Lateralization of spatial relationships between wild mother and infant orcas, Orcinus orca

Karenina, Karina; Giljov, Andrey; Ivkovich, Tatiana V.; Burdin, Alexandr M.; Malashichev, Yegor

doi:10.1016/j.anbehav.2013.09.025

Cited by 45 publications

(36 citation statements)

References 60 publications

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“…As documented among many mammals (e.g., Trivers, 1974), proximity of cetacean mothers and young calves and duration traveling near the mother decreases with increasing calf age, corresponding to larger size and increased calf dexterity (e.g., . Although we found no laterality preference for back-riding among the four mysticete mother-calf pairs we observed, beluga and killer whale calves preferred the right side of their mothers while swimming, a bias attributed to right-hemispheric advantage resulting in left eye social preference, as described in other vertebrates and cetaceans (e.g., Karenina, Giljov, Ivkovich, Burdin, & Malashichev, 2013;.…”

Section: Back-riding By Calvesmentioning

confidence: 58%

“…However, Morete et al (2007) noted the absence of back-riding and less rest and fewer active behavioral events (e.g., rolling) by humpback whale calves within 100 m of vessels. In response to close (< 10 m) boat approaches, killer whale mothers shifted calf position from their right to their left side; the authors suggested that this response improved sensory information flow from the calf to the mother's left eye, resulting in right brain hemisphere advantage in visual acuity/responsiveness to a potential threat (Karenina et al, 2013). Calf laterality in mysticetes may also provide a quantitative measure of disturbance, though we did not find any lateral bias in our small sample size.…”

Section: Back-riding By Calvesmentioning

confidence: 99%

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Cetacean mother-calf behavior observed from a small aircraft off Southern California

Smultea¹,

Fertl²,

Bacon³

et al. 2017

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Section: Back-riding By Calvesmentioning

confidence: 58%

Section: Back-riding By Calvesmentioning

confidence: 99%

Cetacean mother-calf behavior observed from a small aircraft off Southern California

Smultea¹,

Fertl²,

Bacon³

et al. 2017

AB&C

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“…Narwhal newborns were generally located close to the midpoint of the nearest adult female, either at the side (echelon position) or at the tail (infant position). These are the two main positions described for other odontocetes including bottlenose dolphins, belugas, and killer whales (Reid et al 1995;Mann and Smut 1999;Krasnova et al 2006;Noren 2008;Karenina et al 2013). Narwhal newborns tended to be very close to the nearest adult female, with the vast majority within 1/4 body length and nearly all within one body length.…”

Section: Discussionmentioning

confidence: 73%

Aerial photographic identification of narwhal (Monodon monoceros) newborns and their spatial proximity to the nearest adult female

2018

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Population and species management of long-lived species such as narwhal (Monodon monoceros) require long-term ecological monitoring programs to provide baseline information on population structure and dynamics. The success of such programs is dependent on the repeatability of the methods. Here, we propose a dichotomous key to identify narwhal newborns from aerial photography based on cetaceans’ mother–newborn dyad behavioral and narwhal newborn physical description. The key was tested by three inexperienced observers and one expert observer with interobserver agreement classified as fair according to the Cohen Kappa algorithm and criteria thresholds. This study gives some insight into narwhal-newborn spatial position, showing a predominant number of newborns located in the infant and echelon position.

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“…Therefore, social laterality (i.e., laterality expressed in social interactions) could have arisen at the population level because it facilitated intraspecific interactions (Rogers, ). This assumption is supported by studies in invertebrates (e.g., spitting spiders: Ades & Ramires, ; Heuts, Cornelissen, & Lambrechts, ; red wood ants: Frasnelli, Iakovlev, & Reznikova, ; fiddler crabs: Backwell et al, ) and vertebrates (e.g., fish: Bisazza et al, ; Bisazza et al, ; amphibians: Robins et al, , Vallortigara, Rogers, Bisazza, Lippolis, & Robins, ; birds: Vallortigara, Cozzutti, Tommasi, & Rogers, ; Ventolini et al, ; ungulates: Jennings, ; Versace, Morgante, Pulina, & Vallortigara, ; cetaceans: Karenina et al, ; Karenina, Giljov, Ivkovich, Burdin, & Malashichev, ; primates: Baraud, Buytet, Bec, & Blois‐Heulin, , Meguerditchian, Vauclair, & Hopkins, ; Prieur et al, ). For example, red wood ants exhibit a population‐level bias during “feeding” contacts when a “donor” ant exchanges food with a “receiver” ant through trophallaxis: the “receiver” ant uses its right antenna predominantly more often than its left antenna (Frasnelli, et al, ).…”

Section: Brain Lateralisation: a Widespread Phenomenonmentioning

confidence: 86%

History, development and current advances concerning the evolutionary roots of human right‐handedness and language: Brain lateralisation and manual laterality in non‐human primates

et al. 2018

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This review highlights the scientific advances concerning the origins of human right‐handedness and language (speech and gestures). The comparative approach we adopted provides evidence that research on human and non‐human animals’ behavioural asymmetries helps understand the processes that lead to the strong human left‐hemisphere specialisation. We review four major non‐mutually exclusive environmental factors that are likely to have shaped the evolution of human and non‐human primates’ manual asymmetry: socioecological lifestyle, postural characteristics, task‐level complexity and tool use. We hypothesise the following scenario for the evolutionary origins of human right‐handedness: the right‐direction of modern humans’ manual laterality would have emerged from our ecological (terrestrial) and social (multilevel system) lifestyle; then, it would have been strengthened by the gradual adoption of the bipedal stance associated with bipedal locomotion, and the increasing level of complexity of our daily tasks including bimanual coordinated actions and tool use. Although hemispheric functional lateralisation has been shaped through evolution, reports indicate that many factors and their mutual intertwinement can modulate human and non‐human primates’ manual laterality throughout their life cycle: genetic and environmental factors, mainly individual sociodemographic characteristics (e.g., age, sex and rank), behavioural characteristics (e.g., gesture per se and gestural sensory modality) and context‐related characteristics (e.g., emotional context and position of target). These environmental (evolutionary and life cycle) factors could also have influenced primates’ manual asymmetry indirectly through epigenetic modifications. All these findings led us to propose the hypothesis of a multicausal origin of human right‐handedness.

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Lateralization of spatial relationships between wild mother and infant orcas, Orcinus orca

Cited by 45 publications

References 60 publications

Cetacean mother-calf behavior observed from a small aircraft off Southern California

Cetacean mother-calf behavior observed from a small aircraft off Southern California

Aerial photographic identification of narwhal (Monodon monoceros) newborns and their spatial proximity to the nearest adult female

History, development and current advances concerning the evolutionary roots of human right‐handedness and language: Brain lateralisation and manual laterality in non‐human primates

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