Hockin H K Xu1, Michael D Weir, Limin Sun. 1. Department of Endodontics, Prosthodontics and Operative Dentistry, University of Maryland Dental School, 650 West Baltimore Street, Baltimore, MD 21201, USA. hxu@umaryland.edu
Abstract
OBJECTIVES: Secondary caries and restoration fracture are the two main challenges facing tooth cavity restorations. The objective of this study was to develop a composite using tetracalcium phosphate (TTCP) fillers and whiskers to be stress-bearing, and to be "smart" to increase the calcium (Ca) and phosphate (PO(4)) ion release at cariogenic pH. METHODS: TTCP was ball-milled to obtain four different particle sizes: 16.2, 2.4, 1.3, and 0.97 microm. Whiskers fused with nano-sized silica were combined with TTCP as fillers in a resin. Filler level mass fractions varied from 0 to 75%. Ca and PO(4) ion releases were measured vs. time at pH of 7.4, 6, and 4. Composite mechanical properties were measured via three-point flexure before and after immersion in solutions at the three pH. RESULTS: TTCP composite without whiskers had flexural strength similar to a resin-modified glass ionomer (Vitremer) and previous Ca-PO(4) composites. With whiskers, the TTCP composite had a flexural strength (mean+/-S.D.; n=5) of (116+/-9)MPa, similar to (112+/-14)MPa of a stress-bearing, non-releasing hybrid composite (TPH) (p>0.1). The Ca release was (1.22+/-0.16)mmol/L at pH of 4, higher than (0.54+/-0.09) at pH of 6, and (0.22+/-0.06) at pH of 7.4 (p<0.05). PO(4) release was also dramatically increased at acidic pH. After immersion, the TTCP-whisker composite matched the strength of TPH at all three pH (p>0.1); both TTCP-whisker composite and TPH had strengths about threefold that of a releasing control. SIGNIFICANCE: The new TTCP-whisker composite was "smart" and increased the Ca and PO(4) release dramatically when the pH was reduced from neutral to a cariogenic pH of 4, when these ions are most needed to inhibit caries. Its strength was two- to threefold higher than previously known Ca-PO(4) composites and resin-modified glass ionomer. This composite may have the potential to provide the necessary combination of load-bearing and caries-inhibiting capabilities.
OBJECTIVES: Secondary caries and restoration fracture are the two main challenges facing tooth cavity restorations. The objective of this study was to develop a composite using tetracalcium phosphate (TTCP) fillers and whiskers to be stress-bearing, and to be "smart" to increase the calcium (Ca) and phosphate (PO(4)) ion release at cariogenic pH. METHODS:TTCP was ball-milled to obtain four different particle sizes: 16.2, 2.4, 1.3, and 0.97 microm. Whiskers fused with nano-sized silica were combined with TTCP as fillers in a resin. Filler level mass fractions varied from 0 to 75%. Ca and PO(4) ion releases were measured vs. time at pH of 7.4, 6, and 4. Composite mechanical properties were measured via three-point flexure before and after immersion in solutions at the three pH. RESULTS:TTCP composite without whiskers had flexural strength similar to a resin-modified glass ionomer (Vitremer) and previous Ca-PO(4) composites. With whiskers, the TTCP composite had a flexural strength (mean+/-S.D.; n=5) of (116+/-9)MPa, similar to (112+/-14)MPa of a stress-bearing, non-releasing hybrid composite (TPH) (p>0.1). The Ca release was (1.22+/-0.16)mmol/L at pH of 4, higher than (0.54+/-0.09) at pH of 6, and (0.22+/-0.06) at pH of 7.4 (p<0.05). PO(4) release was also dramatically increased at acidic pH. After immersion, the TTCP-whisker composite matched the strength of TPH at all three pH (p>0.1); both TTCP-whisker composite and TPH had strengths about threefold that of a releasing control. SIGNIFICANCE: The new TTCP-whisker composite was "smart" and increased the Ca and PO(4) release dramatically when the pH was reduced from neutral to a cariogenic pH of 4, when these ions are most needed to inhibit caries. Its strength was two- to threefold higher than previously known Ca-PO(4) composites and resin-modified glass ionomer. This composite may have the potential to provide the necessary combination of load-bearing and caries-inhibiting capabilities.
Authors: Lei Cheng; Michael D Weir; Penwadee Limkangwalmongkol; Gary D Hack; Hockin H K Xu; Qianming Chen; Xuedong Zhou Journal: J Biomed Mater Res B Appl Biomater Date: 2011-12-21 Impact factor: 3.368