T. Fujii et al., Microstructural properties of the distal growth plate of the rabbit radiusand ulna: Biomechanical, biochemical, and morphological studies, J ORTHOP R, 18(1), 2000, pp. 87-93
The purposes of this study were to define the tensile properties of each zo
ne of the rabbit growth plate and to correlate them with the microarchitect
ure and biochemical composition of the zones. The epiphysis-growth plate-me
taphysis complex was obtained from the radius and ulna of 20 8-week-old rab
bits. Four dye markers were placed on the growth plate. The complex was loa
ded to failure with a tensile testing machine, and the strain behavior was
recorded simultaneously with a microscope, a charge-coupled device camera,
and a video dimension-analyzer system. The collagenous fiber architecture o
f each zone was examined with a microscope, and the collagen content of eac
h zone was also determined. The tangent modulus of the resting zone was 75%
stiffer than that of the other two zones. The highest values for strain at
failure and energy absorbed to failure were observed in the hypertrophic z
one, and the total collagen content was highest in the proliferating zone.
The collagen fibers were more randomly aligned in the resting zone than in
the other two zones. The diversity observed in the microarchitecture of the
rabbit growth plate correlates with the zone-dependent differences in its
mechanical properties.