Kartogenin Enhances Tendon Graft And Bone Tunnel Healing In A Rat Model

Category: Basic Sciences/Biologics Introduction/Purpose: The normal tendon-bone junction (TBJ) is a strong structure protected by the fibrocartilage transition zone. This allows a gradual transition of mechanical forces between tendon and bone, thus decreasing stress-concentration effects. Healing of the TBJ interface after an injury is slow and even after healing the junction often lacks the transition zone. A study on human patients showed that even years after ACL reconstruction, patients had no fibrocartilage zone regeneration. This and other studies show that surgical repair alone does not restore the unique protective fibrocartilage transition zone. We have shown that KGN injection into injured rat Achilles tendon-bone junctions enhanced wound healing with restored fibrocartilage transition zone. Here, we examined the effects of KGN treatment, along with platelet-rich plasma (PRP), on tendon-bone tunnel healing in rats. Methods: KGN stock was prepared in DMSO and diluted to 100 μM with PRP. PRP was obtained from the blood of Sprague– Dawley rats and the platelet concentration in PRP was adjusted to 3 times over the baseline platelet concentration in whole blood. Thrombin (1 kU/mL), served as the PRP activator. 27 female rats (234˜268g) were used. A 1.5 mm tunnel was drilled at the distal end of tibia. Achilles tendon was resected and sutured in the tunnel. Rats were randomly divided into 1 of 3 treatment groups: Group A: 50µl KGN + PRP; Group B: 50µl PRP solution; Group C: control. Rats were sacrificed at 4, 8, and 12 weeks for histological analysis. Whole tibia with the tendon insertion were harvested, fixed in 10% formalin and decalcified in 10% EDTA. Tissue were sectioned and stained with Safranin O + Fast green, and immunostained for collagen types 1 and 2. Results: All animals were in good condition after surgery and complications were not present. Safranin O staining was higher in the KGN+PRP group than the other groups indicating more cartilage-like tissues regeneration in this group. Formation of the cartilage-like transitional zone was time dependent; i.e., it increased with increase in time (Fig. 1A-C). In contrast, both PRP and control groups had no cartilage-like tissues (Fig. 1D-I); in fact, some gaps in the control group were found in the tendon-bone interface after 4 and 8 weeks (Fig. 1G-I). Finally, the cartilage-like tissues in the KGN+PRP group also stained positive for both Col-1 and Col-2 indicating that these were fibrocartilage tissues (Fig. 2). Conclusion: Here we demonstrated that KGN promotes the formation of fibrocartilage-like interface between the tendon graft and bone tunnel. This result suggests that the delivery of KGN into the tendon-bone interface could be a promising, cell-free approach to augment the tendon-bone interface healing. PRP in this study, while not effective in promoting fibrocartilage formation of the interface in its own right, it functions as an effective carrier that supplies scaffolds and growth factors necessary for the enhancement of wound healing. Future research is required to determine the optimal KGN dosage regimens and the optimal delivery method (e.g. injection vs implantation)

Kartogenin

Category: Basic Sciences/Biologics Introduction/Purpose: Tendon-bone junction (TBJ) injuries are very common and optimal treatment modalities are lacking. TBJ injuries often heal without formation of the fibrocartilage transition zone increasing the risk of rerupture. Current treatments only attach tendons to bones but do not promote healing or regeneration of the fibrocartilage zone. Therefore, we developed a novel approach to heal wounded TBJ using a small molecule called kartogenin (KGN). KGN was previously shown to induce chondrogenesis of tendon stem/progenitor cells (TSCs) in vitro and enhance wound healing in injured rat TBJs in vivo after short- term treatment (2 weeks). It is not known whether these effects can be maintained longterm. Therefore, we studied the long term (3 months) effects of KGN on achilles-tendon-bone junction healing. Methods: KGN stock was prepared in DMSO and diluted to 100 μM with PRP solution. PRP was obtained from the blood of Sprague–Dawley rats and the platelet concentration in PRP was adjusted to 3 times higher than that in whole blood. Thrombin (10 kU/ml) served as the PRP activator. 42 female rats (2.5 – 3 months old) were used. 1 mm diameter defects were created at the Achilles tendon-bone junction area in each hind leg of all rats. Rats were divided into 3 treatment groups: Group 1 (KGN+PRP): KGN (100 μM) +25 μl PRP + 5 μl thrombin; Group 2 (PRP): 25 μl PRP + 5 μl thrombin; and Group 3 (Control): 30 μl saline. All the rats were sacrificed at 3 months, and hind legs harvested for analyses. N= 6 hind legs were used for histological and qPCR analysis. N = 16 hind legs were used for mechanical testing. Results: Single treatment of KGN+PRP demonstrates improved TBJ healing (Fig. 1A) compared to PRP only and control groups (Fig. 1B, C). Fibrocartilage-like tissue regeneration occurred only in the KGN+PRP treated group (Fig. 2A). These results were further confirmed by qPCR, which showed significantly higher expression of cartilage-related genes (Data not shown). Furthermore, the cartilage-like transition zone in the KGN+PRP group also stained positive for Col-I, Col-II, Scx and Sox-9 indicating the regeneration of fibrocartilage tissues in the KGN+PRP treated TBJ (Fig. 3A, B). Mechanical testing showed that the KGN+PRP (47±12 N) and PRP (50±13 N) groups had significantly higher ultimate strength than the controls (39±16 N). There was no significant difference in ultimate strength between the KGN+PRP group and PRP group. Conclusion: In this study, we have shown that KGN injection enhanced healing of the wounded TBJ by promoting the formation of a fibrocartilage transition zone. Thus, KGN can be used as a mode of cell free therapy to promote regeneration of the fibrocartilage transition zone in injured TBJs. PRP alone enhanced healing of the TBJ but did not induce fibrocartilage regeneration. PRP + KGN are advantageous due to the numerous growth factors located within PRP and PRPs ability to serve as a KGN carrier. Future research is needed to optimize KGN and PRP dosage regimens and the optimal delivery methods