The influence of impact interface on human knee injury:
Implications for instrument panel design and
the lower extremity injury criterion.
Proceedings of the 41st
STAPP Car Crash Conference. 1997.
Atkinson, P, Garcia, J,
Haut, R, Altiero, N.
ABSTRACT:
Injury to the lower
extremity during an automotive crash is a significant problem. While the introduction of safety features
(i.e. seat belts, air bags) has significantly reduced fatalities, lower
extremity injury now occurs more frequently, probably for a variety of
reasons. Lower extremity trauma is
currently based on a bone fracture criterion derived from human cadaver impact
experiments. These impact experiments,
conducted in the 1960’s and 70’s, typically used a rigid impact interface to
deliver a blunt insult to the 90° flexed knee.
The resulting criterion states that 10 kN is the maximum load allowed at
the knee during an automotive crash when certifying new automobiles using
anthropomorphic dummies. However,
clinical studies suggest that subfracture loading can cause osteochondral
microdamage which can progress to a chronic and debilitating joint
disease. Additional studies suggest
that the stiffness of the impact interface influences knee injury modalities
resulting from impact loading. In the current
study, a single impact at 27 J of energy with a rigid interface was delivered
to one knee of isolated joint preparations of six cadavers resulting in an
average peak load of 5 kN.
Contralateral knees were impacted with a padded interface at an additional
level of energy at approximately the same load. All rigid impact experiments resulted in some form of injury to
the patella including occult microcracking and gross fracture of the patella. No injuries were detected in the knees from
the padded experiments. Math modeling
of the patellae showed significantly reduced tensile and shear stresses in the
bone with padding. This study suggests
that the current lower extremity injury criterion, based solely on load, may
not be sufficiently conservative. Increasing contact area over the knee reduces stresses in the bone
and prevents both gross bone fracture and bone and cartilage microdamage. Such data may be useful in future instrument
panel designs and might suggest revision to the current lower extremity injury
criterion.
Orthopaedic
Biomechanics Laboratories,
College of Osteopathic Medicine,
Michigan State University,
East Lansing, Michigan 48824
Please
address correspondence to:
Roger C.
Haut, Ph.D.,
Orthopaedic Biomechanics Laboratory,
College of Osteopathic Medicine,
A414 East Fee Hall,
Michigan State University,
East Lansing, MI 48824,
Tel: (517)355-0320,
Fax:
(517)353-0789,
E-mail:
haut@msu.edu