The importance of microstructural variations on the fracture toughness of human dentin

Ivancik, Juliana; Arola, D.

doi:10.1016/j.biomaterials.2012.10.032

Cited by 69 publications

(66 citation statements)

References 53 publications

(81 reference statements)

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“…For cracks in-plane with the tubules, the average initiation 2.2 MPaÁm 0.5 , growth 1.2 MPaÁm 0.5 /mm) and plateau toughness 2.7 MPaÁm 0.5 are greater than those values for the transverse direction (Fig. 8(c)) [66]. The mechanisms contributing to the toughening behavior in this orientation are similar, except perhaps for a larger contribution of the mineralized collagen caused by its orientation.…”

Section: Fracture Properties Of Dentinmentioning

confidence: 60%

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On the Mechanics of Fatigue and Fracture in Teeth

Yahyazadehfar

Ivancik

Majd

et al. 2014

Applied Mechanics Reviews

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Tooth fracture is a major concern in the field of restorative dentistry. However, knowledge of the causes for tooth fracture has developed from contributions that are largely based within the field of mechanics. The present manuscript presents a technical review of advances in understanding the fracture of teeth and the fatigue and fracture behavior of their hard tissues (i.e., dentin and enamel). The importance of evaluating the fracture resistance of these materials, and the role of applied mechanics in developing this knowledge will be reviewed. In addition, the complex microstructures of tooth tissues, their roles in resisting tooth fracture, and the importance of hydration and aging on the fracture resistance of tooth tissues will be discussed. Studies in this area are essential for increasing the success of current treatments in dentistry, as well as in facilitating the development of novel bio-inspired restorative materials for the future.

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Section: Fracture Properties Of Dentinmentioning

confidence: 60%

“…Nevertheless, constraints in tissue volume have limited this configuration to studies of dentin from the tooth crown e.g., Refs. [64][65][66]. A schematic description of the more common specimen configurations that have been adopted is presented in Fig.…”

Section: Methods Of Evaluating Fatigue and Fracture In Tooth Tissuesmentioning

confidence: 99%

On the Mechanics of Fatigue and Fracture in Teeth

Yahyazadehfar

Ivancik

Majd

et al. 2014

Applied Mechanics Reviews

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“…In both cases the resulting differences may be due to the presence of retentions in the EG, which on the one hand implies an increase in the contact surface between the interface components, and on the other the inclusion of resin inside them generates a change of material that brings about a redistribution of forces when the bond is loaded. This way, when the fault in the resin composite-dentin bond is induced with the application of the shear test, the additional contact surface provided by the retentions involves more dentin, causing a cohesive fracture of this substrate, a phenomenon facilitated by the depth of the preparations in the dentin (Ivancik & Arola, 2013). At the same time, these retentions tend to prevent the resin from being dislodged, which causes a cohesive fracture.…”

Section: Resultsmentioning

confidence: 99%

“…Certainly both types of analysis provide relevant objective information as to the mechanical behavior of the adhesive and the substrates (Scherrer et al) involved in the resin-dentin bond of the surface fractured after application of the mechanical test. Nevertheless, their correlation with the clinical behavior of restorations must be established individually for such parameters as microfiltration, bond strength and marginal fit (Heintze), and by association to those studies that evaluate the behavior of the resin-dentin bond interface in terms of resistance to shear forces and traction (Braga et al, 2010;Ivancik & Arola).…”

Section: Discussionmentioning

confidence: 99%

Use of Morphometric Analyses to Assess the Efficacy of the Technique of Resin Composite Bonded to Cervical Dentin with Additional Mechanical Retentions

2016

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Use of morphometric analyses to assess the efficacy of the technique of resin composite bonded to cervical dentin with additional mechanical retentions. Int. J. Morphol., 34(2):597-603, 2016. SUMMARY:The structural changes and morphological derivatives of progressive dentin hypermineralization determine the bonding to its surface. A planimetric study and fracture volume estimate were conducted to assess the efficacy of resin composite bonded to hypermineralized cervical dentin with and without retentions by applying a shear test. Thirty-four premolars from adult patients were used to obtain a flat cervical dentin surface. The specimens were distributed randomly into two groups: 1) experimental, where hemispherical retentions were carved into the cervical dentin, and 2) control, where the flat dentin was maintained. Using a jig, a resin column was built into the dentin surface fitted with bonding in specimens from both groups, which were then subjected to the shear test. The morphological analysis was performed with a microscope while the percentage of remnant surface from each component of the adhesive bond was calculated planimetrically. The volume of lost tissue was determined using Scherle's method. In the planimetric study, the average remnant resin on the surface was significantly higher in the experimental group and there was less intact dentin in the control group. The volumetric assessment also showed a much higher loss of dentin substrate than the experimental group. Consequently, the complementary use of morphometric and volumetric techniques enables the evaluation of the efficacy of a technique, demonstrating that the inclusion of mechanical retentions in hypermineralized cervical dentin improves the bonding properties.

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“…Sa rigidité, inférieure à celle de l'émail, est de 19 GPa. Les deux substrats de modules différents sont en contact grâce à des fibres de collagène, permettant un transfert de contraintes à cette interface, constituant ainsi un mécanisme efficace contre la propagation des fissures et l'absorption des contraintes (12) : c'est la jonction amélo-dentinaire (JAD). Cette interface structurelle et fonctionnelle entre un tissu extrêmement rigide et un tissu flexible donne à l'organe dentaire cette aptitude à supporter les contraintes masticatoires et thermiques tout au long de la vie (13), créant ainsi un excellent compromis entre rigidité, solidité et résilience.…”

Section: Restoration Of Endodontically Treated Molars Is a Daily Chalunclassified