Purpose of the study There are many anatomic descriptions of the spine, but
most concentrate on qualitative information. Quantitative data is however
important to achieve a better clinical approach, to adapt implant size and
to construct geometric models of spine mechanics.
Material and methods We examined 32 dry spines (160 lumbar vertebrae) obtai
ned from the Orfila Museum anatomy laboratory at the Saints-Peres School of
Medicine in Paris. We drew 178 landmarks on the surface of each vertebra a
nd recorded the 3D spatial coordinates of each point using a Fastrack elect
romagnetic system operating with +/- 0.2 mm precision. The coordinates of t
he digitalized points were expressed in a local x-y-z axis field (x = poste
roanterior axis, y = right-left axis, z = caudocranial axis). The origin 0
was half way between the "centers" of the vertebral plates. After calculati
ng 112 linear, angular and surface parameters, results were analyzed with t
he Statview statistics system.
Results All parameters exhibited gaussian distribution. The transpedicular
vertebral depth, corresponding to the maximal penetration of a pedicular sc
rew before touching the anterior wall, was nearly constant: 48 mm (mean). T
he mean height of the pedicle was approximately 16 mm for L1 to L4 and 21 m
m for L5. Pedicle width was 7 mm for L1 and L2 then rapidly widened to reac
h 10 mm for L5. It was noteworthy that the narrowest pedicle (4 mm) was fou
nd in 10% of the L1 vertebrae. There was an exponential rise in the sagitta
l tilt of the pedicles from L1 to L5, measuring approximately 8 degrees for
L1 and rising to 24 degrees for L5.
Discussion Our sample of human spines with unknown clinical characteristics
(age, sex) is representative of anatomy laboratory populations, generally
composed of subjects over 40 years of age, and is thus adapted for studies
of the degenerative spine. Our findings are generally in agreement with dat
a reported in the literature and also provided complementary quantitative d
ata concerning the transpedicular vertebral depth that was found to be a ra
ther constant feature of the lumbar spine. It measured between 40 and 56 mm
for 95% of the study population. The dimensions of the pedicle is particul
arly important: the width must be known to determine the size of pedicle sc
rews; it measured between 7 and 12 mm in 95% of the population. The largest
mean cross section of the pedicle was found for L5 (82mm(2)), but measured
less than 60 mm(2) in 10% of the vertebrae, suggesting predisposition to s
pondylolysis.