Experimental model of osteoporosis: comparison between ovariectomy and botulinum toxin A

Atmaca, Halil; Aydin, Adem; Musaoğlu, Resul

doi:10.1590/S1413-78522013000600009

Abstracts

OBJECTIVE: To evaluate whether Botulinum toxin-A (BTx-A) has a similar effect to that of ovariectomy (OVx) on bone regarding bone mineral densitometry. METHODS: A total of 51 female rats were randomly divided into three groups of 17 animals each. The rats in the first group formed the control group, without any surgical procedure (Group 1). Group 2 received BTx-A while Group 3 was subjected to OVx. A total of 8 IU of BTx-A was injected into the right femoral region of all rats in Group 2. At baseline and 14 weeks later, bone mineral densities (BMD) of the left and right femurs of all rats in both groups were measured. RESULTS: There was no statistically significant difference between the groups with respect to baseline BMD. At the 14th week the BMD of the right femurs were statistically significantly higher in Group 1 than other groups, although there was no statistically significant difference between Groups 2 and 3. The mean BMD results of the left femur in Group 3 were statistically significantly lower than the results in Groups 1 and 2 at the 14th week. CONCLUSION: The results of the current study showed that BTx-A had a similar effect to that of OVx on osteoporosis regarding BMD. Evidence Level I, Experimental, Controlled, Animal Study.

Botulinum toxins, type A; Ovariectomy; Osteoporosis

OBJETIVO: Avaliar se a toxina botulínica tipo A (TB-A) tem efeito similar ao da ovariectomia (OVX) sobre os ossos com relação à densitometria mineral óssea. MÉTODOS: Um total de 51 ratas foi dividido randomicamente em três grupos de 17 animais cada. As ratas no primeiro grupo foram o controle, sem qualquer procedimento cirúrgico (Grupo 1). O Grupo 2 recebeu TB-A, enquanto o Grupo 3 foi submetido a OVX. Um total de 8 UI de TB-A foi injetado na região femoral direita de todas as ratas do Grupo 2. No início do estudo e 14 semanas depois, mediu-se a densidade mineral óssea (DMO) dos fêmures esquerdo e direito de todas as ratas em ambos os grupos. RESULTADOS: Não houve diferença estatisticamente significante entre os grupos com relação à DMO do início do estudo. Na 14ªsemana, a DMO dos fêmures direitos foi estatisticamente superior no Grupo 1 do que nos outros grupos, embora não houvesse diferença com significância estatística entre os Grupos 2 e 3. Os resultados médios da DMO dos fêmures esquerdos no Grupo 3 foram inferiores, com significância estatística, do que os resultados dos Grupos 1 e 2 na 14ª semana. CONCLUSÃO: Os resultados do presente estudo mostraram que a TB-A teve efeito similar ao da OVX sobre a osteoporose, no que diz respeito à DMO. Nível de Evidência I, Estudo Experimental, Controlado em Animais.

Toxinas botulínicas tipo A; Ovariectomia; Osteoporose

ORIGINAL ARTICLE

Experimental model of osteoporosis: comparison between ovariectomy and botulinum toxin A

Halil Atmaca^I; Adem Aydin^II; Resul Musaoğlu^III

^IDepartment of Orthopaedics and Traumatology, Midyat State Hospital , Mardin-Turkey

^IIDepartment of Orthopaedics and Traumatology, Izmit Seka State Hospital Kocaeli-Turkey

^IIIDepartment of Orthopaedics and Traumatology, Kocaeli University, School of Medicine, Kocaeli-Turkey

^{Correspondence} Correspondence: Midyat State Hospital Department of Orthopaedics and Traumatology 47500 Mardin-Turkey drhalilatmaca@hotmail.com

ABSTRACT

OBJECTIVE: To evaluate whether Botulinum toxin-A (BTX-A) has a similar effect to that of ovariectomy (OVX) on bone regarding bone mineral densitometry.

METHODS: A total of 51 female rats were randomly divided into three groups of 17 animals each. The rats in the first group formed the control group, without any surgical procedure (Group 1). Group 2 received BTX-A while Group 3 was subjected to OVX. A total of 8 IU of BTX-A was injected into the right femoral region of all rats in Group 2. At baseline and 14 weeks later, bone mineral densities (BMD) of the left and right femurs of all rats in both groups were measured.

RESULTS: There was no statistically significant difference between the groups with respect to baseline BMD. At the 14^th week the BMD of the right femurs were statistically significantly higher in Group 1 than other groups, although there was no statistically significant difference between Groups 2 and 3. The mean BMD results of the left femur in Group 3 were statistically significantly lower than the results in Groups 1 and 2 at the 14^th week.

CONCLUSION: The results of the current study showed that BTX-A had a similar effect to that of OVX on osteoporosis regarding BMD. Evidence Level I, Experimental, Controlled, Animal Study.

Keywords: Botulinum toxins, type A. Ovariectomy. Osteoporosis.

INTRODUCTION

Osteoporosis is a chronic disease that affects millions people characterized by a decrease in bone mass and deterioration in bone micro architecture which leads to an enhance fragility of the skeleton, and therefore to a greater risk of fracture. Decreased physical activity and skeletal unloading may contribute to osteoporotic bone loss. Prolonged immobilization consequent to long periods of bed rest, decreased muscle function caused by neurological conditions and injuries, as well as weightlessness of spaceflight result in a very fast and severe bone loss attended by uncoupling between bone formation and resorption. Removal of physical loading decreases osteoblast function, whereas mechanical stimulation in general has been shown to have an anabolic effect on bone cell dynamics, bone mass, and quality.¹ Animal models provide more uniform experimental material and allow for extensive testing of potential therapies. The high cost and long time frame of clinical testing are other reasons why animal models play a crucial role in osteoporosis research.² Ovariectomy, change of diet, drugs, immobilization, breeding, central control of bone mass are commonly used for an osteoporosis animal model.³ The ovariectomized (OVX) rat model is most commonly used in research on postmenopausal osteoporosis. After ovariectomy, bone resorption exceeds bone formation initially, causing bone loss. Soon thereafter, bone remodelling reaches a steady state, where resorption and formation are balanced.⁴

Botulinum toxin type A (BTX-A) is one of seven serologically distinct neuromuscular blocking agents produced by the bacterium Clostridium botulinum.⁵ BTX-A is highly specific for motor nerve terminals and has a high capacity for diffusion through muscle upon injection. These factors make BTX-A an ideal agent for induction of muscle weakness and paralysis. Our hypothesized was that immobilization of the extremity after BTX-A injection may causes regional osteoporosis in the injected side. The main purpose of this study was to evaluate whether BTX-A has a similar effect with OVX on bones regarding to bone mineral densitometry (BMD).

MATERIALS AND METHODS

Animal Model and Study Design

This experimental study was carried out in the Experimental Medicine and Clinical Research Unit (EMCRU) of Kocaeli University after the approval of the Animal Research Ethical Committee was obtained. In the present study, 51 female Wistar Albino rats aged 3-3.5 months, weighing between 200-300g were used as experimental animals. The Animals were divided randomly in to three groups of seventeen animals each. The rats in the first group were control with no additional surgical procedure (Group 1). Group 2 received BTX-A while Group 3 was subjected to OVX. Total of 8 IU of BTX-A (Botox^®, Allergan, Irvine, California) was injected into the right femoral region of all rats in group 2; 4 IU into the anterior muscle group and 4 IU into the posterior muscle group.⁶ At the beginning and 14 weeks later, bone mineral density (BMD) of the left and right femurs of all rats in three groups were measured in vivo under ketamin anesthesia with a dual-energy X-ray absorbsiometry. After initial BMD measurements bilateral ovariectomy was performed to the rats in group 3. The rats were anaesthetized with an intra-peritoneal injection of ketamine (50 mg/kg-Ketalar^®). 500 mg/kg ampicillin-sulbactam (Ampisid^®) was injected intramuscularly to the rats. Rats were shaved and aseptically prepared and were operated by the same surgeon.OVX were performed by transverse ventral incision. All Rats were acclimatized to caged laboratory conditions and were allowed to feed with a standard diet and water ad libitum. The room temperature and humidity were maintained at 20-24ºC and at 50-60%, respectively. The light cycle was fixed at 12 hours. Two animals in group 1, one in group 2 and two in group 3 died during the follow- up period (one during surgery) so 46 rats with 92 femur were evaluated finally. All animals in this study were sacrificed at 14^th week by using high dose of ketamine.

Bone densitometry

At the baseline and 14 week later, bone mineral density (BMD) of the femurs were measured in vivo under anesthesia with a dual-energy X-ray absorptiometer (Norland XR-36) using the small-animal software in each rat. Initially 51 rats with 102 femurs were evaluated while 46 rats with 92 femurs were measured at the end of 14 weeks. In all measurements the animals were placed in a supine position with a complete abduction of the hind limbs and each analysis was performed by the same researcher. The instrument was calibrated daily. The scan images were analyzed and BMD (in grams per square centimeter) (gr/cm²) of the metaphyseal zone of proximal femurs were determined.

Statistical analysis

Each mouse had its BMD evaluated separately in twelve subgroups for the right and left femurs regarding to mean baseline and final (14^th week). Mean and standard deviation (SD) were calculated for descriptive statistics of continuous variables and median values for discrete variables. Kolmogorov-Smirnov test was used to analyse the normality of data. The means of groups were analyzed by using ANOVA. Post hoc Bonferroni's multiple comparison procedure was used to determine which values were significantly different. Paired t-tests were used to compare means for BMD data between the subgroups. Two tailed hypothesis was considered in the analyses and a significant difference was accepted while p<0.05. SPSS 15.0 Software for Windows (SPSS Inc., Chicago, IL, USA) was used in the evaluation of statistical analysis.

RESULTS

The mean BMDs at the beginning and final follow-up of right and left femurs of all animals as show in Figure 1. There was no statistically significant difference between the groups with respect to baseline BMD of right and left femurs (p = 1,000 and p = 0,788 respectively). With respect to 14^th week BMD of the right femurs, there was statistically differences between the groups (p=0,000). Bonferroni test showed the difference was sourced from group 1 when compared with the others while there was no statistically significant difference between groups 2 and 3 (p =0,256). The mean BMD results of the left femurs in group 3 were statistically lower than the results in groups 1 and 2 at the time of 14^th week. The statistically significance results of all subgroups were given in Table 1.

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DISCUSSION

BMD' decrease after ovariectomy is expected in both femurs.⁴ Also BTX-A injection decreased BMD of the right femurs of the rats as same as OVX while there was no statistically significant difference between the left femurs of same animals in group 2 and the rats in control group.

Several experimental interventions are used to induce osteopenia and osteoporosis in the rats.⁴ The rate of bone loss in male and female rats is highly dependent upon the method used to induce osteoporosis, and the site evaluated and if that loss refers to the cancellous or cortical bone.^4,7 All experimental osteoporosis protocols can be implemented in skeletally immature or mature rats.⁸ Although rats reach sexual maturity at the age of 2.5 months, their skeleton is considered mature after the age of 10 months.⁷ If skeletally immature rats are involved, then a low peak bone mass is achieved, a fact that is considered to be a high risk factor for human osteoporotic fractures. This trait is why the skeletally immature rat is an appropriate animal model in the research of endocrine, nutritional and environmental factors, all of which can influence peak bone mass.

The skeletally mature rat is an appropriate animal model for the research of postmenopausal and immobilization osteoporosis.⁹ After OVX, bone resorption exceeds bone formation initially, causing bone loss. Soon thereafter, bone remodelling reaches a steady state, where resorption and formation are balanced.⁴ In cortical bone, enlargement of the marrow cavity is an indirect measure of bone loss. This enlargement in the diaphysis of long bones is due to increased endosteal bone resorption¹⁰ and periosteal bone apposition.¹¹ Endosteal resorption and the simultaneous periosteal bone formation result in a very slow rate of cortical bone loss.¹¹ The main concerns about OVX are its irreversible and generalize effects on bones and other systemic. But BTX-A is easy to apply and has reversible and regional osteoporotic effect on bones.

Another method for inducing osteoporosis in rats is through immobilization. There are several methods of immobilization.^4,12,13 Because of the regional acceleratory phenomenon, the rate of bone loss is more fast after surgical methods than immobilization.¹⁴ In the immobilization model, the bulk of bone loss occurs in the hind limbs, because they are the sites of greatest mechanical loading, but in general, the rate of bone loss is faster in cancellous than in cortical bone. This difference can partly be attributed to the surface to volume ratio, which is increased in cancellous bone.⁷ In the current study BTX-A was used as a method of immobilization and had similar result on BMD with OVX. Nevertheless; the lack of fast mobilization due to paralyze of right femurs of the rats in group 2, there was slight and statistically insignificant decrease in the left femurs with respect to BMD.

Recently Aydın et al.¹⁵ reported their results regarding the effect of BTX-A on fracture healing. They reported statistically significant increase in union, spongious bone formation and bone marrow organization scores as well as elastic modulus value of BTX-A injected sides. They concluded that BTX-A administration increases the healing power in a relatively fixated fracture and decreases the callus diameter as if rigid fixation had been performed.¹⁵ Nevertheless, Hao et al.¹⁶ aimed to investigate whether local muscle atrophy and dysfunction affect fracture healing in a rat femur fracture model by using Botulinum toxin A (BTX-A). They concluded that; biomechanical testing indicated that the femurs of the BXTA-treated side exhibited inferior mechanical properties compared with the control side. The inferior outcome following BXTA injection, compared with saline injection, in terms of callus resistance may be the consequence of unexpected load and mechanical unsteadiness caused by muscle atrophy and dysfunction. Based on this information; it may be mentioned that the usage of BTX-A instead of OVX is not recommended in the study which evaluate fracture healing and osteoporosis simultaneously.

The association of both metods, OVX and immobilization can combining the advantages of both and also can markedly reduce the time when bone mass loss becomes apparent, especially for cortical bone.^17,18 The current study mainly suffers from the lack of data on the effect of OVX and immobilization in same subjects. Although biomechanical characteristics, cortical and cancelleous bone thickness and also muscle weights to investigate atrophy were not evaluated, the current study showed BTX-A had similar effect on BMD with OVX which may be use further investigations about experimental animal osteoporosis models.

CONCLUSION

The results of the current study showed that BTX-A has a similar osteoporotic effect with OVX on bones regarding bone mineral densitometry in rats that has been common used for animal model of osteoporosis.

REFERENCES

Article received in 01/06/2013, approved in 07/31/2013

All the authors declare that there is no potential conflict of interest referring to this article.

Work performed at Experimental Medicine and Clinical Research Unit (EMCRU) of Kocaeli University, Kocaeli-Turkey.

1. Bikle DD, Halloran BP, Morey-Holton E. Space flight and the skeleton: lessons for the earthbound. Endocrinologist. 1997;7(1):10-22.
2. Hartke JR. Preclinical development of agents for the treatment of osteoporosis. Toxicol Pathol. 1999;27(1):143-7.
3. Egermann M, Goldhahn J, Schneider E. Animal models for fracture treatment in osteoporosis. Osteoporos Int. 2005;16(Suppl 2):S129-38.
4. Lelovas PP, Xanthos TT, Thoma SE, Lyritis GP, Dontas IA. The laboratory rat as an animal model for osteoporosis research. Comp Med. 2008;58(5):424-30.
5. Brin MF. Botulinum toxin: chemistry, pharmacology, toxicity, and immunology. Muscle Nerve Suppl. 1997;6:S146-68.
6. Aoki KR. A comparison of the safety margins of botulinum neurotoxin serotypes A, B, and F in mice. Toxicon. 2001;39(12):1815-20.
7. Jee WS, Yao W. Overview: animal models of osteopenia and osteoporosis. J Musculoskelet Neuronal Interact. 2001;1(3):193-207.
8. Shen V, Liang XG, Birchman R, Wu DD, Healy D, Lindsay R, et al. Short-term immobilization-induced cancellous bone loss is limited to regions undergoing high turnover and/or modeling in mature rats. Bone. 1997;21(1):71-8.
9. Turner RT, Maran A, Lotinun S, Hefferan T, Evans GL, Zhang M, et al. Animal models for osteoporosis. Rev Endocr Metab Disord. 2001;2(1):117-27.
10. Turner RT, Vandersteenhoven JJ, Bell NH. The effects of ovariectomy and 17 beta-estradiol on cortical bone histomorphometry in growing rats. J Bone Miner Res. 1987;2(2):115-22.
11. Miller SC, Bowman BM, Miller MA, Bagi CM. Calcium absorption and osseous organ-, tissue-, and envelope-specific changes following ovariectomy in rats. Bone. 1991;12(6):439-46.
12. Zeng QQ, Jee WS, Bigornia AE, King JG Jr, D' Souza SM, Li XJ, et al. Time responses of cancellous and cortical bones to sciatic neurectomy in growing female rats. Bone. 1996;19(1):13-21.
13. Thompson DD, Rodan GA. Indomethacin inhibition of tenotomy-induced bone resorption in rats. J Bone Miner Res. 1988;3(4):409-14.
14. Frost HM. The regional acceleratory phenomenon: a review. Henry Ford Hosp Med J. 1983;31(1):3-9.
15. Aydin A, Memisoglu K, Cengiz A, Atmaca H, Muezzinoglu B, Muezzinoglu US. Effects of botulinum toxin A on fracture healing in rats: an experimental study. J Orthop Sci. 2012;17(6):796-801.
16. Hao Y, Ma Y, Wang X, Jin F, Ge S. Short-term muscle atrophy caused by botulinum toxin-A local injection impairs fracture healing in the rat femur. J Orthop Res. 2012;30(4):574-80.
17. Cavolina JM, Evans GL, Harris SA, Zhang M, Westerlind KC, Turner RT. The effects of orbital spaceflight on bone histomorphometry and messenger ribonucleic acid levels for bone matrix proteins and skeletal signaling peptides in ovariectomized growing rats. Endocrinology. 1997;138(4):1567-76.
18. Okumura H, Yamamuro T, Kasai R, Hayashi T, Tada K, Nishii Y. Effect of 1 alpha-hydroxyvitamin D3 on osteoporosis induced by immobilization combined with ovariectomy in rats. Bone. 1987;8(6):351-5.

Correspondence:

Midyat State Hospital

Department of Orthopaedics and Traumatology

47500 Mardin-Turkey

drhalilatmaca@hotmail.com

Publication Dates

Publication in this collection
05 Nov 2013
Date of issue
2013

History

Received
06 Jan 2013
Accepted
31 July 2013

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Bikle DD, Halloran BP, Morey-Holton E. Space flight and the skeleton: lessons for the earthbound. Endocrinologist. 1997;7(1):10-22.

[2] 2. Hartke JR. Preclinical development of agents for the treatment of osteoporosis. Toxicol Pathol. 1999;27(1):143-7.

[3] 3. Egermann M, Goldhahn J, Schneider E. Animal models for fracture treatment in osteoporosis. Osteoporos Int. 2005;16(Suppl 2):S129-38.

[4] 4. Lelovas PP, Xanthos TT, Thoma SE, Lyritis GP, Dontas IA. The laboratory rat as an animal model for osteoporosis research. Comp Med. 2008;58(5):424-30.

[5] 5. Brin MF. Botulinum toxin: chemistry, pharmacology, toxicity, and immunology. Muscle Nerve Suppl. 1997;6:S146-68.

[6] 6. Aoki KR. A comparison of the safety margins of botulinum neurotoxin serotypes A, B, and F in mice. Toxicon. 2001;39(12):1815-20.

[7] 7. Jee WS, Yao W. Overview: animal models of osteopenia and osteoporosis. J Musculoskelet Neuronal Interact. 2001;1(3):193-207.

[8] 8. Shen V, Liang XG, Birchman R, Wu DD, Healy D, Lindsay R, et al. Short-term immobilization-induced cancellous bone loss is limited to regions undergoing high turnover and/or modeling in mature rats. Bone. 1997;21(1):71-8.

[9] 9. Turner RT, Maran A, Lotinun S, Hefferan T, Evans GL, Zhang M, et al. Animal models for osteoporosis. Rev Endocr Metab Disord. 2001;2(1):117-27.

[10] 10. Turner RT, Vandersteenhoven JJ, Bell NH. The effects of ovariectomy and 17 beta-estradiol on cortical bone histomorphometry in growing rats. J Bone Miner Res. 1987;2(2):115-22.

[11] 11. Miller SC, Bowman BM, Miller MA, Bagi CM. Calcium absorption and osseous organ-, tissue-, and envelope-specific changes following ovariectomy in rats. Bone. 1991;12(6):439-46.

[12] 12. Zeng QQ, Jee WS, Bigornia AE, King JG Jr, D' Souza SM, Li XJ, et al. Time responses of cancellous and cortical bones to sciatic neurectomy in growing female rats. Bone. 1996;19(1):13-21.

[13] 13. Thompson DD, Rodan GA. Indomethacin inhibition of tenotomy-induced bone resorption in rats. J Bone Miner Res. 1988;3(4):409-14.

[14] 14. Frost HM. The regional acceleratory phenomenon: a review. Henry Ford Hosp Med J. 1983;31(1):3-9.

[15] 15. Aydin A, Memisoglu K, Cengiz A, Atmaca H, Muezzinoglu B, Muezzinoglu US. Effects of botulinum toxin A on fracture healing in rats: an experimental study. J Orthop Sci. 2012;17(6):796-801.

[16] 16. Hao Y, Ma Y, Wang X, Jin F, Ge S. Short-term muscle atrophy caused by botulinum toxin-A local injection impairs fracture healing in the rat femur. J Orthop Res. 2012;30(4):574-80.

[17] 17. Cavolina JM, Evans GL, Harris SA, Zhang M, Westerlind KC, Turner RT. The effects of orbital spaceflight on bone histomorphometry and messenger ribonucleic acid levels for bone matrix proteins and skeletal signaling peptides in ovariectomized growing rats. Endocrinology. 1997;138(4):1567-76.

[18] 18. Okumura H, Yamamuro T, Kasai R, Hayashi T, Tada K, Nishii Y. Effect of 1 alpha-hydroxyvitamin D3 on osteoporosis induced by immobilization combined with ovariectomy in rats. Bone. 1987;8(6):351-5.

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Experimental model of osteoporosis: comparison between ovariectomy and botulinum toxin A

Abstracts

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History