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Predictive torque equations for joints of the extremities

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The purpose of this study was to develop regression equations predicting torque output throughout the range of motion for the human elbow, shoulder, knee, and hip. Twenty-two healthy males participated. Torque values throughout the sagittal plane range of motion (i.e., flexion and extension) of the right elbow, shoulder, knee and hip were recorded (isokinetic dynamometer, 1 rad/sec) and expressed as a percentage of the peak torque produced for each motion. For each joint tested, regression equations based on ensemble-averaged, normalized torque data were calculated to predict the relative torque throughout the investigated range of motion when torque in one angular position was known. Shoulder flexion was best described by a second-order polynomial, while shoulder extension, elbow and knee flexion and extension, and hip flexion were described best by third-order polynomials. Hip extension was best described by a fourth-order polynomial. The regression multiple R2 values ranged between 0.998 and 1.000. These regression equations can be used to predict the expected torque anywhere in the sagittal plane range of motion based on knowledge of a torque recorded at another joint angle for the elbow, shoulder, knee, or hip joint. These equations can be used in the clinical setting when a direct examination of strength capability is not possible due to limitations in equipment or due to the presence of pain within the arc of motion.
Słowa kluczowe
Rocznik
Strony
49--60
Opis fizyczny
Bibliogr. 19 poz., tab., wykr.
Twórcy
autor
  • Academy of Physical Education, Biomechanics Laboratory, Paderewskiego 35, 51-612 Wrocław
autor
  • Academy of Physical Education, Biomechanics Laboratory, Paderewskiego 35, 51-612 Wrocław
Bibliografia
  • [1] BOBER T., HAY J.G., Topografia siły głównych mięśni kończyn człowieka, Wychowanie Fizyczne i Sport, 1990, 3, 3–22.
  • [2] BUCHNER D.M., L ARSON E.B., WAGNER E.H., KOEPSELL T.D., De L ATEUR B.J., Evidence for a non-linear relatonship between leg strength and gait speed, Age Ageing, 1996, 25(5), 386–391.
  • [3] CHARTERIS J., GOSLIN B.R., In vivo approximations of the classic in vitro length–tension relationship: An isokinetic evaluation, Journal of Orthopaedic and Sports Physical Therapy, 1986, 7(5), 222–231. Predictive torque equations 61
  • [4] CLARKE H.H., Muscular strength and endurance in man, Englewood Cliffs, NJ, 1966, Prentice Hall, pp. 1–51.
  • [5] DOSS W.S., KARPOVICH P.V., A comparison of concentric, eccentric and isometric strength of elbow flexors, J. Appl. Physiol., 1965, 20(2), 351–353.
  • [6] GALLAGHER M.A., C UOMO F., POLONSKY L., BERLINER K., Z UCKERMAN J.D., Effects of age, testing speed and arm dominance on isokinetic strength of the elbow, J. Shoulder Elbow Sugr., 1997, 6(4), 340–346.
  • [7] GRAVEL D., GAGNON M., PLAMONDON A., DESJARDINS P., Development and application of predictive equations of maximal static moments generated by the trunk musculature, Clin. Biomech., 1997, 12(5), 314–324.
  • [8] GRAVES J.E., POLLOCK M.L., JONES A.E., COLVIN A.B., L EGGETT S.H., Specificity of limited range of motion variable resistance training, Med. Sci. Sports Exerc., 1989, 21(1), 84–89.
  • [9] HEINRICHS K.I., PERRIN D.H., WELTMAN A., GIECK J.H., B ALL D.W., Effect of protocol and assessment device on isokinetic peak torque on the quadriceps muscle group, Isokinetic and Exercise Science, 1995, 5, 7–13.
  • [10] HERZOG W., HASLER E.M., ABRAHAMSE S.K., A comparison of knee extensor strength curves obtained theoretically and experimentally, Medicine and Science in Sports and Exercise, 1991, 23, 108–114.
  • [11] HILL A.V., First and Last Experiments in Muscle Mechanics, London, Cambridge University Press, 1970.
  • [12] HOLMES J.R., ALDERINK G.J., Isokinetic strength characteristics of the quadratics femoris and hamstring muscles in high school students, Phys. Ther., 1984, 64(6), 914–918.
  • [13] KUMAR S., DUFRESNE R.M., VAN SCHOOR T., Human trunk strength profile in flexion and extension, Spine, 1995, 20(2), 160–168.
  • [14] KUMAR S., DUFRESNE R.M., VAN SCHOOR T., Human trunk strength profile in lateral flexion and axial rotation, Spine, 1995, 20(2), 169–177.
  • [15] L IEBER R.L., Skeletal Muscle Structure and Function: Implications for Rehabilitation and Sports Medicine, Baltimore, Williams and Wilkins, 1992.
  • [16] SALEM G.J., WANG M.Y., YOUNG J.T., MARION M., GREENDALE G.A., Knee strength and lower-and higher-intensity functional performance in older adults, Med. Sci. Sports Exerc., 2000, 32(10), 1679–1684.
  • [17] SCHANNE F.J.J., A Three-Dimensional Hand Force Capability Model for a Seated Person, Volumes I and II, 1972.
  • [18] SCUDDER G.N., Torque curves produced at the knee during isometric and isokinetic exercise, Arch. Phys. Med. Rehabil., 1980, 61(2), 68–73.
  • [19] WYATT M.P., E DWARDS A.M., Comparison of quadriceps and hamstring torque values during isokinetic exercise, Journal of Orthopaedic and Sports Physical Therapy, 1981, 3, 48–55.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPB1-0014-0019
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