ABSTRACT
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.
Subject(s)
Animals , Rabbits , Adipocytes , Anterior Cruciate Ligament Reconstruction , Fibrin Tissue Adhesive/therapeutic use , Stem CellsABSTRACT
O objetivo deste estudo foi avaliar o reparo da cartilagem hialina equina, por meio de análises macroscópica (através de videoartroscopia) e histológica (através de fragmentos de biopsia), em defeitos condrais induzidos na tróclea lateral do fêmur tratados pela técnica de microperfurações subcondral associada ou não com administração intra-articular de cartogenina. Foram utilizados seis equinos pesando em média (±DP) 342±1,58 kg, com a idade aproximada de 7,2±1,30 anos e escore corporal de 7,1±0,75, que foram submetidos a videoartroscopia para indução da lesão condral de 1 cm2 na tróclea lateral do fêmur e realização da técnica de microperfuração do osso subcondral de ambos os joelhos. Foram realizadas quatro aplicações semanais com 20 μM de cartogenina intra-articulares em um dos joelhos (grupo tratado) e solução de ringer com lactato na articulação contralateral (grupo controle). Após o período de 60 dias, foram feitas as avaliações macroscópicas, através de videoartroscopias, e histológicas, através de biopsia. Não foram observadas diferenças significativas nos escores macroscópicos e histológicos para reparação condral entre animais dos grupos tratados e não tratados (P>0,05). De modo geral, a porcentagem média de cartilagem hialina no tecido de reparo (17,5%) foi condizente com a literatura internacional usando outros tipos de perfuração condral. Entretanto, não se observaram diferenças estatísticas entre grupos (P>0,05). A terapia com cartogenina, segundo protocolo utilizado, não produziu melhora do processo cicatricial em lesões condrais induzidas e tratadas com microperfurações na tróclea lateral do fêmur em equinos.
The aim of this study was to evaluate the joint cartilage repair by macroscopic (via arthroscopy) and histological (biopsy fragments) analyses in chondral defects induced into equine femoral trochlea treated by microperforation associated with or without intra-articular administration of kartogenin. Six horses weighing 342±1.58 kg (mean ± SD), aged approximately 7.2±1.30 years and with a body condition score of 7.1±0.75, were used. The horses underwent arthroscopy for induction of 1-cm2 chondral lesions in lateral femoral trochlea immediately treated by microperforation of the subchondral bone of both knees. Four weekly intra-articular injections of kartogenin (20μM) in one knee (treated group) and Ringer lactate solution in the contralateral joint (control group) were performed during the postoperative period. After 60 days, macroscopic evaluations were performed by video-arthroscopy, and biopsy samples of the repair tissue were taken for histopathological healing evaluation. No significant change was observed in macroscopic and histological scores for chondral healing between treated and untreated groups (P>0.05). The overall mean percentage of hyaline cartilage in both groups (17.5%) was consistent with other international studies using other types of chondral microperforation; however, no statistical differences were observed between groups (P>0.05). In conclusion, the therapy with kartogenin, according to the used protocol, did not produce any macroscopic and histological healing improvement in induced chondral lesions treated with microperforations in equine femoral trochlea.
Subject(s)
Animals , Cell Self Renewal/physiology , Hyaline Cartilage/surgery , Hyaline Cartilage/pathology , Horses/surgery , Cartilage, Articular/surgery , Cartilage, Articular/injuries , Osteoarthritis/veterinary , Histological Techniques/veterinaryABSTRACT
As a degenerative disease caused by multiple factors, osteoarthritis is characterized by articular cartilage degeneration and reactive hyperplasia of joint edge and the subchondral bone. Recently, kartogenin (KGN) was identified to promote chondrocyte differentiation. KGN can block interleukin 1β(IL-1β)-caused loss of extracellular matrix and proteoglycan. Transforming growth factor β1(TGF-β1), bone morphogenetic protein 7(BMP-7), and KGN together can synergistically promote the expression of lubricin in chondrocytes. KGN can also induce cartilage-like tissue formation in tendon-bone junction. In addition, chitosan (CHI)-KGN nanoparticles and CHI-KGN microspheres can more effectively induce chondrogenic differentiation than unconjugated KGN. Here in this paper we summarized the roles of KGN in regulating the cartilage regeneration.