ABSTRACT
PURPOSE:
To evaluate the clinical applicability of Pozzolana Biologic Silva cement (PBS(r)) in endodontic surgery.
METHODS:
Persistent apical periodontitis was diagnosed in 30 teeth of 12 patients by cone-beam computed tomography (CT). All patients had 2 or 4 affected teeth and underwent endodontic surgery with root-end filling. Patients with 2 affected teeth had one tooth (control) treated with mineral trioxide aggregate (MTA-Angelus(r)) as a root-end filling material, and the other tooth treated with PBS (experiment). When the patient had four affected teeth, two of them were treated with MTA and two with PBS. Six months after surgery, all patients were assessed by CT scan. Between-group comparisons of measurements were performed using the Wilcoxon test.
RESULTS:
Periradicular tissue regeneration was observed in all cases. Significant within-group differences in long axes of the lesion were found in the bucco-palatal direction (PBS group, p=0.0012; MTA group, p=0.024) and coronal-apical direction (PBS group, p=0.0007; MTA group, p=0.0015) between pre- and postoperative measurements.
CONCLUSIONS:
Pozzolana Biologic Silva cement can be used in the treatment of persistent periradicular lesions. The clinical use of PBS as a root-end filling material may be an alternative to MTA. PBS has additives, which provide enhanced strength.
Key words:
Apicoectomy; Biocompatible Materials; Dental Cements.
Introduction
Endodontic surgery is a therapeutic resource indicated when conventional endodontic treatments fail11. Serrano-Giménez M, Sánchez-Torres A, Gay-Escoda C. Prognostic factors on periapical surgery: a systematic review. Med Oral Patol Oral Cir Bucal. 2015 Nov 1;20(6):e715-22. PMID:26449431.,22. Lauber R, Bornstein MM, von Arx T. Cone beam computed tomography in mandibular molars referred for apical surgery. Schweiz Monatsschr Zahnmed. 2012;122(1):12-24. PMID:22362057.. The development of biocompatible cements made this surgical treatment a viable alternative for the preservation of the tooth as a functional unit33. Shinbori N, Grama AM, Patel Y, Woodmansey K, He J. Clinical outcome of endodontic microsurgery that uses EndoSequence BC root repair material as the root-end filling material. J Endod. 2015 May;41(5):607-12. PMID:25702859.
4. Caron G, Azérad J, Faure MO, Machtou P, Boucher Y. Use of a new retrograde filling material (Biodentine) for endodontic surgery: two case reports. Int J Oral Sci. 2014 Dec;6(4):250-3. PMID:24810806.
5. Bernabé PF, Azuma MM, Ferreira LL, Dezan-Júnior E, Gomes-Filho JE, Cintra LT. Root reconstructed with mineral trioxide aggregate and guided tissue regeneration in apical surgery: a 5-year follow-up. Braz Dent J. 2013;24(4):428-32. PMID:24173269.-66. von Arx T, Roux E, Bürgin W. Treatment decisions in 330 cases referred for apical surgery. J Endod. 2014 Feb;40(2):187-91. PMID:24461402.. Root-end filling materials are required to provide hermetic sealing and to be biocompatible and a precursor for carbonate-apatite formation, which promotes biomineralization, resulting in periodontal ligament at the bone-cement-dentin interface77. Dreger LA, Felippe WT, Reyes-Carmona JF, Felippe GS, Bortoluzzi EA, Felippe MC. Mineral trioxide aggregate and Portland cement promote biomineralization in vivo. J Endod. 2012 Mar;38(3):324-9. PMID:22341069.
8. Dorileo MC, Pedro FL, Bandeca MC, Guedes OA, Villa RD, Borges AH. Comparative analysis of physicochemical properties of root perforation sealer materials. Restor Dent Endod. 2014 Aug;39(3):201-9. PMID:25110644.-99. Lourenço Neto N, Marques NC, Fernandes AP, Rodini CO, Duarte MA, Lima MC, Machado MA, Abdo RC, Oliveira TM. Biocompatibility of Portland cement combined with different radiopacifying agents. J Oral Sci. 2014;56(1):29-34. PMID:24739705..
Mineral trioxide aggregate (MTA) is currently the cement of choice, meeting standard requirements for use as a root-end filling material1010. Aminozarbian MG, Barati M, Salehi I, Mousavi SB. Biocompatibility of mineral trioxide aggregate and three new endodontic cements: an animal study. Dent Res J (Isfahan). 2012 Jan;9(1):54-9. PMID:22363364.
11. Marciano MA, Guimarães BM, Amoroso-Silva P, Camilleri J, Hungaro Duarte MA. Physical and chemical properties and subcutaneous implantation of mineral trioxide aggregate mixed with propylene glycol. J Endod. 2016 Mar;42(3):474-9. PMID:26706789.-1212. Forghani M, Bidar M, Shahrami F, Bagheri M, Mohammadi M, Attaran Mashhadi N. Effect of MTA and Portland cement on fracture resistance of dentin. J Dent Res Dent Clin Dent Prospects. 2013;7(2):81-5. PMID:23875085.. However, MTA has no additives. The absence of additives may affect the mechanical strength of the material1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.. Also, bismuth oxide is added to MTA for radiopacity, but it can result in increased porosity and decreased resistance in the long term1414. Camilleri J, Sorrentino F, Damidot D. Investigation of the hydration and bioactivity of radiopacified tricalcium silicate cement, Biodentine and MTA Angelus. Dent Mater. 2013 May;29(5):580-93. PMID:23537569.,1515. Antonijevic D, Medigovic I, Zrilic M, Jokic B, Vukovic Z, Todorovic L. The influence of different radiopacifying agents on the radiopacity, compressive strength, setting time, and porosity of Portland cement. lin Oral Investig. 2014 Jul;18(6):1597-604. PMID:24233183..
Portland cement is the most common type cement used in civil engineering applications. The major components of Portland cement are comparable to those of MTA, except for the radiopaque agent bismuth oxide1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.
14. Camilleri J, Sorrentino F, Damidot D. Investigation of the hydration and bioactivity of radiopacified tricalcium silicate cement, Biodentine and MTA Angelus. Dent Mater. 2013 May;29(5):580-93. PMID:23537569.-1515. Antonijevic D, Medigovic I, Zrilic M, Jokic B, Vukovic Z, Todorovic L. The influence of different radiopacifying agents on the radiopacity, compressive strength, setting time, and porosity of Portland cement. lin Oral Investig. 2014 Jul;18(6):1597-604. PMID:24233183.. Other similarities between the two materials include antimicrobial activity and biocompatibility33. Shinbori N, Grama AM, Patel Y, Woodmansey K, He J. Clinical outcome of endodontic microsurgery that uses EndoSequence BC root repair material as the root-end filling material. J Endod. 2015 May;41(5):607-12. PMID:25702859.,1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.,1616. Silva Neto JD, Brito RH, Schnaider TB, Gragnani A, Engelman M, Ferreira LM. Root perforations treatment using mineral trioxide aggregate and Portland cements. Acta Cir Bras. 2010 Dec;25(6):479-84. PMID:21120277.
17. Hwang YC, Kim DH, Hwang IN, Song SJ, Park YJ, Koh JT, Son HH, Oh WM. Chemical constitution, physical properties, and biocompatibility of experimentally manufactured Portland cement. J Endod. 2011 Jan;37(1):58-62. PMID:21146078.
18. Dreger LA, Felippe WT, Reyes-Carmona JF, Felippe GS, Bortoluzzi EA, Felippe MC. Mineral trioxide aggregate and Portland cement promote biomineralization in vivo. J Endod. 2012 Mar;38(3):324-9. PMID:22341069.
19. Koçak S, Erten H, Baris E, Türk S, Alaçam T. Evaluation of the biocompatibility of experimentally manufactured Portland cement: an animal study. J Clin Exp Dent. 2014 Feb 1;6(1):e17-21. PMID:24596630.-2020. Petrou MA, Alhamoui FA, Welk A, Altarabulsi MB, Alkilzy M, H Splieth C. A randomized clinical trial on the use of medical Portland cement, MTA and calcium hydroxide in indirect pulp treatment. Clin Oral Investig. 2014 Jun;18(5):1383-9. PMID:24043482.. Previous studies indicate the potential viability of using Portland cement in the same applications as MTA. Silva Neto and colleagues1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.,1616. Silva Neto JD, Brito RH, Schnaider TB, Gragnani A, Engelman M, Ferreira LM. Root perforations treatment using mineral trioxide aggregate and Portland cements. Acta Cir Bras. 2010 Dec;25(6):479-84. PMID:21120277. compared experimentally Portland cement containing natural additives (pozzolana and calcium carbonate) with MTA-Angelus and found that both materials are biocompatible and induce biomineralization. These authors also found that the presence of natural additives in Portland cement had no effect on these properties and may provide superior resistance to masticatory forces1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.,1616. Silva Neto JD, Brito RH, Schnaider TB, Gragnani A, Engelman M, Ferreira LM. Root perforations treatment using mineral trioxide aggregate and Portland cements. Acta Cir Bras. 2010 Dec;25(6):479-84. PMID:21120277.. Studies on surface electromyography (EMG) of masticatory muscles, orofacial motion, temporomandibular disorders (TMD), and orofacial myofunctional status according to gender, age, tooth status, and facial morphology have shown that both healthy and treated teeth require resistance to occlusal forces. Thus, root-end filling materials should provide resistance to masticatory load1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.,1616. Silva Neto JD, Brito RH, Schnaider TB, Gragnani A, Engelman M, Ferreira LM. Root perforations treatment using mineral trioxide aggregate and Portland cements. Acta Cir Bras. 2010 Dec;25(6):479-84. PMID:21120277.,2121. Hugger S, Schindler HJ, Kordass B, Hugger A. Surface EMG of the masticatory muscles (part 2): fatigue testing, mastication analysis and influence of different factors. Int J Comput Dent. 2013;16(1):37-58. PMID:23641663.,2222. De Felício CM, Ferreira CL, Medeiros AP, Rodrigues Da Silva MA, Tartaglia GM, Sforza C. Electromyographic indices, orofacial myofunctional status and temporomandibular disorders severity: a correlation study. J Electromyogr Kinesiol. 2012 Apr;22(2):266-72. PMID:22206640..
Pozzolana Biologic Silva cement (PBS(r)) is a biocompatible medical Portland cement that contains pozzolana and calcium carbonate as additives, which confer compressive strength to the material2323. da Silva SR, da Silva Neto JD, Veiga DF, Schnaider TB, Ferreira LM. Portland cement versus MTA as a root-end filling material. A pilot study. Acta Cir Bras. 2015 Feb;30(2):160-4. PMID:25714696.. PBS was developed as part of a doctoral dissertation (J.D.S.N.) and master's thesis (S.R.S.), based on the white structural Portland cement with additives (WSPCA), which was adapted for clinical use. WSPCA has shown good physical properties and to be a biocompatible material1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.,1616. Silva Neto JD, Brito RH, Schnaider TB, Gragnani A, Engelman M, Ferreira LM. Root perforations treatment using mineral trioxide aggregate and Portland cements. Acta Cir Bras. 2010 Dec;25(6):479-84. PMID:21120277.. A patent was filed for the use of WSPCA as a dental filling material at the Brazilian patent office (INPI, Instituto Nacional de Propriedade Industrial, in Portuguese) in June 2013 and published in November 2015 (patent no. BR10 2013 031603-2 A2). The trademark application for the PBS cement was filed at INPI (case no. 909673667) in July 2015 and the medical cement is currently in the industrialization phase. A pilot clinical study2323. da Silva SR, da Silva Neto JD, Veiga DF, Schnaider TB, Ferreira LM. Portland cement versus MTA as a root-end filling material. A pilot study. Acta Cir Bras. 2015 Feb;30(2):160-4. PMID:25714696. was conducted comparing the WSPCA (later called PBS cement) with MTA-Angelus(r) as a root-end filling materials in endodontic surgery; serving as basis for this study with a larger sample. Because it is essential that root-filling materials resist masticatory forces2424. Chakraborty A, Dey B, Dhar R, Sardar P. Healing of apical rarefaction of three nonvital open apex anterior teeth using a white Portland cement apical plug. Contemp Clin Dent. 2012 Sep;3(Suppl 2):S177-81. PMID:23230357.,2525. Kayahan MB, Nekoofar MH, McCann A, Sunay H, Kaptan RF, Meraji N, Dummer PM. Effect of acid etching procedures on the compressive strength of 4 calcium silicate-based endodontic cements. J Endod. 2013 Dec;39(12):1646-8. PMID:24238465., PBS may be an alternative to MTA in endodontic surgery.
Thus, the aim of this study was to compare the regeneration of periradicular tissues after endodontic surgery using PBS and MTA-Angelus as root-end filling materials.
Methods
This prospective clinical study was approved by the Research Ethics Committee of the Universidade do Vale do Sapucaí (UNIVÁS) (approval nº 280009) and Brazil Platform System (approval nº CAAE 15093613.5.0000.5102), and performed in full accordance with the ethical principles of the Declaration of Helsinki of 1975 as revised in 2008. For all patients, written informed consent was obtained prior to their inclusion in the study, and anonymity was assured.
Eligibility criteria included patients 18 to 60 years of age, who had two or four teeth with persistent periradicular lesions.
Exclusion criteria were diabetes, heart diseases, being pregnant, renal diseases, and chronic debilitating diseases. Patients lost to the 6-month follow-up were also excluded from the study.
In order to calculate the sample size, the following criteria were used for comparisons of measurements of the long axes of lesions in the bucco-palatal direction and coronal-apical direction. Mean ± standard deviation (SD) values of 4.1 ± 3.0 mm and 0.84 ± 1.3 mm were estimated for the axes on the bucco-palatal and coronal-apical directions, respectively. The sample size was calculated using the formulas:
where, n1 and n2 = sample shape for the PBS and MTA groups, respectively; σ1 and σ2 = standard deviation for the PBS and MTA groups, respectively; ∆= difference between mean values; Z1-α/2 = two-tailed Z-value = 1.96; Z1-β = power of 80%. Setting the significance level α at 5%, the confidence interval at 95%, and the power of the sample at 80%, the sample size of 8 teeth in each group would be required to detect this difference. Anticipating some dropouts and to prevent errors, 15 teeth were allocated to each group, increasing the statistical power to 97.14%, which was estimated using the method of approximation to normal distribution.
Thus, a total of 30 teeth showing no degree of mobility, with persistent periradicular lesions of 12 patients were selected for the study. The lesions were diagnosed using cone-beam computed tomography (cone-beam CT; Model i-CAT 17-19, Imaging Sciences International LLC, Hatfield, PA, USA)2323. da Silva SR, da Silva Neto JD, Veiga DF, Schnaider TB, Ferreira LM. Portland cement versus MTA as a root-end filling material. A pilot study. Acta Cir Bras. 2015 Feb;30(2):160-4. PMID:25714696.,2626. Castro-Ruiz CT, Noriega J, Guerrero ME. Validity of ridge mapping and cone beam computed tomography in dental implant therapy. J Indian Soc Periodontol. 2015 May-Jun;19(3):290-3. PMID:26229269.,2727. Ferrare N, Leite AF, Caracas HC, de Azevedo RB, de Melo NS, de Souza Figueiredo PT. Cone-beam computed tomography and microtomography for alveolar bone measurements. Surg Radiol Anat. 2013 Aug;35(6):495-502. PMID:23400642.. The dimensions of the long axes of the lesions in the bucco-palatal and coronal-apical directions were measured using CT images analyzed with the Dental Slice virtual navigation software (Bioparts Prototipagem Biomédica, Brasilia, DF, Brazil).
All patients had 2 or 4 affected teeth and underwent endodontic surgery with root-end filling. Patients with 2 affected teeth had one tooth (control) treated with MTA-Angelus as a root-end filling material, and the other tooth treated with PBS (experiment). When the patient had four affected teeth, two of them were treated with MTA and two with PBS. The teeth were randomly allocated to the control (MTA) or study (PBS) groups using the Random software (Excel 4.0, Microsoft, Redmond, WA, USA).
Before the surgical procedure, the patients rinsed their mouth with 5 ml of 0.12% chlorhexidine digluconate for one minute and then received 2% lidocaine with noradrenaline 1:100,000 as supraperiosteal infiltration, according to conventional techniques. A relaxing incision was made in the gingival sulcus with a scalpel blade (no. 15). Blunt dissection was carried out with a Molt elevator; the apical lesion was located using a no. 5 dental explorer; and osteotomy was made using an Ostby chisel and a carbide bur no. 4. Next, curettage of the lesion was done with a periodontal curette (no. 13/14). A low-speed bur (no. 700) was used for apicoectomy. A step-back instrumentation technique performed with an ultrasonic tip (SD90, Dabi Atlante, Ribeirão Preto, SP, Brazil) was used for root-end cavity preparation. The cavity was dried with absorbent paper points and root-end filling was carried out with either PBS or MTA. The root-end filling material was packed and the root was planed to the apical end using appropriate instruments. Periapical radiographs were obtained with a periapical film. The bone cavity was cleaned with sterile saline solution and filled with calcium carbonate powder. The flap was repositioned and secured with 4-0 silk suture. All patients were prescribed 875-mg amoxicillin-clavulanate potassium tablet twice daily for seven days, 4-mg dexamethasone tablet twice daily for three days, and 750-mg paracetamol tablet every six hours in the first postoperative day. The suture was removed seven days after surgery.
The teeth and surrounding tissues were assessed clinically and by CT scan at the 6-month follow-up2828. Sood N, Maheshwari N, Gothi R, Sood N. Treatment of large periapical cyst like lesion: a noninvasive approach: a report of two cases. Int J Clin Pediatr Dent. 2015 May-Aug;8(2):133-7. PMID:26379382.. The dimensions of the long axes of the lesions in the bucco-palatal and coronal-apical directions were measured preoperatively and 6-month postoperatively using CT images.
Statistical analysis
The Wilcoxon test was used to compare delta percent (∆%) changes in linear measurements (long axes of the lesions) and measurements related to root-end filling materials between groups and over time.
Statistical analysis was carried out using the Statistical Package for the Social Sciences (SPSS) 18.0 (SPSS Inc., Chicago, IL, USA). All statistical tests were performed at a significance level α of 0.05 (p < 0.05).
Results
Periradicular tissue regeneration was observed in all cases. Significant within-group differences in the long axes of the lesions were found in the bucco-palatal direction (PBS group, p = 0.0012; MTA group, p = 0.024) and coronal-apical direction (PBS group, p = 0.0007; MTA group, p = 0.0015) between pre- and postoperative measurements. Pre- and postoperative cone-beam CT images are shown as examples (Figures 1 and 2).
Preoperative (top) and 6-month postoperative (bottom) cone-beam CT images showing affected teeth treated with either MTA (tooth 1) or PBS (tooth 2) as root-end filling materials.
Preoperative (top) and 6-month postoperative (bottom) cone-beam CT images showing affected teeth treated with either MTA (teeth 1 and 3) or PBS (teeth 2 and 4) as root-end filling materials.
Discussion
When conventional endodontic treatments fail, endodontic surgery is an alternative to save the tooth. For the success of this surgical procedure, the cement used as root-end filling material must meet necessary requirements, including biocompatibility, resistance to masticatory forces and ability to induce biomineralization88. Dorileo MC, Pedro FL, Bandeca MC, Guedes OA, Villa RD, Borges AH. Comparative analysis of physicochemical properties of root perforation sealer materials. Restor Dent Endod. 2014 Aug;39(3):201-9. PMID:25110644.,99. Lourenço Neto N, Marques NC, Fernandes AP, Rodini CO, Duarte MA, Lima MC, Machado MA, Abdo RC, Oliveira TM. Biocompatibility of Portland cement combined with different radiopacifying agents. J Oral Sci. 2014;56(1):29-34. PMID:24739705..
MTA is considered the gold standard for root-end filling77. Dreger LA, Felippe WT, Reyes-Carmona JF, Felippe GS, Bortoluzzi EA, Felippe MC. Mineral trioxide aggregate and Portland cement promote biomineralization in vivo. J Endod. 2012 Mar;38(3):324-9. PMID:22341069.,1717. Hwang YC, Kim DH, Hwang IN, Song SJ, Park YJ, Koh JT, Son HH, Oh WM. Chemical constitution, physical properties, and biocompatibility of experimentally manufactured Portland cement. J Endod. 2011 Jan;37(1):58-62. PMID:21146078.,2121. Hugger S, Schindler HJ, Kordass B, Hugger A. Surface EMG of the masticatory muscles (part 2): fatigue testing, mastication analysis and influence of different factors. Int J Comput Dent. 2013;16(1):37-58. PMID:23641663., induces biomineralization, and is associated with favorable prognosis in endodontic surgeries. However, MTA contains bismuth oxide, which is a factor that must be taken into consideration when using this cement as a root-end filling material. Bismuth oxide is added to MTA for radiopacity, but in the long term it can cause changes in the cement, resulting in increased porosity and decreased mechanical resistance1414. Camilleri J, Sorrentino F, Damidot D. Investigation of the hydration and bioactivity of radiopacified tricalcium silicate cement, Biodentine and MTA Angelus. Dent Mater. 2013 May;29(5):580-93. PMID:23537569.,1515. Antonijevic D, Medigovic I, Zrilic M, Jokic B, Vukovic Z, Todorovic L. The influence of different radiopacifying agents on the radiopacity, compressive strength, setting time, and porosity of Portland cement. lin Oral Investig. 2014 Jul;18(6):1597-604. PMID:24233183.,2424. Chakraborty A, Dey B, Dhar R, Sardar P. Healing of apical rarefaction of three nonvital open apex anterior teeth using a white Portland cement apical plug. Contemp Clin Dent. 2012 Sep;3(Suppl 2):S177-81. PMID:23230357.,2525. Kayahan MB, Nekoofar MH, McCann A, Sunay H, Kaptan RF, Meraji N, Dummer PM. Effect of acid etching procedures on the compressive strength of 4 calcium silicate-based endodontic cements. J Endod. 2013 Dec;39(12):1646-8. PMID:24238465.. Comparisons of Portland cement used in civil construction with MTA have indicated that both materials have similar composition and physical and biological properties33. Shinbori N, Grama AM, Patel Y, Woodmansey K, He J. Clinical outcome of endodontic microsurgery that uses EndoSequence BC root repair material as the root-end filling material. J Endod. 2015 May;41(5):607-12. PMID:25702859.,1818. Dreger LA, Felippe WT, Reyes-Carmona JF, Felippe GS, Bortoluzzi EA, Felippe MC. Mineral trioxide aggregate and Portland cement promote biomineralization in vivo. J Endod. 2012 Mar;38(3):324-9. PMID:22341069.,1919. Koçak S, Erten H, Baris E, Türk S, Alaçam T. Evaluation of the biocompatibility of experimentally manufactured Portland cement: an animal study. J Clin Exp Dent. 2014 Feb 1;6(1):e17-21. PMID:24596630.,2929. Viapiana R, Guerreiro-Tanomaru JM, Hungaro-Duarte MA, Tanomaru-Filho M, Camilleri J. Chemical characterization and bioactivity of epoxy resin and Portland cement-based sealers with niobium and zirconium oxide radiopacifiers. Dent Mater. 2014 Sep;30(9):1005-20. PMID:24950807.,3030. Húngaro Duarte MA1, de Oliveira El Kadre GD, Vivan RR, Guerreiro Tanomaru JM, Tanomaru Filho M, de Moraes IG. Radiopacity of Portland cement associated with different radiopacifying agents. J Endod. 2009 May;35(5):737-40. PMID:19410095.. These studies suggest further investigation of the feasibility of using Portland cement as an endodontic material.
The development of PBS began with experimental studies comparing Portland cement containing natural additives (pozzolana and calcium carbonate) with MTA when used in the repair of root perforations in dogs. Periradicular tissue regeneration was observed for both materials and the presence of cement additives had no effect on biocompatibility1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.,1616. Silva Neto JD, Brito RH, Schnaider TB, Gragnani A, Engelman M, Ferreira LM. Root perforations treatment using mineral trioxide aggregate and Portland cements. Acta Cir Bras. 2010 Dec;25(6):479-84. PMID:21120277.. The literature provides solid foundation for the development of clinical studies with Portland cement1010. Aminozarbian MG, Barati M, Salehi I, Mousavi SB. Biocompatibility of mineral trioxide aggregate and three new endodontic cements: an animal study. Dent Res J (Isfahan). 2012 Jan;9(1):54-9. PMID:22363364.,2222. De Felício CM, Ferreira CL, Medeiros AP, Rodrigues Da Silva MA, Tartaglia GM, Sforza C. Electromyographic indices, orofacial myofunctional status and temporomandibular disorders severity: a correlation study. J Electromyogr Kinesiol. 2012 Apr;22(2):266-72. PMID:22206640.. Petrou et al.2020. Petrou MA, Alhamoui FA, Welk A, Altarabulsi MB, Alkilzy M, H Splieth C. A randomized clinical trial on the use of medical Portland cement, MTA and calcium hydroxide in indirect pulp treatment. Clin Oral Investig. 2014 Jun;18(5):1383-9. PMID:24043482. conducted a clinical study using Portland cement and MTA and defined Portland cement as medical cement.
A pilot clinical study was designed to compare the outcomes of endodontic surgery using either MTA or PBS as a root-end filling material and it was found that PBS led to tissue regeneration2929. Viapiana R, Guerreiro-Tanomaru JM, Hungaro-Duarte MA, Tanomaru-Filho M, Camilleri J. Chemical characterization and bioactivity of epoxy resin and Portland cement-based sealers with niobium and zirconium oxide radiopacifiers. Dent Mater. 2014 Sep;30(9):1005-20. PMID:24950807.. The present study was conducted with a sample larger than that of the previous pilot study and the use of both cements as root-end filling materials resulted in significant periradicular tissue regeneration, consistent with other studies1313. Silva Neto JD, Schnaider TB, Gragnani A, Paiva AP, Novo NF, Ferreira LM. Portland cement with additives in the repair of furcation perforations in dogs. Acta Cir Bras. 2012 Nov;27(11):809-14. PMID:23117614.,1616. Silva Neto JD, Brito RH, Schnaider TB, Gragnani A, Engelman M, Ferreira LM. Root perforations treatment using mineral trioxide aggregate and Portland cements. Acta Cir Bras. 2010 Dec;25(6):479-84. PMID:21120277.,2020. Petrou MA, Alhamoui FA, Welk A, Altarabulsi MB, Alkilzy M, H Splieth C. A randomized clinical trial on the use of medical Portland cement, MTA and calcium hydroxide in indirect pulp treatment. Clin Oral Investig. 2014 Jun;18(5):1383-9. PMID:24043482.,2323. da Silva SR, da Silva Neto JD, Veiga DF, Schnaider TB, Ferreira LM. Portland cement versus MTA as a root-end filling material. A pilot study. Acta Cir Bras. 2015 Feb;30(2):160-4. PMID:25714696..
The PBS cement is a biocompatible and bioactive material with resistance to compression due to the presence of natural additives (pozzolana and calcium carbonate) in its composition. The human masticatory system is complex. The anterior (incisors and canines) and intermediate (premolars) teeth treated by endodontic surgery in the present study had different masticatory and mechanical demands. Studies on surface EMG have shown that masticatory muscles and teeth are subject to fatigue effects during the mastication process that are influenced by diferent factors, such as gender, age, tooth status, and facial morphology, resulting in different occlusal relationships during static and dynamic occlusion. Both healthy and treated anterior and intermediate teeth need to show mechanical resistance to masticatory forces2121. Hugger S, Schindler HJ, Kordass B, Hugger A. Surface EMG of the masticatory muscles (part 2): fatigue testing, mastication analysis and influence of different factors. Int J Comput Dent. 2013;16(1):37-58. PMID:23641663.. The presence of PBS can be detected in radiographs without the addition of radiopaque agents. Thus, PBS is an alternative to MTA-Angelus in endodontic surgery. Further clinical studies are necessary to assess the effectiveness of PBS in the different applications in which MTA is utilized.
Conclusions
The use of Pozzolana Biologic Silva and mineral trioxide aggregate as root-end filling materials led to regeneration of periradicular tissues and repair of periradicular lesions. Thus, the clinical use of PBS is an alternative to the treatment of endodontic surgery.
References
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30Húngaro Duarte MA1, de Oliveira El Kadre GD, Vivan RR, Guerreiro Tanomaru JM, Tanomaru Filho M, de Moraes IG. Radiopacity of Portland cement associated with different radiopacifying agents. J Endod. 2009 May;35(5):737-40. PMID:19410095.
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Financial source: none
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1
Research performed at Professional Master's Program in Applied Health Sciences, Universidade do Vale do Sapucaí (UNIVÁS), Pouso Alegre-MG, and Division of Plastic Surgery, Department of Surgery, Universidade Federal de São Paulo (UNIFESP), Brazil. Part of Master degree thesis, Professional Master's Program in Applied Health Sciences. Tutor: Taylor Brandão Schnaider.
Publication Dates
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Publication in this collection
June 2016
History
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Received
22 Feb 2016 -
Reviewed
19 Apr 2016 -
Accepted
18 May 2016