Pathologies affecting the joint cartilage, such as chondral and osteochondral (OCL) lesions, which are precursors of osteoarthritis (OA), have generated numerous publications in international literature due to the low capacity for repair of this tissue and the lack of optimal treatment options available.1 This has led to an increasing interest in the development of experimental strategies which are capable of generating physiopathological knowledge allowing an adequate assessment of new treatments. For this reason, the development of experimental animal models for research work is essential to the development of innovative therapeutic strategies. Among these are currently the use of platelet-rich plasma,2 autologous implant of chondrocytes associated to membrane and, more recently, some experiences with pluripotent mesenchymal cells,3 reinforcing the importance of these experimental models.

The literature contains reports of several models in research relating to OCL,4–7 including medium-sized (rabbits and dogs) and large (sheep and horses) animals. Nevertheless, there are very few assessments of rodent models for the study of osteochondral pathologies, despite the fact that their low cost, high reproductive rates and ease of maintenance make them highly suitable candidates. The main concern with regard to these animals is their high rate of spontaneous OCL repair. For this reason, they are mainly used in studies on genetic alterations to generate a spontaneous OA.7,8 However, potential repair of OCL in adult mice models has not been validated in any published study. The objective of the present work is to analyze a reproducible and inexpensive adult mouse model with critical OCL for experimental studies.

The OCL were macroscopically and microscopically visible in the 38 knees studied (19 knees for each period), both on day 7 and on day 14. The microscopic analysis detected a solution of contiguity in the chondral surface which was compatible with the instruments used to create the 0.5mm diameter OCL in all the samples analyzed. In addition, the depth of the lesion reached at least the physis in all cases (Fig. 2A and B).

Figure 2.

Histological analysis of the OCL produced. Shown as a sagittal section of the trochlear region of an animal sacrificed after 7 days, representing the full sample. (A) Staining with hematoxylin–eosin showing the solution of contiguity of the joint surface. (B) Staining with safranin-O; it is possible to identify the OCL and depth reaching the physis (*).

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When analyzing the histological sections after 7 days, we found inflammatory connective repair tissue and did not observe the presence of chondrocytes in the damaged region (Fig. 2A). Staining with safranin-O showed that, despite this attempted repair, the characteristics of the extracellular matrix in the damaged region were clearly different from those of the surrounding chondral tissue, with a notable decrease in the amount of glycosaminoglycans. The histological score obtained was of 4.2±0.29, showing significant differences with the control region (normal cartilage, 22 points, P<0.001).

In the group of animals assessed after 14 days, the histological results were similar to those described above, highlighting a lower presence of inflammatory cells. In 1 knee we observed symptoms compatible with acute osteomyelitis connected to the induced OCL. The histological score obtained was of 4.1±0.33, with significant difference compared to the control region (P<0.001). Comparison of the results obtained in the 2 periods assessed did not find significant differences (Fig. 3).

Figure 3.

Histological score (ICRS II) with statistically significant differences compared to the control region, with no differences between the 2 periods studied. *P<0.05.

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Different animal models have been proposed for the study of chondral physiology and physiopathology, in particular smaller animals, such as rabbits and dogs, and larger ones, such as sheep and horses. However, the complexities associated to the use of these types of animals has led to a limited availability of these models, especially for studies in which the transfer of knowledge from in vitro models is increasingly being applied. Smaller animals, including rodents, offer comparative advantages for the development of scientific research, mainly their low maintenance costs, high reproductive rate, short experimental time and reproducibility of results. Furthermore, there are athymic, transgenic and knockout animals for certain pathologies, so they represent an interesting alternative as first animal model.8

Among the main disadvantages attributed to experimental mice models are the small size of the joint, narrowness of the joint cartilage and high rate of spontaneous regeneration or repair maintained during their adult life due to the persistence of the physis, which could have a negative influence when assessing therapies.11 However, after reviewing the available literature, we did not find any publications regarding adult mice models which reported spontaneous regeneration or repair of chondral or osteochondral lesions, with only 1 report of OCL focusing on young animals (8 weeks), in which this intrinsic capacity for repair was partially demonstrated.12 Similarly, adequate studies of therapeutic alternatives for the study of OCL have been developed in animals which share many of the characteristics described with our model, like rats.13

Out results, both at 7 and 14 days, were consistent in their capacity to generate reproducible OCL of a critical size which, although inducing a reparative process by the organism, as illustrated by the presence of inflammatory cells, were not adequately covered by new chondral tissue, as reflected by the histological scores.

Although it has been recognized that, in mice, progenitor cells derived from the physis have the potential to repair damage at the joint level, as is as also the case in human beings, the molecular and histological processes which mediate this repair are not fully understood.14 It is known that embryogenesis of the joint cartilage in mice takes place early, as the joint cartilage can be identified after 2 weeks of embryonic development,15 thus leading us to believe that the time required to regenerate the damaged cartilage should be in the same order of magnitude. For this reason, the periods assessed in the present work (7 and 14 days of natural evolution after the OCL) should enable us to determine the potential for innate repair in adult animals. We believe that the short follow-up period required represents an advantage of the proposed model. In addition, this is supported by the decrease in the initial reparative response, characterized by a decrease of the cellular component of inflammatory cells seen at 14 days, a similar phenomenon to that published in OCL models in other animal species.13 The low histological score obtained in the 2 periods studied agrees with the low capacity of adult animals to repair the critical lesion generated, regardless of the persistence of the physis. We believe that this is crucial, as it proves that our surgical model will enable the observation of significant improvements in relation to the regenerative capacity of certain treatments.

The specific limitations of the proposed animal model include the fact that it does not correspond to the classical OCL observed in clinical practice, both regarding the causal mechanism and the area in which they occur. In human beings, OCL take place mainly in the femoral condyles, which, being a load area, have a different behavior regarding their potential for repair. For these reasons, the adult mouse model for critical OCL at the level of the femoral trochlea presented in this study is highly reproducible. In our results, the innate potential for regeneration of the animals secondary to the presence of the physis during their adult life did not manage to adequately repair the lesion generated by the procedure on the joint cartilage. This model will enable the development of new studies aimed at obtaining better treatments for chondral pathologies.

Level of evidence i.

This study was financed with publicly available research funds from Universidad del Desarrollo (project 23.400.099) and the Chilean Orthopedic and Traumatology Society. These resources have not generated any conflict of interest to be declared.

The authors have no conflict of interest to declare.