P. Schiereck scite author profile

Ground reaction forces from two force plates are used to determine the cyclic oscillations of the body center of mass while walking at preferred speed. Good approximations to the oscillations may be obtained from formulae containing just the first- and second-order Fourier coefficients of the combined left-right ground reaction forces taken over a complete walking cycle. The symmetric components of the oscillations have consistent mutual phase relations for normal subjects, so that the amplitudes alone can be used as sufficient parameters to characterize the body center of mass oscillations. The analytical technique enables detection of small but consistent gait asymmetries.

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Characterization of gait of young adult females by means of body centre of mass oscillations derived from ground reaction forces

Crowe¹,

Schiereck

Boer

et al. 1993

Gait & Posture

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Effects of wave reflection timing on left ventricular mechanics

Zannoli

Schiereck

Celletti

et al. 1999

Journal of Biomechanics

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Influence of the velocity of changes in end-diastolic volume on the starling mechanism of isolated left ventricles

Kil

Schiereck

1983

Pflugers Arch.

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1. In this study the relationships between active developed systolic pressure, end-diastolic pressure and different diastolic volumes are studied in Tyrode perfused isolated rabbit left ventricles. Contractions were isovolumic. 2. Rapid diastolic volume changes were imposed on top of different preset basic diastolic volumes. These volume changes are shown to produce systolic and diastolic pressure values that cannot be explained by assuming a single pressure-volume relation during systole and diastole. The changes in pressure are in the same direction but higher than is expected on the basis of the increase or decrease of the ventricular end-diastolic volume alone. 3. The variation of the diastolic pressure-volume relation cannot be explained by assuming variations of the heart's passive elasticity or viscous effects within its wall. During diastole the effect is completely reversible without concomitant systolic effects. No velocity dependent effect of the quick volume change could be observed if the time duration was varied between 10 and 65 ms. The results are in keeping with the hypothesis that active force generating mechanisms may be present during the diastolic pause. 4. The effects observed during systole suggest the possibility of length dependent activation of the myocardial cells. This results in different inotropic conditions of the heart at identical volumes, depending on how these volumes were installed. These volumes may be considered to affect intrinsic properties of the muscle cells on a beat to beat basis.

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P. Schiereck

Absence of Photosystem 2 in heterocysts of the blue-green alga Anabaena

Characterization of human gait by means of body center of mass oscillations derived from ground reaction forces

Characterization of gait of young adult females by means of body centre of mass oscillations derived from ground reaction forces

Effects of wave reflection timing on left ventricular mechanics

Influence of the velocity of changes in end-diastolic volume on the starling mechanism of isolated left ventricles

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