Cracks in bone cement have been observed in carefully examined post-mortem
preparations of cemented stems. These cracks were probably caused by fatigu
e, and frequently appeared to initiate at pores. Ubiquitous porosity, occur
ring preferentially at, or near, the stem, is most likely caused by polymer
ization shrinkage. Preparation of air-free cement has only a marginal influ
ence on the interface porosity, but pre-heating the stem in order to revers
e the direction of polymerization can reduce or eliminate it. To estimate t
he impact of interface porosity on the fatigue strength of bone cement, tes
t plates for this study were cast in a steel mold without release foils, an
d with one side of the mold warmer. Sample plates so prepared from chilled,
partial vacuum-mixed PALACOS(R) R, have one face essentially pore-free and
the other porous, the extent and morphology of the porosity being very sim
ilar to that observed on the stem-cement interface. Four-point bending fati
gue strength, determined after 60 d conditioning in Ringer's solution at 37
degrees C, was only 20 MPa (at 10(6) cycles, with the porous side under te
nsion) compared to 30 MPa for conventionally prepared, pore-free material.
This corresponds to a 10-100 fold reduction in cycles to failure in the ran
ge of stresses predicted to occur in vivo. (C) 1998 Kluwer Academic Publish
ers.