Pakistan Journal of Medical Sciences

Published by : PROFESSIONAL MEDICAL PUBLICATIONS

ISSN 1681-715X

HOME   |   SEARCH   |   CURRENT ISSUE   |   PAST ISSUES

-

ORIGINAL ARTICLE

-

Volume 25

April - June 2009 (Part-I)

Number  2


 

Abstract
PDF of this Article

Influence of commiphora mukul resin on the knee
articular cartilage of rats in experimental
osteoarthritis induced by iodoacetate

Mahsa Hadipour-Jahromy1, Reza Mozaffari-Kermani2,
Fatemehsadat Nobakht3

ABSTRACT

Objective: To investigate the influence of Commiphora mukul resin (guggul) on the knee articular cartilage of rats in experimental osteoarthritis.

Methodology: To induce osteoarthritis (OA), single intra-articular injection of MIA (1 mg) in the rat knee joints was performed. Histopathological changes in knee joints were observed after two weeks. The beneficial effect of guggul was studied, orally.

Results: The early OA characterized by areas of chondrocytes degeneration in the tibial plateaus and femoral condyles. Changes to the subchondral bone and proteoglycane contents and synovial cell proliferation, were observed. Administration of guggul prevented the negative effects of iodoacetate, dose dependently. Chondrocyte damages were significantly prevented and proteoglycane were less affected, especially in high guggul dose and no cell proliferation and inflammatory cell were detected in synovial.

Conclusion: The effectiveness of guggul in improvement of histopathological damages is emphasized and its chondroprotective effect in vivo is highlighted.

KEY WORDS: Guggul, Osteoarthritis, Animal model.

Pak J Med Sci    April - June 2009    Vol. 25 No. 2    269-273

How to cite this article:

Jahromy MH, Kermani RM, Nobakht F. Influence of commiphora mukul resin on the knee articular cartilage of rats in experimental osteoarthritis induced by iodoacetate. Pak J Med Sci 2009;25(2): 269-273.


1. Mahsa Hadipour-Jahromy, Pharm.D.,
PhD of Pharmacology, Assistant Professor,
Head of Dept. Pharmacology,
Medical Sciences Research Center,
2. Reza Mozaffari-Kermani, MD, PhD of Pathology,
Assistant Professor, Dept. Pathology,
3. Fatemehsadat Nobakht, MD,
1-3: Tehran Medical Branch,
Islamic Azad University, Tehran, Iran

Correspondence

Mahsa Hadipour-Jahromy,
Zargandeh, Shariati Ave.,
Islamic Azad University, Tehran Medical Unit,
P.O. BOX: 19395-1495, Tehran, Iran
Email: jahromymh@yahoo.com 

* Received for Publication: June 16, 2008

* Revision Received: December 29, 2008

* Revision Accepted: January 1, 2009


INTRODUCTION

Osteoarthritis (OA) is the most common form of joint disease in over one-half of people older than 65 years of age. OA is primarily noted in the weight-bearing joints (i.e., knees, hips) and involves both the degeneration of articular cartilage as well as changes to the subchondral bone.1,2 Currently, there are no commercially available drugs definitively proven to alter the natural progression of this disease in the clinic. The treatment of patients with OA is often directed at relieving pain and restoring function through the use of pharmacological therapies or phytochemical-rich diet.3

An animal model that mimics the behavioral, biochemical and pharmacological parameters of OA-associated joint discomfort has been introduced. Injection of the metabolic inhibitor, monosodium iodoacetate (MIA), into joints, inhibits glyceraldehye-3-phosphate dehydrogenase activity in chondrocytes, resulting in disruption of glycolysis and eventual cell death. The progressive loss of chondrocytes results in histological and morphological changes to the articular cartilage, closely resembling those seen in human OA.4-7

Mukul myrrh (Commiphora mukul, Burseraceae), is a tree native to Arabia and India. The tree exudes a yellowish resin called gum guggul or guggulu that has a balsamic odor. Guggul is a highly valued botanical medicine used in Ayurveda, Indian system of medicine. It is used for lipid disorders, Acne vulgaris, arthritis and obesity.8,9 Although, guggul has demonstrated anti-inflammatory activity in rats, no study has been carried out in rat model of osteoarthritis, yet.

Aim of The study: Currently there are no commercially available drugs, definitely proven to alter the natural progression of the disease in the clinic, and since guggul resin is widely consumed and implicated with potential human health benefit, the present study was designed to investigate the effect of guggul on the pathological changes of knee’s rats after induction of experimental osteoarthritis with iodoacetate.

METHODOLOGY

Induction of osteoarthritis: The procedures used in this study were in accordance with the guidelines of the Pfizer Animal Care and Use Committee. Male Wistar rats (200-250g) were used. For induction of MIA-induced arthritis, rats were anesthetized with ketamine Hydrochloride (50 mg/ml for injection USP, Rotexmedica, Germany) and given a single intra-articular injection of 1mg MIA (Crystal Powder M=185.96 g/mol, Germany, Sigma) through the infrapatellar ligament of the left knee10 and sacrificed at 1, 14 and 28 days post injection. The amount of MIA injected into the joint was determined from the dose-response study in which the appropriate degree of joint discomfort was observed using a concentration of 1mg/joint (results not shown).

MIA was dissolved in physiologic saline and administered in a volume of 50µl using a 30-gauge needle. The right contra lateral control knee was injected with 50µl of physiologic saline.

Treatment: The beneficial effects of guggul (Kisalaya Pharmaceuticals Ltd. Indore, India) at ranges equal to anti-lipid effects in men (15, 30 and 45 mg/kg, orally) was studied in different groups each containing ten rats, after induction of OA (from day one post MIA injection). The resin was dissolved in saline and administered orally, using feeding needle, everyday. The control group received only saline. Histopathological changes in knee joints were studied after two weeks.

Histological analysis: Histological changes were assessed in all rats that had received 1mg/knee of MIA or saline. Animals were killed by chloroform at the time indicated. Soft tissue was removed from the left (osteoarthritic) and right (contra lateral control) legs. The patella was removed from each knee to facilitate thorough fixation of the joint. Tissue samples were prepared for light microscopy using standard procedures. Briefly, samples were preserved in 10% neutral-buffered formalin and subsequently decalcified in 5% formic acid for 72 hour. Samples were dehydrated in an ethanol series and embedded in paraffin. Sections were stained with either hematoxylin–eosin or toluidine blue. Histopathological change of each knee was quantitatively expressed simply by the summation of individual grades (slight: 1 for +, moderate: 2 for ++, severe: 3 for +++) and calculating the average pathology scores, for each finding.7 A Board-certified pathologist scored all samples. Statistical analyses to test for differences in response were performed using one-way ANOVA. Individual values throughout the paper are given as mean±standard of the mean (origin 6).

RESULTS

In MIA treated animals, histopathological alterations were completely time dependent. Histological findings such as disorganization of chondrocytes, erosion and fibrillation of cartilage surface, subchondral bone exposure, and loss of proteoglycane in cartilage were observed after fourteen days, in iodoacetate injected knee, staining with hematoxilin-eosine and toluidine blue. Joint cartilage of both femoral and tibial bone showed irregular surface that was occasionally accompanied by ulceration and/or fibrillation especially after 28 days. Histopathological findings and pathology scores for MIA-induced OA (1mg) after 1, 14 and 28 days are summarized in Fig-1.

Administration of guggul resin in different groups of rats prevented, to some extent, the negative effects of iodoacetate on chondrocytes, especially at maximum amount that we used. With administration of 45mg/kg, chondrocyte organization was preserved by approximately 50%, and their number was focally increased with less damage to proteoglycane (around 65%) in the epiphyseal plate, in period of two weeks. No inflammatory cells or cell proliferation in synovial were observed, in any treated groups. Scoring of histological findings confirmed the tendency of guggul in protection of both chondrocytes and proteoglycane and its high anti-inflammatory effects. Summation of all average pathology finding scores in saline, control, low-, moderate- and high-guggul resin groups were 0.00, 12.10, 6.40, 5.80, and 3.90, respectively (Table-I).

DISCUSSION

Guggul, a well-known anti-dyslipidemic10,11 and anti-inflammatory drug8,9,12 has shown the potential of chondrocyte protection in the present study. Gugulipid treatment proffered a salutary effect on rodent models of OA commonly used to screen chondroprotective drugs. The present study also confirms the anti-inflammatory effects of guggul in OA, even at low dose. This effect has been reported in some inflammatory diseases,12 but no work has been done on experimental model of osteoarthritis. Osteoarthritis processes that lead to the structural changes and pain are complex and poorly understood. So far, studies to elucidate the pathophysiology of OA and identify therapeutic interventions to treat the disease have been hampered by the lack of a rapid, reproducible animal model that mimics both the histologic changes and symptoms. A rat model of OA-associated joint discomfort allows both the rapid analysis of the mechanisms involved with OA pain and the evaluation of therapeutic interventions to treat the joint discomfort associated with the disease. This model involves the intra-articular injection of MIA into the right femorotibial joint of Wistar rats. The MIA model is well established and has been utilized in a number of different species including horses, chickens, mice, guinea pigs and rats.5-7 Intra-articular injection of MIA results in an inhibition of glyceraldehye-3-phosphate, ultimately resulting in disruption of chondrocyte metabolism and eventual cell death. This progressive loss of chondrocytes results in histologic changes that resemble several of the salient features noted in human OA, including collapse of the cartilaginous matrix, fibrillation, and osteophyte formation.

The amount of MIA utilized in this study was chosen based on both the degree of joint discomfort and the histologic changes. Interestingly, histologic examination revealed that the MIA primarily targets the articular cartilage of the medial tibial plateaus.13 This is supported by the fact that the rat is a medial weight-bearing animal and demonstrating a requirement for weight bearing on the affected joint for lesion development. Based on these findings, it is apparent that the model appears to reproduce the early lesions of OA, similar to those observed in the human disease. Due to these histologic similarities, various adaptations of the model have been utilized to examine both the pathophysiology of OA and a number of pharmacologic agents including NSAIDs, corticosteroids and inhibitors of matrix metalloproteinases.3,13 These studies, however, have relied on histologic/morphologic end points for determination of efficacy of these agents to modify OA. Alcoholic extract of guggul has been shown to regulate inflammation, obesity, rheumatoid arthritis, hyperlipidemia and thyroid regulatory activity.8,9,10-12 Matrix metalloproteinases (MMP) are enzymes important in maintenance of normal cellular architecture including chondrocyte, assisting with creation of interstitial spaces by destroying structural proteins thereby facilitating multiple inflammatory processes. It has been reported that human chondrocyte MMP’s were inhibited by some herbal extracts such as acetone extract of whole pomegranate fruit in vitro,14 has the potential for prevention and treatment of inflammation and cancer15 and improves a depressive state and bone properties in menopausal syndrome model ovariectomized mice.16

Our results showed that apart from the elimination of inflammation, chondro-protection has happened probably because guggul is able to inhibit MMP in chondrocyte and thus, more proteoglycane existed in the knee joint. Due to the exact histopathological similarity of this experimental osteoarthritis with the one happening in human, the protection of chondrocyte by guggul might have been of great value as a natural remedy for osteoarthritis, rather than consumption of pain relieving agents, which shows a wide range of side effects.

ACKNOWLEDGEMENT

The corresponding author would like to thank Medical Sciences Research Center for their support.

REFERENCES

1. Carter DR, Beaupre GS, Wong M. The mechanobiology of articular cartilage development and degeneration. Clin Orthop 2004;427:69-77.

2. Clavo E, Palacios I, Delgado E. Histopathological correlation of cartilage swelling detected by MRI in early experimental osteoarthritis. Osteoarthritis and Cartilage 2004;11:878-86.

3. Pendleton A, Arden N, EULAR recommendations for the management of knee osteoarthritis: report of a task force of the Standing Committee for International Clinical Studies Including Therapeutic Trials (ESCIIT). Ann Rheum Dis 2000;59:936-44.

4. Dumond H, Presle N, Pottie P. Site-specific changes in gene expression and cartilage metabolism during early experimental osteoarthritis. Osteoarthritis and Cartilage 2004;12:284-95.

5. Guzman RE, Evans MG, Bove S. Mono-iodoacetate- induced histological changes in subchondral bone and articular cartilage of rat Femorotibial joints: an animal model of osteoarthritis. Toxicol Pathol 2003;6:619-24.

6. Guingamp C, Gegout-Pottie P, Philippe L, Mono-iodoacetate-induced experimental osteoarthritis: a dose-response study of loss of mobility, morphology, and biochemistry. Arthritis Rheum 1997;40:1670-9.

7. Kobayashi K, Imaizumi R, Sumichka H. Sodium iodoacetate-induced osteoarthritis and associated pain model in rats. J Vet Med Sci 2003;65:1195-9.

8. Panda S, Kar A, Gugulu (C. Mukul) induces triiodothyronine production/; possible involvement of lipid peroxidation, Pharmacol Lett 1999 65(12):137-141.

9. Saxena G, Pratap SH, Pol R. Gugulipid, an extract of C. Mukul with lipid lowering properties, has protestion against streptozotocin-induced memory deficits in mice, Pharmacol Biochem Behav 2007;86:797-805.

10. Ulbrichta C, Baschb E, Szaparyc P, Hammernessd P, Axentseve S, Boonf H, et al. Guggul for hyperlipidemia: A review by the Natural Standard Research Collaboration, Complementary Therapies in Medicine 2005;13:279-90.

11. Sahni S, Hepfinger CA, Sauer KA. Guggulipid use in hyperlipidemia: case report and review of the literature. Am J Health Syst Pharm 2005;15:62(16):1690-2.

12. Tripathi YB, Reddy MM, Pandey RS, Subhashini, Tiwari OP, Singh BK, et al. Anti-inflammatory properties of BHUx, a polyherbal formulation to prevent atherosclerosis. Inflammopharmacology 2004;2(2):131-52.

13. Bove SE, Calcattera MS, Brooker RM. Weight bearing as a measure of disease progression and efficacy of anti-inflammatory compounds in a model of monosodium iodoacetate-induced osteoarthritis. Osteoarthritis and Cartilage 2003;11:821-30.

14. Ahmed S, Wang N, Hafeez B, Punica granatum L. extract inhibits IL-1beta-induced expression of matrix metalloproteinases by inhibiting the activation of MAP kinases and NF-kappa B in human chondrocytes in vitro. J Nutr 2005;35:2098-102.

15. Lansky E, Newman R. Punica granatum (pomegranate) and its potential for prevention and treatment of inflammation and cancer. J Ethnopharmacol 2007;09:177-06.

16. Mori-Okamoto J, Otawara-Hamamoto Y, Yamato H. Pomegranate extract improves a depressive state and bone properties in menopausal syndrome model ovariectomized mice. J Ethnopharmacol 2004;2:93-101.


HOME   |   SEARCH   |   CURRENT ISSUE   |   PAST ISSUES

Professional Medical Publications
Room No. 522, 5th Floor, Panorama Centre
Building No. 2, P.O. Box 8766, Saddar, Karachi - Pakistan.
Phones : 5688791, 5689285 Fax : 5689860
pjms@