Animal lifestyle affects acceptable mass limits for attached tags

Rory P. Wilson; Kayleigh A. Rose; Richard Gunner; Mark D. Holton; Nikki J. Marks; Nigel C. Bennett; Stephen H. Bell; Joshua P. Twining; Jamie Hesketh; Carlos M. Duarte; Neil Bezodis; Milos Jezek; Michael Painter; Vaclav Silovsky; Margaret C. Crofoot; Roi Harel; John P.Y. Arnould; Blake M. Allan; Desley A. Whisson; Abdulaziz Alagaili; D. Michael Scantlebury

doi:10.1098/rspb.2021.2005

Animal lifestyle affects acceptable mass limits for attached tags

Rory P. Wilson, Kayleigh A. Rose, Richard Gunner, Mark D. Holton, Nikki J. Marks, Nigel C. Bennett, Stephen H. Bell, Joshua P. Twining, Jamie Hesketh, Carlos M. Duarte, Neil Bezodis, Milos Jezek, Michael Painter, Vaclav Silovsky, Margaret C. Crofoot, Roi Harel, John P.Y. Arnould, Blake M. Allan, Desley A. Whisson, Abdulaziz AlagailiD. Michael Scantlebury

Research output: Contribution to journal › Article › peer-review

30 Citations (Scopus)

Abstract

Animal-attached devices have transformed our understanding of vertebrate ecology. To minimize any associated harm, researchers have long advocated that tag masses should not exceed 3% of carrier body mass. However, this ignores tag forces resulting from animal movement. Using data from collar-attached accelerometers on 10 diverse free-ranging terrestrial species from koalas to cheetahs, we detail a tag-based acceleration method to clarify acceptable tag mass limits. We quantify animal athleticism in terms of fractions of animal movement time devoted to different collar-recorded accelerations and convert those accelerations to forces (acceleration × tag mass) to allow derivation of any defined force limits for specified fractions of any animal's active time. Specifying that tags should exert forces that are less than 3% of the gravitational force exerted on the animal's body for 95% of the time led to corrected tag masses that should constitute between 1.6% and 2.98% of carrier mass, depending on athleticism. Strikingly, in four carnivore species encompassing two orders of magnitude in mass (ca 2-200 kg), forces exerted by '3%' tags were equivalent to 4-19% of carrier body mass during moving, with a maximum of 54% in a hunting cheetah. This fundamentally changes how acceptable tag mass limits should be determined by ethics bodies, irrespective of the force and time limits specified.

Original language	English
Article number	20212005
Number of pages	9
Journal	Proceedings of the Royal Society B: Biological Sciences
Volume	288
Issue number	1961
DOIs	https://doi.org/10.1098/rspb.2021.2005
Publication status	Published - 27 Oct 2021

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Wilson, R. P., Rose, K. A., Gunner, R., Holton, M. D., Marks, N. J., Bennett, N. C., Bell, S. H., Twining, J. P., Hesketh, J., Duarte, C. M., Bezodis, N., Jezek, M., Painter, M., Silovsky, V., Crofoot, M. C., Harel, R., Arnould, J. P. Y., Allan, B. M., Whisson, D. A., ... Scantlebury, D. M. (2021). Animal lifestyle affects acceptable mass limits for attached tags. Proceedings of the Royal Society B: Biological Sciences, 288(1961), Article 20212005. https://doi.org/10.1098/rspb.2021.2005

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title = "Animal lifestyle affects acceptable mass limits for attached tags",

abstract = "Animal-attached devices have transformed our understanding of vertebrate ecology. To minimize any associated harm, researchers have long advocated that tag masses should not exceed 3% of carrier body mass. However, this ignores tag forces resulting from animal movement. Using data from collar-attached accelerometers on 10 diverse free-ranging terrestrial species from koalas to cheetahs, we detail a tag-based acceleration method to clarify acceptable tag mass limits. We quantify animal athleticism in terms of fractions of animal movement time devoted to different collar-recorded accelerations and convert those accelerations to forces (acceleration × tag mass) to allow derivation of any defined force limits for specified fractions of any animal's active time. Specifying that tags should exert forces that are less than 3% of the gravitational force exerted on the animal's body for 95% of the time led to corrected tag masses that should constitute between 1.6% and 2.98% of carrier mass, depending on athleticism. Strikingly, in four carnivore species encompassing two orders of magnitude in mass (ca 2-200 kg), forces exerted by '3%' tags were equivalent to 4-19% of carrier body mass during moving, with a maximum of 54% in a hunting cheetah. This fundamentally changes how acceptable tag mass limits should be determined by ethics bodies, irrespective of the force and time limits specified.",

keywords = "collar design, detriment, ethics, guidelines, tag mass",

author = "Wilson, {Rory P.} and Rose, {Kayleigh A.} and Richard Gunner and Holton, {Mark D.} and Marks, {Nikki J.} and Bennett, {Nigel C.} and Bell, {Stephen H.} and Twining, {Joshua P.} and Jamie Hesketh and Duarte, {Carlos M.} and Neil Bezodis and Milos Jezek and Michael Painter and Vaclav Silovsky and Crofoot, {Margaret C.} and Roi Harel and Arnould, {John P.Y.} and Allan, {Blake M.} and Whisson, {Desley A.} and Abdulaziz Alagaili and Scantlebury, {D. Michael}",

note = "Publisher Copyright: {\textcopyright} 2021 The Author(s).",

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doi = "10.1098/rspb.2021.2005",

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Wilson, RP, Rose, KA, Gunner, R, Holton, MD, Marks, NJ, Bennett, NC, Bell, SH, Twining, JP, Hesketh, J, Duarte, CM, Bezodis, N, Jezek, M, Painter, M, Silovsky, V, Crofoot, MC, Harel, R, Arnould, JPY, Allan, BM, Whisson, DA, Alagaili, A & Scantlebury, DM 2021, 'Animal lifestyle affects acceptable mass limits for attached tags', Proceedings of the Royal Society B: Biological Sciences, vol. 288, no. 1961, 20212005. https://doi.org/10.1098/rspb.2021.2005

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T1 - Animal lifestyle affects acceptable mass limits for attached tags

AU - Wilson, Rory P.

AU - Rose, Kayleigh A.

AU - Gunner, Richard

AU - Holton, Mark D.

AU - Marks, Nikki J.

AU - Bennett, Nigel C.

AU - Bell, Stephen H.

AU - Twining, Joshua P.

AU - Hesketh, Jamie

AU - Duarte, Carlos M.

AU - Bezodis, Neil

AU - Jezek, Milos

AU - Painter, Michael

AU - Silovsky, Vaclav

AU - Crofoot, Margaret C.

AU - Harel, Roi

AU - Arnould, John P.Y.

AU - Allan, Blake M.

AU - Whisson, Desley A.

AU - Alagaili, Abdulaziz

AU - Scantlebury, D. Michael

PY - 2021/10/27

Y1 - 2021/10/27

N2 - Animal-attached devices have transformed our understanding of vertebrate ecology. To minimize any associated harm, researchers have long advocated that tag masses should not exceed 3% of carrier body mass. However, this ignores tag forces resulting from animal movement. Using data from collar-attached accelerometers on 10 diverse free-ranging terrestrial species from koalas to cheetahs, we detail a tag-based acceleration method to clarify acceptable tag mass limits. We quantify animal athleticism in terms of fractions of animal movement time devoted to different collar-recorded accelerations and convert those accelerations to forces (acceleration × tag mass) to allow derivation of any defined force limits for specified fractions of any animal's active time. Specifying that tags should exert forces that are less than 3% of the gravitational force exerted on the animal's body for 95% of the time led to corrected tag masses that should constitute between 1.6% and 2.98% of carrier mass, depending on athleticism. Strikingly, in four carnivore species encompassing two orders of magnitude in mass (ca 2-200 kg), forces exerted by '3%' tags were equivalent to 4-19% of carrier body mass during moving, with a maximum of 54% in a hunting cheetah. This fundamentally changes how acceptable tag mass limits should be determined by ethics bodies, irrespective of the force and time limits specified.

AB - Animal-attached devices have transformed our understanding of vertebrate ecology. To minimize any associated harm, researchers have long advocated that tag masses should not exceed 3% of carrier body mass. However, this ignores tag forces resulting from animal movement. Using data from collar-attached accelerometers on 10 diverse free-ranging terrestrial species from koalas to cheetahs, we detail a tag-based acceleration method to clarify acceptable tag mass limits. We quantify animal athleticism in terms of fractions of animal movement time devoted to different collar-recorded accelerations and convert those accelerations to forces (acceleration × tag mass) to allow derivation of any defined force limits for specified fractions of any animal's active time. Specifying that tags should exert forces that are less than 3% of the gravitational force exerted on the animal's body for 95% of the time led to corrected tag masses that should constitute between 1.6% and 2.98% of carrier mass, depending on athleticism. Strikingly, in four carnivore species encompassing two orders of magnitude in mass (ca 2-200 kg), forces exerted by '3%' tags were equivalent to 4-19% of carrier body mass during moving, with a maximum of 54% in a hunting cheetah. This fundamentally changes how acceptable tag mass limits should be determined by ethics bodies, irrespective of the force and time limits specified.

KW - collar design

KW - detriment

KW - ethics

KW - guidelines

KW - tag mass

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ER -

Animal lifestyle affects acceptable mass limits for attached tags

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