M V Swain1, A Coldea2, A Bilkhair3, P C Guess3. 1. Faculty of Dentistry, Health Science Centre, Kuwait University, Kuwait. Electronic address: mswain@mail.usyd.edu.au. 2. Vita Zahnfabrik, Bad Säckingen, Germany. 3. Prosthetic Department, Faculty of Dentistry, University of Freiburg, Germany.
Abstract
OBJECTIVES: This paper investigates the structure and some properties of resin infiltrated ceramic network structure materials suitable for CAD/CAM dental restorative applications. METHODS: Initially the basis of interpenetrating network materials is defined along with placing them into a materials science perspective. This involves identifying potential advantages of such structures beyond that of the individual materials or simple mixing of the components. RESULTS: Observations from a number of recently published papers on this class of materials are summarized. These include the strength, fracture toughness, hardness and damage tolerance, namely to pointed and blunt (spherical) indentation as well as to burr adjustment. In addition a summary of recent results of crowns subjected to simulated clinical conditions using a chewing simulator are presented. These results are rationalized on the basis of existing theoretical considerations. SIGNIFICANCE: The currently available ceramic-resin IPN material for clinical application is softer, exhibits comparable strength and fracture toughness but with substantial R-curve behavior, has lower E modulus and is more damage tolerant than existing glass-ceramic materials. Chewing simulation observations with crowns of this material indicate that it appears to be more resistant to sliding/impact induced cracking although its overall contact induced breakage load is modest.
OBJECTIVES: This paper investigates the structure and some properties of resin infiltrated ceramic network structure materials suitable for CAD/CAM dental restorative applications. METHODS: Initially the basis of interpenetrating network materials is defined along with placing them into a materials science perspective. This involves identifying potential advantages of such structures beyond that of the individual materials or simple mixing of the components. RESULTS: Observations from a number of recently published papers on this class of materials are summarized. These include the strength, fracture toughness, hardness and damage tolerance, namely to pointed and blunt (spherical) indentation as well as to burr adjustment. In addition a summary of recent results of crowns subjected to simulated clinical conditions using a chewing simulator are presented. These results are rationalized on the basis of existing theoretical considerations. SIGNIFICANCE: The currently available ceramic-resin IPN material for clinical application is softer, exhibits comparable strength and fracture toughness but with substantial R-curve behavior, has lower E modulus and is more damage tolerant than existing glass-ceramic materials. Chewing simulation observations with crowns of this material indicate that it appears to be more resistant to sliding/impact induced cracking although its overall contact induced breakage load is modest.
Authors: Mehmet Mustafa Özarslan; Ulviye Şebnem Büyükkaplan; Çağatay Barutcigil; Merve Özarslan; Kubilay Barutcigil; Nurullah Türker Journal: Head Face Med Date: 2018-11-26 Impact factor: 2.151
Authors: Rasha A Alamoush; Nick Silikas; Nesreen A Salim; Suhad Al-Nasrawi; Julian D Satterthwaite Journal: Biomed Res Int Date: 2018-10-23 Impact factor: 3.411