Cardiac oxygen limitation during an acute thermal challenge in the European perch: Effects of chronic environmental warming and experimental hyperoxia

Oxygen supply to the heart has been hypothesized to limit cardiac performance and whole animal acute thermal tolerance (CTmax) in fish. We tested these hypotheses by continuously measuring venous oxygen tension (Pvo2) and cardiovascular variables in vivo during acute warming in European perch ( Perc...

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Bibliographic Details
Main Authors: A Ekström, J Brijs, Timothy Clark, A Gräns, F Jutfelt, E Sandblom
Format: Article in Journal/Newspaper
Language:unknown
Published: 2016
Subjects:
Science & Technology
Life Sciences & Biomedicine
Physiology
cardiac performance
myocardial oxygenation
PvO(2) threshold
thermal acclimation
teleost
TROUT ONCORHYNCHUS-MYKISS
ACUTE TEMPERATURE INCREASE
RAINBOW-TROUT
CLIMATE-CHANGE
AEROBIC SCOPE
SALMON ONCORHYNCHUS
GADUS-MORHUA
ACCLIMATION CAPACITY
CHINOOK SALMON
PACIFIC SALMON
Pvo2 threshold
Acute Disease
Adaptation
Physiological
Animals
Ecosystem
Global Warming
Heart
Heart Rate
Heat-Shock Response
Myocardium
Oxygen
Perches
Thermotolerance
050204 Environmental Impact Assessment
050205 Environmental Management
School of Life and Environmental Sciences
4104 Environmental management
Pacific
Gadus morhua
Online Access:http://hdl.handle.net/10536/DRO/DU:30105039
https://figshare.com/articles/journal_contribution/Cardiac_oxygen_limitation_during_an_acute_thermal_challenge_in_the_European_perch_Effects_of_chronic_environmental_warming_and_experimental_hyperoxia/20824054
Description
Summary:Oxygen supply to the heart has been hypothesized to limit cardiac performance and whole animal acute thermal tolerance (CTmax) in fish. We tested these hypotheses by continuously measuring venous oxygen tension (Pvo2) and cardiovascular variables in vivo during acute warming in European perch ( Perca fluviatilis) from a reference area during summer (18°C) and a chronically heated area (Biotest enclosure) that receives warm effluent water from a nuclear power plant and is normally 5–10°C above ambient (24°C at the time of experiments). While CTmaxwas 2.2°C higher in Biotest compared with reference perch, the peaks in cardiac output and heart rate prior to CTmaxoccurred at statistically similar Pvo2values (2.3–4.0 kPa), suggesting that cardiac failure occurred at a common critical Pvo2threshold. Environmental hyperoxia (200% air saturation) increased Pvo2across temperatures in reference fish, but heart rate still declined at a similar temperature. CTmaxof reference fish increased slightly (by 0.9°C) in hyperoxia, but remained significantly lower than in Biotest fish despite an improved cardiac output due to an elevated stroke volume. Thus, while cardiac oxygen supply appears critical to elevate stroke volume at high temperatures, oxygen limitation may not explain the bradycardia and arrhythmia that occur prior to CTmax. Acute thermal tolerance and its thermal plasticity can, therefore, only be partially attributed to cardiac failure from myocardial oxygen limitations, and likely involves limiting factors on multiple organizational levels.

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