key: cord-0016703-0bh7c9tp
authors: Fahlman, Andreas; Aoki, Kagari; Bale, Gemma; Brijs, Jeroen; Chon, Ki H.; Drummond, Colin K.; Føre, Martin; Manteca, Xavier; McDonald, Birgitte I.; McKnight, J. Chris; Sakamoto, Kentaro Q.; Suzuki, Ippei; Rivero, M. Jordana; Ropert-Coudert, Yan; Wisniewska, Danuta M.
title: The New Era of Physio-Logging and Their Grand Challenges
date: 2021-03-30
journal: Front Physiol
DOI: 10.3389/fphys.2021.669158
sha: 2dd0b13b1736c4b02789881945e067106ee8e7e1
doc_id: 16703
cord_uid: 0bh7c9tp

nan

The field of bio-sensing refers to studies where the physiology of an animal, its behavior and movement, as well as the characteristics of the environment it moves in, is measured either by electronic sensor-carrying devices that store the data (bio-logging), or those that transmit the data directly (bio-telemetry). 1 One of the first bio-sensing studies was conducted over 80 years ago with the attachment of a capillary tube to a fin whale (Balaenoptera physalus) to assess the dive depth of a free-ranging marine mammal (Scholander, 1940) . In humans, the stethoscope was developed by Rene Laennec in 1819 as the first non-invasive heart monitor, which solved the challenge of listening to the heart by placing an ear on the patient's chest (not always welcome in the Victorian era) (Roguin, 2006) . Quickly the system found new uses eventually leading to a shift from subjective to objective data about the internal body. The field of bio-sensing has since increased exponentially and revolutionized our understanding of animal ecology. With the technological development of miniaturized sensors, numerous studies of movement ecology, behavior, and communication in a diverse range of animals (e.g., species of fish, reptiles, birds and mammals) have been reviewed in (Frost et al., 1997; Davis, 2008; Ropert-Coudert et al., 2009a; Rutz and Hays, 2009; Swain et al., 2011; Hussey et al., 2015; Wilmers et al., 2015; Endo and Wu, 2019; Börger et al., 2020; Wassmer et al., 2020) . While determining the physiological limits and plasticity of a species is essential for understanding its ecology and evolution, studies that measure the physiological responses of free-ranging animals (i.e., physio-logging) have not seen the same exponential increase, even though physiological questions were at the origin of the use of data loggers in seminal work done by field physiologists such as Gerry Kooyman, Paul Ponganis, Warren Zapol, and Patrick Butler (Butler and Woakes, 1979; Falke et al., 1985; Kooyman, 1985; Ponganis et al., 1991) .

The slower growth of the physio-logging field could be due to the commercial unavailability of physiological sensors, or that the available sensors were too large, based on static-technologies, or required specialized surgical training and extensive knowledge of the anatomy and physiology of the animal for successful implantation. Despite these challenges, studies using bio-sensing tools have renewed the interest in physio-logging and attempted to understand the physiology of an animal through inference from their behavior (Wilson et al., 2002; Hooker et al., 2009; Goldbogen et al., 2011 Goldbogen et al., , 2019b Kolarevic et al., 2016; Føre et al., 2018b; Quick et al., 2020) .

Physio-loggers have recently been used on farmed animals (livestock) to record physiological variables (e.g., body temperature, respiration and heart rates) in order to monitor water intake, the occurrence of diseases, energy expenditure in grazing activities, and effect of diet on body temperature under cold and warm conditions (Brosh et al., 2006; Eigenberg et al., 2008; AlZahal et al., 2011; Arias et al., 2011; Aharoni et al., 2013; Cantor et al., 2018) . In the human arena -where early biotelemetry approaches were born -technological advances such as movement sensors initially allowed anyone with a "smartphone" or "smartwatch" to assess their daily energy consumption, leading to the so-called "quantified health" movement (Scully et al., 2012) . Indeed, subsequent development of non-invasive sensing (photoplethysmography) enabled new and exciting possibilities to track health and fitness in a large number of people (Dörr et al., 2019; Seshadri et al., 2020) . In addition, recent developments in wearable medical and nanotechnology, with increased battery life, storage capacity and a range of sensors have increased our ability to study physiological function both non-invasively and continuously over months and years (Kang et al., 2016; Kaidarova et al., 2018 Kaidarova et al., , 2019 Lee et al., 2019; Lazaro et al., 2020) . Thus, tools capable of measuring a range of important and informative physiological parameters are now available, and are continuously being improved and adapted to work on an increasing range of species. These developments will revolutionize the capacity to measure and assess the physiology of animals and humans over extended periods of time, which will allow a comprehensive evaluation of the physiological function of animals in their natural environment. This new era of physio-logging will enable long-term studies to better understand fundamental physiological function, health, welfare or well-being of animals and humans, as well as their responses to environmental and/or anthropogenic changes.

Much of what we know about animal physiology has been obtained by measuring physiological parameters on captive, semi-captive, or restrained animals including measures of heart rate, blood flow, blood chemistry, blood gases, and metabolic rate (Berkson, 1967; Kooyman et al., 1970; Kooyman and Campbell, 1972; Kooyman and Sinnett, 1982; Lutcavage et al., 1989; Ponganis et al., 1990; Reed et al., 1994 Reed et al., , 2000 Gräns et al., 2010; Kang et al., 2016; Brijs et al., 2018; Berenbrink, 2021; Svendsen et al., 2021) . Unfortunately, in such situations, it is difficult to assess the magnitude of potential confounding factors such as stress or manipulation on the measured physiological variable. In recent years, there has been a focus on measuring physiology in free-ranging animals. For example, trained animals that are desensitized to the experimental procedures have been used to study diving energetics, cardiorespiratory and vascular physiology, and cerebrovascular physiology (Elsner, 1965; Olsen et al., 1969; Ridgway and Howard, 1979; Williams et al., 1993; Hurley and Costa, 2001; Fahlman et al., 2008 Fahlman et al., , 2019 Fahlman et al., , 2020a Mortola and Sequin, 2009; Rosen and Trites, 2013; Worthy et al., 2013; Elmegaard et al., 2016 Elmegaard et al., , 2019 Takei et al., 2016; McKnight et al., 2019; Meir et al., 2019; Pedersen et al., 2020; Blawas et al., 2021) . As bio-logging technologies have advanced, physiological parameters such as heart rate, respiration rate, and blood O 2 have even been measured in free-ranging fish, reptiles, birds, and mammals (Falke et al., 1985; Ponganis et al., 1991; Thompson and Fedak, 1993; Southwood et al., 1999; Andrews et al., 2000; Froget et al., 2004; Ropert-Coudert et al., 2006 , 2009b Meir et al., 2009; Yamamoto et al., 2009; Meir and Ponganis, 2010; Ponganis, 2013, 2014; Sakamoto et al., 2013; Duriez et al., 2014; Goldbogen et al., 2019a; McKnight et al., 2019 McKnight et al., , 2021a Sumich, 2021) . There is a parallel shift in the paradigm of physiological monitoring of humans. Whereas once health monitoring was exclusively a physician-based in-patient activity, the emergence of health and fitness wearables has led to the so-called "quantified self " movement, where patients are producing data in support of diagnostics (Patel and Tarakji, 2021) .

Progress on medical sensing technology has increased significantly. A wide range of physiological monitoring technologies are now available and are setting the stage from which physiological bio-sensing could profit immensely. For instance, virtually anyone with a "smartphone" or "smartwatch" can now assess their daily calorie expenditure as sensors within the phone can estimate the number of steps taken or distance moved. Similarly, researchers have applied this principle to free-ranging animals and are able to derive an estimate of energy expended in the wild via a measure of dynamic body movements measured by animal-embarked accelerometers (Wilson et al., , 2020 Gleiss et al., 2011 ) that correlates well with other direct measures of energy expended even in wild animals (Elliott et al., 2013; Jeanniard-Du-Dot et al., 2017; Hicks et al., 2020) . Phonospirometry (i.e., the use of the breath sound to estimate respiratory flow) is being used to perform lung function testing in both humans and animals (Sumich and May, 2009; Larson et al., 2012; Sumich, 2021; Van Der Hoop et al., 2021) . In addition, the ongoing development of wearable medical sensors that can detect glucose levels, estimate heart rate via waterproof ECG electrodes (Reyes et al., 2014; Noh et al., 2016) or assess blood flow/volume changes and/or blood oxygen saturation changes provide a particularly exciting avenue for future research (Bockstaele et al., 2014; McKnight et al., 2019 McKnight et al., , 2021a . These technological advancements open up enormous possibilities as they will enable investigating the physiological function in freely moving, and even free-ranging animals, with minimal disturbances. Further, the development of fully bioresorbable microchip technologies capable of measuring a variety of physiological parameters (Kang et al., 2016) could offer opportunities to measure new, fine-scale physiological metrics in free-moving and free-ranging animals. Thus, long-term data sets on movement, married with physiological data could become available, contributing essential components to frameworks that assess the consequences of environmental and/or anthropogenic impacts such as Population Consequences of Disturbance (PCoD, Booth et al., 2014; Pirotta et al., 2018) , as well as to develop a fundamental understanding of the physiology of a diverse range of species.

The collection of long-term and/or high-resolution data sets is likely to result in analytical challenges. For example, ECG collection sampled at 200 Hz over a whole year results in 6.3 billion data points. While ECG could be reduced to instantaneous heart rate (if H ) (Sakamoto et al., 2021) , normal statistical tools, such as comparison of means or medians are not applicable and are likely to result in erroneous conclusions. More sophisticated analytical methods, including signal processing or time-series analysis, will have to be developed and introduced to deal with a growing number of studies that focus on physiological function and eco-physiology. There has recently been a rapid growth in analytical techniques in bioinformatics, where new tools and databases have been developed to handle the large data sets that result from sequencing the genome of various species and to evaluate gene networks and differential changes in molecular products. A similar exponential growth has been seen within data processing methods based on Artificial Intelligence (AI) and Machine Learning (ML). These methods are used in several different fields today, especially when data sets are too large and/or complex to handle through conventional means, and it is likely that they prove useful for processing datasets from biosensors. Although many AI/ML methods are "a black box, " in the sense that they do not describe the mechanistic links between input and output (e.g., environmental and/or anthropogenic changes and sensor output in this case), they could be useful for compressing and condensing large data sets and identifying unknown relationships between inputs and measured features (Rasheed et al., 2020) .

In the last 40 years, the field of bio-sensing has provided important information about the ecology and behavior of wild animals, largely focusing on describing where they go and what they do there. Animal tracking studies have substantially improved the knowledge of movement patterns and drivers of movement in marine, terrestrial and avian species. However, the rapid development and miniaturization of bio-sensing electronics capable of measuring a raft of physiological variables present innovative and exciting tools that will revolutionize this field of research and usher in a new era of physio-logging. These technologies will allow us to comprehensively evaluate how and why animals make the journeys they do (e.g., bar-headed geese flying over the Himalayas, Cuvier's beaked whales diving to 3000 m for over 3 h; Hawkes et al., 2013; Quick et al., 2020) . Such studies will provide a foundation for understanding how animals may respond to alterations in the environment and the physiological boundaries for survival. Physio-logging can also provide the necessary tools for conservation management, which will contribute toward reducing the impacts of anthropogenic disturbances on species, communities and even ecosystems. For example, assessment of stress levels, such as measuring corticosterone or heart rate may help evaluate the impact of anthropogenetic disturbance (Miksis et al., 2001) . Furthermore, physio-logging is also likely to provide an important diagnostic tool for evaluating the well-being and welfare of farmed terrestrial and aquatic animals. These technologies can provide a unique opportunity for health monitoring via an "animal-eye" view of the conditions that farmed animals experience in human care on a day-to-day basis, enabling a better understanding of how to address the challenges faced by industries attempting to produce a profitable, ethical and environmentally sustainable product (Berckmans, 2004; Føre et al., 2018a; Brijs et al., 2021) . Many of the responses evaluated in these managed settings could also be translated to wild animals given the clear link between physiology and welfare (Gregory, 2004; Baird et al., 2016; Føre et al., 2018a; Svendsen et al., 2021) . Finally, physiologging is likely to promote improved health and wellness in humans, where early detection of disease allows improved treatment outcome.

As we enter a new age in the study of physiology of animals and humans living in complex environments, the Physiologging journal aims to provide a forum where scientists, and conservation practitioners among others, can share knowledge on how modern sensing technology and analytical approaches can be used to understand physiological function and health of animals and humans.

Foraging behavior of two cattle breeds, a whole-year study: I. Heat production, activity, and energy costs1

The use of a radiotelemetric ruminal bolus to detect body temperature changes in lactating dairy cattle

Breathing frequencies of northern elephant seals at sea and on land revealed by heart rate spectral analysis

Effects of diet type and metabolizable energy intake on tympanic temperature of steers fed during summer and winter seasons

Program animal welfare: using behavioral and physiological measures to assess the well-being of animals used for education programs in zoos

Automatic on-line monitoring of animals by precision livestock farming

The role of myoglobin in the evolution of mammalian diving capacity -The August Krogh principle applied in molecular and evolutionary physiology

Physiological adjustments to deep diving in the pacific green turtle (Chelonia mydas agassizii)

Respiratory sinus arrhythmia and submersion bradycardia in bottlenose dolphins (Tursiops truncatus)

Glucose sensing by means of silicon photonics

A protocol for implementing the interim Population Consequences of Disturbance (PCoD) approach: quantifying and assessing the effects of UK offshore renewable energy developments on marine mammal populations

Biologging Special Feature

Bio-sensing technologies in aquaculture: how remote monitoring can bring us closer to our farm animals

The final countdown: Continuous physiological welfare evaluation of farmed fish during common aquaculture practices before and during harvest

Energy cost of cows' grazing activity: use of the heart rate method and the Global Positioning System for direct field estimation1

Changes in heart rate and respiratory frequency during natural behaviour of ducks, with particular reference to diving

Impact of observed and controlled water intake on reticulorumen temperature in lactating dairy cattle

Bio-logging as a method for understanding natural systems

The WATCH AF Trial: SmartWATCHes for detection of atrial fibrillation

How cheap is soaring flight in raptors? A preliminary investigation in freely-flying vultures

Sensors for dynamic physiological measurements

Accelerometry predicts daily energy expenditure in a bird with high activity levels

Cognitive control of heart rate in diving harbor porpoises

Drivers of the dive response in trained harbour porpoises (Phocoena phocoena)

Heart rate response in forced versus trained experimental dives in pinnipeds

Biosensors for the assessment of fish health: a review

Conditioned variation in heart rate during static breath-holds in the bottlenose dolphin (Tursiops truncatus) Frontiers

Cardiorespiratory coupling in cetaceans; a physiological strategy to improve gas exchange?

Re-evaluating the significance of the dive response during voluntary surface apneas in the bottlenose dolphin

Metabolic costs of foraging and the management of O2 and CO2 stores in Steller sea lions

Seal lung collapse during free diving: evidence from arterial nitrogen tensions

Precision fish farming: a new framework to improve production in aquaculture

Using acoustic telemetry to monitor the effects of crowding and delousing procedures on farmed Atlantic salmon (Salmo salar)

Heart rate and energetics of free-ranging king penguins (Aptenodytes patagonicus)

A review of livestock monitoring and the need for integrated systems

Making overall dynamic body acceleration work: on the theory of acceleration as a proxy for energy expenditure

Extreme bradycardia and tachycardia in the world's largest animal

Why whales are big but not bigger: physiological drivers and ecological limits in the age of ocean giants

Mechanics, hydrodynamics and energetics of blue whale lunge feeding: efficiency dependence on krill density

Effects of feeding on thermoregulatory behaviours and gut blood flow in white sturgeon (Acipenser transmontanus) using biotelemetry in combination with standard techniques

Physiology and Behaviour of Animal Suffering

The paradox of extreme high-altitude migration in bar-headed geese Anser indicus

Acceleration predicts energy expenditure in a fat, flightless, diving bird

Could beaked whales get the bends? Effect of diving behaviour and physiology on modelled gas exchange for three species: Ziphius cavirostris, Mesoplodon densirostris and Hyperoodon ampullatus

Standard metabolic rate at the surface and during trained submersions in adult California sea lions (Zalophus californianus)

Aquatic animal telemetry: A panoramic window into the underwater world

Activity-specific metabolic rates for diving, transiting, and resting at sea can be estimated from time-activity budgets in free-ranging marine mammals

Wearable multifunctional printed graphene sensors

Flexible and biofouling independent salinity sensor

Bioresorbable silicon electronic sensors for the brain

The use of acoustic acceleration transmitter tags for monitoring of Atlantic salmon swimming activity in recirculating aquaculture systems (RAS). Aquac. Eng. 72-73

Physiology without restraint in diving mammals

Heart rates in freely diving weddell seals, Leptonychotes weddelli

Bronchograms and tracheograms of seals under pressure

Pulmonary shunts in Harbor seals and sea lions during simulated dives to depth

SpiroSmart: using a microphone to measure lung function on a mobile phone

Wearable armband device for daily life electrocardiogram monitoring

Implanted nanosensors in marine organisms for physiological biologging: design, feasibility, and species variability

Respiratory mechanics of the loggerhead sea turtle, Caretta caretta

Insights from venous oxygen profiles: oxygen utilization and management in diving California sea lions

Deep-diving sea lions exhibit extreme bradycardia in long duration dives

Shining new light on mammalian diving physiology using wearable near-infrared spectroscopy

When the human brain goes diving: using NIRS to measure cerebral and systemic cardiovascular responses to deep, breath-hold diving in elite freedivers

Shining new light on sensory brain activation and physiological measurement in seals using wearable optical technology

Extreme hypoxemic tolerance and blood oxygen depletion in diving elephant seals

Blood temperature profiles of diving elephant seals

Reduced metabolism supports hypoxic flight in the high-flying bar-headed goose (Anser indicus)

Cardiac respones to acoustic playback experiments in the captive bottlenose dolphin (Tursiops truncatus)

End-tidal CO2 in some aquatic mammals of large size

A copper-meshed CB/PDMS electrode for underwater ECG monitoring: comparison with commercial electrodes in fresh, salt, & chlorine water

Mechanics of ventilation in the pilot whale

Smartwatch diagnosis of atrial fibrillation in patient with embolic stroke of unknown source: a case report

Whistling is metabolically cheap for communicating bottlenose dolphins (Tursiops truncatus)

Understanding the population consequences of disturbance

Cardiac output in swimming California sea lions, Zalophus californianus

Cardiac output and stroke volume in swimming harbor seals

Extreme diving in mammals: first estimates of behavioural aerobic dive limits in Cuvier's beaked whales

Digital twin: values, challenges and enablers from a modeling perspective

Gas exchange of captive freely diving grey seals (Halichoerus grypus)

Gas exchange and heart rate in the harbour porpoise, Phocoena phocoena

Novel electrodes for underwater ECG monitoring

Dolphin lung collapse and intramuscular circulation during free diving: evidence from nitrogen washout

Rene Theophile Hyacinthe Laënnec (1781-1826): the man behind the stethoscope

Diving into the world of biologging

ECG response of koalas to tourists proximity: a preliminary study

Electrocardiogram recordings in free-ranging gannets reveal minimum difference in heart rate during flapping versus gliding flight

Resting metabolic rate of a mature male beluga whale (Delphinapterus leucas)

New frontiers in biologging science

A non-invasive system to measure heart rate in hard-shelled sea turtles: Potential for field applications

Heart rate and estimated energy expenditure of flapping and gliding in black-browed albatrosses

Experimental investigations on the respiratory function in diving mammals and birds

Physiological parameter monitoring from optical recordings with a mobile phone

Wearable sensors for COVID-19: a call to action to harness our digital infrastructure for remote patient monitoring and virtual assessments

Heart rates and diving behavior of leatherback sea turtles in the eastern pacific ocean

Why Baja? A bioenergetic model for comparing metabolic rates and thermoregulatory costs of gray whale calves

Scaling and remote monitoring of tidal lung volumes of young gray whales, Eschrichtius robustus. Marine Mammal Sci

Heart rate and swimming activity as stress indicators for Atlantic salmon (Salmo salar)

Tracking livestock using global positioning systems -are we still lost?

Development of an animal-borne blood sample collection device and its deployment for the determination of cardiovascular and stress hormones in phocid seals

Cardiac responses of grey seals during diving at sea

Free-ranging bottlenose dolphins meet changing respiratory demands by breathing with a low but variable tidal volume

Editorial: ecology and behaviour of free-ranging animals studied by advanced data-logging and tracking techniques

The physiology of bottlenose dolphins (Tursiops truncatus): heart rate, metabolic rate and plasma lactate concentration during exercise

The golden age of bio-logging: how animal-bllllorne sensors are advancing the frontiers of ecology

Lip-reading in remote subjects: an attempt to quantify and separate ingestion, breathing and vocalisation in free-living animals using penguins as a model

Estimates for energy expenditure in free-living animals using acceleration proxies: A reappraisal

Moving towards acceleration for estimates of activity-specific metabolic rate in free-living animals: the case of the cormorant

Basal metabolism of an adult male killer whale (Orcinus orca)

Evidence of dominant parasympathetic nervous activity of great cormorants (Phalacrocorax carbo)

All authors listed have made a substantial, direct and intellectual contribution to the work, and approved it for publication.