An engineering perspective on the development and evolution of implantable cardiac monitors in free-living animals

Laske, Timothy G.; Garshelis, David L.; Iles, Tinen L.; Iaizzo, Paul A.

doi:10.1098/rstb.2020.0217

Cited by 7 publications

(7 citation statements)

References 88 publications

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“…Recording multiple physiological parameters simultaneously, e.g. body temperature, heat flux, blood and tissue oxygenation, blood metabolites and gases, gastric pH and motility, or diving air volume and respiratory rate, could help to achieve this by providing a more comprehensive representation of an individual's physiological status [57,107,108].…”

Section: Summary and Future Research Directionsmentioning

confidence: 99%

Heart rate as a measure of emotional arousal in evolutionary biology

Wascher

2021

Phil. Trans. R. Soc. B

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How individuals interact with their environment and respond to changes is a key area of research in evolutionary biology. A physiological parameter that provides an instant proxy for the activation of the automatic nervous system, and can be measured relatively easily, is modulation of heart rate. Over the past four decades, heart rate has been used to assess emotional arousal in non-human animals in a variety of contexts, including social behaviour, animal cognition, animal welfare and animal personality. In this review, I summarize how measuring heart rate has provided new insights into how social animals cope with challenges in their environment. I assess the advantages and limitations of different technologies used to measure heart rate in this context, including wearable heart rate belts and implantable transmitters, and provide an overview of prospective research avenues using established and new technologies, with a special focus on implications for applied research on animal welfare. This article is part of the theme issue ‘Measuring physiology in free-living animals (Part II)’.

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Section: Summary and Future Research Directionsmentioning

confidence: 99%

Heart rate as a measure of emotional arousal in evolutionary biology

Wascher

2021

Phil. Trans. R. Soc. B

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“…The species candidate pool for neuro-biologging is going to be fundamentally limited by battery power into the future (Laske et al, 2021). While semiconductor size will continue to decrease exponentially (halving every 18 months), battery technology has failed to keep pace, ultimately playing into ethical concerns regarding the "5% rule": a device should never exceed 5% of an animal's mass (Portugal and White, 2018;Kay et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

An implantable neurophysiology platform: Broadening research capabilities in free-living and non-traditional animals

Gaidica

Dantzer²

2022

Front. Neural Circuits

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Animal-borne sensors that can record and transmit data (“biologgers”) are becoming smaller and more capable at a rapid pace. Biologgers have provided enormous insight into the covert lives of many free-ranging animals by characterizing behavioral motifs, estimating energy expenditure, and tracking movement over vast distances, thereby serving both scientific and conservational endpoints. However, given that biologgers are usually attached externally, access to the brain and neurophysiological data has been largely unexplored outside of the laboratory, limiting our understanding of how the brain adapts to, interacts with, or addresses challenges of the natural world. For example, there are only a handful of studies in free-living animals examining the role of sleep, resulting in a wake-centric view of behavior despite the fact that sleep often encompasses a large portion of an animal’s day and plays a vital role in maintaining homeostasis. The growing need to understand sleep from a mechanistic viewpoint and probe its function led us to design an implantable neurophysiology platform that can record brain activity and inertial data, while utilizing a wireless link to enable a suite of forward-looking capabilities. Here, we describe our design approach and demonstrate our device’s capability in a standard laboratory rat as well as a captive fox squirrel. We also discuss the methodological and ethical implications of deploying this new class of device “into the wild” to fill outstanding knowledge gaps.

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“…half of all beavers lost their heart rate logger suggests that the logger or the suture material caused a foreign body reaction by the beavers’ immune system, resulting in loss of the heart rate logger. Implant loss was also reported in American black bears, where both subcutaneous and intraperitoneal bio-loggers were externalized > 44 days post-implantation [ 19 ], with fewer rejections occurring in subsequent studies that used the smaller ‘Reveal LINQ’ heart rate model [ 45 ]. We found no differences among models (that markedly differed in size), which does not support the idea that smaller loggers are more likely to be rejected.…”

Section: Discussionmentioning

confidence: 99%

Retention and loss of PIT tags and surgically implanted devices in the Eurasian beaver

et al. 2022

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Background Passive integrated transponder devices (PIT tags) are a valuable tool for individual identification of animals. Similarly, the surgical implantation of transmitters and bio-loggers can provide useful data on animal location, physiology and behavior. However, to avoid unnecessary recapture and related stress of study animals, PIT tags and bio-loggers should function reliably for long periods of time. Here, we evaluated the retention of PIT tags, and of very high frequency (VHF) transmitters and bio-loggers that were either implanted subcutaneously or into the peritoneal cavity of Eurasian beavers (Castor fiber). Results Over a 21-year period, we implanted PIT tags in 456 individuals and failed to detect a PIT tag at recapture in 30 cases, consisting of 26 individuals (6% of individuals). In all instances, we were still able to identify the individual due to the presence of unique ear tag numbers and tail scars. Moreover, we implanted 6 VHFs, 36 body temperature loggers and 21 heart rate loggers in 28 individuals, and experienced frequent loss of temperature loggers (at least 6 of 23 recaptured beavers) and heart rate loggers (10 of 18 recaptured beavers). No VHFs were lost in 2 recaptured beavers. Conclusions Possible causes for PIT tag loss (or non-detection) were incorrect implantation, migration of the tag within the body, a foreign body reaction leading to ejection, or malfunctioning of the tag. We speculate that logger loss was related to a foreign body reaction, and that loggers were either rejected through the incision wound or, in the case of temperature loggers, possibly adhered and encapsulated to intestines, and then engulfed by the gastro-intestinal tract and ejected. We discuss animal welfare implications and give recommendations for future studies implanting bio-loggers into wildlife.

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An engineering perspective on the development and evolution of implantable cardiac monitors in free-living animals

Cited by 7 publications

References 88 publications

Heart rate as a measure of emotional arousal in evolutionary biology

Heart rate as a measure of emotional arousal in evolutionary biology

An implantable neurophysiology platform: Broadening research capabilities in free-living and non-traditional animals

Retention and loss of PIT tags and surgically implanted devices in the Eurasian beaver

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