Effect of preheating and ultrasonic energy on penetration of low viscosity enamel resin infiltrant
Ghoneim, M., Aboushelib, M., Dawod, H., Gaber, R., Raafa, N., Ali, H., Abdelrahman, R. (2020). Effect of preheating and ultrasonic energy on penetration of low viscosity enamel resin infiltrant. EKB Journal Management System, 66(Issue 1 - January (Fixed Prosthodontics, Dental Materials, Conservative Dentistry & Endodontics)), 423-427. doi: 10.21608/edj.2020.79118
Mona M. Ghoneim; Moustafa N. Aboushelib; Hebatullah Dawod; Rowan A. Gaber; Nourhan Raafa; Hagar M. Ali; Rania S. Abdelrahman. "Effect of preheating and ultrasonic energy on penetration of low viscosity enamel resin infiltrant". EKB Journal Management System, 66, Issue 1 - January (Fixed Prosthodontics, Dental Materials, Conservative Dentistry & Endodontics), 2020, 423-427. doi: 10.21608/edj.2020.79118
Ghoneim, M., Aboushelib, M., Dawod, H., Gaber, R., Raafa, N., Ali, H., Abdelrahman, R. (2020). 'Effect of preheating and ultrasonic energy on penetration of low viscosity enamel resin infiltrant', EKB Journal Management System, 66(Issue 1 - January (Fixed Prosthodontics, Dental Materials, Conservative Dentistry & Endodontics)), pp. 423-427. doi: 10.21608/edj.2020.79118
Ghoneim, M., Aboushelib, M., Dawod, H., Gaber, R., Raafa, N., Ali, H., Abdelrahman, R. Effect of preheating and ultrasonic energy on penetration of low viscosity enamel resin infiltrant. EKB Journal Management System, 2020; 66(Issue 1 - January (Fixed Prosthodontics, Dental Materials, Conservative Dentistry & Endodontics)): 423-427. doi: 10.21608/edj.2020.79118

Effect of preheating and ultrasonic energy on penetration of low viscosity enamel resin infiltrant

Egyptian Dental Journal
Article 8, Volume 66, Issue 1 - January (Fixed Prosthodontics, Dental Materials, Conservative Dentistry & Endodontics), January 2020, Page 423-427  XML PDF (737.15 K)
Document Type: Original Article
DOI: 10.21608/edj.2020.79118
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Authors
Mona M. Ghoneim1; Moustafa N. Aboushelib2; Hebatullah Dawod3; Rowan A. Gaber3; Nourhan Raafa3; Hagar M. Ali3; Rania S. Abdelrahman4
1Associate Professor of Restorative Dentistry, Faculty of Dentistry, Alexandria university, Egypt.
2Professor of Biomaterials, Faculty of Dentistry, Alexandria university, Egypt
3Researcher at Biomaterials Lab, Faculty of Dentistry, Alexandria University, Egypt
4Instructor in Operative Department, Faculty of Dentistry, Alexandria University, Egypt
Abstract
Objectives: to determine the depth of resin infiltrated hybrid enamel after application of TTEMA/TEGDMA resin infiltration agent enriched with nano-hydroxy apatite applied on early carious enamel lesions.
Materials and Methods: Sound maxillary centrals were coated with a nail varnish, leaving a window of 4 mm × 4 mm on buccal surface of sound and intact enamel. All specimens were subsequently immersed in a demineralizing solution to produce artificial enamel lesions then etched with a mixture of 2% chlorhexidine and 10% hydrochloric acid. After washing and drying the enamel was coated with a low viscosity TTEMA/TEGDMA resin infiltration agent followed by light polymerization. The effect of addition of 10% nano-hydroxy apatite, preheating at 45ºC, and ultrasonic activation was tested in separate groups. Sectioned specimens were examined under a stereomicroscope equipped with a high-resolution digital camera for determining of the depth of penetration of the low viscosity resin in microns (α=0.05).
Results: Data analysis revealed significant difference in depth of enamel hybrid layer between the tested groups (F=14.2, P<0.001). Average penetration depth was 185 ± 17 µm for TTEMA/TEGDMA resin infiltration agent. Addition of 10% nano-hydroxy apatite reduced penetration depth to 141± 19 µm. On the contrary, preheating and ultrasonic activation increased penetration depth to 211± 13 µm and 221 ± 12 µm respectively.
Conclusions: Within the limitations of this study, the penetration depth of TTEMA/TEGDMA resin infiltration agent was significantly influenced by addition of nano-hydroxy apatite particles. Preheating and ultrasonic activation increased penetration depth significantly.
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