Muscle dynamics in fish during steady swimming

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Muscle dynamics in fish during steady swimming. / Shadwick, RE; Steffensen, JF; Katz, SL; Knower, T.

In: Integrative and Comparative Biology, Vol. 38, No. 4, 1998, p. 755-770.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Shadwick, RE, Steffensen, JF, Katz, SL & Knower, T 1998, 'Muscle dynamics in fish during steady swimming', Integrative and Comparative Biology, vol. 38, no. 4, pp. 755-770. https://doi.org/10.1093/icb/38.4.755

APA

Shadwick, RE., Steffensen, JF., Katz, SL., & Knower, T. (1998). Muscle dynamics in fish during steady swimming. Integrative and Comparative Biology, 38(4), 755-770. https://doi.org/10.1093/icb/38.4.755

Vancouver

Shadwick RE, Steffensen JF, Katz SL, Knower T. Muscle dynamics in fish during steady swimming. Integrative and Comparative Biology. 1998;38(4):755-770. https://doi.org/10.1093/icb/38.4.755

Author

Shadwick, RE ; Steffensen, JF ; Katz, SL ; Knower, T. / Muscle dynamics in fish during steady swimming. In: Integrative and Comparative Biology. 1998 ; Vol. 38, No. 4. pp. 755-770.

Bibtex

@article{c43242f0be9f11df825b000ea68e967b,
title = "Muscle dynamics in fish during steady swimming",
abstract = "SYNOPSIS. Recent research in fish locomotion has been dominated by an interest in the dynamic mechanical properties of the swimming musculature. Prior observations have indicated that waves of muscle activation travel along the body of an undulating fish faster than the resulting waves of muscular contraction, suggesting that the phase relation between the muscle strain cycle and its activation must vary along the body. Since this phase relation is critical in determining how the muscle performs in cyclic contractions, the possibility has emerged that dynamic muscle function may change with axial position in swimming fish. Quantification of muscle contractile properties in cyclic contractions relies on in vitro experiments using strain and activation data collected in vivo. In this paper we discuss the relation between these parameters and body kinematics. Using videoradiographic data from swimming mackerel we demonstrate that red muscle strain can be accurately predicted from midline curvature but not from lateral displacement. Electromyographic recordings show neuronal activation patterns that are consistent with red muscle performing net positive work at all axial positions. The relatively constant cross-section of red muscle along much of the body suggests that positive power for swimming is generated fairly uniformly along the length of the fish.",
author = "RE Shadwick and JF Steffensen and SL Katz and T Knower",
year = "1998",
doi = "10.1093/icb/38.4.755",
language = "English",
volume = "38",
pages = "755--770",
journal = "Integrative and Comparative Biology",
issn = "1540-7063",
publisher = "Oxford University Press",
number = "4",

}

RIS

TY - JOUR

T1 - Muscle dynamics in fish during steady swimming

AU - Shadwick, RE

AU - Steffensen, JF

AU - Katz, SL

AU - Knower, T

PY - 1998

Y1 - 1998

N2 - SYNOPSIS. Recent research in fish locomotion has been dominated by an interest in the dynamic mechanical properties of the swimming musculature. Prior observations have indicated that waves of muscle activation travel along the body of an undulating fish faster than the resulting waves of muscular contraction, suggesting that the phase relation between the muscle strain cycle and its activation must vary along the body. Since this phase relation is critical in determining how the muscle performs in cyclic contractions, the possibility has emerged that dynamic muscle function may change with axial position in swimming fish. Quantification of muscle contractile properties in cyclic contractions relies on in vitro experiments using strain and activation data collected in vivo. In this paper we discuss the relation between these parameters and body kinematics. Using videoradiographic data from swimming mackerel we demonstrate that red muscle strain can be accurately predicted from midline curvature but not from lateral displacement. Electromyographic recordings show neuronal activation patterns that are consistent with red muscle performing net positive work at all axial positions. The relatively constant cross-section of red muscle along much of the body suggests that positive power for swimming is generated fairly uniformly along the length of the fish.

AB - SYNOPSIS. Recent research in fish locomotion has been dominated by an interest in the dynamic mechanical properties of the swimming musculature. Prior observations have indicated that waves of muscle activation travel along the body of an undulating fish faster than the resulting waves of muscular contraction, suggesting that the phase relation between the muscle strain cycle and its activation must vary along the body. Since this phase relation is critical in determining how the muscle performs in cyclic contractions, the possibility has emerged that dynamic muscle function may change with axial position in swimming fish. Quantification of muscle contractile properties in cyclic contractions relies on in vitro experiments using strain and activation data collected in vivo. In this paper we discuss the relation between these parameters and body kinematics. Using videoradiographic data from swimming mackerel we demonstrate that red muscle strain can be accurately predicted from midline curvature but not from lateral displacement. Electromyographic recordings show neuronal activation patterns that are consistent with red muscle performing net positive work at all axial positions. The relatively constant cross-section of red muscle along much of the body suggests that positive power for swimming is generated fairly uniformly along the length of the fish.

U2 - 10.1093/icb/38.4.755

DO - 10.1093/icb/38.4.755

M3 - Journal article

VL - 38

SP - 755

EP - 770

JO - Integrative and Comparative Biology

JF - Integrative and Comparative Biology

SN - 1540-7063

IS - 4

ER -

ID: 21951339