The arrangement and function of octopus arm musculature and connective tissue

The morphology of the musculature and connective tissues of the arms of Octopus bimaculoides was analyzed with light microscopy. We also studied O. briareus and O. digueti, which possess relatively more elongate and less elongate arms, respectively. The morphology of the arms was found to be remarkably uniform among species. The arms consist of a densely packed three‐dimensional arrangement of muscle fibers and connective tissue fibers surrounding a central axial nerve cord. Three primary muscle fiber orientations were observed: 1) transverse muscle fibers oriented in planes perpendicular to the long axis of the arm; 2) longitudinal muscle fibers oriented parallel to the long axis; and 3) oblique muscle fibers arranged in helixes around the arm. The proportion of the arm cross section occupied by each of these muscle fiber groups (relative to the total cross sectional area of the musculature) remains constant along the length of the arm, even though the arm tapers from base to tip. A thin circular muscle layer wraps the arm musculature on the aboral side only. Much of this musculature has its origin and insertion on several robust connective tissue sheets including a layer surrounding the axial nerve cord and crossed‐fiber connective tissue sheets located on the oral and the aboral sides of the arm. An additional thin layer of connective tissue wraps the arm musculature laterally and also serves as a site of origin and insertion of some of the muscle fibers. The fibers of the oral and aboral crossed‐fiber connective tissue sheets are arranged oblique to the long axis of the arm with the same fiber angle as the oblique muscle layers that originate and insert on the sheets. The oblique muscle layers and the crossed‐fiber connective tissue sheets thus form composite right‐ and left‐handed helical fiber arrays. Analysis of arm morphology from the standpoint of biomechanics suggests that the transverse musculature is responsible for elongation of the arms, the longitudinal musculature is responsible for shortening, and the oblique muscle layers and associated connective tissues create torsion. Arm bending may involve unilateral contraction of longitudinal muscle bundles in combination with resistance to arm diameter increase due to contraction of the transverse musculature or passive stiffness of the arm tissues. The arms may also be bent by a combination of decrease in diameter due to contraction of the transverse musculature and maintenance of constant length on one side of the arm by unilateral activity of longitudinal muscle bundles. An increase in flexural stiffness of the arm may be achieved by cocontraction of the transverse and longitudinal muscle. Torsional stiffness may be increased by simultaneous contraction of both the right‐ and left‐handed oblique muscle layers. J. Morphol., 2007. © 2007 Wiley‐Liss, Inc.

[1]  Georges Cuvier,et al.  Mémoires pour servir a l'histoire et a l'anatomie des mollusques , 1817 .

[2]  G. Chapman Of the Movement of Worms , 1950 .

[3]  NOUVELLES RECHERCHES SUR LE SYSTÈME NERVEUX DU BRAS DES CÉPHALOPODES AVEC DES MÉTHODES SPÉCIFIQUES POUR LE TISSU NERVEUX , 1954 .

[4]  Ferdinando Rossi,et al.  NOUVELLES CONTRIBUTIONS LA CONNAISSANCE DU SYSTME NERVEUX DU TENTACULE DES CPHALOPODES. II. , 1956 .

[5]  G. Chapman THE HYDROSTATIC SKELETON IN THE INVERTEBRATES , 1958 .

[6]  R. B. Clark Dynamics in Metazoan Evolution: The Origin of the Coelom and Segments. , 1964 .

[7]  P. Graziadei,et al.  Muscle receptors in cephalopods , 1965, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[8]  G. Chapman Versatility of hydraulic systems , 1975 .

[9]  W. F. Gutmann Relationships Between Invertebrate Phyla Based on Functional-Mechanical Analysis of the Hydrostatic Skeleton , 1981 .

[10]  R. B. Clark Locomotion and the phylogeny of the Metazoa , 1981 .

[11]  W. Kier The functional morphology of the musculature of squid (Loliginidae) arms and tentacles , 1982, Journal of morphology.

[12]  Richard A. Cloney,et al.  Chromatophore Organs, Reflector Cells, Iridocytes and Leucophores in Cephalopods , 1983 .

[13]  J. Messenger,et al.  Magnesium chloride as an anaesthetic for cephalopods. , 1985, Comparative biochemistry and physiology. C, Comparative pharmacology and toxicology.

[14]  W. Kier,et al.  Tongues, tentacles and trunks: the biomechanics of movement in muscular‐hydrostats , 1985 .

[15]  W. Kier,et al.  The arrangement and function of molluscan muscle , 1988 .

[16]  W. Kier,et al.  Trunks, Tongues, and Tentacles: Moving with Skeletons of Muscle , 1989 .

[17]  Ron O'Dor,et al.  Squid as Elite Athletes: Locomotory, Respiratory, and Circulatory Integration , 1990 .

[18]  W. Kier,et al.  The Morphology and Mechanics of Octopus Suckers. , 1990, The Biological bulletin.

[19]  Y Gutfreund,et al.  Organization of Octopus Arm Movements: A Model System for Studying the Control of Flexible Arms , 1996, The Journal of Neuroscience.

[20]  B. Hochner,et al.  Patterns of Arm Muscle Activation Involved in Octopus Reaching Movements , 1998, The Journal of Neuroscience.

[21]  B. Hochner,et al.  Neuromuscular system of the flexible arm of the octopus: physiological characterization. , 2000, Journal of neurophysiology.

[22]  B. Hochner,et al.  Control of Octopus Arm Extension by a Peripheral Motor Program , 2001, Science.

[23]  W. Kier,et al.  The Structure and Adhesive Mechanism of Octopus Suckers1 , 2002, Integrative and comparative biology.

[24]  W. Kier,et al.  MUSCLE ARRANGEMENT, FUNCTION AND SPECIALIZATION IN RECENT COLEOIDS , 2004 .

[25]  J. Browning The vasculature of Octopus arms: A scanning electron microscope study of corrosion casts , 1980, Zoomorphology.

[26]  S. Wainwright Design in hydraulic organisms , 1970, Die Naturwissenschaften.

[27]  Tamar Flash,et al.  Dynamic model of the octopus arm. I. Biomechanics of the octopus reaching movement. , 2005, Journal of neurophysiology.

[28]  Tamar Flash,et al.  Dynamic model of the octopus arm. II. Control of reaching movements. , 2005, Journal of neurophysiology.

[29]  Christopher C. Pagano,et al.  Continuum robot arms inspired by cephalopods , 2005, SPIE Defense + Commercial Sensing.

[30]  Germán Sumbre,et al.  Neurobiology: Motor control of flexible octopus arms , 2005, Nature.

[31]  Bryan A. Jones,et al.  Practical kinematics for real-time implementation of continuum robots , 2006, Proceedings 2006 IEEE International Conference on Robotics and Automation, 2006. ICRA 2006..

[32]  B. Hochner,et al.  Octopuses Use a Human-like Strategy to Control Precise Point-to-Point Arm Movements , 2006, Current Biology.

[33]  Ian D. Walker,et al.  Field trials and testing of the OctArm continuum manipulator , 2006, Proceedings 2006 IEEE International Conference on Robotics and Automation, 2006. ICRA 2006..

[34]  Ian D. Walker,et al.  Practical Kinematics for Real-Time Implementation of Continuum Robots , 2006, IEEE Transactions on Robotics.

[35]  Ian D. Walker,et al.  Kinematics for multisection continuum robots , 2006, IEEE Transactions on Robotics.