Adverse effect of beta-tricalcium phosphate with zeta potential control in repairing critical defects in rats' calvaria

Souza, Daniel Falbo Martins de; Correa, Luciana; Sendyk, Daniel Isaac; Burim, Rafael Augusto; Naclério-Homem, Maria da Graça; Deboni, Maria Cristina Zindel

doi:10.1016/j.rboe.2015.07.010

ABSTRACT

OBJECTIVE:

To evaluate whether a new biphasic cement composed of calcium sulfate and beta tricalcium phosphate with zeta potential control could induce or lead to bone neoformation in critical defects.

METHODS:

A critical defect of diameter 8 mm was made in the calvaria of forty male Wistar rats. In the Test Group (n = 20), the defects were filled with cement. In the Control Group (n = 20), the defect was not filled and only coagulum was present. The animals were sacrificed 7, 14, 21 and 42 days after the operation. Calvaria specimens were subjected to microtomography and were then prepared for histological analysis. The analyses included morphological assessment on the histopathology of the repair; comparative morphometric evaluation of the area of formation of bone trabeculae between the groups; and histochemical staining by means of tartrate-resistant phosphatase (TRAP) in order to identify osteoclasts.

RESULTS:

Microtomographic images of the defects filled by the cement did not show any decrease in area over the course of postoperative evolution. In the Test Group, the material continued to present a foreign-body response until the last observational periods. Histomorphological analysis showed that there were more significant groupings of giant cells in the Test Group and greater maturity of neoformed bone in the Control Group. Exogenous material was also present. Histomorphometric analysis showed that in the Control Group, the total area of bone neoformation was significantly greater (p = 0.009) and grew progressively. The giant cells presented a positive reaction to TRAP but no osteoclasts were observed.

CONCLUSION:

The ceramic cement did not induce or lead to bone neoformation from the microtomographic or histological point of view.

Keywords:
Bone regeneration; Wistar rats; Biocompatible materials; Zeta potential

RESUMO

OBJETIVO:

Avaliar se um novo cimento bifásico composto por sulfato de cálcio e beta fosfato tricálcico com controle de potencial zeta poderia induzir ou conduzir a neoformação óssea em defeitos críticos.

MÉTODOS:

Foi feito um defeito crítico de 8 mm de diâmetro na calvária de 40 ratos Wistar machos. No grupo teste (n = 20) os defeitos foram preenchidos pelo cimento. No grupo controle (n = 20) os defeitos não foram preenchidos, permaneceu apenas o coágulo. Os animais sofreram eutanásia em 7, 14, 21 e 42 dias do pós-operatório. Espécimes da calvária foram microtomografados e posteriormente preparados para análise histológica. As análises incluíram a avaliação morfológica da histopatologia do reparo e a avaliação morfométrica da área de formação das trabéculas ósseas comparativamente entre os grupos e coloração histoquímica por meio da fosfatase tartrato-resistente (TRAP) para identificação de osteoclastos.

RESULTADOS:

As imagens microtomográficas dos defeitos preenchidos pelo cimento não apresentaram diminuição da área de acordo com a progressão dos períodos pós-operatórios. No grupo teste houve permanência do material e resposta corpo estranho até os últimos períodos de observação. A histomorfologia mostrou agrupamentos mais expressivos de células gigantes no grupo teste e osso neoformado mais maduro no grupo controle e comprovou a presença de material exógeno. Na histomorfometria, a área total de neoformação óssea foi significativamente maior (p = 0,009) e crescente no grupo controle. As células gigantes apresentaram expressão histoquímica positiva para TRAP e não foram observados osteoclatos.

CONCLUSÃO:

O cimento cerâmico não induziu ou conduziu a neoformação óssea sob o ponto de vista microtomográfico e histológico.

Palavras-chave:
Regeneração óssea; Ratos Wistar; Materiais biocompatíveis; Potencial zeta

Introduction

Autogenous graft is still the material of choice for the reconstruction of bone tissue loss in orthopedic and maxillofacial surgery. However, increase in operation time, surgical trauma and possible complications inherent to the donor area approach does not always make it feasible. New biomaterials and substances that can mimic the characteristics of the autogenous bone tissue have been a constant pursuit of bioengineering.

Among the alloplastic materials most often used nowadays are bioceramics, mainly hydroxyapatite and beta-tricalcium phosphate (ß-TCP). The latter shows a more rapid biodegradation than hydroxyapatite and in some situations this may be a more advantageous characteristic for a biomaterial, mainly when there is no need for mechanical strength. Moreover, beta-tricalcium phosphate has been widely used as a carrier or scaffold in tissue engineering.

Recently, a biphasic ceramic material consisting of calcium sulfate and beta-tricalcium phosphate with a negative surface charge, called zeta potential control, was launched in the international market with the proposal of making beta-tricalcium phosphate an inductive bone substitute and thus, promote bone regeneration.¹1. Yang HL, Zhu XS, Chen L, Chen CM, Mangham DC, Coulton LA, et al. Bone healing response to a synthetic calcium sulfate/ - tricalcium phosphate graft material in a sheep vertebral body defect model. J Biomed Mater Res B Appl Biomater. 2012;100(7):1911-21.

According to the manufacturer,²2. Biocomposites L. GeneX((r)) . Injectable bone graft with ZPC. Biocomposites, Ltda.; 2014. Available at: http://www.biocomposites.com/ortho/Genex2.asp [cited 15.02.14].
http://www.biocomposites.com/ortho/Genex... this ceramic is fully synthetic and has what they called "intelligent porosity", which facilitates cell growth and nutrient distribution in the extracellular matrix internally in the macroporosities of this compound. Some authors have demonstrated intense bone regeneration capacity in vertebral defects in sheep.¹1. Yang HL, Zhu XS, Chen L, Chen CM, Mangham DC, Coulton LA, et al. Bone healing response to a synthetic calcium sulfate/ - tricalcium phosphate graft material in a sheep vertebral body defect model. J Biomed Mater Res B Appl Biomater. 2012;100(7):1911-21.

The osteogenic potential of this compound, however, has been questioned. Some authors have shown concern about the biological safety of the product.³3. Saadoun S, Macdonald C, Bell BA, Papadopoulos MC. Dangers of bone graft substitutes: lessons from using GeneX. J Neurol Neurosurg Psychiatry. 2011;82(8):e3. Other researchers⁴4. Friesenbichler J, Maurer-Ertl W, Sadoghi P, Pirker- Fruehauf U, Bodo K, Leithner A. Adverse reactions of artificial bone graft substitutes: lessons learned from using tricalcium phosphate geneX((r)) . Clin Orthop Relat Res. 2014;472(3):976-82. discontinued early clinical trials due to the appearance of unexpected adverse effects, such as aseptic inflammation and delayed repair. The literature is scarce on the analysis of the biological behavior of this new biomaterial in bone repair in in vivo studies.

In this context, we propose an in vivo study to assess, from the microtomographic and histological point of view, whether this bioceramic compound can induce or lead to bone neoformation in critical defect models in rat calvaria.

Material and methods

Experimental procedure

This research project was approved by the Institutional Ethics Committee on Animal Use (CEUA) under protocol number 006/2014 and in accordance with the ethical principles of animal experimentation adopted by the Brazilian Society for Laboratory Animal Science (SBCAL).

Forty (40) male Wistar rats (Rattus norvegicus albinus), weighing between 200 g and 250 g and aged approximately 45 days, were operated on under general anesthesia by intramuscular injection in the right rear paw of each animal of ketamine hydrochloride (Dopalen^(r), Vetbrands) at a dose of 0.8 mg/kg associated with muscle relaxant xylazine (Rompum^(r), Bayer) at a dose of 0.3 mg/kg. All animals received antibiotic prophylaxis through intramuscular injection of benzathine benzylpenicillin (Roche^(r)) at a dose of 150,000 IU/kg.

After trichotomy, followed by skin antisepsis with 2% chlorhexidine digluconate, an access was made to the calvaria through a 2 cm-rectilinear incision in the skin of the medial region of the skull, extending from the nasofrontal area to the occipital protuberance. The skin, subcutaneous tissue, temporal muscle and the periosteum were divulsed laterally.

A bone defect was created in the central region of the animal calvaria using an 8 mm-diameter steel trephine drill (Sistemas de Implantes Nacionais - SIN^(r)), adapted to a counter-angle implant motor (Driller^(r) - Carapicuíba - São Paulo) under low speed and constant irrigation with 0.9% saline solution.

The animals were randomly divided into two groups: Test Group (n = 20), which received cement consisting of beta tricalcium phosphate (ß-TCP) and calcium sulphate at a ratio of 1:1 (Genex - Biocomposites^(r) - Staffordshire - England) to fill the critical defect in the calvaria at the amount of 25 mm³3. Saadoun S, Macdonald C, Bell BA, Papadopoulos MC. Dangers of bone graft substitutes: lessons from using GeneX. J Neurol Neurosurg Psychiatry. 2011;82(8):e3. per defect, and the Control Group (n = 20), which remained with the critical defect filled only by a clot.

Synthesis of the skin was performed with 3/0 silk thread (Ethicon^(r)). Throughout the study period, the animals were kept in ventilated polypropylene cages, covered with sterilized wood shavings, with day/night cycles of 12/12 h, and were fed rodent chow (Labina for Rodents, Purina^(r)) and water ad libitum.

Five animals from each group were euthanized in a CO₂ chamber after 7, 14, 21 and 42 days postoperatively. After euthanasia, the skulls were dissected and representative fragments of the calvaria with the defect area were fixed in 10% buffered formalin.

Prior to the processing and histological analysis, a specimen from a rat in the Test Group and from a rat in the Control Group, in each of the study periods, were submitted to microtomography in a 100 kV to 100 µA SkyScan microtomographer in the Department of Animal Physiology of the Biology Institute of Universidade de São Paulo.

The samples were placed at and fixed to the equipment cell, which was set for a resolution of 2000 × 2000 pixels and 16 µm sections. The time of image acquisition was approximately 2 h per sample. Images were analyzed and reconstructed in two and three dimensions, using the InVesalius sofware (Division of Three-Dimensional Technologies of Centro de Tecnologia da Informação de Campinas - São Paulo).

The biomaterial volume was quantified in cubic millimeters (mm³3. Saadoun S, Macdonald C, Bell BA, Papadopoulos MC. Dangers of bone graft substitutes: lessons from using GeneX. J Neurol Neurosurg Psychiatry. 2011;82(8):e3.). In the two-dimensional images, the sagittal and axial distances of the bone defect and three-dimensional axial distance were measured in millimeters (mm).

For the histological analysis, the specimens (n = 5) from each group and preoperative observation period were immersed in 10% EDTA solution (pH 7.4) for six weeks for bone tissue decalcification. The defect area was sectioned in half, exactly at the median sagittal plane of the rat calvaria, which resulted in two parts of the wound: the left side and the right side (S1 and S2). Each side of the defect was embedded in paraffin and subsequently, four 4.5 cm-thick parasagittal sections were obtained and stained with Masson trichrome. Histological sections were assessed using a conventional light microscope (Olimpus^(r) CH2, Olympus Optical Co. Ltd., Japan) in a blinded fashion by an experienced pathologist. The histomorphological aspects considered the presence of the following repair characteristics: edema, inflammatory infiltrate, granulation tissue, bleeding/blood clot, bone neoformation, foreign body reaction and the presence of exogenous material. The parameters were weighed using an arbitrary scale by the following scores: 0 = absent; 1 = mild; 2 = mild to moderate; 3 = moderate to intense and 4 = intense.

The histomorphometric analysis was used to quantify the neoformed bone tissue area in randomly selected sections on both halves (left and right) in three regions of the wound, the anterior region (close to the nasal bone), the central region and the posterior region (close to the occipital bone). Histological images of each region were obtained with a 40× magnification using a CCD camera (Sony^(r)) coupled to a microscope (Jeol^(r)) and an image capture board (Captivator^(r)).

Then, these images were transferred to a digital morphometry software program (ImageJ, NIH - National Institutes of Health). The formation of neoformed trabecular bone was identified and delimited using a hand free software tool. Measurements were performed in four semi-serial histological sections of each slide.

The total area of bone neoformation was obtained at each field and added to the value obtained on the opposite side of the wound. At the end, mean was calculated for the total area of neoformed bone tissue for each group and period.

In order to identify osteoclastic cells, two randomized cuts on each side of the wound from two animals from each group were randomly chosen and submitted to histochemical staining to demonstrate tartar phosphatase-resistant acid (TRAP). Histological sections were incubated for 3 h at room temperature, in solution containing sodium tartrate, tartaric acid and disodium salt (Sigma(tm)).

After incubation, the sections were rinsed in tap water, allowed to air dry at 25 °C and counterstained with 1% fast green (Fisher Scientific Co.) for approximately 1 min. A mouse femur section (stored paraffin-embedded material) with bone wound repair was used as a positive control for this immunohistochemical reaction. After staining, the slides were kept in dark field to be subsequently assessed under light microscopy.

Histological data were analyzed by nonparametric inferential statistics using the Mann-Whitney test with the Biostat 5.0 software with a significance level of 5%.

Results

The results of microtomographic image analysis are shown in Table 1 and Fig. 1. The intensity in gray levels of the biomaterial was close to that of bone, but the biomaterial showed granularity, allowing it to be differentiated from bone.

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Table 1
Volume of remaining material and microtomographic two-dimensional, three-dimensional measurements of bone defects according to the periods of postoperative observation in the Test and Control Groups.

Fig. 1
Coronal view of the calvaria defects reconstructed by MicroCT in the control and Test Groups according to the observation periods. At (a) 7 days, (b) 14 days, (c) 21 days and (d) 42 days after surgery the Control Group show the defect image without bone neoformation. At (e) 7 days, (f) 14 days, (g) 14 days and (h) 42 days after surgery, the Test Group shows in blue the remaining volume of ßTCP cement.

Histological examination regarding repair morphology is shown in Table 2 and main histological aspects are shown in Fig. 2. Fig. 3 shows the result of staining for TRAP (tartrate -resistant acid phosphatase) in the Test Group 42 days postoperatively.

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Table 2
Values of the medians [max-min] of the score intensities for the histological variables of the bone defect.

Fig. 2
Histological sections representative of critical defects in each group in the periods of 21 and 42 days postoperatively. In (A) Control Group - 21 days, shows deposition of collagen and osteoid matrix adjacent to the defect border (arrow). In (B) Test Group - 21 days, shows exogenous material cluster (long arrow) encapsulated by intense deposition of fibrous connective tissue (short arrow). In (C) Control Group - 42 days, shows bone deposition of mature and immature bone on the defect borders (arrow). In (D) intense deposition of fibrous connective tissue and clusters of exogenous material and nests of adjacent giant cells (arrow) (Masson staining, magnification 2.5×).

Fig. 3
Positive expression of tartrate-resistant acid phosphatase (TRAP) of multinucleated giant cells (large arrows) adjacent to the exogenous material clusters (thin arrows) - Test Group period of 42 days (TRAP staining, magnification 40×).

Results of the histomorphometric analysis of bone neoformation area are shown in Fig. 4.

Fig. 4
Histomorphometric analysis for the area (µm²⁾ of bone neoformation related to the groups and periods. Means (± standard deviation).

Discussion

The literature describes that calcium phosphates and their derivatives, including beta-tricalcium phosphate, act more directly on osteoblasts and have been extensively studied as bone replacement for more than two decades, as they promote bone neoformation by osteoconduction and have good biocompatibility.⁵5. Pioletti DP, Takei H, Lin T, Van Landuyt P, Ma QJ, Kwon SY, et al. The effects of calcium phosphate cement particles on osteoblast functions. Biomaterials. 2000;21(11):1103-14.^,⁶6. Handschel J, Wiesmann HP, Stratmann U, Kleinheinz J, Meyer U, Joos U. TCP is hardly resorbed and not osteoconductive in a non-loading calvarial model. Biomaterials. 2002;23(7):1689-95.^and⁷7. Matsumoto G, Omi Y, Kubota E, Ozono S, Tsuzuki H, Kinoshita Y, et al. Enhanced regeneration of critical bone defects using a biodegradable gelatin sponge and beta-tricalcium phosphate with bone morphogenetic protein-2. J Biomater Appl. 2009;24(4):327-42.

Its effects as inorganic scaffold for bone tissue regeneration are already well documented, including dental lesions,⁸8. Aguirre Zorzano LA, Rodríguez Tojo MJ, Aguirre Urizar JM. Maxillary sinus lift with intraoral autologous bone and B-tricalcium phosphate: histological and histomorphometric clinical study. Med Oral Patol Oral Cir Bucal. 2007;12(7): E532-6.^,⁹9. Ortega EV, Mourelo JP, Egea JJS, Perez OP, Soteras RM. La utilización del betafosfato tricálcico como biomaterial en implantología oral. Rev Periodoncia. 2007;19(3):141-9.^,¹⁰10. Mourelo JP, Guerra AJ, Guil LM, Egea JJS, Ortega EV. Regeneración ósea guiada con implante unitario con nanosuperficie y betafosfato tricálcico. Rev Periodoncia. 2010;22(3):127-37.^and¹¹11. Zavaglia FC. Síntese, caracterização e processamento de beta fosfato tricálcico para a manufatura de implantes personalizados [tese]. Campinas: Universidade Estadual de Campinas, Faculdade de Engenharia Química; 2011. in spite of still controversial findings, ranging from bone neoformation that is superior to the one observed in autogenous grafts¹²12. Luvizuto ER, Tangl S, Zanoni G, Okamoto T, Sonoda CK, Gruber R, et al. The effect of BMP-2 on the osteoconductive properties of - tricalcium phosphate in rat calvaria defects. Biomaterials. 2011;32(15):3855-61. and anorganic bovine bone graft,¹³13. Velasco Ortega E, Pato Mourelo J, Segura Egea JJ, Pérez Pérez O, Medel Soteras R. La utilización del beta-fosfato tricálcico como biomaterial en implantologia oral. Av Periodoncia. 2007;19(3):141-50. to robust evidence of insufficient osteogenesis.¹⁴14. Orii H, Sotome S, Chen J, Wang J, Shinomiya K. Beta-tricalcium phosphate (beta-TCP) graft combined with bone marrow stromal cells (MSCs) for posterolateral spine fusion. J Med Dent Sci. 2005;52(1):51-7.^and¹⁵15. Gupta MC, Theerajunyaporn T, Maitra S, Schmidt MB, Holy CE, Kadiyala S, et al. Efficacy of mesenchymal stem cell enriched grafts in an ovine posterolateral lumbar spine model. Spine (Phila Pa 1976). 2007;32(7):720-6.

The biomaterial used in this study (GeneX^(r)) is relatively new and it is a ceramic compound, which has negative surface charge control. Investigations about its efficacy have most often focused on repair defects of the spine or long bones.¹⁶16. Liu B, Lun DX. Current application of - tricalcium phosphate composites in orthopaedics. Orthop Surg. 2012;4(3):139-44. Yang et al.¹1. Yang HL, Zhu XS, Chen L, Chen CM, Mangham DC, Coulton LA, et al. Bone healing response to a synthetic calcium sulfate/ - tricalcium phosphate graft material in a sheep vertebral body defect model. J Biomed Mater Res B Appl Biomater. 2012;100(7):1911-21. demonstrated in an in vivo study that this ceramic material promoted superior bone formation in vertebral defects in eight weeks when compared with the use of a polymer cement (polymethylmethacrylate). However, in their conclusions, they indicate that the ß-TCP ceramic needs to be further assessed.

As the manufacturer's proposal was to add a surface treatment on the ceramic particles that allowed osteoinduction, a critical bone defect model would provide important information if the bone neoformation occurred where it would not be expected.

This type of model is quite often described in the literature and it is, in a way, acknowledged for this type of in vivo assay. ¹⁷17. Einhorn TA. Clinically applied models of bone regeneration in tissue engineering research. Clin Orthop Relat Res. 1999; 367 Suppl:S59-67.^,¹⁸18. Cacchioli A, Spaggiari B, Ravanetti F, Martini FM, Borghetti P, Gabbi C. The critical sized bone defect: morphological study of bone healing. Ann Fac Med Vet Parma. 2006;26:97-110.^,¹⁹19. Bodde EW, Boerman OC, Russel FG, Mikos AG, Spauwen PH, Jansen JA. The kinetic and biological activity of different loaded rhBMP-2 calcium phosphate cement implants in rats. J Biomed Mater Res A. 2008;87(3):780-91.^,²⁰20. Messora MR, Nagata MJ, Dornelles RC, Bomfim SR, Furlaneto FA, de Melo LG, et al. Bone healing in critical-size defects treated with platelet-rich plasma activated by two different methods. A histologic and histometric study in rat calvaria. J Periodontal Res. 2008;43(6):723-9.^,²¹21. Efeoglu C, Burke JL, Parsons AJ, Aitchison GA, Scotchford C, Rudd C, et al. Analysis of calvarial bone defects in rats using microcomputed tomography: potential for a novel composite material and a new quantitative measurement. Br J Oral Maxillofac Surg. 2009;47(8):616-21.^,²²22. Paulo Ade O, Castro- Silva II, Oliveira DF, Machado ME, Bonetti- Filho I, Granjeiro JM. Repair of critical-size defects with autogenous periosteum-derived cells combined with bovine anorganic apatite/collagen: an experimental study in rat calvaria. Braz Dent J. 2011;22(4):322-8.^,²³23. Scotchford CA, Shahtaheri M, Chen PS, Evans M, Parsons AJ, Aitchison GA, et al. Repair of calvarial defects in rats by prefabricated, degradable, long fibre composite implants. J Biomed Mater Res A. 2011;96(1):230-8.^and²⁴24. Spicer PP, Kretlow JD, Young S, Jansen JA, Kasper FK, Mikos AG. Evaluation of bone regeneration using the rat critical size calvarial defect. Nat Protoc. 2012;7(10):1918-29. We used the critical defect model in rat calvaria because it is easy to create, reproduce and the fact that an 8 mm-extension defect would allow us to verify the occurrence of osteoconduction or induction of the material in a standardized and reliable manner.

Contrary to the favorable outcome described by German researchers,²⁵25. Smeets R, Kolk A, Gerressen M, Driemel O, Maciejewski O, Hermanns- Sachweh B, et al. A new biphasic osteoinductive calcium composite material with a negative Zeta potential for bone augmentation. Head Face Med. 2009;5:13. our results did not show bone neoformation after insertion of this ceramic compound in filling defects. Cement with zeta potential control did not stimulate bone neoformation in critical defects created in rat calvaria or showed rapid absorption by the volume of exogenous material observed in microtomographic images in all study periods.

Recently, Saadoun et al.³3. Saadoun S, Macdonald C, Bell BA, Papadopoulos MC. Dangers of bone graft substitutes: lessons from using GeneX. J Neurol Neurosurg Psychiatry. 2011;82(8):e3. and Friesenbichler et al.⁴4. Friesenbichler J, Maurer-Ertl W, Sadoghi P, Pirker- Fruehauf U, Bodo K, Leithner A. Adverse reactions of artificial bone graft substitutes: lessons learned from using tricalcium phosphate geneX((r)) . Clin Orthop Relat Res. 2014;472(3):976-82. showed significant complications of this material on tissues when used to fill bone defects in clinical trials, although Laycock and Cooper²⁶26. Laycock PA, Cooper JJ. Adverse reactions of artificial bone graft substitutes: lessons learned from using tricalcium phosphate geneX((r)) . Clin Orthop Relat Res. 2014;472(2):765-6. attributed these adverse effects to the still inadequate use of this biomaterial.

Obviously, the presence of a significantly higher amount of inflammatory infiltrate in the Test Group is directly related to the greater response to the presence of a foreign body when compared to the Control Group. The fact that the foreign body response remained for the entire duration of the experiment can lead to the formation of material clusters, which should be expelled from the wound area in the encapsulated form. This fact may help to explain the description of "soft tissue cysts" made by Friesenbichler et al.⁴4. Friesenbichler J, Maurer-Ertl W, Sadoghi P, Pirker- Fruehauf U, Bodo K, Leithner A. Adverse reactions of artificial bone graft substitutes: lessons learned from using tricalcium phosphate geneX((r)) . Clin Orthop Relat Res. 2014;472(3):976-82.

The clinical relevance of this study should be emphasized from the histopathological point of view, because there were no standardized experimental preclinical studies to disclose the behavior of this material on the repair of healthy bone tissue yet.

According to the histomorphometric findings, the proposal of a more significant bone neoformation in the Test Group was not demonstrated either. The results show that bone formation was more intense and significantly higher in the Control Group and denied our hypothesis of trying to demonstrate the osteoinductive potential promised by the manufacturer.

Results showed that the superiority in bone formation in controls led us to believe that this ceramic composite prevented the small bone formation that would occur in the defect.

Our results are also in accordance with those from other authors,²⁷27. Gera I, Döri F, Keglevich T, Anton S, Szilágyi E, Windisch P. Experience with the clinical use of beta-tri-calcium phosphate (Cerasorb) as a bone replacement graft material in human periodontal osseous defects. Fogorv Sz. 2002;95(4):143-7.^and²⁸28. Frota R, Da Silva-Júnior VA, Teixeira M, Sobral AP, Emanuel-Dias-de Oliveira e Silva, Da Silveira MM, et al. Histological evaluation of bone repair using - tricalcium phosphate. Med Oral Patol Oral Cir Bucal. 2011;16(2):e190-4. according to whom the application of other types of beta-tricalcium phosphate for bone loss repair, in minor defects and crossover studies in the same animal did not influence the amount of bone formation.

To assess whether there was increased osteoclastogenesis and increased bone resorption, a histochemical reaction was carried out by TRAP staining in the wound area. However, the foreign body response giant cells were the ones that showed positivity for this biochemical marker. This may lead to the hypothesis that the material in the tissue might possibly have induced specific biochemical signals.

Thus, giant cells, probably in an attempt to absorb exogenous material, might also have resorbed bone. Studies demonstrating the expression of other specific markers related to repair and induction of bone tissue formation could be carried out to better explain this fact.

By the time this study was planned, we expected to find beneficial effects of Genex^(r) in bone regeneration, especially considering that this material had favorable reports in clinical use. Finally, our results are relevant, as they confirm that this type of ceramic must be reconsidered as a bone substitute.

Conclusion

Within the limitations of this study, the biphasic ceramic cement consisting of calcium sulfate and beta-tricalcium phosphate and zeta potential did not induce or resulted in bone neoformation of 8 mm critical bone defects created in rat calvaria from the microtomographic and histological points of view.

Acknowledgements

To Prof. Dr. Jorge Vicente Lopes da Silva and Paulo Henrique Junqueira Amorim - CTI Renato Archer - Division of Three-dimensional technologies - Campinas - SP - Brazil, for the processing and analyses of 3D images.

References

¹
Yang HL, Zhu XS, Chen L, Chen CM, Mangham DC, Coulton LA, et al. Bone healing response to a synthetic calcium sulfate/ - tricalcium phosphate graft material in a sheep vertebral body defect model. J Biomed Mater Res B Appl Biomater. 2012;100(7):1911-21.
²
Biocomposites L. GeneX((r)) . Injectable bone graft with ZPC. Biocomposites, Ltda.; 2014. Available at: http://www.biocomposites.com/ortho/Genex2.asp [cited 15.02.14].
» http://www.biocomposites.com/ortho/Genex2.asp
³
Saadoun S, Macdonald C, Bell BA, Papadopoulos MC. Dangers of bone graft substitutes: lessons from using GeneX. J Neurol Neurosurg Psychiatry. 2011;82(8):e3.
⁴
Friesenbichler J, Maurer-Ertl W, Sadoghi P, Pirker- Fruehauf U, Bodo K, Leithner A. Adverse reactions of artificial bone graft substitutes: lessons learned from using tricalcium phosphate geneX((r)) . Clin Orthop Relat Res. 2014;472(3):976-82.
⁵
Pioletti DP, Takei H, Lin T, Van Landuyt P, Ma QJ, Kwon SY, et al. The effects of calcium phosphate cement particles on osteoblast functions. Biomaterials. 2000;21(11):1103-14.
⁶
Handschel J, Wiesmann HP, Stratmann U, Kleinheinz J, Meyer U, Joos U. TCP is hardly resorbed and not osteoconductive in a non-loading calvarial model. Biomaterials. 2002;23(7):1689-95.
⁷
Matsumoto G, Omi Y, Kubota E, Ozono S, Tsuzuki H, Kinoshita Y, et al. Enhanced regeneration of critical bone defects using a biodegradable gelatin sponge and beta-tricalcium phosphate with bone morphogenetic protein-2. J Biomater Appl. 2009;24(4):327-42.
⁸
Aguirre Zorzano LA, Rodríguez Tojo MJ, Aguirre Urizar JM. Maxillary sinus lift with intraoral autologous bone and B-tricalcium phosphate: histological and histomorphometric clinical study. Med Oral Patol Oral Cir Bucal. 2007;12(7): E532-6.
⁹
Ortega EV, Mourelo JP, Egea JJS, Perez OP, Soteras RM. La utilización del betafosfato tricálcico como biomaterial en implantología oral. Rev Periodoncia. 2007;19(3):141-9.
¹⁰
Mourelo JP, Guerra AJ, Guil LM, Egea JJS, Ortega EV. Regeneración ósea guiada con implante unitario con nanosuperficie y betafosfato tricálcico. Rev Periodoncia. 2010;22(3):127-37.
¹¹
Zavaglia FC. Síntese, caracterização e processamento de beta fosfato tricálcico para a manufatura de implantes personalizados [tese]. Campinas: Universidade Estadual de Campinas, Faculdade de Engenharia Química; 2011.
¹²
Luvizuto ER, Tangl S, Zanoni G, Okamoto T, Sonoda CK, Gruber R, et al. The effect of BMP-2 on the osteoconductive properties of - tricalcium phosphate in rat calvaria defects. Biomaterials. 2011;32(15):3855-61.
¹³
Velasco Ortega E, Pato Mourelo J, Segura Egea JJ, Pérez Pérez O, Medel Soteras R. La utilización del beta-fosfato tricálcico como biomaterial en implantologia oral. Av Periodoncia. 2007;19(3):141-50.
¹⁴
Orii H, Sotome S, Chen J, Wang J, Shinomiya K. Beta-tricalcium phosphate (beta-TCP) graft combined with bone marrow stromal cells (MSCs) for posterolateral spine fusion. J Med Dent Sci. 2005;52(1):51-7.
¹⁵
Gupta MC, Theerajunyaporn T, Maitra S, Schmidt MB, Holy CE, Kadiyala S, et al. Efficacy of mesenchymal stem cell enriched grafts in an ovine posterolateral lumbar spine model. Spine (Phila Pa 1976). 2007;32(7):720-6.
¹⁶
Liu B, Lun DX. Current application of - tricalcium phosphate composites in orthopaedics. Orthop Surg. 2012;4(3):139-44.
¹⁷
Einhorn TA. Clinically applied models of bone regeneration in tissue engineering research. Clin Orthop Relat Res. 1999; 367 Suppl:S59-67.
¹⁸
Cacchioli A, Spaggiari B, Ravanetti F, Martini FM, Borghetti P, Gabbi C. The critical sized bone defect: morphological study of bone healing. Ann Fac Med Vet Parma. 2006;26:97-110.
¹⁹
Bodde EW, Boerman OC, Russel FG, Mikos AG, Spauwen PH, Jansen JA. The kinetic and biological activity of different loaded rhBMP-2 calcium phosphate cement implants in rats. J Biomed Mater Res A. 2008;87(3):780-91.
²⁰
Messora MR, Nagata MJ, Dornelles RC, Bomfim SR, Furlaneto FA, de Melo LG, et al. Bone healing in critical-size defects treated with platelet-rich plasma activated by two different methods. A histologic and histometric study in rat calvaria. J Periodontal Res. 2008;43(6):723-9.
²¹
Efeoglu C, Burke JL, Parsons AJ, Aitchison GA, Scotchford C, Rudd C, et al. Analysis of calvarial bone defects in rats using microcomputed tomography: potential for a novel composite material and a new quantitative measurement. Br J Oral Maxillofac Surg. 2009;47(8):616-21.
²²
Paulo Ade O, Castro- Silva II, Oliveira DF, Machado ME, Bonetti- Filho I, Granjeiro JM. Repair of critical-size defects with autogenous periosteum-derived cells combined with bovine anorganic apatite/collagen: an experimental study in rat calvaria. Braz Dent J. 2011;22(4):322-8.
²³
Scotchford CA, Shahtaheri M, Chen PS, Evans M, Parsons AJ, Aitchison GA, et al. Repair of calvarial defects in rats by prefabricated, degradable, long fibre composite implants. J Biomed Mater Res A. 2011;96(1):230-8.
²⁴
Spicer PP, Kretlow JD, Young S, Jansen JA, Kasper FK, Mikos AG. Evaluation of bone regeneration using the rat critical size calvarial defect. Nat Protoc. 2012;7(10):1918-29.
²⁵
Smeets R, Kolk A, Gerressen M, Driemel O, Maciejewski O, Hermanns- Sachweh B, et al. A new biphasic osteoinductive calcium composite material with a negative Zeta potential for bone augmentation. Head Face Med. 2009;5:13.
²⁶
Laycock PA, Cooper JJ. Adverse reactions of artificial bone graft substitutes: lessons learned from using tricalcium phosphate geneX((r)) . Clin Orthop Relat Res. 2014;472(2):765-6.
²⁷
Gera I, Döri F, Keglevich T, Anton S, Szilágyi E, Windisch P. Experience with the clinical use of beta-tri-calcium phosphate (Cerasorb) as a bone replacement graft material in human periodontal osseous defects. Fogorv Sz. 2002;95(4):143-7.
²⁸
Frota R, Da Silva-Júnior VA, Teixeira M, Sobral AP, Emanuel-Dias-de Oliveira e Silva, Da Silveira MM, et al. Histological evaluation of bone repair using - tricalcium phosphate. Med Oral Patol Oral Cir Bucal. 2011;16(2):e190-4.

☆
Study carried out at the Department of Surgery, Prosthesis and Oral and Maxillofacial Traumatology, Faculdade de Odontologia, Universidade de São Paulo (USP), São Paulo, SP, Brazil.

Publication Dates

Publication in this collection
May-Jun 2016

History

Received
22 June 2015
Accepted
07 July 2015

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[4] ⁴
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[8] ⁸
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[10] ¹⁰
Mourelo JP, Guerra AJ, Guil LM, Egea JJS, Ortega EV. Regeneración ósea guiada con implante unitario con nanosuperficie y betafosfato tricálcico. Rev Periodoncia. 2010;22(3):127-37.

[11] ¹¹
Zavaglia FC. Síntese, caracterização e processamento de beta fosfato tricálcico para a manufatura de implantes personalizados [tese]. Campinas: Universidade Estadual de Campinas, Faculdade de Engenharia Química; 2011.

[12] ¹²
Luvizuto ER, Tangl S, Zanoni G, Okamoto T, Sonoda CK, Gruber R, et al. The effect of BMP-2 on the osteoconductive properties of - tricalcium phosphate in rat calvaria defects. Biomaterials. 2011;32(15):3855-61.

[13] ¹³
Velasco Ortega E, Pato Mourelo J, Segura Egea JJ, Pérez Pérez O, Medel Soteras R. La utilización del beta-fosfato tricálcico como biomaterial en implantologia oral. Av Periodoncia. 2007;19(3):141-50.

[14] ¹⁴
Orii H, Sotome S, Chen J, Wang J, Shinomiya K. Beta-tricalcium phosphate (beta-TCP) graft combined with bone marrow stromal cells (MSCs) for posterolateral spine fusion. J Med Dent Sci. 2005;52(1):51-7.

[15] ¹⁵
Gupta MC, Theerajunyaporn T, Maitra S, Schmidt MB, Holy CE, Kadiyala S, et al. Efficacy of mesenchymal stem cell enriched grafts in an ovine posterolateral lumbar spine model. Spine (Phila Pa 1976). 2007;32(7):720-6.

[16] ¹⁶
Liu B, Lun DX. Current application of - tricalcium phosphate composites in orthopaedics. Orthop Surg. 2012;4(3):139-44.

[17] ¹⁷
Einhorn TA. Clinically applied models of bone regeneration in tissue engineering research. Clin Orthop Relat Res. 1999; 367 Suppl:S59-67.

[18] ¹⁸
Cacchioli A, Spaggiari B, Ravanetti F, Martini FM, Borghetti P, Gabbi C. The critical sized bone defect: morphological study of bone healing. Ann Fac Med Vet Parma. 2006;26:97-110.

[19] ¹⁹
Bodde EW, Boerman OC, Russel FG, Mikos AG, Spauwen PH, Jansen JA. The kinetic and biological activity of different loaded rhBMP-2 calcium phosphate cement implants in rats. J Biomed Mater Res A. 2008;87(3):780-91.

[20] ²⁰
Messora MR, Nagata MJ, Dornelles RC, Bomfim SR, Furlaneto FA, de Melo LG, et al. Bone healing in critical-size defects treated with platelet-rich plasma activated by two different methods. A histologic and histometric study in rat calvaria. J Periodontal Res. 2008;43(6):723-9.

[21] ²¹
Efeoglu C, Burke JL, Parsons AJ, Aitchison GA, Scotchford C, Rudd C, et al. Analysis of calvarial bone defects in rats using microcomputed tomography: potential for a novel composite material and a new quantitative measurement. Br J Oral Maxillofac Surg. 2009;47(8):616-21.

[22] ²²
Paulo Ade O, Castro- Silva II, Oliveira DF, Machado ME, Bonetti- Filho I, Granjeiro JM. Repair of critical-size defects with autogenous periosteum-derived cells combined with bovine anorganic apatite/collagen: an experimental study in rat calvaria. Braz Dent J. 2011;22(4):322-8.

[23] ²³
Scotchford CA, Shahtaheri M, Chen PS, Evans M, Parsons AJ, Aitchison GA, et al. Repair of calvarial defects in rats by prefabricated, degradable, long fibre composite implants. J Biomed Mater Res A. 2011;96(1):230-8.

[24] ²⁴
Spicer PP, Kretlow JD, Young S, Jansen JA, Kasper FK, Mikos AG. Evaluation of bone regeneration using the rat critical size calvarial defect. Nat Protoc. 2012;7(10):1918-29.

[25] ²⁵
Smeets R, Kolk A, Gerressen M, Driemel O, Maciejewski O, Hermanns- Sachweh B, et al. A new biphasic osteoinductive calcium composite material with a negative Zeta potential for bone augmentation. Head Face Med. 2009;5:13.

[26] ²⁶
Laycock PA, Cooper JJ. Adverse reactions of artificial bone graft substitutes: lessons learned from using tricalcium phosphate geneX((r)) . Clin Orthop Relat Res. 2014;472(2):765-6.

[27] ²⁷
Gera I, Döri F, Keglevich T, Anton S, Szilágyi E, Windisch P. Experience with the clinical use of beta-tri-calcium phosphate (Cerasorb) as a bone replacement graft material in human periodontal osseous defects. Fogorv Sz. 2002;95(4):143-7.

[28] ²⁸
Frota R, Da Silva-Júnior VA, Teixeira M, Sobral AP, Emanuel-Dias-de Oliveira e Silva, Da Silveira MM, et al. Histological evaluation of bone repair using - tricalcium phosphate. Med Oral Patol Oral Cir Bucal. 2011;16(2):e190-4.

Period	Group	n	Volume of biomaterial (mm³)	Two-dimensional distances		Tridimensional axial distance (mm)
Period	Group	n	Volume of biomaterial (mm³)	Axial	Sagittal
7 days	Control	1		8.97	8.95	8.96
7 days	Test	1	25.11	8.32	8.16	9.39
14 days	Control	1		9.46	9.41	9.50
14 days	Test	1	10.96	7.72	10.81	7.34
21 days	Control	1		8.41	8.58	8.15
21 days	Test	1	7.00	7.77	9.55	9.51
42 days	Control	1		8.75	8.56	9.06
42 days	Test	1	11.64	9.88	11.51	11.10

Variables	7 days			14 days			21 days			42 days
Variables	Control	Test	p	Control	Test	p	Control	Test	p	Control	Test	p
Edema	2 [2-1]	1 [2-1]	0.22	2 [2-1]	1 [1-0]	0.075	1 [1-0]	1 [1-0]	1	0 [2-0]	0 [1-0]	0.916
Inflammatory infiltrate	1 [2-1]	4 [4-4]	0.004	1 [3-1]	4 [4-3]	0.008	1 [1-0]	4 [4-4]	0.003	1 [1-0]	4 [4-3]	0.006
Granulation tissue	3 [4-3]	3 [3-2]	0.212	2 [3-1]	4 [4-3]	0.011	1 [1-1]	2 [3-2]	0.004	1 [2-1]	1 [1-1]	0.317
Hemorrhage/thrombus	3 [3-1]	2 [3-1]	0.496	2 [3-2]	1 [4-0]	0.193	3 [3-1]	0 [4-0]	0.106	2 [3-0]	1 [3-0]	0.335
Bone neoformation	1 [2-1]	1 [1-1]	0.317	2 [2-1]	2 [3-1]	0.605	2 [3-1]	2 [2-1]	0.339	2 [3-1]	1 [2-1]	0.418
Foreign body reaction	0 [1-0]	4 [4-4]	0.005	1 [2-1]	4 [4-4]	0.005	0 [2-0]	4 [4-3]	0.007	1 [2-0]	4 [4-3]	0.006
Exogenous material	0 [0-0]	4 [4-3]	0.007	0 [0-0]	4 [4-4]	0.005	0 [0-0]	2 [3-2]	0.005	0 [0-0]	3 [4-2]	0.008

Brasil