Best practices for non‐lethal blood sampling of fish <i>via</i> the caudal vasculature

Lawrence, Michael; Raby, Graham D.; Teffer, Amy K.; Jeffries, Ken M.; Danylchuk, Andy J.; Eliason, Erika J.; Hasler, Caleb T.; Clark, Timothy D.; Cooke, Steven J.

doi:10.1111/jfb.14339

Cited by 68 publications

(58 citation statements)

References 132 publications

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“…Alternatively, for a trait like ODBA for which sources of measurement error in sharks are understood, observed variability is likely due to accelerometers being too large 42 , dorsal fins of neonates not being rigid enough for attachment 43 , and the brevity of monitoring that precluded us from accounting for circadian activity rhythms. Among haematological traits, variability in blood pH, for instance, can result because arterial blood cannot be selectively sampled in elasmobranch fishes using caudal puncture 44 . Variation in ṀO 2Min and ṀO 2Max fell within www.nature.com/scientificreports/ ranges reported in teleost fishes, whilst variation in aerobic scope was greater 32 .…”

Section: Discussionmentioning

confidence: 99%

The power struggle: assessing interacting global change stressors via experimental studies on sharks

Bouyoucos

Watson

Planes

et al. 2020

Sci Rep

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Ocean warming and acidification act concurrently on marine ectotherms with the potential for detrimental, synergistic effects; yet, effects of these stressors remain understudied in large predatory fishes, including sharks. We tested for behavioural and physiological responses of blacktip reef shark (Carcharhinus melanopterus) neonates to climate change relevant changes in temperature (28 and 31 °C) and carbon dioxide partial pressures (pCO2; 650 and 1050 µatm) using a fully factorial design. Behavioural assays (lateralisation, activity level) were conducted upon 7–13 days of acclimation, and physiological assays (hypoxia tolerance, oxygen uptake rates, acid–base and haematological status) were conducted upon 14–17 days of acclimation. Haematocrit was higher in sharks acclimated to 31 °C than to 28 °C. Significant treatment effects were also detected for blood lactate and minimum oxygen uptake rate; although, these observations were not supported by adequate statistical power. Inter-individual variability was considerable for all measured traits, except for haematocrit. Moving forward, studies on similarly ‘hard-to-study’ species may account for large inter-individual variability by increasing replication, testing larger, yet ecologically relevant, differences in temperature and pCO2, and reducing measurement error. Robust experimental studies on elasmobranchs are critical to meaningfully assess the threat of global change stressors in these data-deficient species.

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Section: Discussionmentioning

confidence: 99%

The power struggle: assessing interacting global change stressors via experimental studies on sharks

Bouyoucos

Watson

Planes

et al. 2020

Sci Rep

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show abstract

“…This method, colloquially known as the “grab‐and‐stab” technique, always involves at least some handling stress, as the fish must first be netted from a holding tank and restrained prior to drawing blood (Clark et al., 2011). In many cases, fish are also euthanized with an overdose of anaesthetic (e.g., MS‐222) prior to drawing blood—a process which undoubtedly disturbs baseline physiological condition (although see Lawrence et al., 2020 for a recent review on non‐lethal blood sampling in fish). Handling stress, although unavoidable, makes it difficult to capture the resting haematological profile of free‐ranging fish and potentially masks underlying baseline changes in haematological variables, particularly if the changes are subtle.…”

Section: The Effects Of Hyperoxia On the Oxygen Transport Cascadementioning

confidence: 99%

Fish and hyperoxia—From cardiorespiratory and biochemical adjustments to aquaculture and ecophysiology implications

2020

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Hyperoxia occurs when water oxygen (O2) levels exceed normal atmospheric pressure (i.e., >100% air saturation). Fish can experience hyperoxia in shallow environments due to photosynthesis or in aquaculture through O2 supplementation. This review provides a comprehensive synthesis of the effects of hyperoxia on fish, spanning influences on cardiorespiratory function, acid‐base balance, oxidative stress and whole animal performance (e.g., thermal tolerance and growth). Fish hypoventilate in hyperoxia, but arterial and venous blood oxygenation increases in spite of reduced convection. Persistently high levels of blood oxygenation in hyperoxia do not commonly result in reduced blood O2 carrying capacity, but assessments in undisturbed fish are required to clarify this. Hypoventilation also causes the retention of carbon dioxide, hence respiratory acidosis. Another consequence of hyperoxia is increased levels of oxidative stress and concomitant changes to antioxidant defence systems. Despite these changes, however, the bulk of evidence shows no effect of hyperoxia on growth. Hyperoxia does impact the aerobic metabolic rate of fish with either no effect or elevated resting metabolic rate and substantial increases in maximum metabolic rate. There is also evidence that hyperoxia increases aerobic capacity improves cardiac performance and mitigates anaerobic stress during acute warming. Along with improved upper thermal tolerance in some species, these findings collectively suggest that hyperoxia might provide fish a metabolic refuge during acute warming. Since hyperoxia occurs in shallow aquatic habitats, further research establishing the ecophysiological implications of concomitant heat stress and hyperoxia is pertinent, particularly with a changing climate.

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“…Postrelease mortality rates vary widely among shark species (Ellis et al, 2017) and depend on factors such as gear type, duration of capture, respiratory mode (Dapp et al, 2016), and aerobic scope (Priede, 1985;Korsmeyer et al, 1996;Talwar et al, 2017). Traditionally, PRM rates have been assessed by using pop-off satellite archival tags (PSATs) (e.g., Heberer et al, 2010;French et al, 2015), but the cost of such tags often precludes the use of large sample sizes (Donaldson et al, 2008), making accurate assessments of PRM for a species difficult.…”

mentioning

confidence: 99%

Stress response and postrelease mortality of blacktip sharks (Carcharhinus limbatus) captured in shore-based and charter-boat-based recreational fisheries

Weber¹,

Frazier²,

Whitney³

et al. 2020

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Best practices for non‐lethal blood sampling of fish via the caudal vasculature

Cited by 68 publications

References 132 publications

The power struggle: assessing interacting global change stressors via experimental studies on sharks

The power struggle: assessing interacting global change stressors via experimental studies on sharks

Fish and hyperoxia—From cardiorespiratory and biochemical adjustments to aquaculture and ecophysiology implications

Stress response and postrelease mortality of blacktip sharks (Carcharhinus limbatus) captured in shore-based and charter-boat-based recreational fisheries

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