Sea turtles compensate deflection of heading at the sea surface during directional travel

Narazaki, Tomoko; Sato, Katsufumi; Abernathy, Kyler; Marshall, Greg; Miyazaki, Nobuyuki

doi:10.1242/jeb.034637

Cited by 45 publications

(30 citation statements)

References 45 publications

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“…3D paths were calculated using data on depth, swim speed, acceleration, and magnetism obtained from the 3D loggers, as described by previous studies535455. The 3D paths were reconstructed every 1 sec using a dead-reckoning method53565758. Video data were checked by using VLC media player (VideoLAN project: https://www.videolan.org) to identify any feeding events.…”

Section: Methodsmentioning

confidence: 99%

The feeding habit of sea turtles influences their reaction to artificial marine debris

Fukuoka

Yamane

Kinoshita

et al. 2016

Sci Rep

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Ingestion of artificial debris is considered as a significant stress for wildlife including sea turtles. To investigate how turtles react to artificial debris under natural conditions, we deployed animal-borne video cameras on loggerhead and green turtles in addition to feces and gut contents analyses from 2007 to 2015. Frequency of occurrences of artificial debris in feces and gut contents collected from loggerhead turtles were 35.7% (10/28) and 84.6% (11/13), respectively. Artificial debris appeared in all green turtles in feces (25/25) and gut contents (10/10), and green turtles ingested more debris (feces; 15.8 ± 33.4 g, gut; 39.8 ± 51.2 g) than loggerhead turtles (feces; 1.6 ± 3.7 g, gut; 9.7 ± 15.0 g). In the video records (60 and 52.5 hours from 10 loggerhead and 6 green turtles, respectively), turtles encountered 46 artificial debris and ingested 23 of them. The encounter-ingestion ratio of artificial debris in green turtles (61.8%) was significantly higher than that in loggerhead turtles (16.7%). Loggerhead turtles frequently fed on gelatinous prey (78/84), however, green turtles mainly fed marine algae (156/210), and partly consumed gelatinous prey (10/210). Turtles seemed to confuse solo drifting debris with their diet, and omnivorous green turtles were more attracted by artificial debris.

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Section: Methodsmentioning

confidence: 99%

The feeding habit of sea turtles influences their reaction to artificial marine debris

Fukuoka

Yamane

Kinoshita

et al. 2016

Sci Rep

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“…There are several existing methods for locating animals in space and time including radio telemetry [136], satellite or geographic positioning systems [11,137,138] and acoustic arrays [139]. None of these methods works for all species and habitats and, consequently, travel paths are frequently reconstructed by bridging sporadic points and have low spatio-temporal resolution [140,141].…”

Section: Potential Application Of Accelerometry: Position and Locationmentioning

confidence: 99%

“…Furthermore, these errors accumulate over time, making location estimates increasingly worse further from the last known location. Because of these problems, dead-reckoning from accelerometry data has been used infrequently and most researchers interested in movement speed have added separate speed sensors (small external propellers) to the telemetry tags [24,137,[141][142][143][144]. As GPS technology becomes more widely integrated into accelerometer tags, the greatest potential for dead-reckoned animal location comes in recreating the exact travel path between subsequent GPS locations collected at short intervals e.g., <15 min [24,139].…”

Section: Potential Application Of Accelerometry: Position and Locationmentioning

confidence: 99%

Observing the unwatchable through acceleration logging of animal behavior

et al. 2013

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Behavior is an important mechanism of evolution and it is paid for through energy expenditure. Nevertheless, field biologists can rarely observe animals for more than a fraction of their daily activities and attempts to quantify behavior for modeling ecological processes often exclude cryptic yet important behavioral events. Over the past few years, an explosion of research on remote monitoring of animal behavior using acceleration sensors has smashed the decades-old limits of observational studies. Animal-attached accelerometers measure the change in velocity of the body over time and can quantify fine-scale movements and body postures unlimited by visibility, observer bias, or the scale of space use. Pioneered more than a decade ago, application of accelerometers as a remote monitoring tool has recently surged thanks to the development of more accessible hardware and software. It has been applied to more than 120 species of animals to date. Accelerometer measurements are typically collected in three dimensions of movement at very high resolution (>10 Hz), and have so far been applied towards two main objectives. First, the patterns of accelerometer waveforms can be used to deduce specific behaviors through animal movement and body posture. Second, the variation in accelerometer waveform measurements has been shown to correlate with energy expenditure, opening up a suite of scientific questions in species notoriously difficult to observe in the wild. To date, studies of wild aquatic species outnumber wild terrestrial species and analyses of social behaviors are particularly few in number. Researchers of domestic and captive species also tend to report methodology more thoroughly than those studying species in the wild. There are substantial challenges to getting the most out of accelerometers, including validation, calibration, and the management and analysis of large quantities of data. In this review, we illustrate how accelerometers work, provide an overview of the ecological questions that have employed accelerometry, and highlight the emerging best practices for data acquisition and analysis. This tool offers a level of detail in behavioral studies of free-ranging wild animals that has previously been impossible to achieve and, across scientific disciplines, it improves understanding of the role of behavioral mechanisms in ecological and evolutionary processes. AbstractResumen: El comportamiento es un mecanismo importante de la evolución y que se paga a través del gasto de energía. Sin embargo, los biólogos de campo raramente observan los animales durante más de una fracción de sus actividades y los intentos de cuantificar el comportamiento para el modelado de los procesos ecológicos a menudo excluyen eventos crípticos pero importantes. En los últimos años se produjeron avances importantes en el monitoreo remoto del comportamiento de los animales, utilizando sensores de telemétro de aceleración (acelerómetros) que empujan los límites tradicionales de los estudios observacionales. Acelerómetros uni...

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“…Low-light levels probably would not preclude navigation because elephant seals have remarkably sensitive vision (Levenson and Schusterman, 1999). Straight-line underwater swimming and adjusting traveling direction at the surface were observed in loggerhead turtles Caretta caretta (Narazaki et al, 2009), although the cue(s) used have not been determined. This behavior resembles our results.…”

Section: Discussionmentioning

confidence: 99%

Underwater and surface behavior of homing juvenile northern elephant seals

Matsumura

Watanabe

Robinson

et al. 2011

Journal of Experimental Biology

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SUMMARYNorthern elephant seals, Mirounga angustirostris, travel between colonies along the west coast of North America and foraging areas in the North Pacific. They also have the ability to return to their home colony after being experimentally translocated. However, the mechanisms of this navigation are not known. Visual information could serve an important role in navigation, either primary or supplementary. We examined the role of visual cues in elephant seal navigation by translocating three seals and recording their heading direction continuously using GPS, and acceleration and geomagnetic data loggers while they returned to the colony. The seals first reached the coast and then proceeded to the colony by swimming along the coast. While underwater the animals exhibited a horizontally straight course (mean net-to-gross displacement ratio0.94±0.02). In contrast, while at the surface they changed their headings up to 360deg. These results are consistent with the use of visual cues for navigation to the colony. The seals may visually orient by using landmarks as they swim along the coast. We further assessed whether the seals could maintain a consistent heading while underwater during drift dives where one might expect that passive spiraling during drift dives could cause disorientation. However, seals were able to maintain the initial course heading even while underwater during drift dives where there was spiral motion (to within 20deg). This behavior may imply the use of non-visual cues such as acoustic signals or magnetic fields for underwater orientation.

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Sea turtles compensate deflection of heading at the sea surface during directional travel

Cited by 45 publications

References 45 publications

The feeding habit of sea turtles influences their reaction to artificial marine debris

The feeding habit of sea turtles influences their reaction to artificial marine debris

Observing the unwatchable through acceleration logging of animal behavior

Underwater and surface behavior of homing juvenile northern elephant seals

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