A Non-Invasive Method for Generating the Cyclic Loading-Induced Intra-Articular Cartilage Lesion Model of the Rat Knee

Summary

Here, we present the cyclic loading-induced intra-articular cartilage lesion model of the rat knee, generated by 60 cyclic compressions over 20 N, resulting in damage to the femoral condylar cartilage in rats.

Abstract

The pathophysiology of primary osteoarthritis (OA) remains unclear. However, a specific subclassification of OA in relatively younger age groups is likely correlated with a history of articular cartilage damage and ligament avulsion. Surgical animal models of OA of the knee play an important role in understanding the onset and progression of post-traumatic OA and aid in the development of novel therapies for this disease. However, non-surgical models have been recently considered to avoid traumatic inflammation that could affect the evaluation of the intervention.

In this study, an intra-articular cartilage lesion rat model induced by in vivo cyclic compressive loading was developed, which allowed researchers to (1) determine the optimal magnitude, speed, and duration of load that could cause focal cartilage damage; (2) assess post-traumatic spatiotemporal pathological changes in chondrocyte vitality; and (3) evaluate the histological expression of destructive or protective molecules that are involved in the adaptation and repair mechanisms against joint compressive loads. This report describes the experimental protocol for this novel cartilage lesion in a rat model.

Introduction

Traditionally, anterior cruciate ligament (ACL) transection or destabilization of the medial meniscus has been considered optimal for investigating post-traumatic osteoarthritis (PTOA) in small animals. In recent years, non-invasive cyclic compression models have been used to study PTOA. This model was originally designed to investigate the cancellous bone response to mechanical loading¹ and was then modified as a non-surgical animal model for PTOA studies^2,3,4,5,6. The rationale is to collide the articular cartilage by applying a periodic external force, which triggers a series of inflammatory responses. However, this model has only been applied to mice, and the appropriate magnitude of loading on larger animals has not been discussed.

Another problem with the previous model is that the high-volume protocol included too many cycles, which caused excessive thickening of the subchondral bone, an unwanted side effect, in several samples⁷. Therefore, a novel method of cyclic compression with the appropriate magnitude for large animals and a lower loading side effect was developed⁸. The overall goal of the current article is to describe the protocol of the non-invasive cyclic compression model in rats and observe the representative results of cartilage degeneration. The current protocol would help readers interested in the application of the non-invasive cyclic compression model on rats.

Protocol

The protocol was approved by the Animal Research Committee of Kyoto University (approval number: Med kyo 17616).

1. Perform in vivo cyclic compression on the rat knee

1. Induce experimental animal anesthesia
   1. Induce anesthesia in a 12-week-old Wistar rat (256.8 ± 8.7 g) by inhalation of 5% isoflurane solution in the anesthesia box.
   2. Intraperitoneally inject a mixture of three anesthetic agents⁹, including medetomidine, midazolam, and butorphanol, at 2 mg/kg of the rat body weight, and shave the area around the right knee joint. Confirm sufficient anesthetization by lack of pedal reflex to a toe-pinch.
2. Mount the anesthetized rat on the fixation device.
   1. Place the anesthetized rat lying on their belly on the baseplate (Figure 1), with the right knee attached to a small piece of resin with a concave groove. Place the right hind limb in the hip extension, knee flexion, and ankle extension positions, with the knee flexed at approximately 140°. Accommodate the heel of the rat on the wedge-shaped groove on the movable fixture.
   2. Move the fixation device to the stress/tensile testing instrument (see the Table of Materials). After ensuring that there are no contacts with the load cell, open the stress/tensile testing instrument control software (Table of Materials) and click on the Calibration button. After calibration, attach the top of the frame to the load cell carefully. To keep the knee joint closely attached to the frame, turn on the rotary knob on the movable main operational panel slowly until the pre-load reaches 5 N.
3. Build a loading method and set up the compressive test.
   1. On the Main menu, click on Create a new method | System label. Set Test Mode to Cycle, and Test Type to Compression. Click on the Sensor label and select the Test tab to check that the limit is within 60 N. In addition, select the Stroke tab and check that the limit is within 500 mm.
      NOTE: The above step will stop the operation immediately if there is a large displacement on the stress point.
   2. Under the Testing control label, select Origin of growth to start the main program with 0.3%/full scale. Of the four sections in a loading cycle, set the Stroke speed in control in the 1^st and 3^rd sections to 1 mm/s. Set the Maximum testing force in the 2^nd section to 20 N, and the Minimum testing force in the 4^th section to 5 N. Set "the Duration of hold" to 0.5 s for the peak load and 10 s for the minimum load (Figure 2).
      NOTE: As this step defines every cycle, ensure that the joint surfaces are in contact with each other and are moving at a reasonable speed and that the motion is maintained.
   3. In the Pre-load tab at the bottom of the page, ensure that On is checked, the Speed of deflection removal is set to 100 mm/min, and maximum force is 5 N. In the Specimen label, set the Material as Metal.
      NOTE: These detailed settings may be specific for each manufacturer.
   4. In the Main menu, under the Select method and test section, select the method that was just built, and click on Start to begin the test.
      NOTE: The table at the bottom shows the actual measurements of the peak load and displacement.
   5. Set the number of cycles to 60.
      ​NOTE: The entire loading session includes 60 cycles, which lasts approximately 12 min. In the control group, rats underwent 5 N pre-loading for 12 min pre-load under the same conditions.
4. After loading, return the rat to its cage and monitor until full recovery. Maintain a 12-12 h light-dark schedule in the cage with sufficient space and food ad libitum. After the required experimental periods, sacrifice the rats with an overdose of the mixture of the three anesthetic agents injected intraperitoneally or carbon dioxide inhalation for analysis (1 h-8 weeks).

Results

A representative result of the short-term changes (1 h and 12 h) in chondrocyte viability in samples subjected to 20 N cyclic loading was obtained. As shown in Figure 3, the number of dead chondrocytes (red fluorescence) increased at 12 h post-trauma. Conversely, the number of living chondrocytes (green fluorescence) continued to decrease, with some samples containing no live chondrocytes in the affected area.

Histology showed that the articular cartilage of the r...

Discussion

For the first time, the current protocol shows how to establish a model of loading-induced cartilage lesion on the lateral femoral condyle in rats, similar to the intra-articular damage model in smaller rodents such as the mouse². However, the loading protocol in mice caused severe osteophyte formation and cruciate ligament lesions, which was not ideal for evaluating the effects of cyclic compression. The current protocol created a focal cartilage lesion in rats with a much lower loading force. Co...

Materials

Name	Company	Catalog Number	Comments
Anesthetic Apparatus for Small Animals	SHINANO MFG CO.,LTD.	SN-487-0T
Autograph AG-X	Shimadzu Corp	N.A.	Precision Universal / Tensile Tester
Fluoview FV10i microscope	Olympus Corp	N.A.	A fully automated confocal laser-scanning microscope
ISOFLURANE Inhalation Solution	Pfizer Japan Inc.	(01)14987114133400
LIVE/DEA Viability/Cytotoxicity Kit	Thermo Fisher Scientific Japan Inc	L3224	A quick and easy two-color assay to determine viability of cells
TRAPEZIUM X Software	Shimadzu Corp	N.A.	Data processing software for Autograph AG-X