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Neurobiology and vision of jumping spiders (Araneae: Salticidae)

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Hill, David E. (2022): Neurobiology and vision of jumping spiders (Araneae: Salticidae). Peckhamia 255 (1): 1-81, DOI: 10.5281/zenodo.6360448

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Publication: 10.7554/eLife.20041 (DOI)
Publication: 10.1371/journal.pone.0025390) (DOI)
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Publication: 10.1016/j.semcdb.2021.05.004):1-4 (DOI)
Publication: 10.3390/vision6010002) (DOI)
Publication: 10.1002/cne.24862) (DOI)
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References

  • Angelini, D. R., P. Z. Liu, C. L. Hughes and T. C. Kaufman. 2005. Hox gene function and interaction in the milkweed bug Oncopeltus fasciatus (Hemiptera). Developmental Biology 287: 440-455.
  • Anken, R. H. and H. Rahmann. 2002. Gravitational zoology: how animals use and cope with gravity. In: Astrobiology The Quest for the Conditions of Life, eds. G. Horneck and C. Baumstark-Khan, Springer: 315-333.
  • Audouin, V. 1826. Explication sommaire des planches d'arachnides de l'Ekgypte et de la Syrie. In: Description de l'Egypte, ou recueil des observations et des recherches qui ont ete faites en Egypte pendant l'expedition de l'armee fran ̉«aise, publie par les ordres de sa Majeste l'Empereur Napoleon le Grand. Histoire Naturelle 1 (4): 1-339.
  • Babu, K. S. 1965. Anatomy of the central nervous system of arachnids. Zoologische JahrbuNcher, Abteilung fuNr allgemeine Zoologie und Physiologie der Tiere 82: 1-154.
  • Babu, K. S. 1973. Histology of the neurosecretory system and neurohemal organs of the spider Argiope aurantia (Lucas). Journal of Morphology 141: 77-98.
  • Babu, K. S. 1985. Patterns of arrangement and connectivity in the central nervous system of arachnids. Chapter I in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 3-19.
  • Babu, K. S. and F. G. Barth. 1984. Neuroanatomy of the central nervous system of the wandering spider, Cupiennius salei. Zoomorphology 104: 344-359.
  • Bach, M. 2022. 147 visual phenomena & optical illusions. Online at: https://michaelbach.de/ot/index.html
  • Banks, N. 1929. Spiders from Panama. Bulletin of the Museum of Comparative Zoology 69: 53-96.
  • Barth, F. G. 1985a. Slit sensilla and the measurement of cuticular strains. Chapter IX in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 162-188.
  • Barth, F. G. 1985b. Neuroethology of the spider vibration sense. Chapter XI in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 203-229.
  • Barth, F. G. 2002. A Spider's World: Senses and Behavior. Springer-Verlag: i-xiv, 1-394.
  • Bartos, M. 2000. Distance of approach to prey is adjusted to the prey's ability to escape in Yllenus arenarius Menge (Araneae, Salticidae). European Arachnology 2000. Proceedings of the 19th European Colloquium of Arachnology: 33-38.
  • Becker, N., S. Prasad-Shreckengast and S. Byosiere. 2021. Methodological challenges in the assessment of dogs' (Canis lupus familiaris) susceptibility of the Ebbinghaus-Titchener illusion using the spontaneous choice task. Animal Behavior and Cognition. 8 (2): 138-151.
  • Behrens, C., T. Schubert, S. Haverkamp, T. Euler and P. Berens. 2016. Connectivity map of bipolar cells and photoreceptors in the mouse retina. eLife 5 (e20041): 1-20. DOI: 10.7554/eLife.20041.
  • Bender, J. and M. Frye. 2009. Invertebrate solutions for sensing gravity. Current Biology, 19 (5): R186-R190.
  • Bennett, T. J. and R. D. Lewis. 1979. Visual orientation in the Salticidae (Araneae). New Zealand Entomologist 7 (1): 58-63.
  • Blest, A. D. 1983. Ultrastructure of secondary retinae of primitive and advanced jumping spiders (Araneae, Salticidae). Zoomorphology 102: 125-141.
  • Blest, A. D. 1984. Ultrastructure of the secondary eyes of a primitive jumping spider, Yaginumanis. Zoomorphology 104: 223- 225.
  • Blest, A. D. 1985a. Retinal mosaics of the principal eyes of jumping spiders (Salticidae) in some neotropical habitats: optical trade-offs between sizes and habitat illuminances. Journal of Comparative Physiology A 157: 391-404.
  • Blest, A. D. 1985b. The fine structure of spider photoreceptors in relation to function. Chapter V in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 79-102.
  • Blest, A. D. 1987. The retinae of Euryattus bleekeri, an aberrant salticid spider from Queensland. Journal of Zoology, London 211: 399-408.
  • Blest, A. D. 1988. Post-embryonic development of the principal retina of a jumping spider I. The establishment of retinal tiering by conformational changes. Philosophical Transactions of the Royal Society of London B 320: 489-504.
  • Blest, A. D. and M. Carter. 1987. Morphogenesis of a tiered principal retina and the evolution of jumping spiders. Nature 328: 152-155.
  • Blest, A. D. and M. Carter. 1988. Post-embryonic development of the principal retina of a jumping spider II. The acquisition and reorganization of rhabdomeres and growth of the glial matrix. Philosophical Transactions of the Royal Society of London B 320: 505-515.
  • Blest, A. D., R. C. Hardie, P. McIntyre and D. S. Williams. 1981. The spectral sensitivities of identified receptors and the function of retinal tiering in the principal eyes of a jumping spider. Journal of Comparative Physiology 145: 227-239.
  • Blest, A. D. and J. Maples. 1979. Exocytotic shedding and glial uptake of photoreceptor membrane by a salticid spider. Proceedings of the Royal Society of London B 204: 105-112.
  • Blest, A. D., P. McIntyre and M. Carter. 1988. A re-examination of the principal retinae of Phidippus johnsoni and Plexippus validus (Araneae: Salticidae): implications for optical modelling. Journal of Comparative Physiology A 162: 47-56.
  • Blest, A. D., D. C. O'Carroll and M. Carter. 1990. Comparative ultrastructure of Layer I receptor mosaics in principal eyes of jumping spiders: the evolution of regular arrays of light guides. Cell and Tissue Research 262: 445-460.
  • Blest, A. D. and G. D. Price. 1984. Retinal mosaics of the principal eyes of some jumping spiders (Salticidae: Araneae): adaptations for high visual acuity. Protoplasma 120: 172-184.
  • Blest, A. D. and C. Sigmund. 1984. Retinal mosaics of the principal eyes of two primitive jumping spiders, Yaginumanis and Lyssomanes: clues to the evolution of salticid vision. Proceedings of the Royal Society of London B 221: 111-125.
  • Blest, A. D. and C. Sigmund. 1985. Retinal mosaics of a primitive jumping spider, Spartaeus (Salticidae: Araneae): a transition between principal retinae serving low and high spatial acuities. Protoplasma 125: 129-139.
  • Bloom, M. and M. A. Berkley. 1977. Visual acuity and the near point of accomodation in cats. Vision Research 17 (6): 723- 730.
  • Bonaric, J. 1995. Le systehme neuroendocrine reDtroceDreDbral des AraigneDes: structure et fonction. Proceedings of the 15th European Colloquium of Arachnology: 27-34.
  • Bridgeman, B. 2007. Efference copy and its limitations. Computers in Biology and Medicine 37: 924-929.
  • Bruce, M., D. Daye, S. M. Long, A. M. Winsor, G. Menda, R. R. Hoy and E. M. Jakob. 2021. Attention and distraction in the modular visual system of a jumping spider. Journal of Experimental Biology 224: 1-5.
  • Bursey, C. R. and R. G. Sherman. 1970. Spider cardiac physiology I, structure and function of the cardiac ganglion. Comparative and General Pharmacology 1: 160-170.
  • Carroll, J., C. J. Murphy, M. Neitz, J. N. Ver Hoeve and J. Neitz. 2001. Photopigment basis for dichromatic color vision in the horse. Journal of Vision 1: 80-87.
  • Caves, E. M. and S. Johnsen. 2018. AcuityView: an R package for portraying the effects of visual acuity on scenes observed by an animal. Methods in Ecology and Evolution, British Ecological Society 9: 793-797, supporting table S1.
  • Cerveira, A. M., R. R. Jackson and X. J. Nelson. 2019. Dim-light vision in jumping spiders (Araneae, Salticidae): identification of prey and rivals. Journal of Experimental Biology 222, jeb198069: 1-7.
  • Charman, W. N. 1991. Optics of the human eye. In: Visual Optics and Instrumentation, ed. J. Cronley Dillon, CRC Press, Boca Raton: 1-26.
  • Chaya, T., A. Mastsumato, Y. Sugita, S. Watanabe, R. Kuwahara, M. Tachibana and T. Furukawa. 2017. Versatile functional roles of horizontal cells in the retinal circuit. Scientific Reports 7 (5540): 1-15.
  • Chen, S. and W. Li. 2013. A color coding amacrine cell may provide a "Blue-Off" signal in a mammalian retina. Nature Neuroscience 15 (7): 954-956.
  • Clark, D. L. and C. L. Morjan. 2001. Attracting female attention: the evolution of dimorphic courtship displays in the jumping spider Maevia inclemens (Araneae: Salticidae). Proceedings of the Royal Society London B 268: 2461-2465.
  • Clark, D. L. and G. W. Uetz. 1993. Signal efficacy and the evolution of male dimorphism in the jumping spider, Maevia inclemens. Proceedings of the National Academy of Sciences of the United States of America 90 (24): 11954-11957.
  • Clerck, C. 1757. Aranei Svecici. Svenska spindlar, uti sina hufvud-slaogter indelte samt under naogra och sextio saNrskildte arter beskrefne och med illuminerade figurer uplyste. Laurentius Salvius, Stockholmiae: 1-154.
  • Crocker, R. L. and R. B. Skinner. 1984. Boolean model of the courtship and agonistic behavior of Hentzia palmarum (Araneae: Salticidae). Florida Entomologist 67 (1): 97-106.
  • Curtis, J. L. 1892. A new jumping spider. Zoe 3: 332-337.
  • Dacke, M., T. A. Doan and D. C. O'Carroll. 2001. Polarized light detection in spiders. The Journal of Experimental Biology 204: 2481-2490.
  • Damen, W. G. M. 2002. Parasegmental organization of the spider embryo implies that the parasegment is an evolutionary conserved entity in arthropod embryogenesis. Development 129: 1239-1250.
  • Damen, W. G. M., M. Hausdorf, E. Seyfarth and D. Tautz. 1998. A conserved mode of head segmentation in arthropods revealed by the expression pattern of Hox genes in a spider. Proceedings of the National Academy of Sciences, USA 95: 10665-10670.
  • Damen, W. G. M. and D. Tautz. 1999. Comparative molecular embryology of arthropods: the expression of Hox genes in the spider Cupiennius salei. Invertebrate Reproduction and Development 36: (1-3): 203-209.
  • Davey, M. P., M. V. Srinivasan and T. Maddess. 1998. The Craik-O'Brien-Cornsweet illusion in honeybees. Naturwissenschaften 85: 73-75.
  • De Agro, M., D. C. Rossler, K. Kim and P. S. Shamble. 2021. Perception of biological motion by jumping spiders. PLOS Biology 19 (7, e3001172): 1-16.
  • Defrize, J., C. R. Lazzari, E. J. Warrant and J. Casas. 2011. Spectral sensitivity of a colour changing spider. Journal of Insect Physiology 57 (4): 508-513.
  • DeVoe, R. D. 1972. Dual sensitivities of cells in wolf spider eyes at ultraviolet and visible wavelengths of light. The Journal of General Physiology 59: 247-269.
  • DeVoe, R. D. and J. E. Zvargulis. 1967. Spectral sensitivities of vision in wolf spiders and jumping spiders. Federation Proceedings 26: 655.
  • DeVoe, R. D., R. J. W. Small and J. E. Zvargulis. 1969. Spectral sensitivities of wolf spider eyes. The Journal of General Physiology 54: 1-32.
  • DeVoe, R. D. 1975. Ultraviolet and green receptors in principal eyes of jumping spiders. Journal of General Physiology 66: 193-207.
  • Doffinger, C. M. 2010. Early steps in ventral nerve cord development in chelicerates and myriapods and formation of brain compartments in spiders. Ph.D. dissertation, Johannes Gutenberg-UniversitaNt, Mainz: i-x, 1-161.
  • Doleschall, L. 1859. Tweede Bijdrage tot de kennis der Arachniden van den Indischen Archipel. Acta Societatis Scientiarum Indica-Neerlandica 5: 1-60.
  • Dolev, Y. 2016. Visual perception in jumping spiders. Ph.D. Dissertation, University of Canterbury: i-vii, 1-177.
  • Drees, O. 1952. Untersuchungen uber die angeborenen Verhaltensweisen bei Springspinnen (Salticidae). Zeitschrift fur Tierpsychologie 9: 169-207.
  • Drewes, C. D. and R. A. Bernard. 1976. Electrophysiological responses of chemosensitive sensilla in the wolf spider. JJournal of Experimental Zoology 198: 423-428.
  • Duelli, P. 1975. Bewegungs-Lokalisation in den Posterolateral-Augen von Evarcha arcuata (Salticidae, Araneae). Preliminary results, 20.II.75: 1-8.
  • Duelli, P. 1977. Evidence for an off-pass-filter in the movement detecting system of jumping spiders (Evarcha arcuata, Salticidae). Proceedings of the Australian Physiological and Pharmacological Society 8: 98.
  • Duelli, P. 1978. Movement detection in the posterolateral eyes of jumping spiders (Evarcha arcuata, Salticidae). Journal of Camparative Physiology 124: 15-26.
  • Duelli, P. 1980. The neuronal organization of the posterior lateral eyes of jumping spiders (Salticidae). Zoologisches Jahrbuch, Abteilung Anatomie 103: 17-40.
  • Dumpert, K. 1978. Spider odor receptor: electrophysiological proof. Experientia 34: 754-755.
  • Duncan, R. O. and G. M. Boynton. 2003. Cortical magnification within human primary visual cortex correlates with acuity thresholds. Neuron 38: 659-671.
  • Eakin, R. M. and J. L. Brandenburger. 1971. Fine structure of the eyes of jumping spiders. Journal of Ultrastructure Research 37: 618-663.
  • Eberhard, W. G. and W. T. Wcislo. 2011. Grade changes in brain-body allometry: morphological and behavioural correlates of brain size in miniature spiders, insects and other invertebrates. In: Advances in Insect Physiology, Volume 40, ed. JeDropme Casas, Academic Press, Burlington: 155-214.
  • Edwards, G. B. 2020. Description of Phidippus pacosauritus sp. nov. (Salticidae: Salticinae: Dendryphantini: Dendryphantina), with a reanalysis of related species in the mystaceus group. Peckhamia 221.1: 1-18.
  • Einthoven, W. 1885. Stereoscopie durch Farbendifferenz. Graefe's Archiv fuNr Ophthalmologie 31:211-238.
  • Elias, D. O., B. R. Land, A. C. Mason and R. R. Hoy. 2006. Measuring and quantifying dynamic visual signals in jumping spiders. Journal of Comparative Physiology A 192, 785-797.
  • Elias, D. O., W. P. Maddison, C. Peckmezian, M. B. Girard and A. C. Mason. 2012. Orchestrating the score: complex multimodal courtship in the Habronattus coecatus group of Habronattus jumping spiders (Araneae: Salticidae). Biological Journal of the Linnean Society 105 (3): 522-547.
  • Faubert J. 1994. Seeing depth in colour: More than just what meets the eyes. Vision Research 34: 1165-1186.
  • Field, G. D., J. L. Gauthier, A. Sher, M. Greschner, T. A. Machado, L. H. Jepson, J. Shlens, D. E. Gunning, K. Mathieson, W. Dabrowski, L. Paninski, A. M. Litke and E. J. Chichilnisky. 2010. Functional connectivity in the retina at the resolution of photoreceptors. Nature 467: 673-678.
  • Fite, K. V. 1973. Anatomical and behavioural correlates of visual acuity in the great hormed owl. Vision Research 13: 219-230.
  • Fleissner, G. and G. Fleissner. 1985. Neurobiology of a circadian clock in the visual system of scorpions. Chapter XVIII in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 351-375.
  • Foelix, R. F. 1985a. Mechano- and chemoreceptive sensilla. Chapter VII in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 118-137.
  • Foelix, R. F. 2011. Biology of Spiders. Third Edition. Oxford University Press. i-vii, 1-419.
  • Foelix, R. F. and I. W. Chu-Wang. 1973a. The morphology of spider sensilla. I. Mechanoreceptors. Tissue Cell 5: 451-460.
  • Foelix, R. F. and I. W. Chu-Wang. 1973b. The morphology of spider sensilla. I. Chemoreceptors. Tissue Cell 5: 451-460.
  • Foelix, R. F. and B. Erb. 2011. Microscopical studies on exuviae of the jumping spider Phidippus regius. Peckhamia 90.1: 1-15.
  • Franze, K, J. Grosche, S. N. Skatchkov, S. Schinkinger, C. Foja, D. Schild, O. Uckermann, K. Travis, A. Reichenbach and J. Guck. 2007. MuNller cells are living optical fibers in the vertebrate retina. Proceedings of the National Academy of Sciences, USA 104 (20): 8287-8292.
  • Frings, H. and M. Frings. 1966. Reactions of orb-weaving spiders (Argiopidae) to airborne sounds. Ecology 47:578 - 588.
  • Gabe, M. 1954. Emplacement et connexions des cellules neurosecretrices chez quelques araneids. Comptes Rendus hebdomadaires des Seances de l'Academie des Sciences Paris 238: 1265-1267.
  • Gardner, B. T. 1966. Hunger and characteristics of the prey in the hunting behavior of salticid spiders. Journal of Comparative Physiology and Psychology 62: 475-478.
  • Geisler, W. S. 1984. Physical limits of acuity and hyperacuity. Journal of the Optical Society of America A 1 (7): 775-782.
  • Gerstaecker, A. 1873. Arachnoidea. In: Die Gliederthier-Fauna des Sansibar-Gebietes. Nach dem von Dr. O. Kersten waNhrend der v. d. Decken'schen Ost-Afrikanischen Expedition im Jahre 1862 und von C. Cooke auf der Insel Sansibar im Jahre 1864 gesammelten Material. C. F. Winter, Leipzig: 461-503, pl. 18.
  • Girard, M. B., M. M. Kasumovic and D. O. Elias. 2011. Multi-modal courtship in the Peacock Spider, Maratus volans (O.P.- Cambridge, 1874). PLoS ONE 6 (9): e25390: 1-10 (doi:10.1371/journal.pone.0025390).
  • Giribet, G., G. D. Edgecombe and W. C. Wheeler. 2001. Arthropod phylogeny based on eight molecular loci and morphology. Nature 413: 157-161.
  • Glasser, A., M. T. Pardue, M. E. Andison and J. G. Sivak. 1997. A behavioral study of refraction, corneal curvature, and accommodation in raptor eyes. Canadian Journal of Zoology 75: 2010-2020.
  • Glenszcyk, M., D. Outomuro, M. Gregoric, S. Kralj-Fiser, J. M. Schneider, D. Nilsson, N. I. Morehouse and C. Tedore. 2022. The jumping spider Saitis barbipes lacks a red photoreceptor to see its own sexually dimorphic red coloration. The Science of Nature 109 (6): 1-13 (https://doi.org/10.1007/s00114-021-01774-6).
  • Gomes, A. D., H. Bartelt and O. Frazao. 2021. Optical vernier effect: recent advances and developments. Laser Photonics Review 2021 (2000588): 1-16.
  • Goodman, J. W. 1968. Introduction to Fourier Optics. McGraw-Hill Physical and Quantum Electronics Series. McGraw-Hill, New York. i-xiv, 1-287.
  • Gorner, P. and B. Claas. 1985. Homing behavior and orientation in the funnel-web spider, Agelena labyrinthica. Chapter XIV in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 275-297.
  • Gote, J. T., P. M. Butler, D. B. Zurek and E. K. Buschbeck. 2019. Growing tiny eyes: how juvenile jumping spiders retain high visual performance in the face of size limitations and developmental constraints. Vision research 160: 24-36.
  • Gray, H. and W. H. Lewis. 1918. Anatomy of the Human Body, Twentieth Edition. Lea & Febiger, Philadephia and New York. 1-1396.
  • Gregory, R. L. and P. Heard. 1979. Border locking and the CafeDWall illusion. Perception 8: 365-380.
  • Griswold, C. E. 1979. New species of Pellenes from California (Araneae: Salticidae). Journal of Arachnology 7: 129-138.
  • Grob, R., C. Tritscher, K. Grubel, C. Stigloher, C. Groh, P. N. Fleischmann and W. Rossler. 2020. Johnston's organ and its central projections in Cataglyphis desert ants. Journal of Comparative Neurology 529 (8): 2138-2155.
  • Gronenberg, W. 1989. Anatomical and physiological observations on the organization of mechanoreceptors and local interneurons in the central nervous system of the wandering spider Cupiennius salei. Cell and Tissue Research 258: 163- 175.
  • Gronenberg, W. 1990. The organization of plurisegmental mechanosensitive interneurons in the central nervous system of the wandering spider Cupiennius salei. Cell and Tissue Research 260: 49-61.
  • Gross, H., F. Blechinger, W. Singer and B. Achtner. 2008. Human eye. Chapter 36 in: Handbook of Optical Systems, Vol. 4, Survey of Optical Instruments, ed. H. Gross. Wiley-Blackwell. 1-1092.
  • Halanych, K. M., and A. M. Janosik. 2006. The state of annelid phylogeny. Integrative and Comparative Biology 46: 533-543.
  • Hamer, R. D., F. A. Carvalho and D. F. Ventura. 2013. Effect of contrast and gaps between Vernier stimulus elements on sweep visual evoked potential measurements of human cortical Vernier responses. Psychology and Neuroscience 6 (2): 199-212.
  • Hanstrom, B. 1921. Uqber die Histologie und vergleichende Anatomie der Sehganglien und Globuli der Araneen. Kungliga Svenska Vetenskapsakademiens Handlingar 61 (12): 1-39.
  • Hanstrom, B. 1935. Fortgesetzte Untersuchungen uber das Araneengehirn. Zoologische JahrbuNcher, Abteilung fuNr Anatomie und Ontogenie der Tiere 59: 455-478.
  • Hardie, R. C. and P. Duelli. 1978. Properties of single cells in the posterior lateral eyes of jumping spiders. Zeitschrift fuNr Naturforschung 33c: 156-158.
  • Harland, D. P. and R. R. Jackson. 2000. 'Eight-legged cats' and how they see - a review of recent research on jumping spiders. Cimbebasia 16: 231-240.
  • Harland, D. P. and R. R. Jackson. 2001a. Cues by which Portia fimbriata, an araneophagic jumping spider, distinguishes jumping-spider prey from other prey. The Journal of Experimental Biology 203: 3485-3494.
  • Harland, D. P. and R. R. Jackson. 2001b. Prey classification by Portia fimbriata, a salticid spider that specializes at preying on other salticids: species that elicit cryptic stalking. Journal of Zoology, London 255: 455-460.
  • Harland, D. P. and R. R. Jackson. 2002. Influence of cues from the anterior medial eyes of virtual prey on Portia fimbriata, an araneophagic jumping spider. The Journal of Experimental Biology 205: 1861-1868.
  • Harland, D. P., D. Li and R. R. Jackson. 2012. How jumping spiders see the world. Chapter 9 in: How Animals See the World: Comparative Behavior, Biology, and Evolution of Vision, eds. O. F. Lazareva, T. Shimizu, & E. A. Wasserman, Oxford University Press: 133-163.
  • Harris, D. J. and P. J. Mill. 1973. The ultrastructure of chemoreceptor sensilla in Ciniflo (Araneida, Arachnida). Tissue Cell 5: 679-689.
  • Harris, D. J. and P. J. Mill. 1977a. Observations on the leg receptors of Ciniflo (Araneida, Dictynidae). I. External mechanoreceptors. Journal of Comparative Physiology 119: 37-54.
  • Harris, D. J. and P. J. Mill. 1977b. Observations on the leg receptors of Ciniflo (Araneida, Dictynidae). II. Chemoreceptors. Journal of Comparative Physiology 119: 55-62.
  • Hashimi, H., M. Pakbin, B. Ali, A. Yekta, H. Ostadimoghaddam, A. Asharlous, M. Aghamirsalim and M. Khabazkhoob. 2019. Near points of convergence and accomodation in a population of university students in Iran. Journal of Opthalmic and Vision Research 14 (3): 306-314.
  • Hengstedberg, R. 1993. Multisensory control in insect oculomotor systems. Chapter 13 in: Visual Motion and its Role in the Stabilization of Gaze, eds. F. A. Miles and J. Wallman, Elsevier: 285-298.
  • Hentz, N. M. 1846. Descriptions and figures of the araneides of the United States. Boston Journal of Natural History 5: 352- 370.
  • Hering, E. 1964. Outlines of a Theory of the Light Sense. English translation from the German by L. M. Hurvich and D. Jameson. Harvard University Press, Cambridge, Massachusetts. 1-317.
  • Hill, D. E. 1975. The structure of the central nervous system of jumping spiders of the genus Phidippus (Araneae: Salticidae). M.S. thesis, Oregon State University: i-ix, 1-94.
  • Hill, D. E. 1977. The pretarsus of salticid spiders. Zoological Journal of the Linnean Society 60 (4): 319-338.
  • Hill, D. E. 1978. Orientation by jumping spiders of the genus Phidippus (Araneae: Salticidae) during the pursuit of prey. Ph.D. dissertation, University of Florida: i-v, 1-202.
  • Hill, D. E. 1979. Orientation by jumping spiders of the genus Phidippus (Araneae: Salticidae) during the pursuit of prey. Behavioral Ecology and Sociobiology 5: 301-322.
  • Hill, D. E. 2006. The structure of the central nervous system of jumping spiders of the genus Phidippus (Araneae: Salticidae). Republication Version 1. Peckhamia Epublications: 1-46.
  • Hill, D. E. 2010a. Use of location (relative direction and distance) information by jumping spiders (Araneae, Salticidae, Phidippus) during movement toward prey and other sighted objectives. Peckhamia 83.1: 1-103.
  • Hill, D. E. 2010b. Targeted jumps by salticid spiders (Araneae: Salticidae: Phidippus). Peckhamia 84.1: 1-35.
  • Hill, D. E. 2010c. Jumping spider feet (Araneae: Salticidae). Peckhamia 85.1: 1-48.
  • Hill, D. E. 2011. The jumping spider mouth (Araneae: Salticidae). Peckhamia 97.1: 1-17.
  • Hill, D. E. 2018a. Notes on the jumping spiders Colonus puerperus (Hentz 1846) and Colonus sylvanus (Hentz 1846) in the southeastern United States (Araneae: Salticidae: Amycoida: Gophoini). Peckhamia 99.2: 1-63.
  • Hill, D. E. 2018b. The jumping behavior of jumping spiders: a review (Araneae: Salticidae). Peckhamia 167.1: 1-8.
  • Hill, D. E. 2020. Respiration by jumping spiders (Araneae: Salticidae). Peckhamia 225.1: 1-28.
  • Hill, D. E, and D. B. Richman. 2009. The evolution of jumping spiders (Araneae: Salticidae): a review. Peckhamia 75.1: 1-7.
  • Hill, D. E., D. L. Glaser and E. C. Galvao. 2021. Extension of fangs during the predatory jumps of jumping spiders (Araneae: Salticidae). Peckhamia 242.1: 1-9.
  • Hill, D. E. and J. C. Otto. 2011. Visual display by male Maratus pavonis (Dunn 1947) and Maratus splendens (Rainbow 1896) (Araneae: Salticidae: Euophryinae). Peckhamia 89.1: 1-41.
  • Hoefler, C. D. and E. M. Jakob. 2006. Jumping spiders in space: movement patterns, nest site fidelity and the use of beacons. Animal Behaviour 71: 109-116.
  • Homann H. 1928. BetraNge zur Physiologie der Spinnenaugen. I. Untersuchungsmethoden. II. Das SehvermoNgen der Salticiden. Zeitschrift fuNr vergleichende Physiologie 7: 201-268.
  • Homann, H. 1950. Die Nebenaugen der Araneen. Zoologische JahrbuNcher, Abteilung fuNr Anatomie und Ontogenie der Tiere 71: 56-144.
  • Homann, H. 1952. Die Nebenaugen der Araneen. Zweite Mitteilung. Zoologische JahrbuNcher, Abteilung fuNr Anatomie und Ontogenie der Tiere 72: 345-364.
  • Howard, S. R., A. Avargue`s-Weber, J. E. Garcia, D. Stuart-Fox and A, G. Dyer. 2017. Perception of contextual size illusions by honeybees in restricted and unrestricted viewing conditions. Proceedings of the Royal Society B 284 (20172278): 1-9.
  • Hu, Z., F. Liu, X. Xu, Z. chen, J. Chen and D. Li. 2012. Spectral transmission of the principal-eye corneas of jumping spiders: implications for ultraviolet vision. The Journal of Experimental Biology 215: 2853-2859.
  • Insausti, T. C., J. Defrize, C. R. Lazzari and J. Casas. 2012. Visual fields and eye morphology support color vision in a colorchanging crab-spider. Arthropod Structure & Development 41: 155-163.
  • Jackson, R. R. 2000. Prey preferences and visual discrimination ability of Brettus, Cocalus and Cyrba, araneophagic jumping spiders (Araneae: Salticidae) from Australia, Kenya and Sri Lanka. New Zealand Journal of Zoology 27: 29-39.
  • Jackson, R. R. and A. D. Blest. 1982. The distances at which a primitive jumping spider, Portia fimbriata, makes visual discriminations. Journal of Experimental Biology 97: 441-445.
  • Jackson, R. R. and D. P. Harland. 2009. One small leap for the jumping spider but a giant step for vision science. The Journal of Experimental Biology 212 (14): 2129-2132.
  • Jakob, E. M., S. M. Long, D. P. Harland, R. R. Jackson, A. Carey, M. E. Searles, A. H. Porter, C. Canavesi and J. P. Rolland. 2018. Lateral eyes direct principal eyes as jumping spiders track objects. Current Biology 28: R1075-R1095.
  • Johnson, A. S. and W. Winlow. 2019. Are neural transactions in the retina performed by phase ternary computation? Animal Behavior and Neuroscience 2 (1): 223-236.
  • Karsch, F. 1878a. Exotisch-araneologisches. Zeitschrift fuNr die Gesammten Naturwissenschaften 51: 322-333, 771-826.
  • Karsch, F. 1878b. Diagnoses Attoidarum aliquot novarum Novae Hollandiae collectionis Musei Zoologici Berolinensis. Mittheilungen des MuNnchener Entomologischen Vereins 2: 22-32.
  • Kashiyama, K., T. Seki, H. Numata and S. G. Goto. 2009. Molecular characterization of visual pigments in Branchiopoda and the evolution of opsins in Arthropoda. Molecular Biology and Evolution 26 (2): 299-311.
  • Kastner, A. 1950. Reaktionen der Hupfspinnen (Salticidae) auf unbegwegte farblose und farbige Gesichtsreize. Zoologische Beitrage. 1: 13-50.
  • Kater, S. B. 1974. Feeding in Helisoma trivolis: the morphological and physiological bases of a fixed action pattern. American Zoologist 14 (3): 1017-1036
  • Katz, M. and P. B. Kruger. 2009. The human eye as an optical system. Chapter 33 in: Duane's Opthalmology, 15th Edition, ed. W. Tasman and E. Jaeger, Lippincott Williams & Wilkins, Philadephia. 1-63.
  • Keyserling, E. 1882. Die Arachniden Australiens, nach der Natur beschrieben und abgebildet. Erster Theil, Lieferung 29-30. Bauer & Raspe, NuNrnberg: 1325-1420, pl. 113-120.
  • Keyserling, E. 1885. Neue Spinnen aus America. VI. Verhandlungen der Kaiserlich-KoNniglichen Zoologisch-Botanischen Gesellschaft in Wien 34: 489-534.
  • Koch, C. L. 1846. Die Arachniden. J. L. Lotzbeck, NuNrnberg. Dreizehnter Band: 1-234, pl. 433-468, figs. 1078-1271; Vierzehnter Band: 1-88, pl. 467-480, figs. 1272-1342.
  • Koch, L. 1878. Japanesische Arachniden und Myriapoden. Verhandlungen der Kaiserlich-KoNniglichen Zoologisch-Botanischen Gesellschaft in Wien 27 (1877): 735-798, pl. 15-16.
  • Koch, L. 1879. Die Arachniden Australiens, nach der Natur beschrieben und abgebildet. Erster Theil, Lieferung 24-25. Bauer & Raspe, NuNrnberg: 1045-1156, pl. 91-100.
  • Komiya, M., S. Yamashita and H. Tateda. 1988. Turning reactions to real and apparent motion stimuli in the posterolateral eyes of jumping spiders. Journal of Comparative Physiology A 163: 585-592.
  • Konkle, T. and A. Oliva. 2012. A real-world size organization of object responses in occipitotemporal cortex. Neuron 74: 1114-1124.
  • Kovoor, J., A. Munoz-Cuevas and J. Ortega-Escobar. 2005. The visual system of Lycosa tarentula (Araneae, Lycosidae): microscopic anatomy of the protocerebral optic centres. Italian Journal of Zoology 72: 205-216.
  • Koyanagi, M., T. Nagata, K. Katoh, S. Yamashita and F. Tokunaga. 2008. Molecular evolution of arthropod color vision deduced from multiple opsin genes of jumping spiders. Journal of Molecular Evolution 66: 130-137.
  • Kuehni, R. G. 2004. Variability in unique hue selection: a surprising phenomenon. Color Research and Application 29: 158- 162.
  • Kuhne, H. 1959. Die neurosekretorischen Zellen und der retrocerebrale neuro-endocrine Komplex von Spinne. Zoologische Jahrbucher, Abteilung fur Anatomie und Ontogenie der Tiere 77: 527-600.
  • Labin, A. M. and E. N. Ribak. 2010. Retinal glial cells enhance human vision acuity. Physical Review Letters 158102: 1-4.
  • Lam, D. Y. S., T. L. Cheng, D. G. Kirschen and D. M. Laby. 2008. Effects of head tilt on stereopsis. Binocular Vision and Strabismus Quarterly Journal 23 (2): 95-104.
  • Land, M. F. 1969a. Structure of the retinae of jumping spiders (Salticidae: Dendryphaninae) in relation to visual optics. Journal of Experimental Biology 51: 443-470.
  • Land, M. F. 1969b. Movements of the retinae of jumping spiders (Salticidae: Dendryphantinae) in response to visual stimuli. Journal of Experimental Biology 51: 471-493.
  • Land, M. F. 1971. Orientation by jumping spiders in the absence of visual feedback. Journal of Experimental Biology 54: 119- 139.
  • Land, M. F. 1972. Stepping movements made by jumping spiders during turns mediated by the lateral eyes. Journal of Experimental Biology 57: 15-40.
  • Land, M. F. 1985a. Fields of view of the eyes of primitive jumping spiders. Journal of Experimental Biology 119: 381-384.
  • Land, M. F. 1985b. The morphology and optics of spider eyes. Chapter IV in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 53-78.
  • Latreille, P. A. 1804. Tableau methodique des Insectes. Nouveau Dictionnaire d'Histoire Naturelle, Paris 24: 129-295.
  • Legendre, R. 1959. Contribution a l'etude du systeme nerveux des araneides. Annales des Sciences Naturelles, Zoologie et Biologie Animale 28: 343-474.
  • Legendre, R. 1961. Sur deux particularities du systeme nerveux central de la mygale Scodra calceata Fabr. Annales des Sciences Naturelles, Zoologie et Biologie Animale 30: 767-771.
  • Legendre, R. 1971. Etat actuel de nos connaissances sur le deDveloppement embryonnaire et la croissance des araigneDes. Annales des Sciences Naturelles, Zoologie et Biologie Animale 96: 93-114.
  • Legendre, R. 1985. The stomatogastric nervous system and neurosecretion. Chapter III in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 38-49.
  • Lewis, R. F., B. M. Gaymard and R. J. Tamargo. 1998. Efference copy provides the eye position information required for visually guided reaching. Journal of Neurophysiology 80 (3): 1605-1608.
  • Li, D. and M. L. M. Lim. 2005. Ultraviolet cues affect the foraging behaviour of jumping spiders. Animal Behaviour 70: 771- 776.
  • Li, J., Z. Zhang, F. Liu, Q. Liu, W. Gan, J. Chen, M. L. M. Lim and D. Li. 2008. UVB-based mate choice cues used by females of the jumping spider Phintella vittata. Current Biology 18: 699-703.
  • Lim, M. L. M. 2006. UV vision in jumping spiders (Araneae: Salticidae): sexual selection and foraging behaviour. Ph.D. Thesis, National University of Singapore: i-xv, 1-258.
  • Lim, M. L. M. and D. Li. 2006a. Behavioural evidence of UV sensitivity in jumping spiders (Araneae: Salticidae). Journal of Comparative Physiology A 192: 871-878.
  • Lim, M. L. M. and D. Li. 2006b. Extreme ultraviolet sexual dimorphism in jumping spiders (Araneae: Salticidae). Biological Journal of the Linnean Society 89: 397-406.
  • Lim, M. L. M., J. Li and D. Li. 2007. Effect of UV-reflecting markings on female mate-choice decisions in Cosmophasis umbratica, a jumping spider from Singapore. Behavioral Ecology 19 (1): 61-66.
  • Liu, Y., A. Maas and D. Waloszek. 2009. Early development of the anterior body region of the grey widow spider Latrodectus geometricus Koch, 1841 (Theridiidae, Araneae). Arthropod Structure & Development 38: 401-416.
  • Locket, N. A. 1992. Problems of deep foveas. Australian and New Zealand Journal of Opthalmology 20 (4): 281-295.
  • Long, S. M. 2016. Spider brain morphology & behavior. Ph.D. dissertation, University of Massachusetts, Amherst: i-xxiii, 1- 215.
  • Lucas, H. 1846. Histoire naturelle des animaux articuleDs. In: Exploration scientifique de l'AlgeDrie pendant les anneDes 1840, 1841, 1842 publieDe par ordre du Gouvernement et avec le concours d'une commission acadeDmique. Aris, Sciences physiques, Zoologie 1: 89-271, pl. 1-17.
  • Maddison, W. P. 2009. New cocalodine jumping spiders from Papua New Guinea (Araneae: Salticidae: Cocalodinae). Zootaxa 2021: 1-22.
  • Maddison, W. P. 2012. Five new species of lapsiine jumping spiders from Ecuador (Araneae: Salticidae). Zootaxa 3424: 51-65.
  • Maddison, W. P. and M. Hedin. 2003. Jumping spider phylogeny (Araneae: Salticidae). Invertebrate Systematics 17: 529- 549.
  • Martin, G. 2017. Sensory Ecology of Birds. Oxford University Press.
  • Martin, G. R. and I. E. Gordon. 1975. Visual acuity in the Tawny Owl (Strix aluco). Vision Research 14: 1393-1397.
  • Masland, R. H. 2001. The fundamental plan of the retina. Nature Neuroscience 4 (9): 877-886.
  • Masland, R. H. 2011. Cell populations of the retina: The Proctor Lecture. Investigative Opthalmology and Visual Science 52 (7): 4581-4591.
  • McCourt, M. E. 1982. A spatial-frequency dependent grating-induction effect. Vision Research 22: 119-134.
  • Meier, F. 1967. Beitrage zur Kenntnis der postembryonalen Entwicklung der Spinnen (Araneida, Labidognatha) unter besonderer Berucksichtigung der Histogenese des Zentralnervensystems. Revue Suisse de Zoologie 74: 1-114.
  • Melin, A. D., D. W. Kline, C. Hiramatsu and T. Caro. 2016. Zebra stripes through the eyes of their predators, zebras, and humans. PLOS One (DOI:10.1371/journal.pone.0145679): 1-18.
  • Menda, G., P. S. Shamble, E. I. Nitzany, J. R. Golden and R. R. Hoy. 2014. Visual perception in the brain of a jumping spider. Current Biology 24: 2580-2585.
  • Mikellidou, K. and P. Thompson. 2013. The vertical-horizontal illusion: assessing the contributions of anisotropy, abutting, and crossing to the misperception of simple line stimuli. Journal of Vision 13 (8)(7): 1-11.
  • Miller, P. E. 2001. Vision in animals - What do dogs and cats see? Waltham/OSU Symposium, Small Animal Opthalmology, online at: https://www.vin.com/apputil/content/defaultadv1.aspx?pId=11132&id=3844144
  • Miller, P. E. and C. J. Murphy. 1995. Vision in dogs. Journal of the American Veterinary Medical Association 207 (12): 1623- 1634.
  • Millot, Jacques. 1949. Ordre des araneides (Araneae). In: Traite de Zoologie, ed. P. Grasse, 6: 589-743.
  • Monnier, P. and S. K. Shevell. 2003. Large shifts in color appearance from patterned chromatic backgrounds. Nature Neuroscience 6: 801-802.
  • Morehouse, N. I., D. B. Zurek, L. A. Taylor, T. Cronin. 2017a. Repeated evolution of color vision underlies rapid diversification of salticid male coloration. In: Proceedings of the Abstract of the Annual Meeting of SICB, New Orleans, LA, USA, 4-8 January 2017.
  • Morehouse, N. I., E. K. Buschbeck, D. B. Zurek, M. Steck and M. L. Porter. 2017b. Molecular evolution of spider vision: new opportunities, familiar players. Biological Bulletin 233: 21-38.
  • Murphy, A. D. 2001. The neuronal basis of feeding in the snail, Helisoma, with comparisons to selected gastropods. Progress in Neurobiology 63 (4): 383-408.
  • Nagata, T., K. Arikawa and M. Kinoshita. 2019. Photoreceptor projection from a four-tiered retina to four distinct regions of the first optic ganglion in a jumping spider. Journal of Comparative Neurology 527: 1346-1361.
  • Nagata, T., M. Koyanaga, H. Tsukamoto, S. Saeki, K. Isono, Y. Shichida, F. Tokunaga, M. Kinoshita, K. Arikawa and A. Terakita. 2012. Depth perception from image defocus in a jumping spider. Science 335: 469-471, supporting material online at www.sciencemag.org/cgi/content/full/335/6067/469/DC1
  • Nagata, T., M. Koyanaga, H. Tsukamoto and A. Terakita. 2010. Identification and characterization of a protostome homologue of peropsin from a jumping spider. Journal of Comparative Physiology A 196: 51-59.
  • Nakamura, T. and S. Yamashita. 2000. Learning and discrimination of colored papers in jumping spiders (Araneae, Salticidae). Journal of Comparative Physiology A 186: 897-901.
  • Nakano, M., C. M. Lockhart, E. J. Kelly and A. E. Rettle. 2014 . Ocular cytochrome P450s and transporters: roles in disease and endobiotic and xenobiotic disposition. Drug Metabolism Reviews, Informa Healthcare (ISSN 1097-9883): 1-14.
  • Nelson, X. J. 2010. Visual cues used by ant-like jumping spiders to distinguish conspecifics from their models. The Journal of Arachnology 38: 27-34.
  • Nelson, X. J. 2021. Visual processing in a unique modular system. Posted online at: https://www.ximenanelson.com/spidervision.html, accessed 12 DEC 2021: 1-6.
  • Nelson, X. J. and R. R. Jackson. 2007. Vision-based ability of an ant-mimicking jumping spider to discriminate between models, conspecific individuals and prey. Insectes Sociaux 54: 1-4.
  • Nelson, X. J. and R. R. Jackson. 2009. Prey classification by an araneophagic ant-like jumping spider (Araneae: Salticidae). Journal of Zoology 279: 173-179.
  • Ninio, J. and K. A. Stevens. 2000. Variations on the Hermann grid: an extinction illusion. Perception 29 (10): 1209-1217.
  • Nolte, A. 2015. Lab report: Investigating jumping spider vision. Published online at: https://www.esa.int/gsp/ACT/doc/ BIO/AlekeNolte_FinalReport.pdf
  • Nolte, A., D. Hennes, D. Izzo, C. Blum, V. V. Hafner and T. Gheysens. 2017. A note on the depth-from-defocus mechanism of jumping spiders. Biomimetics 2 (3): 1-14.
  • Oberdorfer, M. D. 1975. The neural organization of the first optic ganglion of the principal eyes of jumping spiders (Salticidae). Journal of Comparative Neurology 174: 95-118.
  • Otto, J. C. and D. E. Hill. 2012. Contests between male Maratus vespertilio (Simon 1901) (Araneae: Salticidae). Peckhamia 98.1: 1-17.
  • Otto, J. C. and D. E. Hill. 2016. Seven new peacock spiders from Western Australia and South Australia (Araneae: Salticidae: Euophryini: Maratus). Peckhamia 141.1: 1-101.
  • Patterson, S. S., M. Neitz and J. Neitz. 2021. Seminars in Cell and Developmental Biology (https://doi.org/10.1016/ j.semcdb. 2021.05.004): 1-4.
  • Peaslee, A. G. and G. Wilson. 1989. Spectral sensitivity in jumping spiders (Araneae, Salticidae). Journal of Comparative Physiology A 164: 359-363.
  • Peckham, G. W., and E. G. Peckham. 1883. Descriptions of new or little known spiders of the family Attidae from various parts of the United States of North America. Milwaukee. 1-35.
  • Peckham, G. W., and E. G. Peckham. 1885. On some new genera and species of Attidae from the eastern part of Guatamala. Proceedings of the Natural History Society of Wisconsin 1885: 62-86.
  • Peckham, G. W., and E. G. Peckham. 1888. Attidae of North America. Transactions of the Wisconsin Academy of Sciences, Arts and Letters 7: 1-104.
  • Peckham, G. W., and E. G. Peckham. 1895. The sense of sight in spiders with some observations on the color sense. Transactions of the Wisconsin Academy of Sciences, Arts, and Letters 10: 231-261.
  • Peters, H. M. 1969. Maturing and coordination of webbuilding activity. American Zoologist 9: 223-227.
  • Pichaud, F., A. Briscoe and C. Desplan. 1999. Evolution of color vision. Current Opinion in Neurobiology 9: 622-627.
  • Pickard-Cambridge, F. O. 1901. Arachnida - Araneida and Opiliones. In: Biologia Centrali-Americana, Zoology. London 2: 193-312.
  • Pickard-Cambridge, O. 1869. Descriptions and sketches of some new species of Araneida, with characters of a new genus. Annals and Magazine of Natural History (4) 3 (13): 52-74, pl. 4-6.
  • Poggio, T., M. Fahle and S. Edelman. 1992. Fast perceptual learning in visual hyperacuity. Science 256 (5059): 1018-1021.
  • Pridmore, R. W. 2013. Cone receptor sensitivities and unique hue chromatic responses: correlation and causation imply the physiological basis of unique hues. PLOS One 8 (10): e77134: 1-13.
  • Pringle, J. W. S. 1955. The function of the lyriform organs of arachnids. Journal of Experimental Biology 32: 270-278.
  • Pumphrey, R. J. 1948. The theory of the fovea. The Journal of Experimental Biology 25: 299-312.
  • Quesada, R., E. Triana, G. Vargas, J. K. Douglass, M. A. Seid, J. E. Niven, W. G. Eberhard and W. T. Wcislo. 2011. The allometry of CNS size and consequences of miniaturization in orb-weaving and cleptoparasitic spiders. Arthropod Structure and Development 40 (6): 521-529.
  • Rempel, J. G. 1957. The embryology of the black widow spider, Latrodectus mactans (Fabr.). Canadian Journal of Zoology 35: 35-74.
  • Reissland, A. and P. Gorner. 1985. Trichobothria. Chapter VIII in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 138-161.
  • Reymond, L. 1985. Spatial visual acuity of the eagle Aquila audax: a behavioural, optical and anatomical investigation. Vision Research 25: 1477-1491.
  • Richman, D. B. 1982. Epigamic display in jumping spiders (Araneae, Salticidae) and its use in systematics. Journal of Arachnology 10: 47-67.
  • Richman, D. B. and R. R. Jackson. 1992. A review of the ethology of jumping spider (Araneae, Salticidae). Bulletin of the British Arachnological Society 9 (2): 33-37.
  • Robinson, M. H. and C. E. Valerio. 1977. Attacks on large or heavily defended prey by tropical salticid spiders. Psyche 84 (1, 048480): 1-10.
  • Root, T. M. 1985. The central and peripheral organization of scorpion locomotion. Chapter XVII in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 337-347.
  • Rosenzweig, M. R., S. M. Breedlove and A. L. Leiman. 2002. Biological Psychology. Third Edition. Sinauer Associates, Inc. Sunderland, Massachusetts. i-xx, 1-651, A1-A8, G1-G26, R1-R36, AI1-AI7, I1-I12, IC1-IC2.
  • Ross, C. F. 2004. The tarsier fovea: functionless vestige or nocturnal adaptation? Chapter 19 in: Anthropoid Origins: New Visions (Advances in Primatology), eds. C. F. Ross and R. F. Kay, Kluwer/Plenum: 1-747.
  • Roth, L. S. V., A. Balkenius and A. Kelber. 2007. Colour perception in a dichromat. The Journal of Experimental Biology 210: 2795-2800.
  • Saint Remy, G. 1890. Contribution ahl'eDtude du cerveau chez les Arthropodes tracheDates. Thehse preDsenteDahla FaculteDdes Sciences de Paris. 1-274, pl. 1-14.
  • Scheiner, R., A. Weiss, D. Malun and J. Erber. 2001. Learning in honey bees with brain lesions: how partial mushroom-body ablations affect sucrose responsiveness and tactile antennal learning. Animal Cognition 4: 227-235.
  • Scheuring, L. 1914. Die Augen der Arachnoideen II. Zoologische JahrbuNcher. Abteilung fuNr Anatomie und Ontogenie der Tiere 37: 369-464.
  • Schmidt, B. P., M. Neitz and J. Neitz. 2014. Neurobiological hypothesis of color appearance and hue perception. Journal of the Optical Society of America, A, Optics, Image Science, and Vision 31 (4): A195-A207.
  • Schrauf, M., B. Lingelbach and E. R. Wist. 1997. The scintillating grid illusion. Vision Research. 37 (8): 1033-1038.
  • Schwager, E. E. 2008. Segmentation of the spider Achaearanea tepidariorum investigated by gene expression and functional analysis of the gap gene hunchback. Ph.D. dissertation, UniversitaNt zu KoNln: i-viii, 1-181.
  • Schwager, E. E., M. Schoppmeier, M. Pechmann and W. G. M. Damen. 2007. Duplicated Hox genes in the spider Cupiennius salei. Frontiers in Zoology 4 (10): 1-11.
  • Seyfarth, E.-A. 1978. Lyriform slit sense organs and muscle reflexes in the spider leg. Journal of Comparative Physiology 125: 45-57.
  • Seyfarth, E.-A. 1985. Spider proprioception: receptors, reflexes, and control of locomotion. Chapter XII in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 231-248.
  • Seyfarth, E.-A. and F. G. Barth. 1972. Compound slit sense organs on the spider leg: mechanoreceptors involved in kinesthetic orientation. Journal of Comparative Physiology 78: 176-191.
  • Seyfarth, E.-A., W. Gnatzy and K. Hammer. 1990. Coxal hair plates in spiders: physiology, fine structure, and specific central projections. Journal of Comparative Physiology A, 166 (5): 633-642.
  • Seyfarth, E.-A. and H. J. Pfluger. 1984. Proprioceptor distribution and control of a muscle reflex in the tibia of spider legs. Journal of Neurobiology 15: 365- 374.
  • Shamble, P. S., G. Menda, J. R. Golden, E. I. Nitzany, K. Walden, T. Beatus, D. O. Elias, I. Cohen, R. N. Miles and R. R. Hoy. 2016. Airborne acoustic perception by a jumping spider. Current Biology 26: 1-8.
  • Shapley, R. and M. Hawken. 2002. Neural mechanisms for color perception in the primary visual cortex. Current Opinion in Neurobiology 12: 426-432.
  • Shepeleva, I. P. 2022. A comparative analysis of the camera-like eyes of jumping spiders and humans. Vision 6 (2): 1-16 (https://doi.org/10.3390/vision6010002).
  • Sherman, R. G. 1985. Neural control of the heartbeat and skeletal muscle in spiders and scorpions. Chapter XVI in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 319-336.
  • Sherman, R. G., C. R. Bursey, C. R. Fourtner and R. A. Pax. 1969. Cardiac ganglia in spiders (Arachnida: Araneae). Experientia 25: 438-439.
  • Sherman, R. G. and R. A. Pax. 1967. A physiological and morphological study of a spider heart. American Zoologist 7: 190- 191.
  • Sherman, R. G. and R. A. Pax. 1968. The heartbeat of the spider, Geolycosa missouriensis. Comparative Biochemistry and Physiology 26: 529-536.
  • Simon, E. 1868. Monographie des espehces europeDennes de la famille des Attides (Attidae Sundewall. - Saltigradae Latreille). Annales de la SocieDteDEntomologique de France (4) 8: 11-72, 529-726, pl. 5-7.
  • Simon, E. 1885. MateDriaux pour servir ahla faune arachnologiques de l'Asie meDridionale. I. Arachnides recueillis ahWagra- Karoor prehs Gundacul, district de Bellary par M. M. Chaper. II. Arachnides recueillis ahRamnad, district de Madura par M. l'abbeDFabre. Bulletin de la SocieDteDZoologique de France 10: 1-39, pl. 10.
  • Simon, E. 1900. Descriptions d'arachnides nouveaux de la famille des Attidae. Annales de la SocieDteDEntomologique de Belgique, 44: 381-407.
  • Simon, E. 1901. Histoire naturelle des araigneDes. Deuxiehme eDdition, tome second. Roret, Paris: 381-668.
  • Sivertsen, D. W. 1989. The physiology of high-order visual neurons in the jumping spider (Salticidae) and the vocalizations of free ranging owl monkeys. Ph.D. dissertation, California Institute of Technology: i-ix, 1-140.
  • Snyder, A. W. and W. H. Miller. 1978. Telephoto lens system of falconiform eyes. Nature 275 (5676): 127-129.
  • Solomon, S. G. and P. Lennie. 2007. The machinery of colour vision. Nature Reviews, Neuroscience 8: 276-286.
  • Spano, L, L. M. Long and E. M. Jakob. 2012. Secondary eyes mediate the response to looming objects in jumping spiders (Phidippus audax, Salticidae). Biology Letters 8 (6): 949-951.
  • Steinhoff, P. O. M., A. Sombke, J. Liedtke, J. M. Schneider, S. Harzsch, and G. Uhl. 2017. The synganglion of the jumping spider Marpissa muscosa (Arachnida: Salticidae): insights from histology, immunohistochemistry and microCT analysis. Arthropod Structure and Development 46 (2): 156-170.
  • Steinhoff, P. O. M., G. Uhl, S. Harzsch aand A. Sombke. 2020. Visual pathways in the brain of the jumping spider Marpissa muscosa. Journal of Comparative Neurology 2020 (https://doi.org.10.1002/cne.24862): 1-20.
  • Stong, C. L. 1974. The Amateur Scientist. How to create visual illusions. Scientific American 231 (5): 126.
  • Strausfield, N. J., P. Weltzien and F. G. Barth. 1993. Two visual systems in one brain: neuropils serving the principal eyes of the spider Cupiennius salei. The Journal of Comparative Neurology 328 (1): 63-75.
  • Surridge, A. K., D. Osorio and N. I. Mundy. 2003. Evolution and selection of trichromatic vision in primates. Trends in Ecology and Evolution 18 (4): 198-205.
  • Szuts, T. and N. Scharff. 2009. Revision of the living members of the genus Tomocyrba Simon, 1900 (Araneae: Salticidae). Contributions to Natural History 12: 1337-1372.
  • Taylor, P. W., O. Hasson and D. L. Clark. 2000. Body postures and patterns as amplifiers of physical condition. Proceedings of the Royal Society, London B 267: 917-922
  • Taylor, P. W., O. Hasson and D. L. Clark. 2001. Initiation and resolution of jumping spider contests: roles for size, proximity, and early detection of rivals. Behavioral Ecology and Sociobiology 50: 403-413.
  • Taylor, P. W., R. R. Jackson and M. W. Robertson. 1998. A case of blind spider's buff?: prey-capture by jumping spiders (Araneae, Salticidae) in the absence of visual cues. The Journal of Arachnology 26: 369-381.
  • Telford, M. J. and R. H. Thomas. 1998. Expression of homeobox genes shows chelicerate arthropods retain their deutocerebral segment. Proceedings of the National Academy of Sciences, USA 95: 10671-10675.
  • Terakita, A. and T. Nagata. 2014. Functional properties of opsins and their contribution to light-sensing physiology. Zoological Science 31: 653-659.
  • Thorell, T. 1881. Studi sui Ragni Malesi e Papuani. III. Ragni dell'Austro Malesia e del Capo York, conservati nel Museo civico di storia naturale di Genova. Annali del Museo Civico di Storia Naturale di Genova 17: 1-720.
  • Thoreson, W. B. and D. M. Dacey. 2019. Diverse cell types, circuits, and mechanism for color vision in the vertebrate retina. Physiology Reviews 99: 1527-1573.
  • Tork, P. 2019. Pathways of ocular entrainment in Marpissa marina (Araneae, Salticidae). New Zealand Journal of Zoology 46 (4): 321-333.
  • Tucker, V. A. 2000. The deep fovea, sideways vision and spiral flight paths in raptors. The Journal of Experimental Biology 203: 3745-3754.
  • Tuthill, J. C., M. E. Chiappe and M. B. Reiser. 2011. Neural correlates of illusory motion perception in Drosophila. Proceedings of the National Academy of Science, USA 108 (23): 9685-9690.
  • Veilleux, C. C. and E. C. Kirk. 2014. Visual acuity in mammals: effects of eye size and ecology. Brain, Behavior and Evolution 83: 43-53.
  • Walckenaer, C. A. 1837. Histoire naturelle des insectes Aptehres. Tome premier. Roret, Paris: 1-682, pl. 1-15.
  • Walcott, C. 1969. A spider's vibration receptor: it's anatomy and physiology. American Zoologist 9: 133-144.
  • Walls, G. L. 1937. Significance of the foveal depression. Archives of Opthalmology 18: 912-919.
  • Wanless, F. R. 1981. A revision of the spider genus Phaecius (Araneae: Salticidae). Bulletin of the British Museum of Natural History, Zoology 41: 199-212.
  • Wanless, F. R. 1982. A revision of the spider genus Cocalodes with a description of a new related genus (Araneae: Salticidae). Bulletin of the British Museum of Natural History, Zoology 42: 263-298.
  • Wesolowska, W. 1981. Salticidae (Aranei) from North Korea, China and Mongolia. Annales Zoologici, Warszawa 36: 45-83.
  • Westheimer G. L. 1981. Visual hyperacuity. In: Progress in Sensory Physiology, vol. 1, eds. H. Autrum, E. R. Perl, R. F. Schmidt and D. Ottoson, Springer, Berlin, Heidelberg.
  • Westheimer, G. L. 2010. Visual acuity and hyperacuity. Chapter 4 in: Handbook of Optics, Third Edition: 4.1-4.17, online at: https://cgvr.cs.uni-bremen.de/teaching/cg_literatur/visual_acuity.pdf
  • Williams, D. S. and P. McIntyre. 1980. The principal eyes of a jumping spider have a telephoto component. Nature 288: 578- 580.
  • Winkler, P. 2010. The nerve cells of the retina. The Science Journal of the Lander College of Arts and Sciences 3 (1): 78-94.
  • Wu, C. Q. 2010. A neuroanatomically-based model for human color vision. BMC Neuroscience 11. Supplement 1 (P143): 1-2.
  • Yaginuma, T. 1967. Three new spiders (Argiope, Boethus and Cispius) from Japan. Acta Arachnologica 20: 50-64.
  • Yamashita, S. 1985. Photoreceptor cells in the spider eye: spectral sensitivity and efferent control. Chapter VI in: Neurobiology of Arachnids, ed. F. G. Barth, Springer-Verlag: 103-117.
  • Yamashita, S. and H. Tateda. 1976. Spectral sensitivities of jumping spider eyes. Journal of Comparative Physiology 105: 29- 41.
  • Yamashita, S. and H. Tateda. 1978. Spectral sensitivities of the anterior median eyes of the orb web spiders Argiope bruennichii and A. amoena. Journal of Experimental Biology 74: 47-57.
  • Yan, W., M. A. Laboulaye, N. M. Tran, I. E. Whitney, I. Benhar and J. R. Sanes. 2020. Mouse retinal cell atlas: molecular identification of over sixty amacrine cell types. The Journal of Neuroscience 40 (27): 5177-5195.
  • Young, T. 1802. Bakerian lecture: On the theory of light and colours. Philosophical Transactions of the Royal Society, London 92: 12-48.
  • Zhang, J. X. and W. P. Maddison. 2012. New euophryine jumping spiders from Southeast Asia and Africa (Araneae: Salticidae: Euophryinae). Zootaxa 3581: 53-80.
  • Zurek, D. B. 2012. The function of the anterior lateral eyes in the modular vision system of jumping spiders (Araneae, Salticidae). Ph.D. dissertation, Macquarie University: i-xi, 1-152.
  • Zurek, D. B., T. W. Cronin, L. A. Taylor, K. Byrne, M. L. G. Sullivan and N. I. Morehouse. 2015. Spectral filtering enables trichromatic vision in colorful jumping spiders. Current Biology 25: R403-R404.
  • Zurek, D. B. and X. J. Nelson. 2012a. Saccadic tracking of targets mediated by the anterior-lateral eyes of jumping spiders. Journal of Comparative Physiology A 198 (6): 411-417.
  • Zurek, D. B. and X. J. Nelson. 2012b. Hyperacute motion detection by the lateral eyes of jumping spiders. Vision Research 66: 26-30.
  • Zurek, D. B., A. J. Taylor, C. S. Evans and X. J. Nelson. 2010. The role of the anterior lateral eyes in the vision-based behaviour of jumping spiders. The Journal of Experimental Biology 213: 2372-2378.