Abstract
This study aimed to evaluate the effects of different scaling protocols on the morphology and roughness of the root dentin substrate exposure to ionizing radiation. One hundred and thirty extracted bovine incisors were randomly divided into two groups (n=65): non-irradiated (NIR) and irradiated (IR). Each group was initially subdivided into three subgroups according to the type of non-surgical periodontal protocol: NIT: no instrumentation; HS: hand scaling with 15 apical-coronal instrument movements; US: ultrasonic scaling with 15 apical-coronal cycles. Subsequently, all samples were subjected to the prophylaxis protocol, being subdivided into the following groups: NIT/PP: prophylaxis with a fine prophylactic paste using a rubber cup for 15 seconds; HS/PP: Hand scaling followed by the prophylaxis protocol; US/PP: Ultrasonic scaling followed by the prophylaxis protocol. The roughness of the root dentin surface was measured with a profilometer (Ra/Rz - μm), and the morphology of the dentin surfaces was analyzed using scanning electron microscopy (SEM). The analyses were conducted before and after the prophylaxis protocol. In the absence of prophylaxis, the roughest surfaces were observed after ultrasonic instrumentation followed by hand instrumentation for both IR and NIR groups. No difference in Ra and RZ values between HS/PP and US/PP was observed for both substrates. For the IR group, the prophylaxis resulted in similar Ra and RZ values for both instrumentation groups in comparison to no instrumentation. Ordinal logistic regression showed that both HS and US resulted in higher scores than NIT, irrespective of IR presence. In conclusion, the IR showed a rougher root surface for both HS and US in comparison to NIR. However, the prophylaxis procedure significantly reduced the roughness of root surfaces after both instrumentation procedures
Key Words:
radiotherapy; dental calculus; dental prophylaxis
Resumo
O objetivo deste estudo foi avaliar os efeitos de diferentes protocolos de raspagem na morfologia e rugosidade do substrato de dentina radicular exposto à radiação ionizante. Cento e trinta incisivos bovinos extraídos foram divididos aleatoriamente em dois grupos (n = 65): não irradiados (NIR) e irradiados (IR). Cada grupo foi subdividido em seis subgrupos de acordo com o tipo de protocolo periodontal não cirúrgico: NIT: sem instrumentação; NIT/PP: profilaxia com pasta profilática fina usando uma taça de borracha por 15 segundos; HS: raspagem manual com 15 movimentos de instrumento apical-coronal; HS/PP: raspagem manual seguida de protocolo de profilaxia; US: raspagem ultrassônica com 15 ciclos apical-coronais; US/PP: raspagem ultrassônica seguida de protocolo de profilaxia. A rugosidade da superfície da dentina radicular foi medida com um perfilômetro (Ra/Rz - μm) e a morfologia das superfícies da dentina foi analisada usando microscopia eletrônica de varredura (SEM). Na ausência de profilaxia, as superfícies mais ásperas foram observadas após a instrumentação ultrassônica seguida de instrumentação manual para ambos os grupos IR e NIR. Não foi observada diferença nos valores de Ra e RZ entre HS/PP e US/PP para ambos os substratos. Para o grupo IR, a profilaxia resultou em valores de Ra e RZ semelhantes para ambos os grupos de instrumentação em comparação com a ausência de instrumentação. A regressão logística ordinal mostrou que tanto HS quanto US resultaram em escores mais altos do que NIT, independentemente da presença de IR. Em conclusão, o IR apresentou uma superfície radicular mais áspera para ambos os HS e US em comparação com o NIR. No entanto, o procedimento de profilaxia reduziu significativamente a rugosidade das superfícies radiculares após ambos os procedimentos de instrumentação.
Introduction
Head and neck cancer (HNC) represents one of the most common malignant neoplasms, with exponential growth in cases 11 Bray F, Ferlay J, Soerjomataram I, Siegel RL, Torre LA, Jemal A. Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA: a cancer journal for clinicians. 2018;68(6):394-424.. Radiotherapy (RT) plays a key role in HNC treatment, being indicated as a unique therapy in early-stage tumors or combined with surgery or chemotherapy in advanced stages 22 Alterio D, Marvaso G, Ferrari A, Volpe S, Orecchia R, Jereczek-Fossa BA, editors. Modern radiotherapy for head and neck cancer. Seminars in oncology; 2019: Elsevier.. However, RT can adversely affect the oral cavity tissues when applied to the head and neck region since the ionizing radiation has cytotoxic effects against normal and malignant cells 33 Buglione M, Cavagnini R, Di Rosario F, Sottocornola L, Maddalo M, Vassalli L, et al. Oral toxicity management in head and neck cancer patients treated with chemotherapy and radiation: Dental pathologies and osteoradionecrosis (Part 1) literature review and consensus statement. Critical reviews in oncology/hematology. 2016;97:131-42.. Consequently, the HNC radiotherapy treatment has been associated with diverse oral sequelae such as mucositis, hyposalivation, radiation dermatitis, oropharyngeal candidiasis, mucosal pain, taste dysfunction, trismus, temporomandibular dysfunction, dental caries, periodontitis, and osteoradionecrosis 44 Irie M-S, Mendes E-M, Borges J-S, Rabelo G-D. Periodontal therapy for patients before and after radiotherapy: A review of the literature and topics of interest for clinicians. Medicina oral, patologia oral y cirugia bucal. 2018;23(5):e524.,55 Bhandari S, Soni BW, Bahl A, Ghoshal S. Radiotherapy‐induced oral morbidities in head and neck cancer patients. Special Care in Dentistry. 2020;40(3):238-50..
In addition, RT also causes damage to the tooth structure, which affects the mechanical properties and chemical composition of enamel (crystalline structure, acid solubility, and microhardness) and dentin (elastic modulus, microhardness, matrix metalloproteinases releasing) 66 de Miranda RR, Silva ACA, Dantas NO, Soares CJ, Novais VR. Chemical analysis of in vivo-irradiated dentine of head and neck cancer patients by ATR-FTIR and Raman spectroscopy. Clinical oral investigations. 2019;23:3351-8.,77 de Miranda RR, Ribeiro TE, da Silva ELC, S Júnior PCS, Soares CJ, Novais VR. Effects of fractionation and ionizing radiation dose on the chemical composition and microhardness of enamel. Archives of Oral Biology. 2021;121:104959.,88 Reed R, Xu C, Liu Y, Gorski J, Wang Y, Walker M. Radiotherapy effect on nano-mechanical properties and chemical composition of enamel and dentine. Archives of oral biology. 2015;60(5):690-7.. These changes associated with xerostomia caused by hyposalivation can lead to rapid and severe destruction of enamel and dentin 99 Pelloso AM, de Miranda RR, Rossi ME, Bianchini ALB, Marcelino FAS, da Silva ELC, et al. Chemical analysis of irradiated root dentin and its interaction with resin cements. Clinical Oral Investigations. 2022;26(6):4315-25.. Moreover, oral hygiene maintenance can be difficult by RT due to painful sensations associated with xerostomia in the mucosa 1010 Kielbassa AM, Hinkelbein W, Hellwig E, Meyer-Lückel H. Radiation-related damage to dentition. The lancet oncology. 2006;7(4):326-35.. All these changes can impair the patients to adequately control the oral biofilm increasing the risk of periodontal attachment loss and caries 55 Bhandari S, Soni BW, Bahl A, Ghoshal S. Radiotherapy‐induced oral morbidities in head and neck cancer patients. Special Care in Dentistry. 2020;40(3):238-50..
The calculus and biofilm removal carried out during non-surgical periodontal therapy is essential to control periodontal infection and achieve satisfactory periodontal health in HNC patients submitted to RT 55 Bhandari S, Soni BW, Bahl A, Ghoshal S. Radiotherapy‐induced oral morbidities in head and neck cancer patients. Special Care in Dentistry. 2020;40(3):238-50.. This therapy can be made using manual (periodontal curettes) or ultrasonic (ultrasound) instrumentation 1111 Oza RR, Sharma V, Multani P, Balsara K, Bajaj P, Dhadse P. Comparing the Effectiveness of Ultrasonic Instruments Over Manual Instruments for Scaling and Root Planing in Patients With Chronic Periodontitis: A Systematic Review and Meta-Analysis. Cureus. 2022;14(11).. However, these instruments can increase the root surface roughness by increasing the irregularities and sulcus, resulting in greater biofilm adhesion 1212 de Oliveira GJPL, Cominotte MA, Beraldo TPP, Sampaio JEC, Marcantonio RAC. A microscopic analysis of the effects of root surface scaling with different power parameters of Er, Cr: YSGG laser. Microscopy research and technique. 2015;78(6):529-35.,1313 Kumar P, Das SJ, Sonowal ST, Chawla J. Comparison of root surface roughness produced by hand instruments and ultrasonic scalers: an in vitro study. Journal of clinical and diagnostic research: JCDR. 2015;9(11):ZC56.. Therefore, surface polishing (called prophylaxis) should be made to decrease the residual root roughness after periodontal instrumentation 1414 Yildirim TT, Oztekin F, Keklik E, Tozum MD. Surface roughness of enamel and root surface after scaling, root planning and polishing procedures: An in-vitro study. Journal of Oral Biology and Craniofacial Research. 2021;11(2):287-90..
Based on that, this study evaluated the effect of different instrumentation methods (hand or ultrasonic instrumentation, followed or not by prophylaxis) on the root dentin surface roughness of irradiated and non-irradiated bovine teeth. The null hypothesis tested was that both instrumentation methods and tooth irradiation do not affect the roughness of root dentin.
Materials and methods
Sample separation and irradiation
One hundred and thirty extracted bovine incisors were selected for this study. The teeth were stored at 4ºC in distilled water that was replaced weekly. The crowns were separated from the roots at the enamel-cementum junction with a double-faced diamond disk (KG Sorensen, Barueri, SP, Brazil) used with a low-speed handpiece (KaVo do Brasil Ltda, Joinville, SC, Brazil) under copious water spray. A 5 x 5 mm² section was delimited on the buccal root surface and fixed within a rectangular block of polystyrene resin (Cristal, Piracicaba, SP, Brazil). The block measured 2.5 cm in length, 1.5 cm in width, and 1.0 cm in height was obtained with a polyether impression material (Impregum Soft; 3M ESPE, St. Paul, MN, USA) matrix. The surface to be analyzed was flattened using 600-, 800-, 1200- and 2000-grit silicon-carbide papers (Norton, Campinas, SP, Brazil) and polished with metallographic diamond pastes (6, 3, 1, 1⁄4 μm; Arotec, São Paulo, SP, Brazil). The samples were cleaned with three 10-minute ultrasound baths (Cristofoli, Campo Mourão, Paraná, Brazil) with absolute alcohol to remove debris.
The samples were randomly divided into two groups (n=65): non-irradiated (NIR) and irradiated (IR) (Figure 1). The IR samples were fixed in utility wax plates (Technew, Rio de Janeiro, RJ, Brazil) and completely immersed in distilled water at room temperature during irradiation. The distilled water was discarded every 15 days, and the specimens were stored in new distilled water. The irradiation protocol consisted of a total dose of 72 Gy, with 1,8 Gy daily applied five days a week, for eight weeks with X-rays from a linear accelerator (Clinac 600C Varian®-Palo Alto, CA, USA, Beam 6 MV). The NIR samples were stored in distilled water at 4◦C during the time required to complete the irradiation protocol 66 de Miranda RR, Silva ACA, Dantas NO, Soares CJ, Novais VR. Chemical analysis of in vivo-irradiated dentine of head and neck cancer patients by ATR-FTIR and Raman spectroscopy. Clinical oral investigations. 2019;23:3351-8..
Instrumentation
After one week following the completion of the radiotherapy protocol both IR and NIR samples were randomly divided to receive one of the following instrumentations (Figure 1): Hand (n=20) - scaling using hand instrumentation (Gracey curettes 5/6; Hu-Friedy, Chicago, Illinois, USA) with 15 apical-coronal movements; Ultrasonic (n=20): scaling using ultrasonic instrumentation (Piezon PM200; EMS, Nyon, Switzerland), with 15 apical-coronal cycles; or no-instrumentation (n=25). The samples were fixed on a bench vise (185089, MTX, China) during the instrumentation/prophylaxis procedures. One operator performed all scaling and polishing procedures. A second blinded operator evaluated the samples with a profilometer (Surftest SJ-201P; Mitutoyo Corporation, Kawasaki, Kanagawa, Japan).
Determination of the Root Surface Roughness
The surface roughness was measured before and after the interventions (n=15 samples in each group). The root surface roughness was measured with a profilometer. Five parallel readings were performed on an area previously delimited, and the average was calculated. The readings were performed with a 0.25-mm cut-off and 1.25-mm measurement length at a speed of 1 mm/s, covering 3 mm. It was calculated both the mean of the recorded peaks and valleys (Ra) and mean roughness depth (Rz), which is the maximum distance between the highest peak and the deepest valley. The profilometer was positioned in a manner that the height of the reading tip was adapted to the previous map of each sample.
Post-instrumentation prophylaxis
After the measurement of surface roughness, all samples (n=15 in each group) were submitted to prophylaxis with a fine prophylactic paste (Herjos-F; Vigodent S.A., Rio de Janeiro, RJ, Brazil). A rubber cup coupled to a low-speed rotation device was used under constant irrigation for 15 seconds. The surface roughness was measured again, as described previously.
Scanning Electronic Microscopy (SEM) Analysis
The morphological features of the root surfaces were analyzed using SEM. Five samples from each experimental condition were randomly selected for this analysis. For the control group (no instrumentation and no prophylaxis), ten samples from NI and NIR groups were analyzed. These samples were cleaned in an ultrasonic bath (Cristofoli, Campo Mourão, Paraná, Brazil) with distilled water for 30 minutes to remove the debris, followed by dehydration in ascendant concentrations of ethanol (50º, 70º, and 95º) for 10 min in each. Then samples were placed into absolute ethanol for 30 min. After storage in an oven receptacle containing silica for eight hours to remove moisture, the specimens were mounted on an aluminum stub (one stub per group), sputter-coated with a thin layer of gold, and examined with a VEGA 3 LMU scanning electron microscope (TESCAN, Libušina, Czech Republic). The SEM photomicrographs at ×500 magnification were scored individually by five blinded investigators based on the roughness and loss of tooth substance index based on Meyer & Lie, 1977 1515 Meyer K, Lie T. Root surface roughness in response to periodontal instrumentation studied by combined use of microroughness measurements and scanning electron microscopy. Journal of Clinical Periodontology. 1977;4(2):77-91.: [0] - smooth and even root surface without marks from instrumentation and with no loss of tooth substance; [1] - slightly roughened as corrugated local areas confined to the cementum; [2] - definitely corrugated local areas where the cementum may be completely removed, although most of the cementum is still present; [3] - considerable loss of tooth substance with instrumentation marks into the dentin. The cementum is completely removed in large areas or has many lesions from the instrumentation. This index was used to qualitatively score the morphology of the root surface produced by each instrument with or without prophylaxis.
Data analysis
Normal distribution of final values of Ra and Rz were analyzed using the Shapiro-Wilk and Levene test. The assumption of sphericity of checked using Mauchly's W and the data were submitted to Repeated-measures ANOVA. Tukey`s test was used for multiple comparisons. Regarding the scores attributed to SEM images, agreement among the evaluators was assessed by Fleiss Kappa. The score of each specimen was defined as the mode (most observed value) calculated from the scores attributed by the evaluators. Ordinal logistic regression was used to analyze the effect of each factor on scores. A significance level of ( = 0.05 was used for all data analyses.
Results
Evaluation of root surface roughness - Ra
A repeated-measures ANOVA revealed that “substrate” (P < .001), “instrumentation” (p < .001), and “post-instrumentation prophylaxis” (P < 0.001) affected the final Ra values. P-values calculated for all double interactions and the triple interaction were also significant (P < 0.001 for all). In the absence of prophylaxis, the roughest surfaces were observed after ultrasonic instrumentation, followed by hand instrumentation for both IR and NIR groups. No difference in Ra values between hand and ultrasonic instrumentation was observed after prophylaxis for both substrates. For the IR group, the prophylaxis resulted in similar Ra values for both instrumentation groups in comparison to no instrumentation. The substrate irradiation affected the Ra values only when the instrumentation (hand or ultrasonic) was not followed by the prophylaxis (Table 1).
Evaluation of root surface roughness - Rz
A repeated-measures ANOVA showed that the factors “instrumentation” (P < .001), “substrate” (P < 0.001), and “post-instrumentation prophylaxis” (P < 0.001) affected the final values of Rz. All double interactions and the triple interaction had significant p-values (P < 0.001 for all). In the absence of prophylaxis, the highest values of Rz were observed for ultrasound instrumentation, followed by hand instrumentation, in both IR and NIR groups. After prophylaxis, a reduction in Rz values was observed only for ultrasonic instrumentation in the NIR group. In the IR group, a smoother surface was obtained with prophylaxis after both ultrasonic and hand instrumentation. After prophylaxis, no difference in roughness was observed among hand, ultrasonic, and no instrumentation (Table 2). Irradiating the substrate affected the roughness (rougher surface) only when hand or ultrasonic instrumentations were not followed by prophylaxis.
Scores (SEM images)
The repeated-measures ANOVA revealed a moderate concordance among the evaluators was observed (overall Kappa = 0.443). The highest agreement was observed for the score 3 (Kappa = 0.872) and the lowest for the score 1 (Kappa = 0.155). The results of Ordinal logistic regression are presented in Table 3. In general, the substrate did not affect the scores (Figures 2A and 3A). On the other hand, both manual and ultrasonic instrumentation resulted in higher scores than no instrumentation (Figures 2B, 2C, 3B, and 3C), and the scores were reduced after prophylaxis (Figure 2E, 2F, 3E, and 3F).
SEM images (500 x) showing the morphology of root surfaces of different interventions of No Irradiated group: (A) No intervention; (B) Scaling with hand instrumentation; (C) Scaling using a ultrasonic instrumentation; (D) Prophylaxis; (E) Scaling with hand instrumentation followed by prophylaxis; (F) Scaling using a ultrasonic instrumentation followed by prophylaxis.
SEM images (500 x) showing the morphology of root surfaces of different interventions of Irradiated group: (A) No intervention; (B) Scaling with hand instrumentation; (C) Scaling using a ultrasonic instrumentation; (D) Prophylaxis; (E) Scaling with hand instrumentation followed by prophylaxis; (F) Scaling using a ultrasonic instrumentation followed by prophylaxis.
Discussion
To the author's best knowledge, it is noteworthy this is the first in vitro study that evaluated the effect of different scaling protocols on the morphology and roughness of the root dentin substrate exposure to ionizing radiation. Our findings demonstrated that the most pronounced surface alterations were observed in irradiated surfaces after the ultrasonic instrumentation, rejecting the null hypothesis. In addition, no difference in roughness was observed among hand, ultrasonic, and no instrumentation after post-instrumentation prophylaxis in IR and NIR samples. This last finding suggests that prophylaxis can overcome the tooth surface alterations caused by the instrumentation during periodontal treatment.
Different methods have been proposed to analyze changes in the root surface after applying periodontal instruments, including SEM, atomic force microscope, histological evaluation, three-dimensional optical laser scanner, profilometer, and computerized tomography. It is important to emphasize that each technique has particularities and limitations 1212 de Oliveira GJPL, Cominotte MA, Beraldo TPP, Sampaio JEC, Marcantonio RAC. A microscopic analysis of the effects of root surface scaling with different power parameters of Er, Cr: YSGG laser. Microscopy research and technique. 2015;78(6):529-35.,1313 Kumar P, Das SJ, Sonowal ST, Chawla J. Comparison of root surface roughness produced by hand instruments and ultrasonic scalers: an in vitro study. Journal of clinical and diagnostic research: JCDR. 2015;9(11):ZC56.,1616 Osuna LGG, Oliveira GJPLd, Teixeira LHdS, Marquez CO, Irie MS, Soares PBF. The effect of a 3% hydroxyapatite paste prophylaxis after different root-scaling procedures in periodontics. Revista de Odontologia da UNESP. 2019;48.,1717 Karacaoglu F, Orhan K. Comparison of the effects of different instrumentation techniques on root surface roughness and cement loss using micro‐computerized tomography: an in‐vitro study. International Journal of Dental Hygiene. 2022;20(2):339-46.. The present study measured the surface roughness using a contact profilometer device, while surface wear was identified using an SEM. Profilometer analysis is a two-dimensional measurement that provides reliable data for characterizing root surface roughness after debridement, and it is one of the common methods used for surface roughness analysis 1616 Osuna LGG, Oliveira GJPLd, Teixeira LHdS, Marquez CO, Irie MS, Soares PBF. The effect of a 3% hydroxyapatite paste prophylaxis after different root-scaling procedures in periodontics. Revista de Odontologia da UNESP. 2019;48.,1818 Babina K, Polyakova M, Sokhova I, Doroshina V, Arakelyan M, Zaytsev A, et al. The effect of ultrasonic scaling and air-powder polishing on the roughness of the enamel, three different nanocomposites, and composite/enamel and composite/cementum interfaces. Nanomaterials. 2021;11(11):3072.,1919 Gyurkovics M, Baumann T, Carvalho TS, Assunção CM, Lussi A. In vitro evaluation of modified surface microhardness measurement, focus variation 3D microscopy, and contact stylus profilometry to assess enamel surface loss after erosive-abrasive challenges. PLoS One. 2017;12(4):e0175027.. The results of the analysis of roughness were associated with the root wear data observed through SEM images, seeking to improve the characterization of morphological features on the root surfaces. A moderate agreement between the evaluators determining the SEM scores was observed, and the highest agreement occurred for score 3, which indicates more extensive surface wear.
Regarding the roughness parameters after instrumentation, Ra and Rz values showed that ultrasound instrumentation yields the roughest root surfaces, irrespective of the irradiation of the tooth substrate. However, for both instrumentation methods, the surface roughness increase was more pronounced for irradiated substrates. These results may be related to the possible changes in both organic and inorganic contents caused by the ionizing radiation on the dental substrate. Collagen is the most abundant protein in dentin (≈ 90%), and its proteolysis significantly impacts the tissue's structural integrity 66 de Miranda RR, Silva ACA, Dantas NO, Soares CJ, Novais VR. Chemical analysis of in vivo-irradiated dentine of head and neck cancer patients by ATR-FTIR and Raman spectroscopy. Clinical oral investigations. 2019;23:3351-8.. Some studies evaluating changes in the chemical composition of the dental structure indicate a drop in the amide I/amide III and amide I/CH2 ratios. These ratio reductions negatively affect the quality and organization of collagen fibrils and ultimately compromise the physical and mechanical properties of the dentin 66 de Miranda RR, Silva ACA, Dantas NO, Soares CJ, Novais VR. Chemical analysis of in vivo-irradiated dentine of head and neck cancer patients by ATR-FTIR and Raman spectroscopy. Clinical oral investigations. 2019;23:3351-8.,2020 Campi LB, Lopes FC, Soares LES, de Queiroz AM, de Oliveira HF, Saquy PC, et al. Effect of radiotherapy on the chemical composition of root dentin. Head & Neck. 2019;41(1):162-9.. As a consequence of that, a more pronounced instrumentation effect on surface roughness can be expected in substrates with poorer mechanical properties 66 de Miranda RR, Silva ACA, Dantas NO, Soares CJ, Novais VR. Chemical analysis of in vivo-irradiated dentine of head and neck cancer patients by ATR-FTIR and Raman spectroscopy. Clinical oral investigations. 2019;23:3351-8.,2020 Campi LB, Lopes FC, Soares LES, de Queiroz AM, de Oliveira HF, Saquy PC, et al. Effect of radiotherapy on the chemical composition of root dentin. Head & Neck. 2019;41(1):162-9.,2121 da Cunha SRdB, Fonseca FP, Ramos PAMM, Haddad CMK, Fregnani ER, Aranha ACC. Effects of different radiation doses on the microhardness, superficial morphology, and mineral components of human enamel. Archives of Oral Biology. 2017;80:130-5.,2222 Novais VR, Soares PBF, Guimarães CM, Schliebe LRSO, Braga SSL, Soares CJ. Effect of gamma radiation and endodontic treatment on mechanical properties of human and bovine root dentin. Brazilian Dental Journal. 2016;27:670-4..
The polishing of the root surfaces exposed to the oral environment is indicated to reduce the biofilm adhesion, strengthening and facilitating the biofilm mechanical control by the patient 1616 Osuna LGG, Oliveira GJPLd, Teixeira LHdS, Marquez CO, Irie MS, Soares PBF. The effect of a 3% hydroxyapatite paste prophylaxis after different root-scaling procedures in periodontics. Revista de Odontologia da UNESP. 2019;48.. In the present study, the prophylaxis was able to smooth the rough surfaces (Ra and Rz) observed after hand and ultrasonic instrumentations. This reduction in roughness parameters after prophylaxis corroborates with other studies, and it supports the importance of carrying out this procedure during non-surgical periodontal treatment in patients more susceptible to periodontal disease submitted to RT in the head and neck region 44 Irie M-S, Mendes E-M, Borges J-S, Rabelo G-D. Periodontal therapy for patients before and after radiotherapy: A review of the literature and topics of interest for clinicians. Medicina oral, patologia oral y cirugia bucal. 2018;23(5):e524.,1616 Osuna LGG, Oliveira GJPLd, Teixeira LHdS, Marquez CO, Irie MS, Soares PBF. The effect of a 3% hydroxyapatite paste prophylaxis after different root-scaling procedures in periodontics. Revista de Odontologia da UNESP. 2019;48.,2323 Yurdaguven H, Aykor A, Ozel E, Sabuncu H, Soyman M. Influence of a prophylaxis paste on surface roughness of different composites, porcelain, enamel and dentin surfaces. European Journal of Dentistry. 2012;6(01):001-8.. It is also important to report that the prophylaxis procedure in the IR group was more easily executed, which can be demonstrated by lower Ra and Rz values for this group. This observation suggested that reducing phosphate and carbonate concentrations also reduces the dentin microhardness and elastic modulus 66 de Miranda RR, Silva ACA, Dantas NO, Soares CJ, Novais VR. Chemical analysis of in vivo-irradiated dentine of head and neck cancer patients by ATR-FTIR and Raman spectroscopy. Clinical oral investigations. 2019;23:3351-8.,2020 Campi LB, Lopes FC, Soares LES, de Queiroz AM, de Oliveira HF, Saquy PC, et al. Effect of radiotherapy on the chemical composition of root dentin. Head & Neck. 2019;41(1):162-9.,2121 da Cunha SRdB, Fonseca FP, Ramos PAMM, Haddad CMK, Fregnani ER, Aranha ACC. Effects of different radiation doses on the microhardness, superficial morphology, and mineral components of human enamel. Archives of Oral Biology. 2017;80:130-5.,2222 Novais VR, Soares PBF, Guimarães CM, Schliebe LRSO, Braga SSL, Soares CJ. Effect of gamma radiation and endodontic treatment on mechanical properties of human and bovine root dentin. Brazilian Dental Journal. 2016;27:670-4.. In addition, prophylaxis alone did not significantly change the surface roughness in the present study.
The in vitro model developed in the present study simulated the RT for HNC cancer treatment with a rigorous experimental variables control. However, data extrapolation to clinical practice should be done carefully. Several in vitro studies have used human-extracted teeth as substrate. However, further to ethical restrictions, the standardization of samples obtained from bovine incisor teeth is simplest compared to human teeth (e.g., source, age, and other). In addition, similar physical and mechanical properties were observed between bovine and human teeth 2121 da Cunha SRdB, Fonseca FP, Ramos PAMM, Haddad CMK, Fregnani ER, Aranha ACC. Effects of different radiation doses on the microhardness, superficial morphology, and mineral components of human enamel. Archives of Oral Biology. 2017;80:130-5.,2222 Novais VR, Soares PBF, Guimarães CM, Schliebe LRSO, Braga SSL, Soares CJ. Effect of gamma radiation and endodontic treatment on mechanical properties of human and bovine root dentin. Brazilian Dental Journal. 2016;27:670-4.,2424 Khalefa M, Finke C, Jost-Brinkmann P-G. Effects of air-polishing devices with different abrasives on bovine primary and second teeth and deciduous human teeth. Journal of Orofacial Orthopedics/Fortschritte der Kieferorthopadie. 2013;74(5).,2525 Titley K, Childers S, Kulkarni G. An in vitro comparison of short and long-term shear bond strengths of polyacid modified composite resins to primary human and bovine enamel and dentine. European Archives of Paediatric Dentistry. 2006;7:246-52.. Regarding the storage solutions, physiological saline solution, artificial saliva, or distilled water have been used 88 Reed R, Xu C, Liu Y, Gorski J, Wang Y, Walker M. Radiotherapy effect on nano-mechanical properties and chemical composition of enamel and dentine. Archives of oral biology. 2015;60(5):690-7.,2121 da Cunha SRdB, Fonseca FP, Ramos PAMM, Haddad CMK, Fregnani ER, Aranha ACC. Effects of different radiation doses on the microhardness, superficial morphology, and mineral components of human enamel. Archives of Oral Biology. 2017;80:130-5.. As the focus of this study was the direct effect of scaling on irradiated dental tissue, distilled water was chosen as the storage solution. Distilled water provides an environment capable of radiolysis without greater interaction with the teeth.
Conclusion
In conclusion, irradiated dentin showed a rougher root surface for both manual and ultrasonic instrumentation compared to non-radiated dentin. However, the prophylaxis procedure significantly reduced the roughness of root surfaces after both instrumentation procedures.
References
-
1Bray F, Ferlay J, Soerjomataram I, Siegel RL, Torre LA, Jemal A. Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA: a cancer journal for clinicians. 2018;68(6):394-424.
-
2Alterio D, Marvaso G, Ferrari A, Volpe S, Orecchia R, Jereczek-Fossa BA, editors. Modern radiotherapy for head and neck cancer. Seminars in oncology; 2019: Elsevier.
-
3Buglione M, Cavagnini R, Di Rosario F, Sottocornola L, Maddalo M, Vassalli L, et al. Oral toxicity management in head and neck cancer patients treated with chemotherapy and radiation: Dental pathologies and osteoradionecrosis (Part 1) literature review and consensus statement. Critical reviews in oncology/hematology. 2016;97:131-42.
-
4Irie M-S, Mendes E-M, Borges J-S, Rabelo G-D. Periodontal therapy for patients before and after radiotherapy: A review of the literature and topics of interest for clinicians. Medicina oral, patologia oral y cirugia bucal. 2018;23(5):e524.
-
5Bhandari S, Soni BW, Bahl A, Ghoshal S. Radiotherapy‐induced oral morbidities in head and neck cancer patients. Special Care in Dentistry. 2020;40(3):238-50.
-
6de Miranda RR, Silva ACA, Dantas NO, Soares CJ, Novais VR. Chemical analysis of in vivo-irradiated dentine of head and neck cancer patients by ATR-FTIR and Raman spectroscopy. Clinical oral investigations. 2019;23:3351-8.
-
7de Miranda RR, Ribeiro TE, da Silva ELC, S Júnior PCS, Soares CJ, Novais VR. Effects of fractionation and ionizing radiation dose on the chemical composition and microhardness of enamel. Archives of Oral Biology. 2021;121:104959.
-
8Reed R, Xu C, Liu Y, Gorski J, Wang Y, Walker M. Radiotherapy effect on nano-mechanical properties and chemical composition of enamel and dentine. Archives of oral biology. 2015;60(5):690-7.
-
9Pelloso AM, de Miranda RR, Rossi ME, Bianchini ALB, Marcelino FAS, da Silva ELC, et al. Chemical analysis of irradiated root dentin and its interaction with resin cements. Clinical Oral Investigations. 2022;26(6):4315-25.
-
10Kielbassa AM, Hinkelbein W, Hellwig E, Meyer-Lückel H. Radiation-related damage to dentition. The lancet oncology. 2006;7(4):326-35.
-
11Oza RR, Sharma V, Multani P, Balsara K, Bajaj P, Dhadse P. Comparing the Effectiveness of Ultrasonic Instruments Over Manual Instruments for Scaling and Root Planing in Patients With Chronic Periodontitis: A Systematic Review and Meta-Analysis. Cureus. 2022;14(11).
-
12de Oliveira GJPL, Cominotte MA, Beraldo TPP, Sampaio JEC, Marcantonio RAC. A microscopic analysis of the effects of root surface scaling with different power parameters of Er, Cr: YSGG laser. Microscopy research and technique. 2015;78(6):529-35.
-
13Kumar P, Das SJ, Sonowal ST, Chawla J. Comparison of root surface roughness produced by hand instruments and ultrasonic scalers: an in vitro study. Journal of clinical and diagnostic research: JCDR. 2015;9(11):ZC56.
-
14Yildirim TT, Oztekin F, Keklik E, Tozum MD. Surface roughness of enamel and root surface after scaling, root planning and polishing procedures: An in-vitro study. Journal of Oral Biology and Craniofacial Research. 2021;11(2):287-90.
-
15Meyer K, Lie T. Root surface roughness in response to periodontal instrumentation studied by combined use of microroughness measurements and scanning electron microscopy. Journal of Clinical Periodontology. 1977;4(2):77-91.
-
16Osuna LGG, Oliveira GJPLd, Teixeira LHdS, Marquez CO, Irie MS, Soares PBF. The effect of a 3% hydroxyapatite paste prophylaxis after different root-scaling procedures in periodontics. Revista de Odontologia da UNESP. 2019;48.
-
17Karacaoglu F, Orhan K. Comparison of the effects of different instrumentation techniques on root surface roughness and cement loss using micro‐computerized tomography: an in‐vitro study. International Journal of Dental Hygiene. 2022;20(2):339-46.
-
18Babina K, Polyakova M, Sokhova I, Doroshina V, Arakelyan M, Zaytsev A, et al. The effect of ultrasonic scaling and air-powder polishing on the roughness of the enamel, three different nanocomposites, and composite/enamel and composite/cementum interfaces. Nanomaterials. 2021;11(11):3072.
-
19Gyurkovics M, Baumann T, Carvalho TS, Assunção CM, Lussi A. In vitro evaluation of modified surface microhardness measurement, focus variation 3D microscopy, and contact stylus profilometry to assess enamel surface loss after erosive-abrasive challenges. PLoS One. 2017;12(4):e0175027.
-
20Campi LB, Lopes FC, Soares LES, de Queiroz AM, de Oliveira HF, Saquy PC, et al. Effect of radiotherapy on the chemical composition of root dentin. Head & Neck. 2019;41(1):162-9.
-
21da Cunha SRdB, Fonseca FP, Ramos PAMM, Haddad CMK, Fregnani ER, Aranha ACC. Effects of different radiation doses on the microhardness, superficial morphology, and mineral components of human enamel. Archives of Oral Biology. 2017;80:130-5.
-
22Novais VR, Soares PBF, Guimarães CM, Schliebe LRSO, Braga SSL, Soares CJ. Effect of gamma radiation and endodontic treatment on mechanical properties of human and bovine root dentin. Brazilian Dental Journal. 2016;27:670-4.
-
23Yurdaguven H, Aykor A, Ozel E, Sabuncu H, Soyman M. Influence of a prophylaxis paste on surface roughness of different composites, porcelain, enamel and dentin surfaces. European Journal of Dentistry. 2012;6(01):001-8.
-
24Khalefa M, Finke C, Jost-Brinkmann P-G. Effects of air-polishing devices with different abrasives on bovine primary and second teeth and deciduous human teeth. Journal of Orofacial Orthopedics/Fortschritte der Kieferorthopadie. 2013;74(5).
-
25Titley K, Childers S, Kulkarni G. An in vitro comparison of short and long-term shear bond strengths of polyacid modified composite resins to primary human and bovine enamel and dentine. European Archives of Paediatric Dentistry. 2006;7:246-52.
-
Acknowledgements
- The authors are grateful to the Department of Radiology from Universidade do Triângulo Mineiro (UFTM) for performing the bovine roots radiotherapy, we also like to acknowledge the Multiuser Laboratory of Chemistry Institute at the Universidade Federal de Uberlândia for providing the equipment and technical support for experiments involving electron microscopy. This study was supported by grants from the Fundação de Amparo à Pesquisa de Minas Gerais (FAPEMIG), the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior- Brazil (CAPES) - Finance Code 001 and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq).
Publication Dates
-
Publication in this collection
28 Oct 2024 -
Date of issue
2024
History
-
Received
28 Feb 2024 -
Accepted
06 June 2024