Bd. Beynnon et al., ANTERIOR CRUCIATE LIGAMENT STRAIN BEHAVIOR DURING REHABILITATION EXERCISES IN-VIVO, American journal of sports medicine, 23(1), 1995, pp. 24-34
Before studying the biomechanical effects of rehabilitation exercises
on the reconstructed knee, it is important to understand their effects
on the normal anterior cruciate ligament. The objective of this inves
tigation was to measure the strain behavior of this ligament during re
habilitation activities in vivo. Participants were patient volunteers
with normal anterior cruciate ligaments instrumented with the Hall eff
ect transducer. At 10 degrees and 20 degrees of flexion, ligament stra
in values for active extension of the knee with a weight of 45 N appli
ed to a subject's lower leg were significantly greater than active mot
ion without the weight. Isometric quadriceps muscle contraction at 15
degrees and 30 degrees also produced a significant increase in ligamen
t strain, while at 60 degrees and 90 degrees of knee flexion there was
no change in ligament strain relative to relaxed muscle condition. Si
multaneous quadriceps and hamstrings muscles contraction at 15 degrees
produced a significant increase in ligament strain compared with the
relaxed state but did not strain the ligament at 30 degrees, 60 degree
s, and 90 degrees of flexion. Isometric contraction of hamstrings musc
les did not produce change in ligament strain at any flexion angle. Ex
ercises that produce low or unstrained ligament values, and would not
endanger a properly implanted graft, are either dominated by the hamst
rings muscle (isometric hamstring), involve quadriceps muscle activity
with the knee flexed at 60 degrees or greater (isometric quadriceps,
simultaneous quadriceps and hamstrings contraction), or involve active
knee motion between 35 degrees and 90 degrees of flexion.