Genetic variation in bone-regenerative capacity has not been studied in any
animal model system. We developed a "drillhole" model in the tail vertebra
of inbred strains of mice that allows us to reproducibly introduce an inju
ry with a defined boundary and quantify the rate of bone healing using the
combination of high-resolution Faxitron X-ray imaging and the Chemilmager 4
000 Low Light Imaging System. Using this model, we demonstrate that bone-re
generative capacity is a genetically controlled trait with an estimated her
itability of 72%, and that it differs significantly among inbred strains of
mice. Of the 12 inbred strains tested, Sencar/PtJ was identified as the mo
st suitable model for the study of hard-tissue regeneration. This strain re
gained 73% of bone loss 30 days after injury, in contrast to the slow heale
r, CBA/J, which recovered only 25% of the bone loss during the same period.
Bone-regenerative capacity was not correlated with soft-tissue-regenerativ
e capacity, suggesting that different sets of genes may regulate soft- and
hard-tissue regeneration. It was, however, significantly correlated with to
tal bone mineral density (R = 0.49, p < 0.01), indicating that high bone de
nsity is associated not only with prevention of bone fracture, but also wit
h promotion of bone regeneration. (C) 2001 by Elsevier Science Inc. All rig
hts reserved.