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.

Intra litter variation in porcine muscle development

Clelland, Allyson Kara

January 2001

No description available.

590

Muscle ontogeny

Development and pharmacology of muscle and nerve-muscle cultures from Periplaneta americana embryos

Bermudez-Diaz, M. I. A.

January 1987

No description available.

611

Insect muscle morphology

Suppression of a mutation in the Act88F gene of Drosophila melanogaster

Clayton, Jonathan David

January 1994

No description available.

572.8

Muscle genetics

Modelling the myosin molecular motor

Tyrrell, Graham Philip

January 2001

No description available.

572

Muscle protein

Chemomechanical coupling in skeletal muscle

Spencer, C. I.

January 1988

No description available.

612

Muscle contraction chemistry

Mechanisms underlying the decline in response observed during continuous #beta#←1-adrenoceptor stimulation in cardiac tissue

Argent, Cymone Clunis Helena

January 1998

No description available.

610

Cardiac muscle; Stimulation

Expression and regulation of newt simple epithelial keratins in the regenerating limb blastema

Corcoran, Jonathan Patrick Thomas

January 1996

No description available.

572.8

Muscle formation; Repair

Trasnmural differences in control of contraction in rabbit ventricular muscle

Chamunorwa, Joseph Panashe

January 1996

No description available.

610

Cardiac muscle

Control of the systolic calcium transient by sacrolemmal and intracellular mechanisms in rat ventricular myocytes

Negretti Sanchez, Nilda Rosa

January 1993

No description available.

612

Cardiac muscle