A Neurological Comparative Study of the Harp Seal (<i>Pagophilus groenlandicus</i>) and Harbor Porpoise (<i>Phocoena phocoena</i>) Brain

Walløe, Solveig; Eriksen, Nina; Dabelsteen, Torben; Pakkenberg, Bente

doi:10.1002/ar.21295

Cited by 25 publications

(29 citation statements)

References 33 publications

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“…The fact that we could only study 1 specimen of each of the 2 species relates to the very limited availability of toothed whale brain material suitable for stereological investigation. However, our data are consistent within the single cortical areas of our 2 animals (coefficient of error; table 4 ) and they correlate well with data in the literature on the bottlenose dolphin concerning both the total densities of cortical areas (auditory, visual) we investigated and the densities of layers III and V in these cortices [Garey and Leuba, 1986;Morgane et al, 1988, Eriksen andPakkenberg, 2007;Walloe et al, 2010]. We analyzed only cresyl violet-stained sections from the cortex of these 2 animals which were of very good histological quality ( fig.…”

Section: Animalssupporting

confidence: 91%

“…Electrophysiological experiments [Lende and Akdikmen, 1968;Lende and Welker, 1972;Supin, 1970, 1977;Ladygina et al, 1978;Supin et al, 1978Supin et al, , 2001 have shown that near the anteroventral tip of the cerebral hemisphere the motor and somatosensory cortical areas are separated by the cruciate sulcus, presumably a homolog of the central sulcus in primates [Morgane et al, 1980[Morgane et al, , 1986[Morgane et al, , 1990Oelschläger andOelschläger, 2002, 2009]. The auditory field is the largest primary projection area with the highest number of neurons and the largest cortical volume [Walloe et al, 2010; harbor porpoise, Phocoena phocoena ; Eriksen and Pakkenberg, 2007; minke whale, Balaenoptera acutorostrata ]. It is located in the suprasylvian and the posterior ectosylvian gyrus, bordering medially on the visual field which in toothed whales comprises the lateral gyrus adjacent to the interhemispheric cleft ( fig.…”

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confidence: 99%

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Stereology of the Neocortex in Odontocetes: Qualitative, Quantitative, and Functional Implications

et al. 2011

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We investigated the quantitative morphology of the neocortex (gray matter) in 2 toothed whale (odontocete) species (harbor porpoise, Phocoena phocoena; bottlenose dolphin, Tursiops truncatus) with stereological methods. The 4 primary projection areas (motor, somatosensory, auditory, and visual fields) are analyzed for their cell densities in layers III and V with standard design-based stereology methods. Along cortical areas M1, S1, A1, and V1 in Tursiops, neuron density is always higher in layer III than in layer V, whereas the data in Phocoena are variable. Moreover, neuron density in layer III is generally around 1.5 times higher in Tursiops than in Phocoena. Maximal density values are seen in layer III of A1 and V1 in Tursiops and the ratio of layer III/layer V density is maximal in A1 of this species. Thus, layer III could have a higher capacity in the bottlenose dolphin with regard to intrinsic connectivity. Extant knowledge on toothed whale neurobiology and behavior suggests that quantitative/stereological differences between the 2 odontocete species regarding the neuron density of standard cortical units may be correlated with specific adaptations to their respective habitats. In contrast to layers V and VI which mainly serve as an executive system, layer III could represent an intermediate level in sensory and premotor processing which works more tangentially in the cortices via horizontal connections with other cortical areas, respectively. The generally higher density of cortical layer III in Tursiops suggests a higher connectivity of this layer in view of the more agile and complicated behavior of these gregarious animals including versatile phonation by complex sound and ultrasound signals.

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Section: Animalssupporting

confidence: 91%

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confidence: 99%

Stereology of the Neocortex in Odontocetes: Qualitative, Quantitative, and Functional Implications

et al. 2011

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“…For example, Herculano-Houzel [129] suggested that even the cerebral cortex of the largest whales might be composed of only a fraction of the average 16,300 million neurons found in the human cerebral cortex. In fact, both Kazu et al [128], and Herculano-Houzel [129] do not agree with the aforementioned results concerning the neuronal numbers found in the cerebral cortex of the harbour porpoise and the minke whale, [3,127] suggesting that the neuron numbers obtained might be over-estimations of the real values due to undersampling problems associated with the stereology quantification technique.…”

Section: Implications For Cetacean Cognitionmentioning

confidence: 93%

“…Furthermore, using stereology quantification techniques [125,126], it was shown that odontocetes such as the long-finned pilot whale (Globicephala melas), or the harbour porpoise (Phocoena phocoena) have an unexpectedly high number of cortical neurons [30,127]. Figures for harbour porpoises approach the lowest cortical neuron number found in humans [104,105], and long-finned pilot whales possessing the highest number of cortical neurons of any species studied so far, including humans [30].…”

Section: Implications For Cetacean Cognitionmentioning

confidence: 99%

“…Having said this, it is important to highlight that modern unbiased stereology techniques make use of efficient sampling techniques [103,126], therefore even when accounting for the existence of errors, it is unlikely that variance errors that are of the magnitude needed to explain the discrepancies obtained between the predictions of Kazu et al [128] and the neuronal numbers found by Wallöe et al [127], and Mortensen et al [30] would have been made; this is especially so for the study by Mortensen et al [30] which used a meaningful sample of specimens (i.e., n = 10). Furthermore, according to the results of the theoretical model, these data do not falsify, but rather refine the aforementioned hypotheses concerning the levels of intelligence that would be expected for a species based on the cortical neuron numbers [12,23,129], as a larger absolute number of neurons in the cerebral cortex is a necessary but not a sufficient condition for exhibiting higher levels of intelligence.…”

Section: Implications For Cetacean Cognitionmentioning

confidence: 99%

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Is Cetacean Intelligence Special? New Perspectives on the Debate

Chinea

2017

Entropy

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Abstract:In recent years, the interpretation of our observations of animal behaviour, in particular that of cetaceans, has captured a substantial amount of attention in the scientific community. The traditional view that supports a special intellectual status for this mammalian order has fallen under significant scrutiny, in large part due to problems of how to define and test the cognitive performance of animals. This paper presents evidence supporting complex cognition in cetaceans obtained using the recently developed intelligence and embodiment hypothesis. This hypothesis is based on evolutionary neuroscience and postulates the existence of a common information-processing principle associated with nervous systems that evolved naturally and serves as the foundation from which intelligence can emerge. This theoretical framework explaining animal intelligence in neural computational terms is supported using a new mathematical model. Two pathways leading to higher levels of intelligence in animals are identified, each reflecting a trade-off either in energetic requirements or the number of neurons used. A description of the evolutionary pathway that led to increased cognitive capacities in cetacean brains is detailed and evidence supporting complex cognition in cetaceans is presented. This paper also provides an interpretation of the adaptive function of cetacean neuronal traits.

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Comparative Stereology Studies of Brains from Marine Mammals

Eriksen

Pakkenberg

2013

Neurostereology

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A Neurological Comparative Study of the Harp Seal (Pagophilus groenlandicus) and Harbor Porpoise (Phocoena phocoena) Brain

Cited by 25 publications

References 33 publications

Stereology of the Neocortex in Odontocetes: Qualitative, Quantitative, and Functional Implications

Stereology of the Neocortex in Odontocetes: Qualitative, Quantitative, and Functional Implications

Is Cetacean Intelligence Special? New Perspectives on the Debate

Comparative Stereology Studies of Brains from Marine Mammals

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