- 作者:Liudmila A. Denisova ; Roman Gr. Maev ; Valery K. Leontjev ; Alex ; re F. Denisov ; George G. Grayson ; Fedor S. Rusanov ; Evgeny Yu. Bakulin ; Dmitry Yu. Gavrilov ; Tatiana V. Grineva
- 关键词:Acoustic microscopy ; Ultrasound ; Adhesion ; Bonding strength ; Dental materials ; Glass-ionomer cement ; Dentin ; Tooth
- 刊名:Dental Materials
- 出版年:2009
- 出版时间:May 2009
- 年:2009
- 卷:25
- 期:5
- 页码:557-565
- 全文大小:1253 K
ObjectivesThe goal of the present study was to investigate the potential for acoustic microscopy techniques to characterize the cement–dentin interface in restored teeth.Methods
Special flat-parallel specimens and whole extracted teeth with restorations were scanned using a high-frequency (50 MHz) focused ultrasonic transducer. Visual acoustic images (B- and C-scans) of the cement–dentin interface were obtained nondestructively, analyzed and compared with optical images taken after the samples were cut along the scanning axis. The shear bonding strength of a subsection of specimens was tested in a Lloyd material testing machine.
Results
An essential distinction between the acoustical properties associated with good and failed bonding has been shown. In the case of failed adhesion, the ultrasound signal reflection from the cement–dentin interface is up to four to seven times higher in magnitude than in the case of good bonding. The comparison of the ultrasound imaging data with the data obtained using an optical microscope revealed a strong correspondence with the acoustical and optical results with respect to the presence, position and dimensions of the defects. The specimens showing higher ultrasound reflection from cement/dentin interface have also shown lower shear bonding strength.
Significance
The results demonstrate that acoustic scanning with a high-frequency focused ultrasonic probe is a valuable method for nondestructive morpho-mechanical analysis of cement/dentin interface for either experimental models or whole restored teeth. An appropriately expanded approach can be widely used for the pre-clinical evaluation of dental materials. Further, this method may prove beneficial in the design of new diagnostic ultrasound devices and techniques for use within clinical dentistry.