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Books on the topic 'Arthropoda Behavior'

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Author: Grafiati
Published: 4 June 2021
Last updated: 9 February 2022

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1

Kapoor, Vijay Chandra. Perspectives in insect systematics. New Delhi: Inter-India Publications, 1985.

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2

Ewing, Arthur W. Arthropod bioacoustics: Neurobiology and behaviour. Ithaca, N.Y: Comstock Publishing Associates, 1989.

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3

Tautz, Jürgen. Medienbewegung in der Sinneswelt der Arthropoden: Fallstudien zu einer Sinnesökologie. Stuttgart: G. Fischer, 1989.

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4

Alekseev, A. N. Group and individual behavior of infected and noninfected arthropods-- vectors of deseases. St.-Petersburg: Zoological Institute, 1991.

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5

Hoyle, Graham. Identified Neurons and Behavior of Arthropods. Springer, 2012.

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6

Hoyle, Graham. Identified Neurons and Behavior of Arthropods. Springer, 2012.

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7

Greenfield, Michael D. Signalers and Receivers: Mechanisms and Evolution of Arthropod Communication. Oxford University Press, USA, 2002.

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8

1943-, Wiese K., ed. Sensory systems of arthropods. Basel: Birkhäuser Verlag, 1993.

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9

1945-, Evans David L., and Schmidt Justin O. 1947-, eds. Insect defenses: Adaptive mechanisms and strategies of prey and predators. Albany: State University of New York Press, 1990.

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10

Ewing, Arthur W. Arthropod Bioacoustics: Neurobiology and Behaviour. Comstock publishing, 1990.

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11

G, Gribakin F., Wiese K. 1943-, Popov A. V, Akademii͡a︡ nauk SSSR, Deutsche Forschungsgemeinschaft, and Symposium on Sensory Systems and Communication in Arthropods (1st : 1989 : Leningrad, R.S.F.S.R.), eds. Sensory systems and communication in arthropods: Including the first comprehensive collection of contributions by Soviet scientists. Basel: Birkhäuser Verlag, 1990.

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12

Gribakin, F. G., and K. Wiese. Sensory Systems and Communication in Arthropods: Including the First Comprehensive Collection of Contributions by Soviet Scientists (Advances in Lif). Birkhauser, 1990.

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13

Gutiérrez-Cabrera, Ana E., Giovanni Benelli, Thomas Walker, José Antonio De Fuentes-Vicente, and Alex Córdoba-Aguilar. Behavior-based control of arthropod vectors: the case of mosquitoes, ticks, and Chagasic bugs. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198797500.003.0021.

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This chapter outlines the patterns and occurrences of major diseases transmitted by arthropod vectors, highlighting the need for behavior-based control strategies, first, focusing on mosquito control tools with an emphasis on how knowledge of mosquito behavioral ecology may help vector control programmes. The potential of sound traps, swarm manipulation, ‘lure and kill’, radiation, transgenicm and symbiont-based approaches will be outlined, and how mosquito behavior influences these vector control strategies. Secondly, tick control strategies, as well as pheromone-assisted tick control will be reviewed, with special reference to pheromone-assisted matrix for application to vegetation, tick decoy, bont tick decoy, and the deployment of confusants. Thirdly, how Chagasic bugs are traditionally controlled will be summarized. Also, we highlight emerging chemical-based attraction methods, employing bug pheromones, as well as the use of entomopathogens. This review is not a thorough one, as it should only instruct students on how to use arthropod behavior to control arthropod vectors.
14

Barnes, W. J. P. Sensory Guidance in Arthropod Behavior (Studies in Neuroscience). Manchester Univ Pr, 1995.

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15

Mavingui, Patrick, Claire Valiente Mor, and Pablo Tortosa. Exploiting symbiotic interactions for vector/disease control. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198789833.003.0011.

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Arthropods transmit a variety of diseases to humans and animals, including arboviruses, bacteria and parasites. No efficient treatments or control methods are available for many vector-borne diseases, especially for emerging diseases. Therefore, the development of alternative strategies aiming at controlling disease transmission is encouraged worldwide. Although transmission phenomenon is a result of complex interactions involving several actors evolving in a changing environment, the biotic relationship between pathogens and their vectors represents a key step in successful disease transmission. Recent studies highlighted a strong impact of microbiomes on the life-history traits of arthropod hosts. This chapter emphasizes those biotic interactions having an impact on adaptive traits influencing disease transmission. Evidence in behavioral alterations of vector populations/individuals with relevance to vector-pathogen transmission mitigation is reviewed. Opportunities to take advantage of such biotic processes in the control of vector-borne diseases in different epidemiological, entomological and environmental settings are explored.
16

Keiser, Carl N., James L. L. Lichtenstein, Colin M. Wright, Gregory T. Chism, and Jonathan N. Pruitt. Personality and behavioral syndromes in insects and spiders. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198797500.003.0016.

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The field of animal behavior has experienced a surge of studies focusing on functional differences among individuals in their behavioral tendencies (‘animal personalities’) and the relationships between different axes of behavioral variation (‘behavioral syndromes’). Many important developments in this field have arisen through research using insects and other terrestrial arthropods, in part, because they present the opportunity to test hypotheses not accessible in other taxa. This chapter reviews how studies on insects and spiders have advanced the study of animal personalities by describing the mechanisms underlying the emergence of individual variation and their ecological consequences. Furthermore, studies accounting for animal personalities can expand our understanding of phenomena in insect science like metamorphosis, eusociality, and applied insect behavior. In addition, this chapter serves to highlight some of the most exciting issues at the forefront of our field and to inspire entomologists and behaviorists alike to seek the answers to these questions.
17

Reynolds, Don R., and Jason W. Chapman. Long-range migration and orientation behavior. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198797500.003.0007.

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The dramatic long-distance flights of butterflies and other large insects, occurring near the ground, have long been regarded as migratory. In contrast, high-altitude wind-borne movements of small insects have often been viewed differently, as uncontrolled or even accidental displacements. This chapter shows how an individual-based behavioral definition provides a unifying framework for these, and other modes of migration in insects and other terrestrial arthropods, and how it can distinguish migration from other types of movement. The chapter highlights some remarkable behavioral phenomena revealed by radar, including sophisticated flight orientations shown by high-flying migrants. Migration behavior is always supported by a suite of morphological, physiological and life-history traits—together forming a ‘migration syndrome’, itself one interacting component of a ‘migration system’. These traits steer the migrants along a ‘population pathway’ through space and time, while natural selection acts contemporaneously, continually modifying behavior and other aspects of the syndrome.
18

Gwynne, Darryl T. Katydids and Bush-Crickets: Reproductive Behavior and Evolution of the Tettigoniidae (Cornell Series in Arthropod Biology). Comstock Publishing, 2001.

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19

Allaby, Michael. A Dictionary of Zoology. Oxford University Press, 2020. http://dx.doi.org/10.1093/acref/9780198845089.001.0001.

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Over 6,000 entries This best-selling dictionary covers all aspects of zoology, including terms from ecology, animal behaviour, evolution, earth history, zoogeography, genetics, and physiology. It provides taxonomic coverage of arthropods, other invertebrates, fish, reptiles, amphibians, birds, and mammals, all fully updated to include recent changes. Detailed and authoritative, it has been fully updated for the fifth edition with over 700 entries covering taxonomic groups, prefixes, and widely used descriptive terms. All taxonomies have been checked to accommodate recent changes. Recommended web links point to additional resources and appendices include an index of common names, a taxonomic classification, a classification of endangered animals, and a geologic timescale.
20

Austin, Andrew, and Mark Dowton, eds. Hymenoptera: Evolution, Biodiversity and Biological Control. CSIRO Publishing, 2000. http://dx.doi.org/10.1071/9780643090088.

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The Hymenoptera is one of the largest orders of terrestrial arthropods and comprises the sawflies, wasps, ants, bees and parasitic wasps. Hymenoptera: Evolution, Biodiversity and Biological Control examines the current state of all major areas of research for this important group of insects, including systematics, biological control, behaviour, ecology, and physiological interactions between parasitoids and hosts. The material in this volume originates from papers presented at the Fourth International Hymenoptera Conference held in Canberra, Australia in early 1999. This material has been extensively rewritten, refereed and edited; culminating in this authoritative and comprehensive collection of review and research papers on the Hymenoptera. The authors include many world-leading researchers in their respective fields, and this synthesis of their work will be a valuable resource for researchers and students of Hymenoptera, molecular systematics and insect ecology.
21

Roitberg, Bernard D. Chemical communication. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198797500.003.0010.

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Communication takes place when two or more individuals interact via signal release and reception. This chapter focuses on chemical communication among arthropods, first, discussing the physical attributes of chemical communication and following up with examples that demonstrate the importance of chemical communication as a mediator of behavioral, ecological and evolutionary processes. In doing so, both the functional (i.e. why) and causal (i.e. how) aspects of chemical communication are considered. The examples are drawn from a broad range of topics, including mating conflict (and resolution), honest signals (e.g. marking pheromones), deceptive signals (e.g. sexual deception by orchids to exploit pollinators) and impacts on population dynamics via non-consumptive impacts (e.g. alarm pheromones of aphids). Finally, most of the examples illustrate the subtle and contextual nature of chemical communication making the case that to understand chemical communication one must understand the chemical communicators and not just the chemical compounds that mediate their inter-individual interactions.
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