Daniel M. Burchfield scite author profile

Injuries to the anterior cruciate ligament frequently occur under combined mechanisms of knee loading. This in vitro study was designed to measure levels of ligament force under dual combinations of individual loading states and to determine which combinations generated high force. Resultant force was recorded as the knee was extended passively from 90 degrees of flexion to 5 degrees of hyperextension under constant tibial loadings. The individual loading states were 100 N of anterior tibial force, 10 Nm of varus and valgus moment, and 10 Nm of internal and external tibial torque. Straight anterior tibial force was the most direct loading mechanisms; the mean ligament force was approximately equal to applied anterior tibial force near 30 degrees of flexion and to 150% of applied tibial force at full extension. The addition of internal tibial torque to a knee loaded by anterior tibial force produced dramatic increases of force at full extension and hyperextension. This loading combination produced the highest ligament forces recorded in the study and is the most dangerous in terms of potential injury to the ligament. In direct contrast, the addition of external tibial torque to a knee loaded by anterior tibial force decreased the force dramatically for flexed positions of the knee; at close to 90 degrees of flexion, the anterior cruciate ligament became completely unloaded. The addition of varus moment to a knee loaded by anterior tibial force increased the force in extension and hyperextension, whereas the addition of valgus moment increased the force at flexed positions. These states of combined loading also could present an increased risk for injury. Internal tibial torque is an important loading mechanism of the anterior cruciate ligament for an extended knee. The overall risk of injury to the ligament from varus or valgus moment applied in combination with internal tibial torque is similar to the risk from internal tibial torque alone. External tibial torque was a relatively unimportant mechanism for generating anterior cruciate ligament force.

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Biomechanical Consequences of Replacement of the Anterior Cruciate Ligament with a Patellar Ligament Allograft. Part II

Markolf¹,

Burchfield²,

Shapiro³

et al. 1996

The Journal of Bone & Joint Surgery

130

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Estrogen level alters the failure load of the rabbit anterior cruciate ligament

Slauterbeck

Clevenger

Lundberg

et al. 1999

Journal Orthopaedic Research

129

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We hypothesized that increasing the level of circulating serum estrogen would decrease the load at failure for the rabbit anterior cruciate ligament. We developed an animal model in which hormonal manipulations could be correlated with load at failure for the anterior cruciate ligament. Sixteen New Zealand White ovariectomized rabbits were matched and divided into two groups. The eight rabbits that were not treated with the estrogen supplement (Group O) and the eight that were treated with the supplement (Group E) were housed for 30 days. Serum estrogen levels were measured. The knees were stripped of all soft tissue, and the load at failure for the anterior cruciate ligament was measured in a materials testing machine with a displacement rate of 0.5 mm/sec. The load at failure for all 16 specimens in Group E (446 +/- 54 N) (mean +/- SD) was significantly reduced (p = 0.02) compared with that for the nine specimens in Group O (503 +/- 48 N). It is recognized that an increased number of anterior cruciate ligament injuries occurs in female athletes. Although the mechanism responsible for failure of the anterior cruciate ligament in women is yet to be defined, this experiment suggests that estrogen may alter ligament strength.

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