Vision in avian emberizid foragers: maximizing both binocular vision and fronto-lateral visual acuity

Moore, Bret A.; Pita, Diana; Tyrrell, Luke P.; Fernández‐Juricic, Esteban

doi:10.1242/jeb.108613

Cited by 40 publications

(44 citation statements)

References 74 publications

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“…This finding has important implications for the study of avian visual fields (e.g. Martin, 2014;Moore et al, 2015). From a functional perspective, our results mean that when birds diverge their eyes to reduce the size of their blind areas in order to increase visual coverage, the visual fields may not be as wide as previously reported in the literature.…”

Section: −1supporting

confidence: 55%

“…Eye saccades are used not only to relocate gaze but also to modify the configuration of the visual field. For example, birds can converge their eyes to increase the degree of binocular overlap in front of the head (Martin, 1986), which could have consequences for foraging behavior (Moore et al, 2015). Divergent eye saccades reduce the size of the blind area behind the head, increasing visual coverage around the head (Martin, 1986) and hence the chances of detecting threats (Fernández-Juricic et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

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Oculomotor strategy of an avian ground forager: tilted and weakly yoked eye saccades

Tyrrell

Butler

Fernández‐Juricic

2015

Journal of Experimental Biology

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Many bird species are capable of large saccadic eye movements that can result in substantial shifts in gaze direction and complex changes to their visual field orientation. In the absence of visual stimuli, birds make spontaneous saccades that follow an endogenous oculomotor strategy. We used new eye-tracking technology specialized for small birds to study the oculomotor behavior of an open-habitat, groundforaging songbird, the European starling (Sturnus vulgaris). We found that starlings primarily move their eyes along a tilted axis 13.46 deg downwards anteriorly and upwards posteriorly, which differs from the axis parallel to the horizon employed by other species. This tilted axis could enhance foraging and anti-predator strategies while starlings are head-down looking for food, allowing them to direct vision between the open mandibles to visually inspect food items, and above and behind the head to scan areas where predators are more likely to attack. We also found that starlings have neither fully conjugate saccades (as in humans, for example) nor independent saccades (as in chameleons, for example). Rather, they exhibit weakly yoked saccades where the left and right eyes move at the same time but not at the same magnitude. Functionally, weakly yoked saccades may be similar to independent saccades in that they allow the two eyes to concomitantly perform different tasks. The differences between the oculomotor strategies of studied species suggest eye movements play variable but important roles across bird species with different ecological niches.

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Section: −1supporting

confidence: 55%

Section: Introductionmentioning

confidence: 99%

Oculomotor strategy of an avian ground forager: tilted and weakly yoked eye saccades

Tyrrell

Butler

Fernández‐Juricic

2015

Journal of Experimental Biology

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“…The position of these specializations in the retina reveals which part or parts of the visual field are sampled with increased spatial resolving power (SRP) and are thus of particular importance for survival tasks such as location of food and mates, predator surveillance, and obstacle avoidance. In addition to our aforementioned studies, recently a large number of retinal topography studies have revealed important information about retinal organization and evolution in a wide range of birds including waterfowl [Fernández-Juricic et al, 2011a;Lisney et al, 2013a], pen-guins [Coimbra et al, 2012], parrots [Coimbra et al, 2014a], and a variety of passerines [Coimbra et al, 2006[Coimbra et al, , 2009Fernández-Juricic et al, 2011a;Moore et al, 2013Moore et al, , 2015Coimbra et al, 2014b]. Here, as well as providing detailed descriptions of eye morphology and retinal topography in a range of hummingbird species, we tested the following two predictions.…”

Section: Introductionmentioning

confidence: 94%

“…Moroney and Pettigrew, 1987;Fernández-Juricic et al, 2011b;Lisney et al, 2013b;Moore et al, 2013Moore et al, , 2015Krabichler et al, 2015]. Recently, however, Coimbra et al [2014aCoimbra et al [ , b, 2015 pointed out that this approach is problematic.…”

Section: Spatial Resolving Powermentioning

confidence: 99%

“…Although we do not have direct evidence to support this, the central area in A. tzacatl and P. superciliosus may also contain a shallow fovea, which we were not able to detect in whole mounts for these species. Support for this suggestion comes from the fact that the presence of a central fovea is a very common feature in the retinas of a diverse range of birds, including pigeons [Binggeli and Paule, 1969;Querubin et al, 2009], kingfishers [Slonaker, 1897;Moroney and Pettigrew, 1987], terns [Slonaker, 1897;Fite and Rosenfield-Wessels, 1975], swallows [Slonaker, 1897], passerines [Slonaker, 1897;Fite and RosenfieldWessels, 1975;Coimbra et al, 2006Coimbra et al, , 2009Coimbra et al, , 2014bMoore et al, 2013Moore et al, , 2015, parrots [Coimbra et al, 2014a], falcons, eagles, and vultures [Slonaker, 1897;Fite and RosenfieldWessels, 1975;Frost et al, 1990;Inzunza et al, 1991;Lisney et al, 2013b]. In addition, the presence of a second, temporally located area of peak density (which may or may not be foveated) has been reported in many of the groups of birds mentioned above.…”

Section: Topography Of Neurons In the Rgc Layermentioning

confidence: 99%

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Eye Morphology and Retinal Topography in Hummingbirds (Trochilidae: Aves)

Lisney

Wylie²,

Kolominsky³

et al. 2015

Brain Behav Evol

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Hummingbirds are a group of small, highly specialized birds that display a range of adaptations to their nectarivorous lifestyle. Vision plays a key role in hummingbird feeding and hovering behaviours, yet very little is known about the visual systems of these birds. In this study, we measured eye morphology in 5 hummingbird species. For 2 of these species, we used stereology and retinal whole mounts to study the topographic distribution of neurons in the ganglion cell layer. Eye morphology (expressed as the ratio of corneal diameter to eye transverse diameter) was similar among all 5 species and was within the range previously documented for diurnal birds. Retinal topography was similar in Amazilia tzacatl and Calypte anna. Both species had 2 specialized retinal regions of high neuron density: a central region located slightly dorso-nasal to the superior pole of the pecten, where densities reached ∼45,000 cells·mm^-2, and a temporal area with lower densities (38,000-39,000 cells·mm^-2). A weak visual streak bridged the two high-density areas. A retina from Phaethornis superciliosus also had a central high-density area with a similar peak neuron density. Estimates of spatial resolving power for all 3 species were similar, at approximately 5-6 cycles·degree^-1. Retinal cross sections confirmed that the central high-density region in C. anna contains a fovea, but not the temporal area. We found no evidence of a second, less well-developed fovea located close to the temporal retina margin. The central and temporal areas of high neuron density allow for increased spatial resolution in the lateral and frontal visual fields, respectively. Increased resolution in the frontal field in particular may be important for mediating feeding behaviors such as aerial docking with flowers and catching small insects.

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