Analysis of force parameters used to assess the fatigability of mammalian motor units.

Gordon, Debra Anne.

January 1988

The investigation of motor-unit fatigability in reduced-animal models has been dominated by a single fatigue test, one fatigue index, and an emphasis on changes in the magnitude of (usually peak) force. Although the standard fatigue test has been reported to elicit changes in the dynamic phases of an isometric tetanus, this has not been systematically studied in single motor units. Furthermore, changes in the profile of individual tetani during the fatigue test have led some investigators to suggest that other force parameters (i.e., integrated force) or fatigue indices may provide additional information about motor-unit performance during the test. The purposes of this project were to: (1) evaluate the time courses of a variety of force parameters characterizing both the magnitude of force and the dynamic aspects of force during a 4-min fatigue test of functionally isolated cat, tibialis posterior motor units; and (2) determine if motor units could be classified into the conventional motor-unit types based on these new parameters. There was considerable variability in the average time course of the magnitude of force during the fatigue test. The variability within the type FR and F(int) motor-unit groups resulted in several units whose characteristics bordered those which, by definition, separate unit types. The classification of these units depended on the force parameter and fatigue index used to quantify their fatigability. The time course of the magnitude of force also revealed differences in the behavior of potentiating and non-potentiating groups. There were many differences between motor-unit types in terms of dynamic-force parameters before, during and after the fatigue test. Comparison of initial and 2-min values revealed a preferential effect of stimulation on force development in type S and FR units (i.e., increased rate) and on force decay in type F(int) and FF units (i.e., prolonged duration and decreased rate). The time courses of these effects further revealed qualitative differences between different combinations of motor-unit types. Groups of units (or lack thereof) revealed by dynamic-force parameters were compared to conventional motor-unit types by discriminant analysis. The results were not always consistent with conventional types.

Fatigue.

Muscles.

Muscle strength.

Resistance to shell breaking in two intertidal snails

Ash, V. B.

January 1987

No description available.

551.46

Marine shell strength

Bargaining over surplus : Oligopolies, workers and the £Tdistribution of income£T

Dowrick, S.

January 1986

No description available.

331

Labour strength on incomes

Diametral-compression of silicon nitride

Ovri, J. E. O.

January 1986

No description available.

666

Silicon nitride strength

The influence of faults on the engineering behavior of rock masses

Kaaki, Ahmad Abdullah

January 1990

No description available.

551

Friction; Shear strength

Early age strength and creep of slag cement concretes

Al-Kaisi, Ali Farhan

January 1989

No description available.

620.118

Concrete strength development

The fracture behaviour of oriented polyethylene

Hallam, M. A.

January 1987

No description available.

668.4

Polyethylene tensile strength

Failure mechanisms under complex loading of glass-reinforced polyester composites and their matrices : The effect of superposed hydrostatic pressures up to 300 MPa on axial tensile and compressive strengths, and in-plane shear properties of unidirectional

Sigley, R. H.

January 1988

No description available.

668.4

Reinforced polyester strength

Characterisation and design of fire-resistant steels for construction

Kelly, Fergal S.

January 1998

No description available.

669

Strength; Microstructure; Composition

Characterisation & compaction of polyethylene glycols

Larhrib, El Hassane

January 1997

No description available.

615.1

Tablet strength; Compression