Force-Velocity Relationships of a Locust Flight Muscle at Different Times During a Twitch Contraction

Malamud, Jean G.; Josephson, Robert K.

doi:10.1242/jeb.159.1.65

Cited by 22 publications

(1 citation statement)

References 32 publications

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“…However, these muscles are all slower than avian superfast syrinx muscles. Although force–velocity properties have previously been measured in invertebrate superfast muscles, such as insect flight ( Fitzhugh and Marden, 1997 ; Josephson, 1984 ; Malamud and Josephson, 1991 ; Marden, 1995 ) and leg muscles ( Ahn and Full, 2002 ; Eldred et al, 2010 ), we currently lack quantification of the force–velocity relationship in any terrestrial vertebrate superfast muscle (but see Rome et al, 1996 ). Thereby we lack insight in a critical feature describing the mechanical performance of superfast muscles.…”

Section: Introductionmentioning

confidence: 99%

Male and female syringeal muscles exhibit superfast shortening velocities in zebra finches

Gladman,

Elemans

2024

Journal of Experimental Biology

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Vocalisations play a key role in the communication behaviour of many vertebrates. Vocal production requires extremely precise motor control, which is executed by superfast vocal muscles that can operate at cycle frequencies over 100 Hz and up to 250 Hz. The mechanical performance of these muscles has been quantified with isometric performance and the workloop technique, but due to methodological limitations we lack a key muscle property characterising muscle performance, the force-velocity (FV) relationship. Here we quantify the FV relationship in zebra finch superfast syringeal muscles using the isovelocity technique and test if the maximal shortening velocity is different between males and females. We show that syringeal muscles exhibit high maximal shortening velocities of 25 L0 s−1 at 30°C. Using Q10-based extrapolation, we estimate they can reach 37-42 L0 s−1 on average at body temperature, exceeding other vocal and non-avian skeletal muscles. The increased speed does not adequately compensate for reduced force, which results in low power output. This further highlights the importance of high frequency operation in these muscles. Furthermore, we show that isometric properties positively correlate with maximal shortening velocities. While male and female muscles differ in isometric force development rates, maximal shortening velocity is not sex dependent. We also show that cyclical methods to measure force-length properties used in laryngeal studies give the same result as conventional stepwise methodologies, suggesting either approach is appropriate. We argue that vocal behaviour may be affected by the high thermal dependence of superfast vocal muscle performance.

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Section: Introductionmentioning

confidence: 99%

Male and female syringeal muscles exhibit superfast shortening velocities in zebra finches

Gladman,

Elemans

2024

Journal of Experimental Biology

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Invertebrate Locomotor Systems

Full

1997

Comprehensive Physiology

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Turning manoeuvres in free‐flying locusts: Two‐channel radio‐telemetric transmission of muscle activity

Kutsch¹,

Berger²,

Kautz³

2003

J. Exp. Zool.

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A device has been constructed allowing the simultaneous transmission of two separate electrical signals in unrestrained small animals. We employed this device to investigate the motor output in free-flying locusts. The activation pattern of several combinations of different muscles was recorded, including bilateral symmetric muscles and pairs of antagonists. Particular attention was paid to the recruitment of a specific set of flight muscles in both winged segments during rolling manoeuvres. The relationship of the muscle activation with wing movement was analysed in combination with a high-speed video-monitoring. The muscles are activated in advance of the relevant stroke directions, in opposition to previous studies of tethered flying locusts. During turning manoeuvres a statistically significant difference in timing of the bilateral symmetric muscles is not apparent; this contrasts with the distinct difference revealed for the bilateral wing movement. It is discussed that rolling might rely on the fine tuned interaction of several major flight muscles or on the precise activation of a specific wing hinge muscle. Correspondence with investigations of bird flight is discussed.

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Force-Velocity Relationships of a Locust Flight Muscle at Different Times During a Twitch Contraction

Cited by 22 publications

References 32 publications

Male and female syringeal muscles exhibit superfast shortening velocities in zebra finches

Male and female syringeal muscles exhibit superfast shortening velocities in zebra finches

Invertebrate Locomotor Systems

Turning manoeuvres in free‐flying locusts: Two‐channel radio‐telemetric transmission of muscle activity

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