than group C (P<0.05), but difference was not significant between groups A and B (P>0.05). Conclusion Different concentrations ratios of OPG/DPB gel complexes have different effects on the bone tunnel after ACL reconstruction. 100% OPG/DPB gel complex has significant effects to prevent the enlargement of bone tunnel and to enhance tendon bone healing.

Citation： WEIBing, ZOUGuoyao, SONGEnhong, GUANLincong. EXPERIMENTAL STUDY ON DIFFERENT CONCENTRATION RATIOS OF OSTEOPROTEGERIN COMBINED WITH DEPROTEINIZED BONE ON BONE TUNNEL AFTER ANTERIOR CRUCIATE LIGAMENT RECONSTRUCTION. Chinese Journal of Reparative and Reconstructive Surgery, 2015, 29(11): 1369-1375. doi: 10.7507/1002-1892.20150295 Copy

1.	da Silveira Franciozi CE, Ingham SJ, Gracitelli GC, et al. Updates in biological therapies for knee injuries:anterior cruciate ligament. Curr Rev Musculoskelet Med, 2014, 7(3):228-238.
2.	Gadikota HR, Seon JK, Chen CH, et al. In vitro and intraoperative laxities after single-bundle and double-bundle anterior cruciate ligament reconstructions. Arthroscopy, 2011, 27(6):849-860.
3.	Zhao H, Liu X, Zou H, et al. Osteoprotegerin induces podosome disassembly in osteoclasts through calcium, ERK, and p38 MAPK signaling pathways. Cytokine, 2015, 71(2):199-206.
4.	Baharuddin NA, Coates DE, Cullinan M, et al. Localization of RANK, RANKL and osteoprotegerin during healing of surgically created periodontal defects in sheep. J Periodontal Res, 2015, 50(2):211-219.
5.	Kim JG, Kim HJ, Kim SE, et al. Enhancement of tendon-bone healing with the use of bone morphogenetic protein-2 inserted into the suture anchor hole in a rabbit patellar tendon model. Cytotherapy, 2014, 16(6):857-867.
6.	Zhai W, Lv C, Zheng Y, et al. Weak link of tendon-bone healing and a control experiment to promote healing. Arch Orthop Trauma Surg, 2013, 133(11):1533-1541.
7.	缪旭东, 裴国献, 闫乔生, 等. 同种异体脱蛋白骨复合纤维蛋白胶体内构建组织工程骨. 中国组织工程研究, 2013, 17(16):2869-2873.
8.	Dynybil C, Kawamura S, Kim HJ, et al. The effect of osteoprotegerin on tendon-bone healing after reconstruction of the anterior cruciate ligament:a histomorphological and radiographical study in the rabbit. Z Orthop Ihre Grenzgeb, 2006, 144(2):179-186.
9.	赵耀, 翟文亮. 富血小板血浆复合小牛脱蛋白骨重建前交叉韧带腱-骨愈合的组织学观察. 中国修复重建外科杂志, 2010, 24(11):1323-1329.
10.	邹国耀, 宋恩鸿, 李张. 股骨隧道角度对兔前交叉韧带重建术后骨隧道影响的初步探讨. 中国修复重建外科杂志, 2015, 29(2):171-174.
11.	Webster KE, Chiu JJ, Feller JA. Impact of measurement error in the analysis of bone tunnel enlargement after anterior cruciate ligament reconstruction. Am J Sports Med, 2005, 33(11):1680-1687.
12.	Kanazawa T, Soejima T, Noquchi K, et al. Tendon-to-bone healing using autologous bone marrow-derived mesenchymal stem cells in ACL reconstruction without a tibial bone tunnel-A histological study. Muscles Ligaments Tendons J, 2014, 4(2):201-206.
13.	Kuang GM, Yau WP, Lu WW, et al. Local application of strontium in a calcium phosphate cement system accelerates healing of soft tissue tendon grafts in anterior cruciate ligament reconstruction:experiment using a rabbit model. Am J Sports Med, 2014, 42(12):2996-3002.
14.	Oka S, Matsumoto T, Kubo S, et al. Local administration of lowdose simvastatin-conjugated gelatin hydrogel for tendon-bone healing in anterior cruciate ligament reconstruction. Tissue Eng Part A, 2013, 19(9-10):1233-1243.
15.	Takigami J, Hashimoto Y, Yamasaki S, et al. Direct bone-to-bone integration between recombinant human bone morphogenetic protein-2-injected tendon graft and tunnel wall in an anterior cruciate ligament reconstruction model. Int Orthop, 2015, 39(7):1441-1447.
16.	李宁, 张义龙, 李淑英, 等. 骨髓单个核细胞促进腱骨愈合的生物力学测试. 重庆医学, 2012, 41(5):463-465.
17.	Weiler A, Förster C, Hunt P, et al. The influence of locally applied platelet-derived growth factor-BB on free tendon graft remodeling after anterior cruciate ligament reconstruction. Am J Sports Med, 2004, 32(4):881-891.
18.	Cameron ML, Fu FH, Paessler HH, et al. Synovial fluid cytokine concentrations as possible prognostic indicators in the ACLdeficient knee. Knee Surg Sports Traumatol Arthrosc, 1994, 2(1):38-44.
19.	翟文亮, 吕辰玮, 丁真奇, 等. 富血小板血浆与脱蛋白骨复合物能增强早期腱-骨界面的愈合. 中国组织工程研究与临床康复, 2011, 15(51):9505-9508.
20.	Weimin P, Dan L, Yiyong W, et al. Tendon-to-bone healing using an injectable calcium phosphate cement combined with bone xenograft/BMP composite. Biomaterials, 2013, 34(38):9926-9936.

1. da Silveira Franciozi CE, Ingham SJ, Gracitelli GC, et al. Updates in biological therapies for knee injuries:anterior cruciate ligament. Curr Rev Musculoskelet Med, 2014, 7(3):228-238.
2. Gadikota HR, Seon JK, Chen CH, et al. In vitro and intraoperative laxities after single-bundle and double-bundle anterior cruciate ligament reconstructions. Arthroscopy, 2011, 27(6):849-860.
3. Zhao H, Liu X, Zou H, et al. Osteoprotegerin induces podosome disassembly in osteoclasts through calcium, ERK, and p38 MAPK signaling pathways. Cytokine, 2015, 71(2):199-206.
4. Baharuddin NA, Coates DE, Cullinan M, et al. Localization of RANK, RANKL and osteoprotegerin during healing of surgically created periodontal defects in sheep. J Periodontal Res, 2015, 50(2):211-219.
5. Kim JG, Kim HJ, Kim SE, et al. Enhancement of tendon-bone healing with the use of bone morphogenetic protein-2 inserted into the suture anchor hole in a rabbit patellar tendon model. Cytotherapy, 2014, 16(6):857-867.
6. Zhai W, Lv C, Zheng Y, et al. Weak link of tendon-bone healing and a control experiment to promote healing. Arch Orthop Trauma Surg, 2013, 133(11):1533-1541.
7. 缪旭东, 裴国献, 闫乔生, 等. 同种异体脱蛋白骨复合纤维蛋白胶体内构建组织工程骨. 中国组织工程研究, 2013, 17(16):2869-2873.
8. Dynybil C, Kawamura S, Kim HJ, et al. The effect of osteoprotegerin on tendon-bone healing after reconstruction of the anterior cruciate ligament:a histomorphological and radiographical study in the rabbit. Z Orthop Ihre Grenzgeb, 2006, 144(2):179-186.
9. 赵耀, 翟文亮. 富血小板血浆复合小牛脱蛋白骨重建前交叉韧带腱-骨愈合的组织学观察. 中国修复重建外科杂志, 2010, 24(11):1323-1329.
10. 邹国耀, 宋恩鸿, 李张. 股骨隧道角度对兔前交叉韧带重建术后骨隧道影响的初步探讨. 中国修复重建外科杂志, 2015, 29(2):171-174.
11. Webster KE, Chiu JJ, Feller JA. Impact of measurement error in the analysis of bone tunnel enlargement after anterior cruciate ligament reconstruction. Am J Sports Med, 2005, 33(11):1680-1687.
12. Kanazawa T, Soejima T, Noquchi K, et al. Tendon-to-bone healing using autologous bone marrow-derived mesenchymal stem cells in ACL reconstruction without a tibial bone tunnel-A histological study. Muscles Ligaments Tendons J, 2014, 4(2):201-206.
13. Kuang GM, Yau WP, Lu WW, et al. Local application of strontium in a calcium phosphate cement system accelerates healing of soft tissue tendon grafts in anterior cruciate ligament reconstruction:experiment using a rabbit model. Am J Sports Med, 2014, 42(12):2996-3002.
14. Oka S, Matsumoto T, Kubo S, et al. Local administration of lowdose simvastatin-conjugated gelatin hydrogel for tendon-bone healing in anterior cruciate ligament reconstruction. Tissue Eng Part A, 2013, 19(9-10):1233-1243.
15. Takigami J, Hashimoto Y, Yamasaki S, et al. Direct bone-to-bone integration between recombinant human bone morphogenetic protein-2-injected tendon graft and tunnel wall in an anterior cruciate ligament reconstruction model. Int Orthop, 2015, 39(7):1441-1447.
16. 李宁, 张义龙, 李淑英, 等. 骨髓单个核细胞促进腱骨愈合的生物力学测试. 重庆医学, 2012, 41(5):463-465.
17. Weiler A, Förster C, Hunt P, et al. The influence of locally applied platelet-derived growth factor-BB on free tendon graft remodeling after anterior cruciate ligament reconstruction. Am J Sports Med, 2004, 32(4):881-891.
18. Cameron ML, Fu FH, Paessler HH, et al. Synovial fluid cytokine concentrations as possible prognostic indicators in the ACLdeficient knee. Knee Surg Sports Traumatol Arthrosc, 1994, 2(1):38-44.
19. 翟文亮, 吕辰玮, 丁真奇, 等. 富血小板血浆与脱蛋白骨复合物能增强早期腱-骨界面的愈合. 中国组织工程研究与临床康复, 2011, 15(51):9505-9508.
20. Weimin P, Dan L, Yiyong W, et al. Tendon-to-bone healing using an injectable calcium phosphate cement combined with bone xenograft/BMP composite. Biomaterials, 2013, 34(38):9926-9936.

Chinese Journal of Reparative and Reconstructive Surgery

EXPERIMENTAL STUDY ON DIFFERENT CONCENTRATION RATIOS OF OSTEOPROTEGERIN COMBINED WITH DEPROTEINIZED BONE ON BONE TUNNEL AFTER ANTERIOR CRUCIATE LIGAMENT RECONSTRUCTION

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