Imaging Study on Acupuncture Inhibiting Inflammation and Bone Destruction in Knee Osteoarthritis Induced by Monosodium Iodoacetate in Rat Model.

OBJECTIVE: We aim to explore whether acupuncture inhibits inflammation and bone destruction in rat model monosodium iodoacetate (MIA)-induced knee osteoarthritis (KOA) by 18F-fluorodeoxyglucose (18F-FDG) small-animal positron emission tomography (PET) and micro-computed tomography (CT) imaging.
METHODS: KOA was induced in rats by intra-articular injection MIA (2 mg/50 μL) through the right knee of the rats. Forty male Sprague Dawley rats weighing 280 to 340 g (12 weeks old) were randomly divided into four groups including Control group, KOA group, KOA plus manual acupuncture group (KOA+MA), KOA plus sham acupuncture group (KOA+SA). The acupuncture treatment lasted for three weeks (one-day rest after six days of treatment). Paw withdrawal threshold test and open-field test were used to assess mechanical allodynia and locomotor activity respectively for once a week. Hematoxylin and eosin (H&E) staining was used to assess the damage of the cartilage, synovium and infrapatellar fat pad (IFP). 18F-FDG PET was performed to quantify joint inflammation. The influence on the subchondral bone in these rats was confirmed by micro-CT.
RESULTS: Mechanical hyperalgesia, joint inflammation, and obvious bone destruction were observed in the KOA group. H&E staining of the knee joint found that manual acupuncture played a protective effect in cartilage, synovium and IFP destruction. However, compared with KOA group, the results in sham acupuncture had no significant difference. After manual acupuncture treatment in KOA rats, inflammation was significantly suppressed shown by 18F-FDG PET imaging. Micro-CT analysis of the knee joint revealed that manual acupuncture protected bone by inhibiting osteophyte development and subchondral bone remodeling.
CONCLUSION: The results of 18F-FDG PET and micro-CT showed that manual acupuncture inhibited inflammation and bone destruction, which provides reliable evidence for the effectiveness of acupuncture in hindering development of KOA, and provides reliable evidence for clinical application of acupuncture.

Introduction

Osteoarthritis (OA), a common skeletal and muscle disease, is one of the main causes of global disability.1 The number of patients with the prevalence and the incidence increase with age has increased to more than 240 million worldwide.2 While the knee joint is the most common site affected in OA.3 The clinical manifestations of knee osteoarthritis (KOA) are joint pain, swelling, stiffness and even dyskinesia,4,5 which affects the quality of life of patients and aggravates the medical burden of society.6 Variety of physiological and mechanical factors affect the occurrence and development of KOA, involving age, sex, obesity, heredity trauma, and mechanical stress.7

The characteristic case changes all tissues in knee of KOA include articular and meniscal cartilage degeneration and loss, subchondral bone changes, synovial joint inflammation8 and infrapatellar fat pad (IFP) inflammation and fibrosis.9 Inflammation is strongly implicated in the pathogenesis of KOA,10 because KOA is correlated with aging mechanisms such as the presence of an inflammatory microenvironment and the impaired link between inflammasomes and autophagy.11 Previous studies12–15 have reported that inflammation develops within the joint structures, the formation of which is associated with the activation of numerous immune cells which secrete cytokines amplifying the inflammatory process, including tumor necrosis factor alpha (TNF-α) and interleukin (IL), such as IL-1β.IL-6, IL-8 and so on. One study16 suggested that conditioned media from all tissues of OA patients produced high levels of IL-6, IL-8, and CCL2. CCL21, MMP-3, which means all tissues of joint participate in inflammatory process. Meanwhile, There is increasing evidence17 that subchondral bone plays an important role in the progression of OA in recent years. Recent studies18,19 showed that there are distinct microstructural alterations in subchondral bone at different stages of OA. Bone homeostasis is maintained by a balance between bone remodeling, osteoblastic bone formation, and osteoclastic bone resorption.20 Once subchondral bone is destroyed, bone homeostasis would be broken, which is involved in the pathophysiology of OA at the biochemical and mechanical levels. Intra-articular injection of monosodium iodoacetate (MIA) is a chemical method to induce KOA,21 which inhibits the activity of glyceraldehyde 3-phosphate dehydrogenase in chondrocytes, resulting in the destruction of glycolytic pathway.22 Because the site of injection is restricted to the joint space, intra-articular injection of MIA causes mainly chondrocyte cell death, leading to cartilage degeneration and subsequent subchondral bone alterations.23 Furthermore, this model is widely used for pain research and efficacy evaluation of therapeutic interventions.24

At present, the etiology of KOA remains unclear and there is no radical cure for KOA.25 The aim of treatment is mainly limited to relieving knee pain, enhancing mobility and function. Acupuncture is one of the most popular treatments applied in traditional Chinese medicine, which has been generally applied to relieve pain in musculoskeletal diseases.26 In recent years, acupuncture has been widely used to treat KOA, and its effectiveness and safety have been abundantly proved in clinical and experimental studies.27,28 Despite being mature technology, the exact mechanism of acupuncture is still unclear. Meanwhile, few researchers aim to observe the therapeutic effect of the KOA animal model through imaging analysis. In this study, our aim was to investigate the effectiveness of acupuncture in the treatment of KOA from the perspective of imaging. Therefore, positron emission tomography (PET) and micro-computed tomography (CT) will be used to investigate the protective effects of acupuncture on inflammation and subchondral bone in KOA rats in our study.

Materials and Methods

Animals and Model Induction

Studies were conducted in accordance with the Chinese Guidelines of Animal Care and Welfare. Approval was granted by the Animal Care and Use Committee of Hubei University of Chinese medicine (Wuhan, China) for all animal procedures. For all animal experiments, the experimenters assessing the outcomes were blinded to the intervention. Forty male Sprague Dawley rats weighing 280 to 340 g (12 weeks old) were group housed in a room with controlled temperature (22±2°C) under a reversed 12-hour light/dark cycle, and the rats had free access to food and water. The rats were divided into four groups by random number method: Control group (Control, n=10), KOA group (KOA, n=10), KOA plus manual acupuncture group (KOA+MA, n=10), KOA plus sham acupuncture group (KOA+SA, n=10). Rats were briefly anesthetized with isoflurane and received either intra-articular injection through the infrapatellar ligament of the right knee with monosodium iodoacetate (MIA; 2 mg/50 μL, in saline, KOA group) or saline (50 μL, Control group) using a 27-gauge, 0.5-inch needle.

Acupuncture Treatment

One week after intra-articular injection of MIA, the rats of KOA+MA group were treated with 0.30 mm×13 mm acupuncture needles, which were inserted into an acupoint on the right with a depth of 5 mm. The acupoint named “Zusanli” (ST36), located at 2 mm lateral to the anterior tubercle of the tibia and 5 mm below the capitulum fibulae under the knee joint in the rats. The needles were frequently manual rotated for one minute every five minutes. This procedure is repeated for six times (total time is 30 minutes) during the manipulation session. Stimulation was performed once daily for a period of three weeks (one-day rest after six days of treatment). For KOA+SA group, sham acupoint (1–2 cm lateral to the ST36 for rat) was selected in ipsilateral side. The time of operations and penetration depth in sham acupuncture were the same as the manual acupuncture group, but needles were not manually twisted in sham acupuncture. These treatments were performed without anesthesia. The experimental timeline was shown in Figure 1.

Figure 1

Experiment timeline. KOA was induced in rats by intra-articular injection MIA (2 mg/50 μL) through their right knee, while the rats in the Control group were injected with saline at the same position. Rats in experimental groups were underwent following treatments: manual acupuncture or sham acupuncture treatment was performed at the seventh day after modeling and lasted for three weeks. Nociceptive behavioral tests were measured once a week until the treatment was completed. After the last treatment, four rats in each group were randomly selected for 18F-FDG PET imaging. Micro-CT were operated after the rats were sacrificed.

Positron Emission Tomography (PET) Imaging

No rat death was observed during the experiment. After the last treatment, four rats in each group were randomly selected for PET imaging. The rats were fasted overnight before the PET scan. Anesthetized by inhalation of 2% isoflurane, rats were injected with 500±25 μCi 18F-FDG (Wuhan Union Hospital PET Center) through the tail vein. After 60 minutes of FDG uptake, the anesthetized rats were fixed on the scanning bed for 21-minute micro-PET scan by the Trans-PET Bio Caliburn 700 system (Raycan Technology Co., Ltd, Suzhou, China). The PET images were reconstructed using the three-dimensional (3D) OSEM (iteration number was 2, subset number was 12) method with a voxel size of 0.5×0.5×0.5 mm3. Gaussian image post-filtering can be applied with the following parameters: none, low (window size = 3, sigma = 1). Images were displayed with software Carimas (Turku PET Center, Turku, Finland), AMIDE (Amide’s a Medical Imaging Data Examiner) and Pmod (Pmod Technologies LLC, Switzerland). The mean standardized uptake value (SUV) was calculated using the following formula: mean pixel value with the decay-corrected region-of-interest activity (μCi /kg)/(injected dose [μCi]/weight [kg]).

Micro-computed Tomography (CT) Imaging

The rats were euthanized with CO2, and the right knee joint of the rats was dissected and fixed in 4% paraformaldehyde (PFA). Micro-CT was used to evaluate the tibial subchondral bone in the rat specimens. A Bruker SKYSCAN 1276 scanner micro-CT system (Bruker, Karlsruhe, Germany) was used to image the subchondral bone regions in rats at a voltage of 85 kV and a current of 200 μA to obtain images having a pixel size of 10 μm and using 1 mm Al filter to capture the best X-ray projections, with the platform software being used to assess three-dimensional (3D) morphometric analyses, density, and other parameters. We reconstructed and analyzed the 3D structure and morphometry in a double-blind manner. The area between the proximal tibia and the distal femur was selected for analysis of the following parameters: trabecular bone volume fraction (BV/TV), trabecular spacing (Tb.Sp), trabecular number (Tb.N), and trabecular thickness (Tb.Th).

Histopathological Analysis

Following micro-CT scanning, tissues were fixed with 4% PFA, decalcified in 10% EDTA, embedded in paraffin. Then sagittal sections with a thickness of 5 µm were prepared. Histopathological change of knee joint was observed under an optical microscope after hematoxylin and eosin (H&E) staining. Synovial hyperplasia, inflammatory infiltration, and infrapatellar fat pad (IFP) fibrosis were analyzed by H&E staining, including cartilage, synovium and infrapatellar fat pad. Meanwhile, according to the Mankin scoring standards29 (), the pathology the cartilage was calculated. Synovial inflammation was assessed by histopathological synovitis score according to the status of tissue architecture and pathological change in H&E staining30 ().

Nociceptive Behavioral Tests

Severity of joint pain was quantitatively evaluated by paw withdrawal threshold using Electric Von Frey (IITC Life Science Inc., CA, USA). Rats were individually placed in metal cages, which allowed full access to the paws, and the rats were acclimated at least 30 minutes before the test. After the rats were quiet, the probe was applied perpendicularly the mid-plantar surface of the right hind paw to evaluate the withdrawal threshold. Until the force elicited a nocifensive response (ie, paw lifting, jumping), data was recorded on the display screen. This procedure was repeated three times with an interstimulus interval of three minutes. The mean values of the three tests were used for statistical analysis.

Locomotor Activity Test

Open-field test was used to evaluate the alterations in locomotor activity. Prior to testing all rats were transferred to the testing room followed by a 30-minute acclimatization period. The rats were placed at the center of a 1×1×0.5 m chamber and allowed free exploration for five minutes. During this period, the locomotor activity of the rats was recorded using a digital camera placed above the open field apparatus which was connected to a computer. The computer would save and measure activity data, including total distance, average speed, and rest time. The measurement frequency was once a week.

Statistical Analysis

GraphPad Prism (version 8.3.0; GraphPad Software Inc., San Diego, CA, USA) was applied to statistical analysis. The results were expressed as mean ±standard deviation (SD). Comparisons between different groups were analyzed by one-way analysis of variance (ANOVA) with Dunnett’s multiple comparison test or two-way ANOVA with Tukey’s multiple comparison test with repeated measures, followed by post hoc Šidák’s multiple comparison tests. Bonferroni post hoc tests were used for multiple comparisons. P<0.05 was considered to be statistically significant.

Results

MA Inhibits the Joint Inflammation in KOA Rats

PET was used to show the changes of glucose metabolism, which indicated the degree of joint inflammation31 We obtained transverse, sagittal and coronal view of 18F-FDG PET scan of rat right knee joints (Figure 2A). All the ROIs (region of interest) assessed in the right knees of KOA group, comparing to the Control group presented with significantly higher FDG uptake quantified by SUVmax (P<0.01). Compared to the KOA group, the rats of the KOA+MA group showed lower uptake of tracer (P<0.05). The difference of SUVmax between the KOA group and KOA+SA group did not reach statistical significance (P>0.05) (Figure 2B).

Figure 2

Effect of MA on inhibiting inflammation in KOA rats. (A) 18F-FDG PET imaging of mouse right knee joints from transverse, sagittal, and coronal views. Inflammatory site (white arrow). (B) Region of interest (ROIs) 18F-FDG SUVmax from each group. Data are presented as the mean ±standard deviation, n=4/group; Two-way ANOVA was used. KOA group vs Control group (**P<0.01); KOA+MA group vs KOA group (#P<0.05); KOA+MA group vs KOA+SA group (†P<0.05), KOA+SA group vs KOA group (no significant difference. P>0.05).

MA Inhibits the Joint Bone Destruction in KOA Rats

Micro-CT was used to quantify the structural changes in the tibial subchondral bone in these rats. Reconstructed 3D micro-CT images of knee joints in each group were shown in Figure 3A and B, typical 3D reconstructed micro-CT images of the proximal tibial metaphyseal trabecular bone in different groups. Compared with the Control group, the scan results showed that the KOA group and KOA+SA group exhibited obvious bone destruction, which was manifested as an increase in tibial subchondral osteolysis. Meanwhile, the number and connection density of subchondral bone trabeculae decreased, and the bone trabeculae were sparse and disorderly distributed in the KOA group. The bone destruction phenomenon was significantly improved after treatment with manual acupuncture. Statistically, the values of BV/TV, Tb.N and Tb.Th of the model group were downregulated (P<0.01), and the values of Tb.Sp were upregulated than the Control group (P<0.01). Meanwhile, compared with the model group, the manual acupuncture group prominently increased the values of BV/TV, Tb.N and Tb.Th (P<0.01), while the value of Tb.Sp showed the opposite results (P<0.01). However, the parameter analysis of rat knee micro-CT between the KOA group and the KOA+SA group had no significant difference (P>0.05).

Figure 3

Effect of MA on inhibiting the joint bone destruction in KOA rats. (A) Reconstructed 3D micro-CT images of knee joints in each group. (B) 3D reconstruction of tibial plateau trabecular bone in different group. (C) The values of BV/TV in each group. (D) The values of Tb.Th in each group. (E) The values of Tb.Sp in each group. (F) The values of Tb.N in each group. Data are presented as the mean ±standard deviation, n=6/group; KOA group vs Control group (**P<0.01); KOA+MA group vs KOA group (#P<0.05, ##P<0.01); KOA+MA group vs KOA+SA group (†P<0.05, ††P<0.01), KOA+SA group vs KOA group (no significant difference, p>0.05).

MA Inhibits Cartilage, Synovium and IFP Destruction in KOA Rats

Gross microscopy was used to observe the damage of the articular cartilage in the knee joint of rats after treatment. H&E staining was applied to assess the histopathological change of cartilage, synovium and IFP. The keen joint in KOA group and KOA+SA group showed severe cartilage injury, while manual acupuncture significantly alleviated injury (Figure 4A). There was no histopathological variation in the joint of normal rats which showed normal histological structure of the cartilaginous articular surface and synovial membrane, but significant degradation of the cartilage layer and inflammatory cells infiltration as well as congested blood vessels were demonstrated in the knee joint of KOA group. Cartilage destruction was prominently alleviated in the KOA+MA group, while cartilage destruction of the rats did not ameliorate in the KOA+SA group (Figure 4B). The results of Mankin scores in each group were shown in Figure 4E. KOA+MA group was significantly lower than the KOA group and KOA+SA group, while the KOA group and KOA+SA group had no significant difference, which reflected the change of cartilage tissue. Meanwhile, compared with the Control group and KOA+MA group, synovial cell layer was thicker and the cell density of the matrix increased in the KOA group and KOA+SA group (Figure 4C). The synovitis score results were consistent with the above results (Figure 4F). The hyperplastic changes in the IFP surface and the fibrosis of IFP were showen in Figure 4D in the KOA group and KOA+SA group. However, the IFP destruction was significantly improved after the treatment with manual acupuncture. These results suggested that manual acupuncture could alleviate the damage of cartilage, synovium and IFP in KOA.

Figure 4

Effect of MA on protecting cartilage, synovium and IFP damage in KOA rats (A) Macroscopic view of articular cartilage damage surface in each group. (B) H&E staining (original magnification, 40× and 100×), synovial hyperplasia, inflammatory cell infiltration (*), cartilage surface damage (black arrow). (C) Synovial inflammation. 200×. (D) Fibrosis of IFP. 200×. (E) Mankin scores in each group. (F) Synovitis score. Data was presented as the mean ±standard deviation, n=5/group; KOA group vs Control group (**P<0.01), KOA+MA group vs KOA group (##P<0.01), KOA+MA group vs KOA+SA group (††P<0.01).

MA Alleviates Mechanical Allodynia and Improves Locomotor Activity in KOA Rats

We tested the nociceptive behavior which was induced by intra-articular injection of MIA into the right knee of rats. Prior to the start of the MA treatment, IA injection of MIA significantly decreased paw withdrawal threshold (PWT) in ipsilateral, comparing to intra-articular injection of saline (Control group). Compared with the KOA group and KOA+SA group, manual acupuncture significantly attenuated pain behavior of KOA (KOA+MA) at two weeks to four weeks. However, there were no differences between the magnitudes of these measures between the KOA group and KOA+SA group (Figure 5A).

Figure 5

Effect of MA on alleviating mechanical allodynia and improving locomotor activity in KOA rats. (A) PWT was tested by Electric Von Frey before modeling and measured every week. (B–D) represented total distance, average speed and rest time respectively. Two-way ANOVA was used in different time periods. Data was presented as the mean ±standard deviation, n=10/group; KOA group vs Control group (**P<0.01, ***P<0.001), KOA+MA group vs KOA group (#P<0.05, ##P<0.01, ###P<0.001), KOA+MA group vs KOA+SA group (†P<0.05, ††P<0.01, †††P<0.001).

The open field test was used to detect the spontaneous activity of the rats. The timeline is the same as above (Figure 1). The results including total distance, average speed, and rest duration of rats to assess the mobility, and the motion trail were recorded. Compared with the Control group, MIA meaningfully reduced the pain thresholds and spontaneous activity of KOA mice in the first week. In the second week to fourth week, compared with the KOA group or KOA+SA group, MA treatment significantly increased total distance (Figure 5B) and average speed (Figure 5C) (P<0.01), while it significantly reduced rest duration (Figure 5D) (P<0.01).

Therefore, these results demonstrated that manual acupuncture had remarkable inhibitory effect on pain and improved activity ability.

Discussion

In this study, 18F-FDG PET and micro-CT imaging were applied to explore the effect of acupuncture on rat model of MIA-induced KOA, and whether acupuncture inhibits inflammation and bone destruction in the development of KOA. We used 18F-FDG PET to quantify effectively the inflammatory activity of KOA and its therapeutic response on manual acupuncture. In our study, the results of PET suggested that manual acupuncture significantly decreased the glucose uptake, suggesting that MA inhibited local inflammatory reaction of KOA. Therefore, the results of H&E staining further confirmed this conclusion that manual acupuncture not only reduced cartilage injury, but also reduced synovial inflammation and fibrosis of IFP. In our study, the results show that the number, volume, and thickness of trabeculae were significantly increased, and the distance between trabeculae was reduced after treatment with manual acupuncture, compared with KOA rats, which exhibited that acupuncture could inhibit severe bone erosion. Consequently, we considered that acupuncture had a protective effect on subchondral bone for KOA. Meanwhile, we identified that acupuncture showed an obvious effect on analgesia, and the results were consistent with our previous experiments32 that we demonstrated manual acupuncture reduced hyperalgesia and provides a new explanation on the mechanism of acupuncture in treating KOA. In a recent study, Hoshino et al found that synovial inflammation and destruction of subchondral bone was observed as soon as seven days after injection in high-dose MIA (1.0 mg/30 μL).33 Consequently, we used an MIA-induced KOA model to observe the therapeutic effects of MA on pain, inflammation and motor function in KOA model rats.

In the current study, the diagnosis of KOA is based on clinical and imaging findings.34 Although the gold standard for OA imaging is conventional radiography in daily clinical practice, it has a few limitations, such as low sensitivity, compared to PET/CT,35 which is relatively expensive but enables us to obtain more information.36 18F-FDG PET/CT imaging is usually applied to detect the glucose uptake and metabolic changes in human diseases37 using 18F-fluorodeoxyglucose (18F-FDG), a radioactively labelled glucose analogue, which is injected into the body to reflect the status of metabolism activities through the aggregation of radioactivity.38,39 The 18F-FDG uptake was associated with serological and clinical markers of inflammation,40 and the role of 18F-FDG PET in imaging inflammatory conditions has been validated in KOA.41 The high expression of GLUT-1 receptor subtype in stimulated inflammatory cells such as macrophages is one of the potential mechanisms for 18F-FDG uptake in these inflammatory conditions.41 Meanwhile, pro-inflammatory factors obviously increases high metabolic activity of activated inflammatory cells with high glucose uptake and glycolysis process, leading to avid FDG uptake in inflammatory tissues.42 However, the 18F-FDG as a glucose analogue cannot be further metabolized after phosphorylation, which accumulates within cells, then we can quantify 18F-FDG uptake at sites of pathological increased glucose metabolism also in the musculoskeletal tissue.31 Therefore, 18F-FDG accumulation in the knee suggests that inflammatory cytokines enhanced inflammatory activity.

In recent years, micro-CT has become the gold standard for evaluating the microstructure of subchondral bone and trabecular morphological of bone plate in small animal models, such as rats and mice.43 Three-dimensional structure of bone trabecula by micron scanning reconstruction, can accurately measure the overall bone mass parameters and a large number of bone structure parameters of the specimen.44 The imaging and data indicate osteophyte development and subchondral bone remodeling, which could be used to observe bone destruction in the development of the KOA.

Acupuncture has been accepted in China’s Guidelines for the Diagnosis and Treatment of Osteoarthritis45 and the Guidelines of the American Academy of Orthopedic Surgeons.46 Compared with sham acupuncture, effective acupuncture is to penetrate into acupoints with a certain depth and give a certain degree of stimulation. There are many clinical and animal studies on acupuncture in the treatment of KOA, which confirm that acupuncture indeed improves the symptoms of KOA.27,47 Previous studies have found that acupuncture reduces inflammation and pain by regulating a variety of pathways,48,49 such as MCP2/CCR2 signaling pathway and nuclear factor-κB signaling pathway, but few studies investigated acupuncture in reducing the degree of inflammation and protecting subchondral bone from the perspective of imaging. Therefore, our results confirmed that the effect of manual acupuncture was significantly better than sham acupuncture in inhibiting inflammation and bone destruction during the procedure in KOA by PET imaging and micro-CT.

However, limitations have to be noted in this study. We only detected PET and micro-CT imaging after treatment, and did not observe the dynamic changes during treatment, and did not give insight into even longer longitudinal changes after treatment. Furthermore, we have not studied its molecular mechanism in our study. Further studies are needed to explore the effect of acupuncture on KOA during treatment and the local metabolic changes of the joint for a long time after treatment, and what molecular mechanisms are involved in these changes.

In summary, our research shows that manual acupuncture could inhibit inflammation and bone destruction by 18F-FDG PET and micro-CT. And the results provide a new theoretical basis for acupuncture in the treatment of KOA.