Calcium phosphate cement (CPC) sets to form hydroxyapatite and has been use
d in medical and dental procedures. However, the brittleness and low streng
th of CPC prohibit its use in many stress-bearing locations, unsupported de
fects, or reconstruction of thin bones. Recent studies incorporated fibers
into CPC to improve its strength. In the present study, a novel methodology
was used to combine the reinforcement with macroporosity: large-diameter r
esorbable fibers were incorporated into CPC to provide short-term strength.
then dissolved to create macropores. suitable for bone ingrowth. Two types
of resorbable fibers with 322 mum diameters were mixed with CPC to a fiber
volume fraction of 25%. The set specimens were immersed in saline at 37 de
greesC for 1, 7. 14, 28 and 56 d, and were then tested in three-point flexu
re. SEM was used to examine crack-fiber interactions. CPC composite achieve
d a flexural strength 3 times, and work-of-fracture (toughness) nearly 100
times, greater than unreinforced CPC. The strength and toughness were maint
ained for 2-4 weeks of immersion, depending on fiber dissolution rate. Macr
opores or channels were observed in CPC composite after fiber dissolution.
In conclusion, incorporating large-diameter resorbable fibers can achieve t
he needed short-term strength and fracture resistance for CPC while tissue
regeneration is occurring, then create macropores suitable for vascular ing
rowth when the fibers are dissolved. The reinforcement mechanisms appeared
to be crack bridging and fiber pullout; the mechanical properties of the CP
C matrix also affected the composite properties. (C) 2001 Elsevier Science
Ltd. All rights reserved.