|Year : 2020 | Volume
| Issue : 3 | Page : 193-199
Evaluation of the effectiveness of fluoridated and non-fluoridated desensitizing agents in dentinal tubule occlusion using scanning electron microscopy. An in-vitro study
Ashwini Dessai1, Neeta Shetty1, N Srikant2
1 Department of Conservative Dentistry and Endodontics, Manipal College of Dental Sciences, Mangalore, Affiliated to Manipal Academy of Higher Education, Manipal, Karnataka, India
2 Department of Oral Pathology and Microbiology, Manipal College of Dental Sciences, Mangalore, Affiliated to Manipal Academy of Higher Education, Manipal, Karnataka, India
|Date of Web Publication||23-May-2020|
Dr. Neeta Shetty
Department of Conservative Dentistry and Endodontics, Manipal College of Dental Sciences, Mangalore, Affiliated to Manipal Academy of Higher Education, Manipal - 576 104, Karnataka
Source of Support: None, Conflict of Interest: None
Background: Dentin hypersensitivity is primarily caused due to patent or exposed dentinal tubules. Nonfluoridated-desensitizing agents deposit hydroxycarbonate apatite (HCA), within the dentinal tubules, thereby relieving hypersensitivity. Fluoride-containing bioactive glass-based agents form fluorapatite which is less soluble when compared to hydroxyapatite and HCA.
Materials and Methods: In this in vitro study forty dentin specimens obtained from extracted human premolars were divided randomly into four groups (n = 10): Group 1 – fluoridated bioactive glass (FBaG); Group 2 – bioactive glass (BaG); Group 3 – arginine calcium carbonate; Group 4 – saline. 37.5% phosphoric acid was used to ensure patent dentinal tubules. Test agents from each group were applied using a rubber cup. Half the treated samples were then subjected to 6% citric acid treatment. The degree of occlusion was evaluated using the scanning electron microscope, and the microscopic images were scored before and after the citric acid challenge by two blinded endodontists. Statistical analysis was performed using SPSS, one-way ANOVA, and post hoc Tukey test (P = 0.05).
Results: Group 1 demonstrated better tubule occlusion in comparison with Group 2 and a statistically significant difference when compared to Group 3 (P = 0.001). Following acid challenge, Group 2 showed significantly more occluded tubules when compared with Group 3 (P = 0.001) and comparable difference with Group 1.
Conclusion: All desensitizing agents showed satisfactory dentinal tubule occlusion. While fluoridated bioactive glass demonstrated better occlusion immediately after application, Bioactive glass showed better resistance to acid treatment.
Keywords: Bioactive glass, dentin hypersensitivity, scanning electron microscopy
|How to cite this article:|
Dessai A, Shetty N, Srikant N. Evaluation of the effectiveness of fluoridated and non-fluoridated desensitizing agents in dentinal tubule occlusion using scanning electron microscopy. An in-vitro study. Dent Res J 2020;17:193-9
|How to cite this URL:|
Dessai A, Shetty N, Srikant N. Evaluation of the effectiveness of fluoridated and non-fluoridated desensitizing agents in dentinal tubule occlusion using scanning electron microscopy. An in-vitro study. Dent Res J [serial online] 2020 [cited 2020 May 26];17:193-9. Available from: http://www.drjjournal.net/text.asp?2020/17/3/193/284733
| Introduction|| |
Dentin hypersensitivity (DH) is described as a short sharp pain that arises from exposed dentinal tubules to thermal, osmotic, evaporative, chemical, or tactile stimuli that cannot be compared to any dental defect or pathology. Satisfactory occlusion of the exposed tubules can be achieved by smear layer or pellicle formation; however, prolonged exposure to oral fluids can negate this effect. Brännstrom and Astroem described the mechanism for hypersensitivity based on the “hydrodynamic theory. ” Hence, the treatment should be aimed at regaining the original state of the dentin, either by occluding the tubules or by gaining control over the neural elements in the pulp tissue that would weaken the stimulatory effects. These modalities bring about partial or complete tubule obliteration or alteration of sensory activity within the pulp or both.
Bioactive glass (BaG, NovaMin®, developed by NovaMin Technology Inc., Alachua, FL, USA) derived from the original 45S5 Bioglass® (US Biomaterials Corp., Jacksonville, FL, USA) composition was incorporated within dentifrices as a remineralizing agent to treat DH. It precipitates the hydroxycarbonate apatite (HCA) on the surface of the tooth and bringing about subsequent occlusion of the dentinal tubules.,, As the majority of the dentinal matrix is made up of collagen, the BaG particles were expected to bind to the exposed dentin surfaces and bring about the physical occlusion of dentinal tubules. Studies have demonstrated that the initial reactivity of the BaG particles is attributed to the development of a surface negative charge, that enables binding to Type I collagen fibers. The fluoridated daily use toothpaste containing NovaMin for the treatment of DH and repair of sensitive teeth is based upon 5% w/w calcium sodium phosphosilicate (CSPS) technology. The CSPS technology delivers a hydroxyapatite-like reparative layer to the surface of the dentin in vitro, which has shown to be resistant to acid challenge.
Another novel technology introduced in the recent past advocates the use of 8% arginine calcium carbonate (ACC) to treat DH. The deposition of arginine bicarbonate and calcium carbonate has been shown to physically block and seal open dentinal tubules. Arginine and calcium carbonate act simultaneously in accordance with the natural modes of tubule occlusion and deposit a dentin-like mineral, primarily composed of calcium and phosphate, inside the dentinal tubules. This “Pro-Argin ” technology is known to physically occlude and seal the exposed dentinal tubules, thereby relieving DH.
Fluoride is commonly used in varnishes, mouth rinses, and dentifrices since its introduction in 1941. Fluoride ions can be incorporated into the glass matrix as calcium fluoride by part substituting network modifier oxides or by maintaining relatively constant ratios of the other constituents. It was demonstrated that fluoride-containing bioactive glasses (FBaG) form fluorapatite (FAp) instead of HCA. Due to their ability to release fluoride locally, FBaGs make interesting candidates for a variety of clinical applications, one of which includes dentinal tubule occlusion to treat DH. Therefore, the purpose of thisin vitro study was to evaluate the efficacy of fluoridated BaG toothpaste, nonfluoridated BaG toothpaste, and ACC-containing toothpaste in dentinal tubule occlusion using scanning electron microscopy (SEM).
| Materials and Methods|| |
The in vitro study was conducted in the department of conservative dentistry and endodontics after obtaining the Institutional Ethical Committee clearance (Ref. No: 17042).
Forty human permanent maxillary and mandibular premolars that were extracted for orthodontic reasons were used to prepare dentin discs. Teeth with any visible or clinically detectable cracks, stains, caries, wear facets, erosive or abrasive lesions, attrition, restorations, white spot lesions, or hypoplasia were excluded from the study.
A high-speed diamond bur (TF-21, Mani Inc., Japan) was used to decoronate the teeth. Dentin discs of 1.0 ± 0.1 mm thickness were obtained from the middle coronal dentin by sectioning the teeth perpendicular to their long axis. Any remaining enamel was removed and a silicon carbide paper (600 grit) was used to eliminate any surface irregularities and to create a smooth and uniform surface. Specimens were then sonicated for 10 min and then thoroughly rinsed with saline to ensure complete removal of the polishing abrasive. 35% phosphoric acid (3M, ESPE, USA) was used for 30 s to etch the dentin and expose the dentinal tubules. Specimens were then rinsed with distilled water and sonicated for 5 min to remove any residual etchant. The samples were then placed in phosphate-buffered solution (PBS) until further use.
The dentin discs were randomly divided into four groups (n = 10) [Table 1].
Treatment of specimens
The specimens (n = 10) from each group were loaded on microscope slides with the polished surface facing upward and secured using a double-sided tape. The samples were moistened with PBS solution, and a rubber cup attached to a slow-speed handpiece (NSK, Japan) was used to apply the products on the specimens. The samples were left undisturbed for 5 min, following which they were rinsed using distilled water to remove any residual material from the surfaces.
Five specimens were then randomly chosen from each group for SEM analysis.
Remaining specimens (n = 5) from each of the groups were then exposed to 6% citric acid having a pH = 2 in a Petri dish More Details for 1 min and then rinsed with distilled water for 2 min.
Evaluation of dentinal tubule occlusion
The degree of dentinal tubule occlusion was evaluated with the help of an SEM (TM3000 Tabletop Microscope, Hitachi, Tokyo, Japan). The specimens were sputter coated with gold using a gold/palladium mini sputter coater (Emitech SC7620, UK) and examined at an operating voltage of 5 kV. The SEM images were captured at ×2000.
Dentin specimens were evaluated after each of the following situations:
- After etching with phosphoric acid – To confirm that the dentinal tubules are in an open unoccluded state [Figure 1]a, [Figure 2]a and [Figure 3]a
- After application of test agent – To evaluate the degree of dentinal tubule occlusion [Figure 1]b, [Figure 2]b and [Figure 3]b
- After acid challenge – To evaluate the resistance of the treated specimens (occluded tubules) to acid challenge [Figure 1]c, [Figure 2]c and [Figure 3]c.
|Figure 1: Representative scanning microscopic images of the dentin surfaces showing the degree of tubule occlusion (a) after etching with phosphoric acid; (b) after treatment; (c) after treatment followed by the acid challenge for Group 1 – FBaG. FBaG: Fluoridated bioactive glass|
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|Figure 2: Representative scanning microscopic images of the dentin surfaces showing the degree of tubule occlusion (a) after etching with phosphoric acid; (b) after treatment; (c) after treatment followed by the acid challenge for Group 2 –BaG, BaG: Bioactive glass|
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|Figure 3: Representative scanning microscopic images of the dentin surfaces showing the degree of tubule occlusion (a) after etching with phosphoric acid; (b) after treatment; (c) after treatment followed by the acid challenge for Group 3 – ACC, ACC: Arginine calcium carbonate|
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Each treated surface of every specimen was analyzed, and four images were captured to minimize subjectivity. Two well-trained blinded endodontists assessed and scored the degree of tubule occlusion. The tubule occlusion classification scoring system was used, and scoring was based on a categorical scale of 1–5: (1) occluded (100% of tubules occluded); (2) mostly occluded (50–<100% of tubules occluded); (3) partially occluded (25–<50% of tubules occluded); (4) mostly unoccluded (<25% of tubules occluded); (5) unoccluded (0%, no tubule occlusion).
The SPSS 20.0 version was used for the statistical analysis. The mean occlusion scores were analyzed using one-way ANOVA and the post hoc Tukey test. Paired t-test was used for intragroup comparison before and after the acid challenge (P = 0.05).
| Results|| |
Specimens treated with fluoridated bioactive glass (FBaG) demonstrated higher tubule occlusion with a mean value of 3.27, followed by ACC and BaG with mean values of 3.31 and 3.43, respectively [Chart 1]. Following acid challenge, BaG demonstrated the highest degree of tubule occlusion with a mean value of 3.09, followed by FBaG with a mean value of 3.68, and the least number of occluded tubules was observed in the ACC group, with a mean value of 4.3 [Chart 1 ]and [Figure 1]b, [Figure 2]b, [Figure 3]b .
Following acid challenge, intergroup comparison revealed a statistically significant difference between the BaG and the ACC groups [Table 2] and [Figure 2]c, [Figure 3]c.
|Table 2: One-way ANOVA and post hoc Tukey test to assess the tubule occlusion scores before application of test agent and following acid challenge|
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While FBaG and BaG groups showed no significant intragroup difference in dentinal tubule occlusion before and after citric acid challenge, significant intragroup differences were noted with the ACC group [Table 2] and [Figure 3]a,[Figure 3]b,[Figure 3]c. SEM image evaluation of dentin surface treated with fluoridated BaG demonstrated peritubular particle depositions and coverage of the dentinal tubules [Figure 1]b. In the BaG group, few dentinal tubules demonstrated complete occlusion along with some unoccluded tubules [Figure 2]b. The samples subjected to treatment with ACC showed crystal-like depositions within the dentinal tubules [Figure 3]b. Postacid challenge, most tubules in the FBaG and BaG specimens remained fairly occluded [Figure 1]c and [Figure 2]c. However, more unoccluded tubules were seen in the specimens treated with ACC [Figure 3]c. The specimens treated with saline no change in tubule patency before and after the acid challenge [Figure 4]a,[Figure 4]b,[Figure 4]c.
|Figure 4: Representative scanning microscopic images of the dentin surfaces showing the degree of tubule occlusion (a) after etching with phosphoric acid; (b) after treatment; (c) after treatment followed by the acid challenge for Group 4 – Saline.|
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Scoring criteria: 1 = occluded (100% of tubules occluded); 2 = mostly occluded (50–<100% of tubules occluded); 3 = partially occluded (25–<50% of tubules occluded); 4 = mostly unoccluded (<25% of tubules occluded); 5 = unoccluded (0%, no tubule occlusion).
| Discussion|| |
Saliva has shown to naturally occlude dentinal tubules by forming a protective glycoprotein layer with the help of calcium and phosphate ions. This process of natural tubule occlusion is reported to be extremely slow, and the tubule plugging is easily dislodged by dietary acid, thereby rendering it ineffective in providing lasting relief. Hence, various chemical formulations have been developed to occlude the dentinal tubules to reduce dentinal sensitivity.
According to the results of this study, fluoridated BaG [Figure 1] demonstrated better occlusion of dentinal tubules when compared with the ACC group. This difference in occlusion can be attributed to the formation of FAp seen in the FBaG group.,, Based on research by Lynch et al., fluoride-containing BaGs form FAp, which is shown to be more acid resistant than HCA., According to Mneimne et al., an increase in phosphate content in the glass allows the formation of FAp rather than fluorite, even at a lower pH. Furthermore, FAp is less soluble when compared to hydroxyapatite and HCA, thus making it more resistant to attack by acid. Hence, it can be presumed that these particles would be lost less readily, especially on exposure to acidic insults.
The results also demonstrated that the BaG-containing group had the highest number of occluded tubules, especially after the acid challenge. This can be attributed to the mechanism by which these BaGs act. According to Burwell et al., NovaMin present within the BaGs binds to the exposed dentinal surface and reacts with it to form a mineralized layer. The layer formed is not only mechanically strong but also resistant to acid attack. Further, the continuous release of calcium over time has been shown to maintain the protective effects on dentin and maintain occlusion of the dentin tubules., The result obtained in our study is in agreement with otherin vitro studies., Another study concluded that when NovaMin particles come into contact with saliva, an immediate release of sodium ions occurs, which increases the local environmental pH. This combination of sodium ion release and pH rise facilitates the rapid precipitation of a calcium phosphate HCA layer, following the subsequent release of calcium and phosphate ions. Furthermore, the CSPS particles can act as reservoirs to release calcium and phosphate ions continuously into the local environment.
Earlierin vitro studies have also demonstrated that NovaMin was quick in occluding dentinal tubules and forming a protective layer on the dentinal surface., Mony et al., in their comparative study, observed that there was better deposition of material over decalcified enamel by NovaMin than with fluoride. This finding can be further substantiated by variousin vivo studies that have demonstrated better tubule occlusion over a prolonged period with BaGs (NovaMin).,,, Based on a randomized controlled trial carried out by Neuhaus et al., it was observed that a single application of both fluoridated and nonfluoridated prophylaxis pastes containing 15% CSPS (NovaMin) provided a significant reduction of DH immediately after a single application that lasted up to 28 days.
Group III (ACC) exhibited significantly poor tubule occlusion when compared with both the BaG-containing groups. This was consistent with the findings obtained by West et al.; except in their study, the test agents were applied with the help of electric toothbrushes. According to Kleinberg, when arginine and calcium carbonate act together, they form a positively charged complex that enables it to bind to the dentin surface which is negatively charged. Furthermore, the alkaline pH aids in tubule occlusion by enabling the deposition of calcium and phosphate from the saliva and dentinal fluid, thereby enhancing the tubular occlusion. However, the results obtained in this study are similar to anin vivo study by Rao et al. and anin vitro study by Bakri et al., where it was demonstrated that NovaMin-containing desensitizing paste provided better relief than ACC-containing paste.
The results have demonstrated that the degree of tubule occlusion seen with fluoridated BaG was comparable with the BaG group, and both the BaG-containing agents demonstrated resistance to a citric acid challenge and showed better tubule occlusion compared to ACC-containing agent. This result, when compared with other experimental studies by Parkinson and Wilson, Shah et al., and Sauro et al., showed similar findings. As observed, Group III (ACC) demonstrated satisfactory tubule occlusion, but poor resistance to citric acid challenge, similar to other experimental studies by Davies et al, Rajguru et al, and Parkinson and Wilson thereby suggesting that occlusion by arginine based dentifrices is not stable following prolonged acid challenge and is more susceptible to dissolution by acids.
Thus, the results obtained reveal that the degree of tubule occlusion seen with fluoridated BaG was comparable with the BaG group. However, both the BaG-containing agents demonstrated resistance to a citric acid challenge and showed better tubule occlusion compared to ACC-containing agent.
Inability to precisely mimic the intraoral environment, the potential action of saliva, and its buffering ability in the presence of acidic environment could not be evaluated in our study and can be considered as a limitation of this study.
| Conclusion|| |
Within the limitations of this study, it can be concluded that fluoridated and nonfluoridated BaG-containing toothpaste showed a significant degree of dentinal tubule occlusion and can be recommended as desensitizing agents in cases of hypersensitivity. BaGs demonstrated better resistance to acid attack; hence, their use in the treatment of noncarious or erosive lesions is recommended.
Financial support and sponsorship
Conflicts of interest
The authors of this manuscript declare that they have no conflicts of interest, real or perceived, financial or non-financial in this article.
| References|| |
Chen CL, Parolia A, Pau A, Celerino de Moraes Porto IC. Comparative evaluation of the effectiveness of desensitizing agents in dentine tubule occlusion using scanning electron microscopy. Aust Dent J 2015;60:65-72.
Bartold PM. Dentinal hypersensitivity: A review. Aust Dent J 2006;51:212-8.
Brannstrom M, Johnson G, Nordenvall KJ. Transmission and control of dental pain: Resin impregnation for the desensitization of dentin. J Am Dent Assoc 1979;99:612-618.
Lynch E, Brauer DS, Karpukhina N, Gillam DG, Hill RG. Multi-component bioactive glasses of varying fluoride content for treating dentin hypersensitivity. Dent Mater 2012;28:168-78.
Vollenweider M, Brunner TJ, Knecht S, Grass RN, Zehnder M, Imfeld T, et al.
Remineralization of human dentin using ultrafine bioactive glass particles. Acta Biomater 2007;3:936-43.
Kumar A, Singh S, Thumar G, Mengji A. Bioactive glass nanoparticles (NovaMin®) for applications in dentistry. J Dent Med Sci 2015;14:30-5.
Layer TM. Development of a fluoridated, daily-use toothpaste containing NovaMin technology for the treatment of dentin hypersensitivity. J Clin Dent 2011;22:59-61.
Docimo R, Montesani L, Maturo P, Costacurta M, Bartolino M, DeVizio W, et al.
Comparing the efficacy in reducing dentin hypersensitivity of a new toothpaste containing 8.0% arginine, calcium carbonate, and 1450 ppm fluoride to a commercial sensitive toothpaste containing 2% potassium ion: An eight-week clinical study in Rome, Italy. J Clin Dent 2009;20:17-22.
Hamlin D, Williams KP, Delgado E, Zhang YP, DeVizio W, Mateo LR. Clinical evaluation of the efficacy of a desensitizing paste containing 8% arginine and calcium carbonate for the in-office relief of dentin hypersensitivity associated with dental prophylaxis. Am J Dent 2009;22 Spec No A:16A-20A.
Brauer DS, Karpukhina N, O'Donnell MD, Law RV, Hill RG. Fluoride-containing bioactive glasses: Effect of glass design and structure on degradation, pH and apatite formation in simulated body fluid. Acta Biomater 2010;6:3275-82.
Shah FA. Fluoride-containing bioactive glasses: Glass design, structure, bioactivity, cellular interactions, and recent developments. Mater Sci Eng C Mater Biol Appl 2016;58:1279-89.
Bakri MM, Hossain MZ, Razak FA, Saqina ZH, Misroni AA, Ab-Murat N, et al.
Dentinal tubules occluded by bioactive glass-containing toothpaste exhibit high resistance toward acidic soft drink challenge. Aust Dent J 2017;62:186-91.
Mneimne M, Hill RG, Bushby AJ, Brauer DS. High phosphate content significantly increases apatite formation of fluoride-containing bioactive glasses. Acta Biomater 2011;7:1827-34.
Pradeep AR, Sharma A. Comparison of clinical efficacy of a dentifrice containing calcium sodium phosphosilicate to a dentifrice containing potassium nitrate and to a placebo on dentinal hypersensitivity: A randomized clinical trial. J Periodontol 2010;81:1167-73.
Burwell A, Jennings D, Muscle D, Greenspan DC. NovaMin and dentin hypersensitivity –in vitro
evidence of efficacy. J Clin Dent 2010;21:66-71.
Wang Z, Sa Y, Sauro S, Chen H, Xing W, Ma X, et al.
Effect of desensitising toothpastes on dentinal tubule occlusion: A dentine permeability measurement and SEMin vitro
study. J Dent 2010;38:400-10.
Litkowski LJ, Hack GD, Sheaffer HB, Greenspan DC. Occlusion of dentine tubules by 45S5 bioglass bioceramics 10. In: Sedel L, Rey C, editors. Proceedings of the 10th
International Symposium on Ceramics in Medicine. Paris, France; 1997.
Huang X, Li R, Feng Y, Wang Y. Remineralization of demineralized dentin induced by bioactive glass NovaMin. Zhong Nan Da Xue Xue Bao Yi Xue Ban 2018;43:619-24.
Taha AA, Patel MP, Hill RG, Fleming PS. The effect of bioactive glasses on enamel remineralization: A systematic review. J Dent 2017;67:9-17.
Mony S, Rao A, Shenoy R, Suprabha BS. Comparative evaluation of the remineralizing efficacy of calcium sodium phosphosilicate agent and fluoride based on quantitative and qualitative analysis. J Indian Soc Pedod Prev Dent 2015;33:291-5.
] [Full text]
Rajesh KS, Hedge S, Arun Kumar MS, Shetty DG. Evaluation of the efficacy of a 5% calcium sodium phosphosilicate (Novamin) containing dentifrice for the relief of dentinal hypersensitivity: A clinical study. Indian J Dent Res 2012;23:363-7.
] [Full text]
Kakar A, Kakar K, Sreenivasan PK, DeVizio W, Kohli R. Comparison of the clinical efficacy of a new dentifrice containing 8.0% arginine, calcium carbonate, and 1000 ppm fluoride to a commercially available sensitive toothpaste containing 2% potassium ion on dentin hypersensitivity: A randomized clinical trial. J Clin Dent 2012;23:40-7.
Madan N, Madan N, Sharma V, Pardal D, Madan N. Tooth remineralization using bio-active glass-A novel approach. J Acad Adv Dent Res 2011;2:45-50.
Athuluru D, Reddy C, Sudhir KM, Kumar K, Gomasani S, Nagarakanti S. Evaluation and comparison of efficacy of three desensitizing dentifrices on dentinal hypersensitivity and salivary biochemical characteristics: A randomized controlled trial. Dent Res J (Isfahan) 2017;14:150-7.
Neuhaus KW, Milleman JL, Milleman KR, Mongiello KA, Simonton TC, Clark CE, et al.
Effectiveness of a calcium sodium phosphosilicate-containing prophylaxis paste in reducing dentine hypersensitivity immediately and 4 weeks after a single application: A double-blind randomized controlled trial. J Clin Periodontol 2013;40:349-57.
West NX, Hughes JA, Addy M. The effect of pH on the erosion of dentine and enamel by dietary acids in vitro
. J Oral Rehabil 2001;28:860-4.
Kleinberg I. SensiStat. A new saliva-based composition for simple and effective treatment of dentinal sensitivity pain. Dent Today 2002;21:42-7.
Rao A, Mitra D, Prabhakar A, Soni S, Ahmed S, Arya S. The reduction efficacy of dentinal hypersensitivity by two commercially available desensitizing toothpastes: Vantej and Colgate Pro-Argin. Saudi Endod J 2014;4:7.
Parkinson CR, Willson RJ. A comparativein vitro
study investigating the occlusion and mineralization properties of commercial toothpastes in a four-day dentin disc model. J Clin Dent 2011;22:74-81.
Shah S, Shivakumar A, Khot O, Patil C, Hosmani N. Efficacy of NovaMin-and Pro-Argin-containing desensitizing dentifrices on occlusion of dentinal tubules. Dent Hypotheses 2017;8:104. [Full text]
Sauro S, Watson TF, Thompson I. Dentine desensitization induced by prophylactic and air-polishing procedures: Anin vitro
dentine permeability and confocal microscopy study. J Dent 2010;38:411-22.
Davies M, Paice EM, Jones SB, Leary S, Curtis AR, West NX. Efficacy of desensitizing dentifrices to occlude dentinal tubules. Eur J Oral Sci 2011;119:497-503.
Rajguru SA, Padhye AM, Gupta HS. Effects of two desensitizing dentifrices on dentinal tubule occlusion with citric acid challenge: Confocal laser scanning microscopy study. Indian J Dent Res 2017;28:450-6.
] [Full text]
[Figure 1], [Figure 2], [Figure 3], [Figure 4]
[Table 1], [Table 2]