Impact responses of
the flexed human knee
using a deformable
impact interface.
J. Biomechanical Engineering. 123(3):205-211, 2001.
Atkinson, PJ, Haut, RC.
ABSTRACT:
Blunt impact trauma to the
patellofemoral joint during car accidents, sporting activities, and falls can
produce a range of injuries to the knee joint including gross bone fracture,
soft tissue injury, and/or microinjuries to bone and soft tissue. Currently, the only well-established knee
injury criterion applies to knee impacts suffered during car accidents. This criterion is based solely on the peak
impact load delivered to seated cadavers having a single knee flexion
angle. More recent studies, however, suggest
that the injury potential, its location, and the characteristics of the damage
are also a function of knee flexion angle and the stiffness of the impacting
structure. For example, at low flexion
angles fractures of the distal patellar are common with a rigid impact
interface, while at high flexion angles splitting of the femoral condyles is
more evident. Low stiffness impact
surfaces have been previously shown to distribute impact loads over the
anterior surface of the patella to help mitigate gross and microscopic injuries
in the 900 flexed knee. The
objective of the current study was to determine if a deformable impact
interface would just as effectively mitigate gross and microscopic injuries to
the knee at various flexion angles.
Paired experiments were conducted on contralateral knees of 18 human
cadavers at three flexion angles (60°, 90°, 120°). One knee was subjected to a fracture level
impact experiment with a rigid impactor, and the opposite knee was impacted
with a deformable interface (3.3 MPa crush strength honeycomb material) to the
same load. This (deformable) impact
interface was effective at mitigating gross bone fractures at approximately 5
kN at all flexion angles, but the frequency of split fracture of the femoral
condyles may not have been significantly reduced at 1200 flexion.
On the other hand, this deformable interface was not effective in
mitigating microscopic injuries observed for all knee flexion angles These new data, in concert with the existing
literature, suggest the chosen impact interface was not optimal for knee injury
protection in that fracture and other minor injuries were still produced. For example, in 18 cadavers a total of 20
gross fractures and 20 subfracture injuries were produced with a rigid
interface and 5 gross fractures and 21 subfracture injuries with the deformable
interface selected for the current study.
Additional studies will be needed to optimize the knee impact
interface for protection against gross
and microscopic injuries to the knee.
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