Objective: Insertion of a bicortical threaded external fixator pin can caus
e bone damage. An unexpected crack can propagate along the bone when the pi
n touches the far cortex. The objective of this study was to investigate wh
ether drilling and inserting bicortical pins into the shafts of long bones
can cause large distraction forces to be generated between the cortices.
Design: Two flat samples of bone or bone substitute (Tufnol) were mounted p
arallel at each end of a specially designed force measurement column. Three
common pin designs were inserted into the samples: tapered, self-threading
and self-drilling, and self-threading pins. The axial thrust and the corte
x distraction force between the two samples were measured as the pins were
inserted.
Results: High distraction forces were measured between the cortices for all
pin designs, typically 700 to 1,000 Newtons.
Conclusions: The clinical significance of these findings is that the insert
ion of bicortical pins of the designs tested may generate a large distracti
on force between the cortices. This may drive a fracture apart or propagate
an undisplaced fracture. Therefore, care must be taken to ensure that bico
rtical pins are inserted in locations free of local defects.