Your search keyword '"Rummer, Jodie L"' showing total 10 results

1. Effects of projected end-of-century temperature on the muscle development of neonate epaulette sharks, Hemiscyllium ocellatum

Author

Thomas, Peyton A., Peele, Emily E., Wheeler, Carolyn R., Yopak, Kara, Rummer, Jodie L., Mandelman, John W., and Kinsey, Stephen T.

Published

2023

2. Novel use of deep neural networks on photographic identification of epaulette sharks (Hemiscyllium ocellatum) across life stages.

Author

Lonati, Martina, Jahanbakht, Mohammad, Atkins, Danielle, Bierwagen, Stacy L., Chin, Andrew, Barnett, Adam, and Rummer, Jodie L.

Subjects

ARTIFICIAL neural networks, IDENTIFICATION documents, ANIMAL tracks, MACHINE learning, ARTIFICIAL intelligence

Abstract

Photographic identification (photo ID) is an established method that is used to count animals and track individuals' movements. This method performs well with some species of elasmobranchs (i.e., sharks, skates, and rays) where individuals have distinctive skin patterns. However, the unique skin patterns used for ID must be stable through time to allow re‐identification of individuals in future sampling events. More recently, artificial intelligence (AI) models have substantially decreased the labor‐intensive process of matching photos in extensive photo ID libraries and increased the reliability of photo ID. Here, photo ID and AI are used for the first time to identify epaulette sharks (Hemiscyllium ocellatum) at different life stages for approximately 2 years. An AI model was developed to assess and compare the reliability of human‐classified ID patterns in juvenile and neonate sharks. The model also tested the persistence of unique patterns in adult sharks. Results indicate that immature life stages are unreliable for pattern identification, using both human and AI approaches, due to the plasticity of these subadult growth forms. Mature sharks maintain their patterns through time and can be identified by AI models with approximately 86% accuracy. The approach outlined in this study has the potential of validating the stability of ID patterns through time; however, testing on wild populations and long‐term datasets is needed. This study's novel deep neural network development strategy offers a streamlined and accessible framework for generating a reliable model from a small data set, without requiring high‐performance computing. Since many photo ID studies commence with limited datasets and resources, this AI model presents practical solutions to such constraints. Overall, this approach has the potential to address challenges associated with long‐term photo ID data sets and the application of AI for shark identification. [ABSTRACT FROM AUTHOR]

Published

2024

3. Evidence of dystocia in an oviparous shark.

Author

Wheeler, Carolyn R. and Rummer, Jodie L.

Subjects

*DYSTOCIA, *RESEARCH personnel, *RAYS (Fishes), *AGRICULTURE, *VERTEBRATES

Abstract

Dystocia, or obstructed labor, is a well‐documented phenomenon in various captive vertebrates, including fish. However, despite the documentation of dystocia in several viviparous (live‐bearing) Chondrichthyan species (i.e., sharks, rays, skates, and chimaeras), there are no reports to date of dystocia in any oviparous (egg‐laying) species. Here we present a case of a captive female epaulette shark (Hemiscyllium ocellatum) that demonstrated symptoms of dystocia in a research‐related captive breeding programme. This communication serves as documentation that dystocia can occur in oviparous Chondrichthyans, and this information can help inform researchers and veterinary practitioners for improved care. [ABSTRACT FROM AUTHOR]

Published

2024

4. Home range of newborn blacktip reef sharks (Carcharhinus melanopterus), as estimated using mark-recapture and acoustic telemetry

Author

Bouyoucos, Ian A., Romain, Martin, Azoulai, Lorine, Eustache, Kim, Mourier, Johann, Rummer, Jodie L., and Planes, Serge

Published

2020

5. Vulnerability of Eastern Tropical Pacific chondrichthyan fish to climate change.

Author

Cerutti‐Pereyra, Florencia, Drenkard, Elizabeth J., Espinoza, Mario, Finucci, Brittany, Galván‐Magaña, Felipe, Hacohen‐Domené, Ana, Hearn, Alexander, Hoyos‐Padilla, Mauricio E., Ketchum, James T., Mejía‐Falla, Paola A., Moya‐Serrano, Ana V., Navia, Andres F., Pazmiño, Diana A., Ramírez‐Macías, Deni, Rummer, Jodie L., Salinas‐de‐León, Pelayo, Sosa‐Nishizaki, Oscar, Stock, Charles, and Chin, Andrew

Subjects

ECOLOGICAL risk assessment, CHONDRICHTHYES, CARBON emissions, SEA level, CLIMATE change

Abstract

Copyright of Global Change Biology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

6. Juvenile Ribbontail Stingray, Taeniura lymma (Forsskål, 1775) (Chondrichthyes, Dasyatidae), demonstrate a unique suite of physiological adaptations to survive hyperthermic nursery conditions

Author

Dabruzzi, Theresa F., Bennett, Wayne A., Rummer, Jodie L., and Fangue, Nann A.

Published

2013

7. Population variation in the thermal response to climate change reveals differing sensitivity in a benthic shark.

Author

Gervais, Connor R., Huveneers, Charlie, Rummer, Jodie L., and Brown, Culum

Subjects

ACCLIMATIZATION, CLIMATE change, HIGH temperatures, SPECIES distribution, CHONDRICHTHYES, SHARKS, DEMOGRAPHIC change

Abstract

Many species with broad distributions are exposed to different thermal regimes which often select for varied phenotypes. This intraspecific variation is often overlooked but may be critical in dictating the vulnerability of different populations to environmental change. We reared Port Jackson shark (Heterodontus portusjacksoni) eggs from two thermally discrete populations (i.e. Jervis Bay and Adelaide) under each location's present‐day mean temperatures, predicted end‐of‐century temperatures and under reciprocal‐cross conditions to establish intraspecific thermal sensitivity. Rearing temperatures strongly influenced ṀO2Max and critical thermal limits, regardless of population, indicative of acclimation processes. However, there were significant population‐level effects, such that Jervis Bay sharks, regardless of rearing temperature, did not exhibit differences in ṀO2Rest, but under elevated temperatures exhibited reduced maximum swimming activity with step‐wise increases in temperature. In contrast, Adelaide sharks reared under elevated temperatures doubled their ṀO2Rest, relative to their present‐day temperature counterparts; however, maximum swimming activity was not influenced. With respect to reciprocal‐cross comparisons, few differences were detected between Jervis Bay and Adelaide sharks reared under ambient Jervis Bay temperatures. Similarly, juveniles (from both populations) reared under Adelaide conditions had similar thermal limits and swimming activity (maximum volitional velocity and distance) to each other, indicative of conserved acclimation capacity. However, under Adelaide temperatures, the ṀO2Rest of Jervis Bay sharks was greater than that of Adelaide sharks. This indicates that the energetics of cooler water population (Adelaide) is likely more thermally sensitive than that of the warmer population (Jervis Bay). While unique to elasmobranchs, these data provide further support that by treating species as static, homogeneous populations, we ignore the impacts of thermal history and intraspecific variation on thermal sensitivity. With climate change, intraspecific variation will manifest as populations move, demographics change or extirpations occur, starting with the most sensitive populations. [ABSTRACT FROM AUTHOR]

Published

2021

8. Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2.

Author

Heinrich, Dennis D. U., Watson, Sue-Ann, Rummer, Jodie L., Brandl, Simon J., Simpfendorfer, Colin A., Heupel, Michelle R., and Munday, Philip L.

Subjects

FORAGING behavior, SHARK behavior, CARBON dioxide in water, MARINE fish development, HYPOXIA (Water)

Abstract

Increased oceanic uptake of atmospheric carbon dioxide (CO2) is a threat to marine organisms and ecosystems. Among the most dramatic consequences predicted to date are behavioural impairments in marine fish which appear to be caused by the interference of elevated CO2 with a key neurotransmitter receptor in the brain. In this study, we tested the effects of elevated CO2 on the foraging and shelter-seeking behaviours of the reef-dwelling epaulette shark, Hemiscyllium ocellatum. Juvenile sharks were exposed for 30 d to control CO2 (400 µatm) and two elevated CO2 treatments (615 and 910 µatm), consistent with medium- and high-end projections for ocean pCO2 by 2100. Contrary to the effects observed in teleosts and in some other sharks, behaviour of the epaulette shark was unaffected by elevated CO2. A potential explanation is the remarkable adaptation of H. ocellatum to low environmental oxygen conditions (hypoxia) and diel fluctuations in CO2 encountered in their shallow reef habitat. This ability translates into behavioural tolerance of near-future ocean acidification, suggesting that behavioural tolerance and subsequent adaptation to projected future CO2 levels might be possible in some other fish, if adaptation can keep pace with the rate of rising CO2 levels. [ABSTRACT FROM AUTHOR]

Published

2016

9. Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2.

Author

Heinrich, Dennis D. U., Watson, Sue-Ann, Rummer, Jodie L., Brandl, Simon J., Simpfendorfer, Colin A., Heupel, Michelle R., and Munday, Philip L.

Subjects

*FORAGING behavior, *SHARK behavior, *CARBON dioxide in water, *MARINE fish development, *HYPOXIA (Water)

Abstract

Increased oceanic uptake of atmospheric carbon dioxide (CO2) is a threat to marine organisms and ecosystems. Among the most dramatic consequences predicted to date are behavioural impairments in marine fish which appear to be caused by the interference of elevated CO2 with a key neurotransmitter receptor in the brain. In this study, we tested the effects of elevated CO2 on the foraging and shelter-seeking behaviours of the reef-dwelling epaulette shark, Hemiscyllium ocellatum. Juvenile sharks were exposed for 30 d to control CO2 (400 µatm) and two elevated CO2 treatments (615 and 910 µatm), consistent with medium- and high-end projections for ocean pCO2 by 2100. Contrary to the effects observed in teleosts and in some other sharks, behaviour of the epaulette shark was unaffected by elevated CO2. A potential explanation is the remarkable adaptation of H. ocellatum to low environmental oxygen conditions (hypoxia) and diel fluctuations in CO2 encountered in their shallow reef habitat. This ability translates into behavioural tolerance of near-future ocean acidification, suggesting that behavioural tolerance and subsequent adaptation to projected future CO2 levels might be possible in some other fish, if adaptation can keep pace with the rate of rising CO2 levels. [ABSTRACT FROM AUTHOR]

Published

2016

10. How hot is too hot? Thermal tolerance, performance, and preference in juvenile mangrove whiprays, Urogymnus granulatus.

Author

Higgins, Emily, Bouyoucos, Ian A., Downie, Adam T., Illing, Björn, Martins, Ana P.B., Simpfendorfer, Colin A., and Rummer, Jodie L.

Subjects

*MANGROVE ecology, *AEROBIC metabolism, *PHYSIOLOGY, *HEAT waves (Meteorology), *BODY temperature, *ACCLIMATIZATION

Abstract

Mangrove habitats can serve as nursery areas for sharks and rays. Such environments can be thermally dynamic and extreme; yet, the physiological and behavioural mechanisms sharks and rays use to exploit such habitats are understudied. This study aimed to define the thermal niche of juvenile mangrove whiprays, Urogymnus granulatus. First, temperature tolerance limits were determined via the critical thermal maximum (CT Max) and minimum (CT Min) of mangrove whiprays at summer acclimation temperatures (28 °C), which were 17.5 °C and 39.9 °C, respectively. Then, maximum and routine oxygen uptake rates (Ṁ O 2max and Ṁ O 2routine , respectively), post-exercise oxygen debt, and recovery were estimated at current (28 °C) and heatwave (32 °C) temperatures, revealing moderate temperature sensitivities (i.e., Q 10) of 2.4 (Ṁ O 2max) and 1.6 (Ṁ O 2routine), but opposing effects on post-exercise oxygen uptake. Finally, body temperatures (T b) of mangrove whiprays were recorded using external temperature loggers, and environmental temperatures (T e) were recorded using stationary temperature loggers moored in three habitat zones (mangrove, reef flat, and reef crest). As expected, environmental temperatures varied between sites depending on depth. Individual mangrove whiprays presented significantly lower T b relative to T e during the hottest times of the day. Electivity analysis showed tagged individuals selected temperatures from 24.0 to 37.0 °C in habitats that ranged from 21.1 to 43.5 °C. These data demonstrate that mangrove whiprays employ thermotaxic behaviours and a thermally insensitive aerobic metabolism to thrive in thermally dynamic and extreme habitats. Tropical nursery areas may, therefore, offer important thermal refugia for young rays. However, these tropical nursery areas could become threatened by mangrove and coral habitat loss, and climate change. • Mangrove whiprays have high heat tolerance but poor cold tolerance relative to rays. • Mangrove whiprays have low thermal sensitivity of oxygen uptake rates. • Mangrove whiprays showed signs of thermotaxic behaviour. • Mangrove whiprays showed positive electivity above and below body temperatures. • Mangrove habitats may act as thermal refugia for young sharks and rays. [ABSTRACT FROM AUTHOR]

Published

2024