Biomechanics of omnidirectional strikes in flat spiders

ABSTRACT Many ambush predators attack prey using rapid strikes, but these strikes are typically only anteriorly directed. However, a predator may attack laterally and posteriorly oriented prey if it can couple the strikes with rapid body reorientation. Here, we examined omnidirectional strikes in flattie spiders (Selenopidae), a group of sit-and-wait ambush predators found on open surfaces. These spiders attack prey throughout their entire peripheral range using rapid strikes that consist of rapid translation and rotation toward the prey. These spiders ambush with radially oriented, long, laterigrade legs in a ready-to-fire status. Once prey is detected, the spider maneuvers toward it using a single flexion of the legs closest to the prey, which is assisted by 0–3 extension strides by the contralateral legs. The within-stance joint actions by a few legs generate a large resultant force directed toward the prey and a large turning moment. Furthermore, the turning speed is enhanced by rapid midair leg adductions, which effectively reduce the spider's moment of inertia during angular acceleration. Our results demonstrate a novel hunting behavior with high maneuverability that is generated with effectively controlled reconfigurations of long, laterigrade legs. These results provide insights for understanding the diversity of animal legs and developing highly maneuverable multi-legged robots. Highlighted Article: Selenopid spiders can attack prey throughout their entire peripheral range, showing a novel hunting behavior with high maneuverability that is generated with effectively controlled reconfigurations of long, laterigrade legs.

[1]  Michael H. Dickinson,et al.  Flies Evade Looming Targets by Executing Rapid Visually Directed Banked Turns , 2014, Science.

[2]  R. Gillespie,et al.  Life history of the spider Selenops occultus Mello‐Leitão (Araneae, Selenopidae) from Brazil with notes on the natural history of the genus , 2008 .

[3]  C. Kropf Hydraulic System of Locomotion , 2013 .

[4]  W. J. Bell,et al.  Rotational locomotion by the cockroach Blattella germanica , 1981 .

[5]  Sarah C. Crews,et al.  A revision of the spider genus Selenops Latreille, 1819 (Arachnida, Araneae, Selenopidae) in North America, Central America and the Caribbean , 2011, ZooKeys.

[6]  Daniel Koditschek,et al.  Quantifying Dynamic Stability and Maneuverability in Legged Locomotion1 , 2002, Integrative and comparative biology.

[7]  Richard M. Murray,et al.  A Mathematical Introduction to Robotic Manipulation , 1994 .

[8]  Jeffrey A. Walker,et al.  ESTIMATING VELOCITIES AND ACCELERATIONS OF ANIMAL LOCOMOTION: A SIMULATION EXPERIMENT COMPARING NUMERICAL DIFFERENTIATION ALGORITHMS , 1998 .

[9]  K. Kardong,et al.  The predatory strike of the rattlesnake: when things go amiss , 1986 .

[10]  Xinyan Deng,et al.  Flight mechanics and control of escape manoeuvres in hummingbirds. II. Aerodynamic force production, flight control and performance limitations , 2016, Journal of Experimental Biology.

[11]  S. Manton,et al.  Arthropod phylogeny—a modern synthesis* , 2010 .

[12]  Johannes E. Schindelin,et al.  The ImageJ ecosystem: An open platform for biomedical image analysis , 2015, Molecular reproduction and development.

[13]  A. Peattie,et al.  Terrestrial locomotion in arachnids. , 2012, Journal of insect physiology.

[14]  R. Wootton Invertebrate paraxial locomotory appendages: design, deformation and control. , 1999, The Journal of experimental biology.

[15]  Mark S. Harvey,et al.  The spider family Selenopidae (Arachnida, Araneae) in Australasia and the Oriental Region , 2011, ZooKeys.

[16]  J. Camhi,et al.  The wind-evoked escape behavior of the cricket Gryllus bimaculatus: integration of behavioral elements , 1995, The Journal of experimental biology.

[17]  S N Patek,et al.  Strike mechanics of an ambush predator: the spearing mantis shrimp , 2012, Journal of Experimental Biology.

[18]  Xinyan Deng,et al.  Flight mechanics and control of escape manoeuvres in hummingbirds. I. Flight kinematics , 2016, Journal of Experimental Biology.

[19]  J. Shultz,et al.  Arthropod relationships revealed by phylogenomic analysis of nuclear protein-coding sequences , 2010, Nature.

[20]  R. Blickhan,et al.  Hydraulic leg extension is not necessarily the main drive in large spiders , 2012, Journal of Experimental Biology.

[21]  Andrew T. Sensenig,et al.  Mechanics of cuticular elastic energy storage in leg joints lacking extensor muscles in arachnids , 2003, Journal of Experimental Biology.

[22]  Full,et al.  Many-legged maneuverability: dynamics of turning in hexapods , 1999, The Journal of experimental biology.

[23]  J. Shultz,et al.  Morphology of locomotor appendages in Arachnida: evolutionary trends and phylogenetic implications , 1989 .

[24]  Andrew A Biewener,et al.  Outrun or Outmaneuver: Predator-Prey Interactions as a Model System for Integrating Biomechanical Studies in a Broader Ecological and Evolutionary Context. , 2015, Integrative and comparative biology.

[25]  R. Full Invertebrate Locomotor Systems , 2011 .

[26]  S. Combes,et al.  Turbulence-driven instabilities limit insect flight performance , 2009, Proceedings of the National Academy of Sciences.