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Abstract

Using a Cybex II, eight healthy male subjects performed isokinetic knee extensions at two different speeds (30 and 180 deg/sec) and two different positions of the resistance pad (proximal and distal). A sagittal plane, biomechanical model was used for calculating the mag nitude of the tibiofemoral joint compressive and shear forces. The magnitude of isokinetic knee extending moments was found to be significantly lower with the resistance pad placed proximally on the leg instead of distally. The tibiofemoral compressive force was of the same magnitude as the patellar tendon force, with a maximum of 6300 N or close to 9 times body weight (BW). The tibiofemoral shear force changed direction from being negative (tibia tends to move posteriorly in relation to femur) to a positive magnitude of about 700 N or close to 1 BW, indicating that high forces arise in the ACL when the knee is extended more than 60°. The anteriorly directed shear force was lowered consid erably by locating the resistance pad to a proximal position on the leg. This model may be used when it is desirable to control stress on the ACL, e.g., in the rehabilitative period after ACL repairs or reconstruc tions.

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References

Arms SW Pope MH, Johnson RJ, et al The biomechanics of anterior cruciate ligament rehabilitation and reconstruction Am J Sports Med 12 8-18, 1984

Arvidsson I. , Enksson E., Haggmark T., et al. Isokinetic thigh muscle strength after ligament reconstruction in the knee joint Results from a 5-10 year follow up after reconstruction of the anterior cruciate ligament in the knee joint Int J Sports Med 2 7-11. 1981

Butler DL, Noyes FR, Grood ES Ligamentous restraints to anterior-posterior :drawer in the human knee A biomechanical study J Bone Joint Surg 62A 259-270, 1980

Enksson E. Reconstruction of the anterior cruciate ligament. Orthop Clin North Am 7 167-179, 1976

Fugl-Meyer AR , Gustafsson L., Burstedt Y. Isokinetic and static plantar flexion characteristics Eur J Appl Phys 45 221-234, 1980

Fuglevand AJ Resultant muscle torque angular velocity and joint position relationships and activation patterns in maximal knee extension. 10th International Congress of Biomechanics, Umeå, Proceedings 79 1985

Gransberg L. Knutsson E. Determination of dynamic muscle strength in man with acceleration controlled isokineic movements Acta Phys Scand 119 317-320, 1983

Grimby G., Gustafsson E., Peterson L., et al: Quadriceps function and training after knee ligament surgery Med Sci Sports Exerc 12. 70-75, 1980

Grood ES, Suntay WJ, Noyes FR, et al: Biomechanics of the knee-extension exercise J Bone Joint Surg 66A: 725-734, 1984

10.

Haffajee D., Moritz U., Svantesson G. isometric knee extension strength as a function of joint angle, muscle length and motor unit activity Acta Orthop Scand 43 138-147, 1972

11.

Hamberg P., Gillquist J. Knee function after arthroscopic meniscectomy A prospective study Acta Orthop Scand 55. 172-175, 1984

12.

Ingemann-Hansen T., Halkjaer-Kristensen J. Force-velocity relationships in the human quadnceps muscles. Scand J Rehab Med 11 85-89 1979

13.

Johnson D. Controlling anterior shear dunng isokinetic knee extension. J Orthop Sports Phys Ther 4. 23-31, 1982

14.

Junst KA, Otis JC Anteroposterior tibiofemoral displacements during isometric extension efforts The roles of external load and knee flexion angle Am J Sports Med 13. 254-258, 1985

15.

Markhede G. , Nistor L. Strength of plantar flexion and function after resection of various parts of the tnceps surae muscle Acta Orthop Scand 50 693-697, 1979

16.

Murray SM, Warren RF, Otis JC et al. Torque-velocity relationships of the knee extensor and flexor muscles in individuals sustaining injuries of the anterior cruciate ligament Am J Sports Med 12 436-440, 1984

17.

Nisell R., Németh G., Ohlsen H. Joint forces in extension of the knee. Analysis of a mechanical model . Acta Orthop Scand 57. 41-46, 1986

18.

Nordgren B. , Nordesjo L-O., Rauschning W. isokinetic knee extension strength and pain before and after advancement osteotomy of the tibial tuberosity Acta Orthop Trauma Surg 102 95-101 1983

19.

Noyes FR, Keller CS, Grood ES, et al. Advances in the understanding of knee ligament injury, repair, and rehabilitation. Med Sci Sports Exerc 16 427-443, 1984

20.

Oberg B., Moller M., Ekstrand J. et al Exercise for knee flexors and extensors in uninjured soccer players The effects of two different programmes Int J Sports Med 6: 151-154, 1985

21.

Odensten M. , Gillquist J. Functional anatomy of the anterior cruciate ligament and a rationale for reconstruction J Bone Joint Surg 67A 257-262, 1985

22.

Osternig LR , Bates BT, James SL Isokinetic and isometric torque force relationships Arch Phys Med Rehab 58: 254-257, 1977

23.

Osternig LR , Hamill J., Corcos DM et al Electromyographic patterns accompanying isokinetic exercise under varying speed and sequencing conditions. Am J Phys Med 63 289-297, 1984

24.

Paulos L., Noyes FR, Grood E., et al. Knee rehabilitation after anterior cruciate ligament reconstruction and repair Am J Sports Med 9 140-149, 1981

25.

Perrine JJ, Edgerton VR Muscle force-velocity and power-velocity relationships under isokinetic loading . Med Sci Sports Exerc 10 159-166, 1978

26.

Smidt GL Biomechanical analysis of knee flexion and extension J Biomech 6 :79-92,1973

27.

Thorstensson A., Gnmby G., Karlsson J. Force-velocity relations and fiber composition in human knee extensor muscles J Appl Physiol 40 12-16, 1976

28.

Wakim KG, Gersten JW, Elkins EC, et al. Objective recording of muscle strength Arch Phys Med 31 90-100, 1950

29.

Winter DA, Wells RP, Orr GW Errors in the use of isokinetic dynamometers. Eur J Appl Physiol 46 397-408, 1981

Tibiofemoral joint forces during isokinetic knee extension

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