Myotomal slow muscle function of rainbow trout Oncorhynchus mykiss during steady swimming.

Strain and activity patterns were determined during slow steady swimming (tailbeat frequency 1.5-2.5 Hz) at three locations on the body in the slow myotomal muscle of rainbow trout Oncorhynchus mykiss using sonomicrometry and electromyography. Strain was independent of tailbeat frequency over the range studied and increased significantly from +/-3.3 % l0 at 0.35BL to +/-6 % at 0.65BL, where l0 is muscle resting length and BL is total body length. Muscle activation occurred significantly later in the strain cycle at 0.35BL (phase shift 59 degrees) than at 0.65BL (30 degrees), and the duration of activity was significantly longer (211 degrees at 0.35BL and 181 degrees at 0.65BL). These results differ from those of previous studies. The results have been used to simulate in vivo activity in isolated muscle preparations using the work loop technique. Preparations from all three locations generated net positive power under in vivo conditions, but the negative power component increased from head to tail. Both kinematically, and in the way its muscle functions to generate hydrodynamic thrust, the rainbow trout appears to be intermediate between anguilliform swimmers such as the eel, which generate thrust along their entire body length, and carangiform fish (e.g. saithe Pollachius virens), which generate thrust primarily at the tail blade.

[1]  J. Gray,et al.  STUDIES IN ANIMAL LOCOMOTION II. THE RELATIONSHIP BETWEEN WAVES OF MUSCULAR CONTRACTION AND THE PROPULSIVE MECHANISM OF THE EEL , 1933 .

[2]  J. Gray,et al.  Studies in Animal Locomotion: I. The Movement of Fish with Special Reference to the Eel , 1933 .

[3]  D. E. Goldman,et al.  Measurement of High‐Frequency Sound Velocity in Mammalian Soft Tissues , 1954 .

[4]  M. Lighthill Large-amplitude elongated-body theory of fish locomotion , 1971, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[5]  P. Webb I. THRUST AND POWER OUTPUT AT CRUISING SPEEDS , 1971 .

[6]  Richard C. L. Hudson,et al.  On the Function of the White Muscles in Teleosts at Intermediate Swimming Speeds , 1973 .

[7]  S. Grillner,et al.  On the Generation and Performance of Swimming in Fish , 1976 .

[8]  C. R. Mol,et al.  Ultrasound velocity in muscle. , 1982, The Journal of the Acoustical Society of America.

[9]  P. W. Webb,et al.  THE EFFECT OF SIZE AND SWIMMING SPEED ON LOCOMOTOR KINEMATICS OF RAINBOW TROUT , 1984 .

[10]  J. Videler,et al.  FAST CONTINUOUS SWIMMING OF SAITHE (POLLACHIUS VIRENS): A DYNAMIC ANALYSIS OF BENDING MOMENTS AND MUSCLE POWER , 1984 .

[11]  R. Josephson Mechanical Power output from Striated Muscle during Cyclic Contraction , 1985 .

[12]  Wardle Cs Swimming activity in marine fish. , 1985 .

[13]  R. Griffiths Ultrasound transit time gives direct measurement of muscle fibre length in vivo , 1987, Journal of Neuroscience Methods.

[14]  H. Sugi,et al.  Stiffness changes in frog skeletal muscle during contraction recorded using ultrasonic waves. , 1988, The Journal of physiology.

[15]  Paul W. Webb,et al.  ‘Steady’ Swimming Kinematics of Tiger Musky, an Esociform Accelerator, and Rainbow Trout, a Generalist Cruiser , 1988 .

[16]  S. Rossignol,et al.  LOCOMOTION IN LAMPREY AND TROUT: THE RELATIVE TIMING OF ACTIVATION AND MOVEMENT , 1989 .

[17]  John D. Altringham,et al.  Modelling Muscle Power Output in a Swimming Fish , 1990 .

[18]  J. L. van Leeuwen,et al.  Function of red axial muscles of carp (Cyprinus carpio): recruitment and normalized power output during swimming in different modes , 1990 .

[19]  L. Rome,et al.  The influence of temperature on power output of scup red muscle during cyclical length changes. , 1992, The Journal of experimental biology.

[20]  C. I. Smith,et al.  MYOTOMAL MUSCLE FUNCTION AT DIFFERENT LOCATIONS IN THE BODY OF A SWIMMING FISH , 1993 .

[21]  R. Josephson Contraction dynamics and power output of skeletal muscle. , 1993, Annual review of physiology.

[22]  C. S. Wardle,et al.  The timing of the electromyogram in the lateral myotomes of mackerel and saithe at different swimming speeds , 1993 .

[23]  L C Rome,et al.  How fish power swimming. , 1993, Science.

[24]  T. Williams,et al.  Anguilliform body dynamics: a continuum model for the interaction between muscle activation and body curvature , 1994, Journal of mathematical biology.

[25]  C. S. Wardle,et al.  Tuning in to fish swimming waves: body form, swimming mode and muscle function , 1995, The Journal of experimental biology.

[26]  R. James,et al.  The mechanical properties of fast and slow skeletal muscles of the mouse in relation to their locomotory function. , 1995, The Journal of experimental biology.

[27]  Lauder,et al.  Red muscle motor patterns during steady swimming in largemouth bass: effects of speed and correlations with axial kinematics , 1995, The Journal of experimental biology.

[28]  J. Altringham,et al.  Why do tuna maintain elevated slow muscle temperatures? Power output of muscle isolated from endothermic and ectothermic fish. , 1997, The Journal of experimental biology.

[29]  J. Altringham,et al.  A continuous dynamic beam model for swimming fish , 1998 .