Evidence-based Complementary and Alternative Medicine : eCAM. Dec/31/2011; 2012

Published online Aug/7/2012

PMID: 22924056

PMC: 3424602

doi: 10.1155/2012/817814

The Effects of Cosmos caudatus on Structural Bone Histomorphometry in Ovariectomized Rats

Norazlina Mohamed

Sharon Gwee Sian Khee

Ima-Nirwana Soelaiman

Abstract

Osteoporosis is considered a serious debilitating disease. Cosmos caudatus (ulam raja), a plant containing antioxidant compounds and minerals, may be used to treat and prevent osteoporosis. This study determines the effectiveness of C. caudatus as bone protective agent in postmenopausal osteoporosis rat model. Thirty-two female rats, aged 3 months old, were divided into 4 groups. Group one was sham operated (sham) while group two was ovariectomized. These two groups were given ionized water by forced feeding. Groups three and four were ovariectomized and given calcium 1% ad libitum and force-fed with C. caudatus at the dose of 500 mg/kg, respectively. Treatments were given six days per week for a period of eight weeks. Body weight was monitored every week and structural bone histomorphometry analyses of the femur bones were performed. Ovariectomy decreased trabecular bone volume (BV/TV), decreased trabecular number (Tb.N), and increased trabecular separation (Tb.Sp). Both calcium 1% and 500 mg/kg C. caudatus reversed the above structural bone histomorphometric parameters to normal level. C. caudatus shows better effect compared to calcium 1% on trabecular number (Tb.N) and trabecular separation (Tb.Sp). Therefore, Cosmos caudatus 500 mg/kg has the potential to act as the therapeutic agent to restore bone damage in postmenopausal women.

1. Introduction

Estrogen deficiency increases the risk of developing osteoporosis. Estrogen was found to have antioxidant properties [1] and was also shown to increase the expression of glutathione peroxidase in osteoclasts [2], an enzyme which is responsible for the degradation of hydrogen peroxide. Estrogen deficiency will reduce the expression of the enzyme and renders the bone susceptible to hydrogen peroxide attacks.

In osteoporosis, lipid peroxidation is increased due to the reduction in antioxidants [3], and reactive oxygen species are found to play a role in bone metabolism [4]. Free radicals have also been shown to be cytotoxic to osteoblastic cells [5]. Loss of estrogens accelerates the effects of aging on bone by decreasing defence against oxidative stress which leads to bone loss [6].

Since free radicals and lipid peroxidation are involved in bone metabolism and may be the culprit in causing bone loss, substances having antioxidative activities can overcome the detrimental effects. Our previous studies have shown the beneficial effects of palm-oil derived tocotrienols in several experimental osteoporosis, ovariectomized [7], steroid induced [8], and nicotine induced [9]. The effects of palm-oil derived tocotrienols may be attributed to its antioxidative activities.

Thus, in finding alternatives in the treatment of osteoporosis, a local plant, Cosmos caudatus or locally known as “ulam raja” (King's salad), is of consideration. Previous study has shown that this plant has antioxidative activities [10]. It contains phenolic compounds that contribute to the color, antioxidant, and anticarcinogenic properties of the plants. For every 100 g of Cosmos caudatus, the total phenolic compound is 21.41 mg. It is also found that Cosmos caudatus had extremely high antioxidant capacity of about 2,400 mg l ascorbic acid equivalent antioxidant capacity (AEAC) per 100 g of fresh sample [11]. It is also believed that Cosmos caudatus promote the formation of healthy bones [12]. Thus, we hypothesized that Cosmos caudatus may exert protective effects on bone of ovariectomized rats which is a suitable animal model for studying postmenopausal osteoporosis. In this study, the effects of Cosmos caudatus on structural bone histomorphometry were determined.

2. Materials and Methods

2.1. Animals and Treatment

Thirty-two young adult (3 months) female Wistar rats, weighing 190 g–260 g, were obtained from the Laboratory Animal Resource Unit, Faculty of Medicine, Universiti Kebangsaan Malaysia. Rats were randomly assigned to four groups with eight rats in each group. Group 1 was sham operated (sham) while the second was ovariectomized-control group (OVX). The third and fourth groups were ovariectomized and treated with calcium 1% (Ca) ad libitum and force-fed with 500 mg/kg C. caudatus extract (CC), respectively. Treatment was given six days a week for eight weeks and body weight was recorded weekly. The study was approved by the Universiti Kebangsaan Malaysia Animal Ethics Committee with the approval code of PP/FAR/2008/NORAZLINA/12-AUGUST/225-SEPT-2008-AUG-2009.

2.1.1. Diet, Cosmos caudatus, and Calcium 1%

All rats received normal rat chow obtained from Gold Coin, Malaysia. The composition of rat chow is shown in Table 1. The aqueous extract of C. caudatus with the concentration of 500 g/300 mL was prepared by School of Chemical Sciences & Food Technology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia using water extraction method which was previously described [10]. The 500 mg/kg dose was prepared by mixing C. caudatus with deionized water in ratio 3 : 7. Calcium 1% solution was prepared by mixing 1 g of hemicalcium lactic acid (Sigma Chemical CO., USA) with 100 mL deionized water.

2.2. Ovariectomy

Before the surgery, the rats were anesthetized with Ketamil and Ilium Xylazil-20 (Troy Laboratories PTY, Australia), given intraperitoneally, at 1 : 1 ratio. A vertical incision was made approximately 15 cm in the abdomen using a sterilized sharp knife. The right and left ovaries were cut and removed. Before the ovaries were cut, the fallopian tubes were tied to prevent bleeding. The muscle layer under the skin was stitched up by sterile and soluble suture (Serafit, Germany). Then, the outer layer of skin was sewn with nonwater soluble suture (Seralon, Serag Wiessner, Germany). The procedure for sham operated rats was just the same with ovariectomized rats, but both of the ovaries were not removed. Rats were left recuperating for 1 week before commencing the treatment.

2.3. Bone Histomorphometry

Upon sacrifice, the distal part of the femur was fixed with 70% ethanol and undergoes undecalcified bone preparations. The bone samples were embedded in polymer methyl methacrylate according to Difford [13], sectioned at 9 μm thickness using a microtome, stained using von Kossa method [14], and analyzed using an image analyzer with the Video Test-Master software. The parameters measured were trabecular bone volume (BV/TV), trabecular thickness (Tb.Th), trabecular number (Tb.N), and trabecular separation (Tb.Sp). All measurements were performed randomly at the metaphyseal region, which was located 3–7 mm from the lowest point of the growth plate and 1 mm from the lateral cortex [15]. The selected area is the secondary spongiosa area, which is rich in trabecular bone. All parameters were measured according to the American Society of Bone Mineral Research Histomorphometry Nomenclature Committee [16].

2.4. Statistical Analysis

Results were presented as mean ± standard error of the mean (SEM). All data were analysed using the Statistical Package for Social Sciences software. The Kolmogorov-Smirnov test was used for normality. ANOVA followed by Tukey's HSD tests were used for normally distributed data while Kruskal-Wallis and Mann-Whitney tests were used for not normally distributed data.

3. Results

Figure 1 shows the body weight of all groups throughout the study period. Ovariectomized group gained weight and was significantly different compared to sham-operated group beginning from week 3. Similar findings were observed in the calcium supplemented group. Group supplemented with C. caudatus also showed weight gain but did not differ compared to the sham-operated group.

Figure 2 shows the photomicrographs of trabecular bone with von Kossa staining for the different treatment groups. Ovariectomy caused a reduction in bone volume (BV/TV) and an increase in trabecular separation (Tb.Sp) compared to the control group (Figures 3 and 4, resp.). Administration of C. caudatus was able to improve bone volume and trabecular separation in ovariectomized rats (Figures 3 and 4, resp.) while calcium administration was only able to improve bone volume (Figure 3). In addition, the group supplemented with C. caudatus showed a higher trabecular number compared to ovariectomized group (Figure 5). No significant differences were seen in trabecular thickness (Figure 6).

4. Discussion

Ovariectomized rats have been used by researchers as the model for postmenopausal osteoporosis. Even though limitations exist, certain characteristics in the rat model mimic the bone changes in postmenopausal women and made the study of the human disease possible [17, 18]. Reduction in bone mineral density occurs two months after ovariectomy with greater loss seen in regions rich in trabecular bone [19].

Ovariectomized group showed increase in body weight which was statistically different compared to sham-operated group beginning from week 3 (Figure 1). This observation is common in estrogen-deficient animals since the deficient state induces hyperphagia in rats [20]. Group supplemented with calcium showed the same findings. However, rats given C. caudatus did not show a significant increase in body weight. Cosmos caudatus seemed able to prevent weight gain induced by ovariectomy. However, the exact mechanism of this occurrence is unknown.

In this study, ovariectomy caused loss of bone volume, increase in trabecular separation, and decrease in trabecular number (Figures 3, 4, and 5, resp.). The bone loss is reflected in the photomicrograph of the trabecular bone in which the ovariectomized group showed perforated and discontinued trabecular bone compared to the sham-operated group (Figures 2(a) and 2(b)). Similar findings were observed in other studies [21, 22]. However, trabecular thickness did not show any significant differences between the different groups. This is in contrast with other studies [23, 24] which used micro-CT in their studies as opposed to conventional histomorphometry in our study. In another study which used older rats, ovariectomy was also shown to cause a decrease in trabecular thickness [25]. Different method and different age range of the animals may contribute to the discrepancy seen in this study.

Estrogen deficiency is the major factor which affects bone in ovariectomized rats [26]. The deficiency state induces osteocytes apoptosis which further leads to increase in osteoclastic resorption [27]. Ovariectomy has been associated with increase in oxidative stress as evident by high malondialdehyde levels [28]. The condition of oxidative stress would eventually lead to bone loss [29].

Ovariectomized rats supplemented with C. caudatus showed improvements in bone volume, trabecular separation and trabecular number (Figures 3, 4, and 5, resp.). Photomicrograph of the trabecular bone of rats given C. caudatus appears similar to the sham-operated rats (Figures 2(a) and 2(c)). Cosmos caudatus is shown to contain flavonoids [30] and ascorbic acid [31]. It has also been shown to exert antioxidant activity [32]. This may contribute to the bone protective effects of C. caudatus observed in the present study.

The dose of C. caudatus in this study was chosen based on previous study which used C. caudatus at the dose of 100, 200, and 300 mg/kg. In the previous study, the effects of C. caudatus on bone biochemical markers and bone histomorphometry in ovariectomized rats were determined. It was found that C. caudatus at all doses was able to prevent the increase in interleukin-1 and pyridinoline as seen in the ovariectomized group. However, no significant changes were seen in the bone histomorphometry parameters (unpublished data). Thus, in the present study, a higher dose, 500 mg/kg, was used.

In an acute toxicity study done previously, a single dose of C. caudatus was given to male rats at the dose of 50, 500, and 2000 mg/kg. The rats were kept for 7 days before sacrifice. The higher dose of C. caudatus, that is, 2000 mg/kg, was found to increase liver enzymes but did not cause any changes on the haematological parameters such as clotting time, bleeding time, platelet levels, and white cell count (unpublished data). The observations above imply that C. caudatus at the dose of 500 mg/kg is not associated with side effects.

Calcium supplement in combination with vitamin D is recommended in the treatment regime for patients with osteoporosis [33] to reduce risk of nonvertebral fractures [34]. This combination therapy is considered essential but not sufficient for the treatment of osteoporosis and additional benefit may be obtained with the addition of antiresorptive or anabolic agent [35]. In the present study, calcium supplementation also reversed the effects of ovariectomy on bone volume (Figure 2) but failed to show significant changes in the other parameters. Similar findings were observed in previous study in which ovariectomized rats given calcium supplementation still had lower bone volume and trabecular number as compared to sham-operated rats [36]. In another study using ovariectomized rats, calcium supplementation is shown to improve bone fracture healing but failed to improve strength [37]. Another study showed that calcium supplementation suppresses bone formation in magnesium-deficient rats [38]. The findings above suggested that calcium may need to be present with other elements to exert beneficial effects on bone.

All rats received rat chow which contained 0.8–1.2% calcium. The Ca group received additional 1% calcium in drinking water. However, since the calcium was administered via drinking water, the amount of calcium ingested by the rats may vary between individual rats thus causing inconsistent results in the histomorphometry parameters mentioned above.

In the present study, we observed that C. caudatus improved bone structural histomorphometric parameters. In fact, C. caudatus seemed to yield better effects on bone in terms of trabecular separation and trabecular number (Figures 4 and 5). According to Nutriweb Malaysia [39], C. caudatus contains 270 mg calcium per 100 g of the plant. This composition, in addition to its antioxidative property, enables C. caudatus to have a greater effect in reversing bone changes induced by ovariectomy as opposed to calcium supplementation.

Further studies are required to establish the effects of Cosmos caudatus on bone such as the effects on dynamic histomorphometry, bone biomarkers, bone density, and bone calcium content. In addition, further studies are also required to ascertain the active compound and calcium content of the plant as well as its exact mechanism on bone.

5. Conclusion

Cosmos caudatus at the dose of 500 mg/kg reversed bone changes induced by ovariectomy. Thus, C. caudatus has the potential to be used as an alternative for the treatment of postmenopausal osteoporosis.

Figure 1

Body weight of rats for all treatment groups. *Indicates significant difference (P < 0.05) compared to SO group. SO, sham operated; Ovx, ovariectomized; CC, ovariectomized and supplemented with 500 mg/kg Cosmos caudatus; Ca, ovariectomized and supplemented with 1% calcium.

Figure 2

Photomicrographs of trabecular bone. Undecalcified section (100 x magnification) shows trabecular bone (stained black) using von Kossa method. SO, sham operated; Ovx, ovariectomized; CC, ovariectomized and supplemented with 500 mg/kg Cosmos caudatus; Ca, ovariectomized and supplemented with 1% calcium.

Figure 3

Effects of Cosmos caudatus supplementation on bone volume in ovariectomized rats. Groups which share the same alphabet indicate significant difference (P < 0.05). SO, sham operated; Ovx, ovariectomized; CC, ovariectomized and supplemented with 500 mg/kg Cosmos caudatus; Ca, ovariectomized and supplemented with 1% calcium.

Figure 4

Effects of Cosmos caudatus supplementation on trabecular separation in ovariectomized rats. Groups which share the same alphabet indicate significant difference (P < 0.05). SO, sham operated; Ovx, ovariectomized; CC, ovariectomized and supplemented with 500 mg/kg Cosmos caudatus; Ca, ovariectomized and supplemented with 1% calcium.

Figure 5

Effects of Cosmos caudatus supplementation on trabecular number in ovariectomized rats. Groups which share the same alphabet indicate significant difference (P < 0.05). SO, sham operated; Ovx, ovariectomized; CC, ovariectomized and supplemented with 500 mg/kg Cosmos caudatus; Ca, ovariectomized and supplemented with 1% calcium.

Figure 6

Effects of Cosmos caudatus supplementation on trabecular thickness in ovariectomized rats. SO, sham operated; Ovx, ovariectomized; CC, ovariectomized and supplemented with 500 mg/kg Cosmos caudatus; Ca, ovariectomized and supplemented with 1% calcium.

Table 1

Composition of rat chow (Golden Coin, Malaysia).

Composition	Amount/percentage
Crude protein	21–23%
Crude fibre (max)	5.0%
Crude fat (min)	3.0%
Moisture (max)	3.0%
Calcium	0.8–1.2%
Phosphorus	0.6–1.0%
Nitrogen free extract	49.0%
Vitamin A	10 M.I.U.
Vitamin D₃	2.5 M.I.U
Vitamin E	15 g
Vitamin K	trace
Vitamin B₁₂	trace
Thiamine	trace
Riboflavin	trace
Pantothenic acid	trace
Niacin	trace
Pyridoxine	trace
Choline	trace
Santoquin	trace
Microminerals	trace

Acknowledgments

The authors would like to thank Mr. Muhamad Arizi Aziz for the technical support. The authors also expressed their gratitude to the Faculty of Medicine, Universiti Kebangsaan Malaysia for funding the research (Grant no. FF-193-2008).

References

1. BadeauMAdlercreutzHKaihovaaraPTikkanenMJEstrogen A-ring structure and antioxidative effect on lipoproteinsJournal of Steroid Biochemistry and Molecular Biology2005963-4271278[PubMed][Google Scholar]
2. LeanJMJaggerCJKirsteinBFullerKChambersTJHydrogen peroxide is essential for estrogen-deficiency bone loss and osteoclast formationEndocrinology20051462728735[PubMed][Google Scholar]
3. MaggioDBarabaniMPierandreiMMarked decrease in plasma antioxidants in aged osteoporotic women: results of a cross-sectional studyJournal of Clinical Endocrinology and Metabolism200388415231527[PubMed][Google Scholar]
4. SontakkeANTareRSA duality in the roles of reactive oxygen species with respect to bone metabolismClinica Chimica Acta20023181-2145148[PubMed][Google Scholar]
5. MoreauMFChappardDLesourdMMontheardJPBasleMFFree radicals and side products released during methylmethacrylate polimeryzation are cytotoxic for osteoblastic cellsJournal of Biomedical Materials Research199840124131[PubMed][Google Scholar]
6. AlmeidaMHanLMartin-MillanMSkeletal involution by age-associated oxidative stress and its acceleration by loss of sex steroidsJournal of Biological Chemistry2007282372728527297[PubMed][Google Scholar]
7. NorazlinaMIma-NirwanaSGaporMTKhalidBAKPalm vitamin E is comparable to α-tocopherol in maintaining bone mineral density in ovariectomised female ratsExperimental and Clinical Endocrinology and Diabetes20001084305310[PubMed][Google Scholar]
8. Ima-NirwanaSFakhruraziHPalm vitamin E protects bone against dexamethasone-induced osteoporosis in male ratsMedical Journal of Malaysia200257133141[PubMed][Google Scholar]
9. NorazlinaMLeePLLukmanHINazrunASIma-NirwanaSEffects of vitamin E supplementation on bone metabolism in nicotine-treated ratsSingapore Medical Journal2007483195199[PubMed][Google Scholar]
10. Huda-FaujanNNorihamANorrakiahASBabjiASAntioxidative activities of water extracts of some Malaysian herbsASEAN Food Journal20071416168[PubMed][Google Scholar]
11. ShuiGLeongLPShihPWRapid screening and characterisation of antioxidants of Cosmos caudatus using liquid chromatography coupled with mass spectrometryJournal of Chromatography B20058271127138[PubMed][Google Scholar]
12. IsmailSSayuran Tradisional Ulam dan Penyedap Rasa2000Bangui, Central African RepublicUKM
13. DiffordJA simplified method for the preparation of methyl methacrylate embedding medium for undecalcified boneMedical Laboratory Technology19743117981[PubMed][Google Scholar]
14. Von KossaJNachweis von Kalk. Beitrage zur pathologischen Anatomie und zur allgemeinenPathologie190129, article 163[Google Scholar]
15. BaldockPAJMorrisHANeedAGMooreRJDurbridgeTCVariation in the short-term changes in bone cell activity in three regions of the distal femur immediately following ovariectomyJournal of Bone and Mineral Research199813914511457[PubMed][Google Scholar]
16. ParfittAMDreznerMKGlorieuxFHBone histomorphometry: standardization of nomenclature, symbols, and units. Report of the ASBMR Histomorphometry Nomenclature CommitteeJournal of Bone and Mineral Research198726595610[PubMed][Google Scholar]
17. LelovasPPXanthosTTThormaSELyritisGPDontasIAThe laboratory rat as an animal model for osteoporosis researchComparative Medicine2008585424430[PubMed][Google Scholar]
18. TurnerASAnimal models of osteoporosis—necessity and limitationsEuropean Cells and Materials200116681[PubMed][Google Scholar]
19. Ima-NirwanaSNorazlinaMKhalidBAKPattern of bone mineral density in growing male and female rats after gonadectomyJournal of ASEAN Federation of Endocrine Societies1998162136[Google Scholar]
20. EckelLAThe ovarian hormone estradiol plays a crucial role in the control of food intake in femalesPhysiology and Behavior20111044517524[PubMed][Google Scholar]
21. GuoHYJiangLIbrahimSAOrally administered lactoferrin preserves bone mass and microarchitecture in ovariectomized ratsJournal of Nutrition20091395958964[PubMed][Google Scholar]
22. WashimiYItoMMorishimaYEffect of combined humanPTH(1-34) and calcitonin treatment in ovariectomized ratsBone2007415786793[PubMed][Google Scholar]
23. ZhangRLiuZGLiCDu-Zhong (Eucommia ulmoides Oliv.) cortex extract prevent OVX-induced osteoporosis in ratsBone2009453553559[PubMed][Google Scholar]
24. YaoXChenHEmuraSOtakeNShoumuraSEffects of hPTH (1-34) and Gosha-jinki-gan on the trabecular bone microarchitecture in ovariectomized rat tibiaOkajimas Folia Anatomica Japonica2007834107114[PubMed][Google Scholar]
25. RamamurthyNSBainSLiangCTA combination of subtherapeutic doses of chemically modified doxycycline (CMT-8) and a bisphosphonate (Clodronate) inhibits bone loss in the ovariectomized rat: a dynamic histomorphometric and gene expression studyCurrent Medicinal Chemistry200183295303[PubMed][Google Scholar]
26. RouachVKatzburgSKochYSternNSomjenDBone loss in ovariectomized rats: dominant role for estrogen but apparently not for FSHJournal of Cellular Biochemistry20111121128137[PubMed][Google Scholar]
27. EmertonKBHuBWooAAOsteocyte apoptosis and control of bone resorption following ovariectomy in miceBone2010463577583[PubMed][Google Scholar]
28. AydinHDeyneliOYavuzDEffect of oxidative stress on aorta and tibia osteoprotegerin gene expression in ovariectomized ratsMinerva Endocrinologica2011362107115[PubMed][Google Scholar]
29. ZhangYBZhongZMHouGJiangHChenJTInvolvement of oxidative stress in age-related bone lossJournal of Surgical Research20111691e37e42[PubMed][Google Scholar]
30. MustafaRAHamidAAMohamedSBakarFATotal phenolic compounds, flavonoids, and radical scavenging activity of 21 selected tropical plantsJournal of Food Science2010751C28C35[PubMed][Google Scholar]
31. AndarwulanNKurniasihDApriadyRARahmatHRotoAVBollingBWPolyphenols, carotenoids, and ascorbic acid in underutilized medicinal vegetablesJournal of Functional Foods201241339347[Google Scholar]
32. RafatAPhilipKMuniandySAntioxidant properties of indigenous raw and fermented salad plantsInternational Journal of Food Properties2011143599608[PubMed][Google Scholar]
33. BellJSBlackerNEdwardsSOsteoporosis—pharmacological prevention and management in older peopleAustralian Family Physician2012413110118[PubMed][Google Scholar]
34. BodyJJHow to manage postmenopausal osteoporosis?Acta Clinica Belgica2011666443447[PubMed][Google Scholar]
35. LecartMPReginsterJYCurrent options for the management of postmenopausal osteoporosisExpert Opinion on Pharmacotherapy2011121625332552[PubMed][Google Scholar]
36. ShenVBirchmanRXuRLindsayRDempsterDWShort-term changes in histomorphometric and biochemical turnover markers and bone mineral density in estrogen and/or dietary calcium-deficient ratsBone1995161149156[PubMed][Google Scholar]
37. ShuidANMohamadSMohamedNEffects of calcium supplements on fracture healing in a rat osteoporotic modelJournal of Orthopaedic Research2010281216511656[PubMed][Google Scholar]
38. MatsuzakiHMiwaMDietary calcium supplementation suppresses bone formation in magnesium-deficient ratsInternational Journal for Vitamin and Nutrition Research2006763111116[PubMed][Google Scholar]
39. Nutriweb MalaysiaNutrition Composition database - Ulam Raja2012, http://www.nutriweb.org.my/cgi-bin/dbrecords.cgi?comp=Minerals&submit_do=View&food_no=105105&part1=Raw+and+Processed&fname=Ulam+raja&group=Vegetables&mname=Ulam+raja