Aggressiveness-related behavioural types in the pearly razorfish

Martorell-Barceló, Martina; Mulet, Júlia; Sanllehi, Javier; Signaroli, Marco; Lana, Arancha; Barceló-Serra, Margarida; Aspillaga, Eneko; Alós, Josep

doi:10.7717/peerj.10731

Cited by 12 publications

(10 citation statements)

References 86 publications

(155 reference statements)

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“…Nevertheless, this was not the main reason for switching to a deep learning approach, as the efficiency of a well-implemented traditional CV tracking algorithm was not questioned. However, the following set of experimental trails in the behavioural arenas required for another fish species ( Xyrichtys novacula ), applying changing light conditions (experiments on circadian rhythms and chronotypes require day and night light cycles) and presenting new objects ( Martorell-Barceló et al, 2021 ). Under these circumstances, we decided it was more advantageous for our research to train another neural network than having to manually readjust a CV algorithm.…”

Section: Discussionmentioning

confidence: 99%

Measuring inter-individual differences in behavioural types of gilthead seabreams in the laboratory using deep learning

Signaroli

Lana

Martorell-Barceló

et al. 2022

PeerJ

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Deep learning allows us to automatize the acquisition of large amounts of behavioural animal data with applications for fisheries and aquaculture. In this work, we have trained an image-based deep learning algorithm, the Faster R-CNN (Faster region-based convolutional neural network), to automatically detect and track the gilthead seabream, Sparus aurata, to search for individual differences in behaviour. We collected videos using a novel Raspberry Pi high throughput recording system attached to individual experimental behavioural arenas. From the continuous recording during behavioural assays, we acquired and labelled a total of 14,000 images and used them, along with data augmentation techniques, to train the network. Then, we evaluated the performance of our network at different training levels, increasing the number of images and applying data augmentation. For every validation step, we processed more than 52,000 images, with and without the presence of the gilthead seabream, in normal and altered (i.e., after the introduction of a non-familiar object to test for explorative behaviour) behavioural arenas. The final and best version of the neural network, trained with all the images and with data augmentation, reached an accuracy of 92,79% ± 6.78% [89.24–96.34] of correct classification and 10.25 ± 61.59 pixels [6.59-13.91] of fish positioning error. Our recording system based on a Raspberry Pi and a trained convolutional neural network provides a valuable non-invasive tool to automatically track fish movements in experimental arenas and, using the trajectories obtained during behavioural tests, to assay behavioural types.

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Section: Discussionmentioning

confidence: 99%

Measuring inter-individual differences in behavioural types of gilthead seabreams in the laboratory using deep learning

Signaroli

Lana

Martorell-Barceló

et al. 2022

PeerJ

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“…Martorell‐Barceló et al. (2021) filmed individual fish continuously over multiple days to investigate the repeatability of aggressive behaviour, which they extended with deep learning to detect fish automatically over long periods of time (Signaroli, 2020). To further investigate the emergence of individual behavioural types, Laskowski, Jolles et al (pers.…”

Section: Overview Of Applications Across the Biological Domainmentioning

confidence: 99%

“…Lertvilai (2020) built an automated recording device specifically for autonomous zooplankton surveys in the wild. And Hermann et al (2020) developed F I G U R E 3 A diverse range of Raspberry Pi applications: (a) plant phenotyping(Tausen et al, 2020), (b) high-throughput animal recordings(Jolles et al, 2017), (c) a dedicated plant growth cabinet(Ghosh et al, 2018), (d) a 3D-printed microscope (FlyPi; MaiaChagas et al, 2017), (e) an RFID-equipped birdfeeder(Youngblood, 2020), f) long-term monitoring of fish behaviour(Martorell-Barceló et al, 2021), (g) automated bird puzzle boxes(Chimento et al, 2021), (h) an autonomous underwater camera system(Lertvilai, 2020), (i) automated quantification of fly climbing behaviour(Spierer et al, 2021), (j) a field audio recorder for bioacoustics(Bradfer-Lawrence et al, 2019;Whytock & Christie, 2017), (k) an operant conditioning device for wild mesocarnivores(Stanton et al, 2020), (l) autonomous ecosystem monitoring(Sethi et al, 2018), (m) closed-loop virtual reality(Tadres & Louis, 2020), (n) long-term recording of fish from birth (K. Laskowski & J. Jolles, pers. comm.…”

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confidence: 99%

Broad‐scale applications of the Raspberry Pi: A review and guide for biologists

Jolles

2021

Methods Ecol Evol

148

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1. The field of biology has seen tremendous technological progress in recent years, fuelled by the exponential growth in processing power and high-level computing, and the rise of global information sharing. Low-cost single-board computers are predicted to be one of the key technological advancements to further revolutionise this field.2. So far, an overview of current uptake of these devices and a general guide to help researchers integrate them in their work has been missing. In this paper I focus on the most widely used single-board computer, the Raspberry Pi, and review its broad applications and uses across the biological domain.3. Since its release in 2012, the Raspberry Pi has been increasingly taken up by biologists, in the laboratory, the field and in the classroom, and across a wide range of disciplines. A hugely diverse range of applications exists that ranges from simple solutions to dedicated custom-build devices, including nest-box monitoring, wildlife camera trapping, high-throughput behavioural recording, large-scale plant phenotyping, underwater video surveillance, closed-loop operant learning experiments and autonomous ecosystem monitoring. Despite the breadth of its implementations, the depth of uptake of the Raspberry Pi by the scientific community is still limited. 4. The broad capabilities of the Raspberry Pi, combined with its low cost, ease of use and large user community make it a great research tool for almost any project. To help accelerate the uptake of the Raspberry Pi by the scientific community, I provide detailed guidelines, recommendations and considerations, and 30+ step-by-step guides on a dedicated accompanying website (http://raspb erryp i-guide.github.io). I hope this paper will help generate more awareness about the Raspberry Pi among scientists and thereby both fuel the democratisation of science and ultimately help advance our understanding of biology, from the micro-to the macro-scale.

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“…In our study, a mirror was placed in contact with one side of the behavioral arena, simulating the presence of a conspeci c at close range (Table 1). We measured the number of aggressive and hostile "approaches" the sh gave to the mirror per hour by manually visualizing the videos 24,38 .…”

Section: Standardized Behavioral Testsmentioning

confidence: 99%

“…Many of the causes and consequences of sh BTs have been studied on freshwater shes, mainly on zebra sh, Danio rerio 17 , three-spined stickleback, G. aculeatus 18 , and guppy, Poecilia reticulata 19 . In marine species, consistency in individual behavior has been reported, for example, for two-spotted goby, Gobiusculus avescens 20 , gilthead seabream, Sparus aurata 21 , European seabass, Dicentrarchus labrax 22 and pearly razor sh, Xyrichtys novacula 23,24 . In this study, we examine the degree of consistency of individual behavior in wild and reared samples of juvenile gilthead seabreams.…”

Section: Introductionmentioning

confidence: 96%

Disparate behavioral types in wild and reared juveniles of gilthead seabream

Sanllehi¹,

Signaroli²,

Pons³

et al. 2023

Preprint

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Fish differ consistently in behavior within the same species and population, reflecting distinct behavioral types (BTs). Comparing the behavior of wild and reared individuals provides an excellent opportunity to delve into the ecological and evolutionary consequences of BTs. In this work, we evaluated the behavioral variation of wild and reared juvenile gilthead seabreams, Sparus aurata, a highly relevant species for aquaculture and fisheries. We quantified behavioral variation along the five major axes of fish behavioral traits (exploration-avoidance, aggressiveness, sociability, shyness-boldness, and activity) using standardized behavioral tests and a deep learning tracking algorithm for behavioral annotation. Results revealed significant repeatability in all five behavior traits, suggesting high consistency of individual behavioral variation across the different axes in this species. We found reared fish to be more aggressive, social and active compared to their wild conspecifics. Reared individuals also presented less variance in their aggressiveness, lacking very aggressive and very tame individuals. Phenotypic correlation decomposition between behavioral types revealed two different behavioral syndromes: exploration-sociability and exploration-activity. Our work establishes the first baseline of repeatability scores in wild and reared gilthead seabreams, providing novel insight into the behavior of this important commercial species with implications for fisheries and aquaculture.

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Aggressiveness-related behavioural types in the pearly razorfish

Cited by 12 publications

References 86 publications

Measuring inter-individual differences in behavioural types of gilthead seabreams in the laboratory using deep learning

Measuring inter-individual differences in behavioural types of gilthead seabreams in the laboratory using deep learning

Broad‐scale applications of the Raspberry Pi: A review and guide for biologists

Disparate behavioral types in wild and reared juveniles of gilthead seabream

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