Sensory systems in birds: What we have learned from studying sensory specialists

Iwaniuk, Andrew N.; Wylie, Douglas R.

doi:10.1002/cne.24896

Cited by 14 publications

(11 citation statements)

References 157 publications

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“…Birds such as crows even use elaborate head-beak movements to build and use tools (Weir et al, 2002;Bird and Emery, 2009). Such coordinated actions require acute senses (Iwaniuk and Wylie, 2020), but most of all delicate motor planning and motor execution capabilities (Davies and Green, 1994;Brecht et al, 2019). With the exception of birdsong research, a research area that resulted in detailed knowledge on the neuroanatomy and neurophysiology of song production (Elemans, 2014;Schmidt and Wild, 2014;Murphy et al, 2017;Kersten et al, 2021), and despite the solid understanding of the neuroanatomy of the avian motor system (Dubbeldam, 2000), the neurophysiological mechanisms of motor plans and actions are rarely explored in birds.…”

Section: Introductionmentioning

confidence: 99%

Neural Code of Motor Planning and Execution during Goal-Directed Movements in Crows

Rinnert

Nieder

2021

J. Neurosci.

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The planning and execution of head-beak movements are vital components of bird behavior. They require integration of sensory input and internal processes with goal-directed motor output. Despite its relevance, the neurophysiological mechanisms underlying action planning and execution outside of the song system are largely unknown. We recorded single-neuron activity from the associative endbrain area nidopallium caudolaterale (NCL) of two male carrion crows (Corvus corone) trained to plan and execute head-beak movements in a spatial delayed response task. The crows were instructed to plan an impending movement toward one of eight possible targets on the left or right side of a touchscreen. In a fraction of trials, the crows were prompted to plan a movement toward a self-chosen target. NCL neurons signaled the impending motion direction in instructed trials. Tuned neuronal activity during motor planning categorically represented the target side, but also specific target locations. As a marker of intentional movement preparation, neuronal activity reliably predicted both target side and specific target location when the crows were free to select a target. In addition, NCL neurons were tuned to specific target locations during movement execution. A subset of neurons was tuned during both planning and execution period; these neurons experienced a sharpening of spatial tuning with the transition from planning to execution. These results show that the avian NCL not only represents high-level sensory and cognitive task components, but also transforms behaviorally-relevant information into dynamic action plans and motor execution during the volitional perception-action cycle of birds.

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Section: Introductionmentioning

confidence: 99%

Neural Code of Motor Planning and Execution during Goal-Directed Movements in Crows

Rinnert

Nieder

2021

J. Neurosci.

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“…That dromornithids have large, forward facing eyes (see Section 4.4.2.1), robust optic nerves (see Section 3.1.2), and enlarged morphology of trigeminal (V) innervation (see Section 4.4.1), further supports our argument that dromornithids were likely diurnal taxa with a strong reliance on stereopsis and trigeminal (V) somatosensory input. These results also suggest that caution is required when deriving functional or behavioural inference from comparisons of optic lobe absolute size, without accounting for the collective morphology of somatosensory "circuits" (e.g., [150] (p. 9)), such as those of the thalamofugal, tectofugal and third visual pathways (see Section 4.4.2).…”

Section: Optic Lobementioning

confidence: 99%

“…Furthermore, stereotyped species-specific behaviour [93,148], pecking accuracy [149], and the processing of visual information such as brightness, colour, and pattern discrimination [118], have been attributed to processes within the caudolateral telencephalon. Pettigrew and Frost [130] showed that the maxillary (V 2 ) division of the trigeminal (V) nerve, which innervates the upper bill (see Section 4.4.1 above), transmits to extensive terminal fields in the region of the rostrodorsal mesopallium (e.g., [150] (Figure 3b), see also [139]). Similarly, Dubbeldam et al [99] showed that ascending maxillary (V 2 ) and mandibular (V 3 ) trigeminal (V) projections transmitted rostrodorsally, via the nucleus basalis, to mesopallial terminal fields [140].…”

Section: Cerebrummentioning

confidence: 99%

“…These sensorimotor and somatosensory projections were related to the "detection" of food particles, particularly in low-visibility feeding in anseriforms [151][152][153][154], and food grasping in columbiforms [140,155] and passeriforms [156]. Located in the caudal telencephalon, the medial spiriform nucleus receives projections from both somatosensory and visual parts of the wulst (see [121]; and Section 4.4.2.1 above), along with arcopallial projections associated with "motor planning information" from the caudoventral telencephalon, and projects to the cerebellum (see Section 4.4.2.4 below), forming the "telencephalic-cerebellar loop" (sensu [150] (p. 9)).…”

Section: Cerebrummentioning

confidence: 99%

“…Hellmann et al [158] (p. 395) characterised the optic lobe as a "relay station" for transmitting ascending visual output to the forebrain (see Section 4.4.2.1 above), projecting descending output to the premotor regions of the hindbrain (see Section 4.4.2.4 below), and comprise multiple "retinotopically organised, and functionally specific" cell types. So called "optic flow" (sensu [159]), are retinal stimuli generated by self-motion through stationary environments (see [150,160] and references therein). Optic flow stimuli are analysed by recipient nuclei in the accessory optic system and pretectum, wherein the lentiformis mesencephali, or pretectal nucleus, responds to "moving large-field" visual stimuli and generates optokinetic response for the control of posture, eye movement stabilisation, and compensatory movement during locomotion ( [117,150,[160][161][162][163][164] and references therein), facilitated by processes within the cerebellum [87,165].…”

Section: Optic Lobementioning

confidence: 99%

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Endocranial Anatomy of the Giant Extinct Australian Mihirung Birds (Aves, Dromornithidae)

Handley

Worthy

2021

Diversity

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Dromornithids are an extinct group of large flightless birds from the Cenozoic of Australia. Their record extends from the Eocene to the late Pleistocene. Four genera and eight species are currently recognised, with diversity highest in the Miocene. Dromornithids were once considered ratites, but since the discovery of cranial elements, phylogenetic analyses have placed them near the base of the anseriforms or, most recently, resolved them as stem galliforms. In this study, we use morphometric methods to comprehensively describe dromornithid endocranial morphology for the first time, comparing Ilbandornis woodburnei and three species of Dromornis to one another and to four species of extant basal galloanseres. We reveal that major endocranial reconfiguration was associated with cranial foreshortening in a temporal series along the Dromornis lineage. Five key differences are evident between the brain morphology of Ilbandornis and Dromornis, relating to the medial wulst, the ventral eminence of the caudoventral telencephalon, and morphology of the metencephalon (cerebellum + pons). Additionally, dromornithid brains display distinctive dorsal (rostral position of the wulst), and ventral morphology (form of the maxillomandibular [V2+V3], glossopharyngeal [IX], and vagus [X] cranial nerves), supporting hypotheses that dromornithids are more closely related to basal galliforms than anseriforms. Functional interpretations suggest that dromornithids were specialised herbivores that likely possessed well-developed stereoscopic depth perception, were diurnal and targeted a soft browse trophic niche.

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Comparison of vertebrate skin structure at class level: A review

Akat

Yenmiş

Pombal

et al. 2022

The Anatomical Record

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The skin is a barrier between the internal and external environment of an organism. Depending on the species, it participates in multiple functions. The skin is the organ that holds the body together, covers and protects it, and provides communication with its environment. It is also the body's primary line of defense, especially for anamniotes. All vertebrates have multilayered skin composed of three main layers: the epidermis, the dermis, and the hypodermis. The vital mission of the integument in aquatic vertebrates is mucus secretion. Cornification began in apmhibians, improved in reptilians, and endured in avian and mammalian epidermis. The feather, the most ostentatious and functional structure of avian skin, evolved in the Mesozoic period. After the extinction of the dinosaurs, birds continued to diversify, followed by the enlargement, expansion, and diversification of mammals, which brings us to the most complicated skin organization of mammals with differing glands, cells, physiological pathways, and the evolution of hair. Throughout these radical changes, some features were preserved among classes such as basic dermal structure, pigment cell types, basic coloration genetics, and similar sensory features, which enable us to track the evolutionary path. The structural and physiological properties of the skin in all classes of vertebrates are presented. The purpose of this review is to go all the way back to the agnathans and follow the path step by step up to mammals to provide a comparative large and updated survey about vertebrate skin in terms of morphology, physiology, genetics, ecology, and immunology.

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Sensory systems in birds: What we have learned from studying sensory specialists

Cited by 14 publications

References 157 publications

Neural Code of Motor Planning and Execution during Goal-Directed Movements in Crows

Neural Code of Motor Planning and Execution during Goal-Directed Movements in Crows

Endocranial Anatomy of the Giant Extinct Australian Mihirung Birds (Aves, Dromornithidae)

Comparison of vertebrate skin structure at class level: A review

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