Valgus bending and shearing of the knee have been identified as primary mechanisms of injuries in a lateral loading environment applicable to pedestrian-car collisions. Previous studies have reported on the structural response of the knee joint to pure valgus bending and lateral shearing, as well as the estimated injury thresholds for the knee bending angle and shear displacement based on experimental tests. However, epidemiological studies indicate that most knee injuries are due to the combined effects of bending and shear loading. Therefore, characterization of knee stiffness for combined loading and the associated injury tolerances is necessary for developing vehicle countermeasures to mitigate pedestrian injuries. Isolated knee joint specimens (n=40) from postmortem human subjects were tested in valgus bending at a loading rate representative of a pedestrian-car impact. The effect of lateral shear force combined with the bending moment on the stiffness response and the injury tolerances of the knee was concurrently evaluated. In addition to the knee moment-angle response, the bending angle and shear displacement corresponding to the first instance of primary ligament failure were determined in each test. The failure displacements were subsequently used to estimate an injury threshold function based on a simplified analytical model of the knee. The validity of the determined injury threshold function was subsequently verified using a finite element model. Post-test necropsy of the knees indicated medial collateral ligament injury consistent with the clinical injuries observed in pedestrian victims. The moment-angle response in valgus bending was determined at quasistatic and dynamic loading rates and compared to previously published test data. The peak bending moment values scaled to an average adult male showed no significant change with variation in the superimposed shear load. An injury threshold function for the knee in terms of bending angle and shear displacement was determined by performing regression analysis on the experimental data. The threshold values of the bending angle (16.2deg) and shear displacement (25.2mm) estimated from the injury threshold function were in agreement with previously published knee injury threshold data. The continuous knee injury function expressed in terms of bending angle and shear displacement enabled injury prediction for combined loading conditions such as those observed in pedestrian-car collisions.

1.
Edwards
,
K. J.
, and
Green
,
J. F.
, 1999, “
Analysis of the Inter-Relationship of Pedestrian Leg and Pelvis Injuries
,”
Proceedings of the 1999 International Conference on the Biomechanics of Impacts
,
Bron, France
, pp.
355
369
.
2.
Chidester
,
A. B.
, and
Isenberg
,
R. A.
, 2001, “
The Final Report—The Pedestrian Crash Data Study
,” National Highway Traffic Safety Administration Paper No. 248.
3.
Mizuno
,
Y.
, 2003, “
Summary of IHRA Pedestrian Safety Work Group Activities—Proposed Test Methods to Evaluate Pedestrian Protection Afforded by Passenger Cars
,”
Proceedings of the 18th International Technical Conference on the Enhanced Safety of Vehicles
,
Nagoya, Japan
, Paper No. 580.
4.
Ashton
,
S. J.
, 1981, “
Factors Associated With Pelvic and Knee Injuries in Pedestrians Struck by the Fronts of Cars
,”
Proceedings of the SAE World congress
,
Warrendale, PA
, Paper No. 811026.
5.
Teresinski
,
G.
, and
Madro
,
R.
, 2001, “
Knee Joint Injuries as a Reconstructive Factor in Car-to-Pedestrian Accidents
,”
Forensic Sci. Int.
0379-0738,
124
, pp.
74
82
.
6.
Konosu
,
A.
,
Ishikawa
,
H.
, and
Tanahashi
,
M.
, 2001, “
Reconsideration of Injury Criteria for Pedestrian Subsystem Legform Test—Problems of Rigid Legform Impactor
,”
Proceedings of the 17th International Technical Conference on the Enhanced Safety of Vehicles
,
Amsterdam, Netherlands
, Paper No. 01-S8-O-263.
7.
Takahashi
,
Y.
, and
Kikuchi
,
Y.
, 2001, “
Biofidelity of Test Devices and Validity of Injury Criteria for Evaluating Knee Injuries to Pedestrians
,”
Proceedings of the 17th International Technical Conference on the Enhanced Safety of Vehicles
,
Amsterdam, Netherlands
, Paper No. 373.
8.
Kajzer
,
J.
,
Cavallero
,
C.
,
Ghanouchi
,
S.
,
Bonnoit
,
J.
, and
Ghorbel
,
A.
, 1990, “
Response of the Knee Joint in Lateral Impact—Effect of Shearing Loads
,”
Proceedings of the 1990 International Conference on the Biomechanics of Impacts
,
Bron, France
, pp.
293
304
.
9.
Kajzer
,
J.
,
Cavallero
,
C.
,
Bonnoit
,
J.
,
Morjane
,
A.
, and
Ghanouchi
,
S.
, 1993, “
Response of the Knee Joint in Lateral Impact—Effect of Bending Moment
,”
Proceedings of the 1993 International Conference on the Biomechanics of Impacts
,
Bron, France
, pp.
105
116
.
10.
Kajzer
,
J.
,
Schroeder
,
G.
,
Ishikawa
,
H.
,
Matsui
,
Y.
, and
Bosch
,
U.
, 1997, “
Shearing and Bending Effects at the Knee Joint at High Speed Lateral Loading
,”
Proceedings of the SAE World Congress
,
Warrendale, PA
, Paper No. 973326.
11.
Kajzer
,
J.
,
Ishikawa
,
H.
,
Matsui
,
Y.
,
Schroeder
,
G.
, and
Bosch
,
U.
, 1999, “
Shearing and Bending Effects at the Knee Joint at Low Speed Lateral Loading
,”
Proceedings of the SAE World Congress
,
Warrendale, PA
, Paper No. 1999-01-0712.
12.
Ramet
,
M.
,
Bouquet
,
R.
,
Bermond
,
F.
,
Caire
,
Y.
, and
Bouallegue
,
M.
, 1995, “
Shearing and Bending Human Knee Joint Tests in Quasi-Static Lateral Load
,”
Proceedings of the 1995 International Conference on the Biomechanics of Impacts
,
Bron, France
, pp.
93
105
.
13.
Bose
,
D.
,
Bhalla
,
K.
,
van Rooij
,
L.
,
Millington
,
S.
,
Studley
,
A.
, and
Crandall
,
J.
, 2004, “
Response of the Knee Joint to the Pedestrian Impact Loading Environment
,”
Proceedings of the SAE World Congress
,
Warrendale, PA
, Paper No. 2004-01-1608.
14.
Kerrigan
,
J. R.
,
Bhalla
,
K. S.
,
Madeley
,
N. J.
,
Funk
,
J. R.
,
Bose
,
D.
, and
Crandall
,
J. R.
, 2003, “
Experiments for Establishing Pedestrian-Impact Lower Limb Injury Criteria
,”
Proceedings of the SAE World Congress
,
Warrendale, PA
, Paper No. 2003-01-0895.
15.
Arnoux
,
P.-J.
,
Cesari
,
D.
,
Behr
,
M.
,
Thollon
,
L.
, and
Brunet
,
C.
, 2005, “Pedestrian Lower Limb Injury Criteria Evaluation a Finite Element Approach,” Traffic Injury Prevention, 6(3), pp. 288–297.
16.
Langhaar
,
H. L.
, 1951,
Dimensional Analysis and Theory of Models
,
Wiley
,
New York
.
17.
Rooney
,
N.
,
FitzPatrick
,
D. P.
, and
Beverland
,
D.
, 2003, “
Intaroperative Knee Anthropometrics: Correlation With Cartilage Wear
,”
Proceedings of the International Society of Biomechanics Congress
,
Dunedin, New Zealand
.
18.
Azangwe
,
G.
,
Fraser
,
K.
,
Mathias
,
K. J.
,
Siddiqui
,
A. M.
, 2000, “
In Vitro Monitoring of Rabbit Anterior Cruciate Ligament Damage by Acoustic Emission
,”
Med. Eng. Phys.
1350-4533,
22
, pp.
279
283
.
19.
Untaroiu
,
C.
,
Darvish
,
K.
,
Crandall
,
J.
,
Deng
,
B.
, and
Wang
,
J.-T.
, 2005, “
A Finite Element Model of the Lower Limb for Simulating Pedestrian Impacts
,”
STAPP Car Crash Journal
,
49
, pp.
157
181
.
20.
Dommelen
,
J. A. W.
,
Ivarsson
,
B. J.
,
Minary Jolandan
,
M.
,
Millington
,
S. A.
,
Raut
,
M.
,
Kerrigan
,
J. R.
,
Crandall
,
J. R.
, and
Diduch
,
D. R.
, 2005, “
Characterization of the Rate-Dependent Mechanical Properties and Failure of Human Knee Ligaments
,”
Proceedings of the SAE 2005 World Congress
,
Warrendale, PA
, Paper No. 2005-01-0293.
21.
Arnoux
,
P. J.
, 2000, “
Modélisation des ligaments des membres porteurs
,” Ph.D. thesis, Université de la Méditerranée, Marseille, France.
You do not currently have access to this content.