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McIntosh, P. et al. Supersizing salmon farms within the coastal zone: A world evaluation of adjustments in farm expertise and placement from 2005 to 2020. Aquaculture 553, 738046 (2022).
Moe Føre, H. et al. Technological improvements selling sustainable salmon (Salmo salar) aquaculture in Norway. Aquac Rep. 24, 101115 (2022).
Farrell, A. P. Bulk oxygen uptake measured with over 60,000 kg of grownup salmon throughout live-haul transportation at sea. Aquaculture 254, 646–652 (2006).
Johansson, D. et al. Effect of environmental elements on swimming depth preferences of Atlantic salmon (Salmo salar L.) and temporal and spatial variations in oxygen ranges in sea cages at a fjord website. Aquaculture 254, 594–605 (2006).
Solstorm, D. et al. Dissolved oxygen variability in a industrial sea-cage exposes farmed Atlantic salmon to progress limiting circumstances. Aquaculture 486, 122–129 (2018).
Tang, S., Brauner, C. J. & Farrell, A. P. Using bulk oxygen uptake to evaluate the welfare of grownup Atlantic salmon, Salmo salar, throughout industrial live-haul transport. Aquaculture 286, 318–323 (2009).
Nilsson, J. et al. Standardized Operational Welfare Monitoring for Salmon in Food Fish Farms. (Norwegian Institute of Marine Research, 2022).
Noble, C. et al. Welfare Indicators for Farmed Atlantic Salmon: Tools for Assessing Fish Welfare. (Norwegian Institute of Food, Fisheries and Aquaculture Research, 2018).
Claireaux, G. & Chabot, D. Responses by fishes to environmental hypoxia: integration by Fry’s idea of cardio metabolic scope. J. Fish. Biol. 88, 232–251 (2016).
Remen, M., Oppedal, F., Imsland, A. Okay., Olsen, R. E. & Torgersen, T. Hypoxia tolerance thresholds for post-smolt Atlantic salmon: Dependency of temperature and hypoxia acclimation. Aquaculture 416–417, 41–47 (2013).
Remen, M., Oppedal, F., Torgersen, T., Imsland, A. Okay. & Olsen, R. E. Effects of cyclic environmental hypoxia on physiology and feed consumption of post-smolt Atlantic salmon: Initial responses and acclimation. Aquaculture 326–329, 148–155 (2012).
Remen, M., Sievers, M., Torgersen, T. & Oppedal, F. The oxygen threshold for maximal feed consumption of Atlantic salmon post-smolts is extremely temperature-dependent. Aquaculture 464, 582–592 (2016).
Neis, B. et al. Mass mortality occasions in marine salmon aquaculture and their affect on occupational well being and security hazards and threat of damage. Aquaculture 566, 739225 (2023).
Sajid, Z. et al. An aquaculture threat mannequin to grasp the causes and penalties of Atlantic Salmon mass mortality occasions: A evaluation. Rev. Aquac. 16, 1674–1695 (2024).
Føre, M. et al. Digital Twins in intensive aquaculture — Challenges, alternatives and future prospects. Comput. Electron. Agric. 218, 108676 (2024).
Alver, M. O., Føre, M. & Alfredsen, J. A. Predicting oxygen ranges in Atlantic salmon (Salmo salar) sea cages. Aquaculture 548, 737720 (2022).
Bergsson, H., Svendsen, M. B. S. & Steffensen, J. F. Model of Oxygen Conditions inside Aquaculture Sea Cages. Biology 12, 1408 (2023).
Jónsdóttir, Okay. E. et al. Fish welfare primarily based classification methodology of ocean present speeds at aquaculture websites. Aquac Environ. Interact. 11, 249–261 (2019).
Skagseth, Ø., Oppedal, F., Søiland, H. & Hvas, M. Measured oxygen ranges in Norwegian waters and implications for future offshore Atlantic salmon aquaculture. Sci. Rep. 15, 29416 (2025).
Alver, M. O., Føre, M. & Alfredsen, J. A. Effect of cage measurement on oxygen ranges in Atlantic salmon sea cages: A mannequin research. Aquaculture 562, 738831 (2023).
Alver, M. O., Føre, M., Urke, H. A. & Alfredsen, J. A. Mathematical modelling of dissolved oxygen ranges in a multi-cage salmon farm. Aquaculture 593, 741291 (2024).
Russell, W. M. S., Burch, R. L. & Hume, C. W. The Principles of Humane Experimental Technique. (Methuen, 1959).
Berntsson, E. V. C. et al. Managing the Dissolved Oxygen Balance of Open Atlantic Salmon Sea Cages: A Narrative Review. Rev. Aquac. 17, e12992 (2025).
Oppedal, F., Dempster, T. & Stien, L. H. Environmental drivers of Atlantic salmon behaviour in sea-cages: A evaluation. Aquaculture 311, 1–18 (2011).
Clarke, A. & Johnston, N. M. Scaling of metabolic fee with physique mass and temperature in teleost fish. J. Anim. Ecol. 68, 893–905 (1999).
Forsberg, O. I. Modelling oxygen consumption charges of post-smolt Atlantic salmon in commercial-scale, land-based farms. Aquac Int. 2, 180–196 (1994).
Kraskura, Okay., Patterson, D. A. & Eliason, E. J. A evaluation of grownup salmon most swim efficiency. Can. J. Fish. Aquat. Sci. 81, 1174–1216 (2024).
Thorarensen, H. & Farrell, A. P. The organic necessities for post-smolt Atlantic salmon in closed-containment techniques. Aquaculture 312, 1–14 (2011).
Grøttum, J. A. & Sigholt, T. A mannequin for oxygen consumption of Atlantic salmon (Salmo salar) primarily based on measurements of particular person fish in a tunnel respirometer. Aquac Eng. 17, 241–251 (1998).
Macnaughton, C. J., Deslauriers, D., Ipsen, E. L., Corey, E. & Enders, E. C. Using meta-analysis to derive a respiration mannequin for Atlantic salmon (Salmo salar) to evaluate bioenergetics necessities of juveniles in two Canadian rivers. Can. J. Fish. Aquat. Sci. 76, 2225–2234 (2019).
Chabot, D., Steffensen, J. F. & Farrell, A. P. The dedication of ordinary metabolic fee in fishes. J. Fish. Biol. 88, 81–121 (2016).
Norin, T. & Clark, T. D. Measurement and relevance of most metabolic fee in fishes. J. Fish. Biol. 88, 122–151 (2016).
Hvas, M. & Oppedal, F. Sustained swimming capability of Atlantic salmon. Aquac Environ. Interact. 9, 361–369 (2017).
Gjedrem, T., Gjøen, H. M. & Gjerde, B. Genetic origin of Norwegian farmed Atlantic salmon. Aquaculture 98, 41–50 (1991).
Remen, M. et al. Critical swimming pace in teams of Atlantic salmon Salmo salar. Aquac Environ. Interact 8, 659–664 (2016).
Hvas, M., Folkedal, O., Imsland, A. & Oppedal, F. The impact of thermal acclimation on cardio scope and important swimming pace in Atlantic salmon, Salmo salar. J. Exp. Biol. 220, 2757–2764 (2017).
Hvas, M. & Oppedal, F. Influence of experimental set-up and methodology for measurements of metabolic charges and important swimming pace in Atlantic salmon Salmo salar. J. Fish. Biol. 95, 893–902 (2019).
Morin, A. et al. Tank- and cage-farmed Atlantic salmon show related swimming efficiency and urge for food restoration regardless of variations in gill and coronary heart morphology. Aquaculture 609, 742826 (2025).
Gjedrem, T. Genetic enchancment for the event of environment friendly international aquaculture: A private opinion evaluation. Aquaculture 344–349, 12–22 (2012).
Janssen, Okay., Chavanne, H., Berentsen, P. & Komen, H. Impact of selective breeding on European aquaculture. Aquaculture 472, 8–16 (2017).
Næve, I., Korsvoll, S. A., Santi, N., Medina, M. & Aunsmo, A. The energy of genetics: Past and future contribution of balanced genetic choice to sustainable progress and productiveness of the Norwegian Atlantic salmon (Salmo salar) trade. Aquaculture 553, 738061 (2022).
Oppedal, F., Vågseth, T., Dempster, T., Juell, J. E. & Johansson, D. Fluctuating sea-cage environments modify the consequences of stocking densities on manufacturing and welfare parameters of Atlantic salmon (Salmo salar L). Aquaculture 315, 361–368 (2011).
Brown, J. H., Gillooly, J. F., Allen, A. P., Savage, V. M. & West, G. B. Toward a Metabolic Theory of Ecology. Ecology 85, 1771–1789 (2004).
Calder, W. A. Size Function, and Life History. (Harvard University Press, 1984).
Kleiber, M. The Fire of Life: An Introduction to Animal Energetics. (John Wiley & Sons, Inc., 1961).
Peters, R. H. The Ecological Implications of Body Size. (Cambridge University Press, 1983).
Schmidt-Nielsen, Okay. Scaling: Why Is Animal Size so Important?. (Cambridge University Press, 1984).
Clarke, A. & Fraser, Okay. P. P. Why Does Metabolism Scale with Temperature?. Funct. Ecol. 18, 243–251 (2004).
Arrhenius, S. On the response fee of the inversion of non-refined sugar upon souring. J. Phys. Chem. 4, 226–248 (1889).
Arrhenius, S. Quantitative Laws in Biological Chemistry. (G. Bell and Sons, Ltd., 1916).
van ’t Hoff, J. H. Studies in Chemical Dynamics. (F. Müller and Co, Amsterdam, 1896).
Brett, J. R. The respiratory metabolism and swimming efficiency of younger sockeye salmon. J. Fish. Res. Board. Can. 21, 1183–1226 (1964).
Videler, J. J. Fish Swimming. (Springer Netherlands, 1993).
Webb, P. W. Hydrodynamics and Energetics of Fish Propulsion. (Fisheries Research Board of Canada, 1975).
Oldham, T., Nowak, B., Hvas, M. & Oppedal, F. Metabolic and useful impacts of hypoxia fluctuate with measurement in Atlantic salmon. Comp. Biochem. Physiol. Mol. Integr. Physiol. 231, 30–38 (2019).
Hvas, M. Swimming energetics of Atlantic salmon in relation to prolonged fasting at totally different temperatures. Conserv. Physiol. 10, coac037 (2022).
Hvas, M., Karlsbakk, E., Mæhle, S., Wright, D. W. & Oppedal, F. The gill parasite Paramoeba perurans compromises cardio scope, swimming capability and ion stability in Atlantic salmon. Conserv Physiol 5, cox066 (2017).
Hvas, M., Nilsen, T. O. & Oppedal, F. Oxygen Uptake and Osmotic Balance of Atlantic Salmon in Relation to Exercise and Salinity Acclimation. Front Mar. Sci 5, 368 (2018).
Hvas, M., Folkedal, O. & Oppedal, F. What is the restrict of sustained swimming in Atlantic salmon submit smolts?. Aquac Environ. Interact. 13, 189–198 (2021).
R Core Team. R: The R Project for Statistical Computing. (R Foundation for Statistical Computing, 2025).
Pinheiro, J., Bates, D. & Core Team. R. nlme: Linear and Nonlinear Mixed Effects Models. (2025).
Glazier, D. S. Beyond the ‘3/4-power law’: variation within the intra-and interspecific scaling of metabolic fee in animals. Biol. Rev. 80, 611–662 (2005).
Glazier, D. S. Activity impacts intraspecific body-size scaling of metabolic fee in ectothermic animals. J. Comp. Physiol. B. 179, 821–828 (2009).
Burgetz, I. J., Rojas-Vargas, A., Hinch, S. G. & Randall, D. J. Initial Recruitment of Anaerobic Metabolism During Sub-Maximal Swimming in Rainbow Trout (Oncorhynchus mykiss). J. Exp. Biol. 201, 2711–2721 (1998).
Geist, D. R. et al. Relationships between metabolic fee, muscle electromyograms and swim efficiency of grownup chinook salmon. J. Fish. Biol. 63, 970–989 (2003).
Mowi. Salmon Farming Industry Handbook. (2024).
Barrett, L. T., Oldham, T., Kristiansen, T. S., Oppedal, F. & Stien, L. H. Declining size-at-harvest in Norwegian salmon aquaculture: Lice, illness, and the position of stunboats. Aquaculture 559, 738440 (2022).
Falconer, L. et al. Marine aquaculture websites have large potential as information suppliers for local weather change assessments. Aquaculture 595, 741519 (2025).
Korus, J., Filgueira, R. & Grant, J. Influence of temperature on the behaviour and physiology of Atlantic salmon (Salmo salar) on a industrial farm. Aquaculture 589, 740978 (2024).
Hansen, T. J., Fjelldal, P. G., Folkedal, O., Vågseth, T. & Oppedal, F. Effects of sunshine supply and depth on sexual maturation, progress and swimming behaviour of Atlantic salmon in sea cages. Aquac Environ. Interact. 9, 193–204 (2017).
Hvas, M., Folkedal, O. & Oppedal, F. Fish welfare in offshore salmon aquaculture. Rev. Aquac. 13, 836–852 (2021).
Juell, J. E. The behaviour of Atlantic salmon in relation to environment friendly cage-rearing. Rev. Fish. Biol. Fish. 5, 320–335 (1995).
Oppedal, F., Bui, S., Stien, L. H., Overton, Okay. & Dempster, T. Snorkel expertise to scale back sea lice infestations: efficacy will depend on salinity on the farm website, however snorkels have minimal results on salmon manufacturing and welfare. Aquac Environ. Interact. 11, 445–457 (2019).
Sutterlin, A. M., Jokola, Okay. J. & Holte, B. Swimming Behavior of Salmonid Fish in Ocean Pens. J. Fish. Res. Board. Can. 36, 948–954 (1979).
Warren-Myers, F. et al. Full manufacturing cycle, industrial scale tradition of salmon in submerged sea-cages with air domes reduces lice infestation, however creates manufacturing and welfare challenges. Aquaculture 548, 737570 (2022).
Warren-Myers, F. et al. Efficiency of salmon manufacturing in submerged cages with air domes matches customary floor cages when environments are related. Aquaculture 586, 740751 (2024).
Ernest, S. Okay. M. et al. Thermodynamic and metabolic results on the scaling of manufacturing and inhabitants vitality use. Ecol. Lett. 6, 990–995 (2003).
Gillooly, J. F., Brown, J. H., West, G. B., Savage, V. M. & Charnov, E. L. Effects of measurement and temperature on metabolic fee. Science 293, 2248–2251 (2001).
West, G. B., Brown, J. H. & Enquist, B. J. A General Model for the Origin of Allometric Scaling Laws in Biology. Science 276, 122–126 (1997).
West, G. B. & Brown, J. H. The origin of allometric scaling legal guidelines in biology from genomes to ecosystems: in the direction of a quantitative unifying principle of organic construction and group. J. Exp. Biol. 208, 1575–1592 (2005).
Buller, F. The Domesday Book of Giant Salmon (Little, Brown Book Group Limited, 2007).
Gerber, L., MacSween, C. E., Staples, J. F. & Gamperl, A. Okay. Cold-induced metabolic despair in cunner (Tautogolabrus adspersus): A multifaceted mobile occasion. PLOS ONE. 17, e0271086 (2022).
Porter, E. S. & Gamperl, A. Okay. Cardiorespiratory physiology and swimming capability of Atlantic salmon (Salmo salar) at chilly temperatures. J. Exp. Biol. 226, jeb245990 (2023).
Porter, E. S., Clow, Okay. A., Sandrelli, R. M. & Gamperl, A. Okay. Acute and persistent chilly publicity differentially have an effect on cardiac management, however not cardiorespiratory perform, in resting Atlantic salmon (Salmo salar). Curr. Res. Physiol. 5, 158–170 (2022).
Fletcher, G. L., Kao, M. H. & Dempson, J. B. Lethal freezing temperatures of Arctic char and different salmonids within the presence of ice. Aquaculture 71, 369–378 (1988).
Andrew, S., Currie, S. & Morash, A. J. The results of heat thermal variability on metabolism and swimming efficiency in wild Atlantic salmon (Salmo salar). J. Fish. Biol. 106, 893–907 (2025).
Hvas, M., Morin, A., Johansen, I. B. & Vågseth, T. Acute stress-induced mortality in large Atlantic salmon at excessive temperatures is related to inadequate oxygen uptake capability. J. Therm. Biol. 132, 104231 (2025).
Gamperl, A. Okay. et al. The impacts of accelerating temperature and reasonable hypoxia on the manufacturing traits, cardiac morphology and haematology of Atlantic Salmon (Salmo salar). Aquaculture 519, 734874 (2020).
Beamish, F. W. H. 2 – Swimming Capacity in Fish Physiology (eds. Hoar, W. S. & Randall, D. J.) 101–187 (Academic Press, 1978).
Egginton, S. & Sidell, B. D. Thermal acclimation induces adaptive adjustments in subcellular construction of fish skeletal muscle. Am. J. Physiol. -Regul Integr. Comp. Physiol. 256, R1–R9 (1989).
McKenzie, D. J. Swimming and different actions | Energetics of Fish Swimming in Encyclopedia of Fish Physiology (ed. Farrell, A. P.) 1636–1644 (Academic Press, 2011).
Sänger, A. M. & Stoiber, W. 7 – Muscle Fiber Diversity and Plasticity in Fish Physiology (ed. Johnston, I. A.) 187–250 (Academic Press, 2001).
Brett, J. R. The Relation of Size to Rate of Oxygen Consumption and Sustained Swimming Speed of Sockeye Salmon (Oncorhynchus nerka). J. Fish. Res. Board. Can. 22, 1491–1501 (1965).
Brett, J. R. Energy Expenditure of Sockeye Salmon, Oncorhynchus nerka, During Sustained Performance. J. Fish. Res. Board. Can. 30, 1799–1809 (1973).
Hvas, M. & Oppedal, F. Physiological responses of farmed Atlantic salmon and two cohabitant species of cleaner fish to progressive hypoxia. Aquaculture 512, 734353 (2019).
Burt, Okay. et al. Environmental circumstances and incidence of hypoxia inside manufacturing cages of Atlantic salmon on the south coast of Newfoundland. Aquac Res. 43, 607–620 (2012).
Jeong, J. et al. Longitudinal dissolved oxygen patterns in Atlantic salmon aquaculture websites in British Columbia, Canada. Front Mar. Sci 10, 1289375 (2024).
Johansson, D., Juell, J. E., Oppedal, F., Stiansen, J. E. & Ruohonen, Okay. The affect of the pycnocline and cage resistance on present move, oxygen flux and swimming behaviour of Atlantic salmon (Salmo salar L.) in manufacturing cages. Aquaculture 265, 271–287 (2007).
Oldham, T., Oppedal, F. & Dempster, T. Cage measurement impacts dissolved oxygen distribution in salmon aquaculture. Aquac Environ. Interact. 10, 149–156 (2018).
Wen, X., Ong, M. C., Yin, G., Ludvigsen, T. & Oppedal, F. Influence of Ocean Currents and Stocking Density on the Dissolved Oxygen Distribution Inside Gravity-Type Fish Cages. J Offshore Mech. Arct. Eng 147, 061301 (2025).
Alver, M. O., Alfredsen, J. A. & Sigholt, T. Dynamic modelling of pellet distribution in Atlantic salmon (Salmo salar L.) cages. Aquac Eng. 31, 51–72 (2004).
Alver, M. O. et al. Modelling of floor and 3D pellet distribution in Atlantic salmon (Salmo salar L.) cages. Aquac Eng. 72–73, 20–29 (2016).
Stehfest, Okay. M., Carter, C. G., McAllister, J. D., Ross, J. D. & Semmens, J. M. Response of Atlantic salmon Salmo salar to temperature and dissolved oxygen extremes established utilizing animal-borne environmental sensors. Sci. Rep. 7, 4545 (2017).
Brett, J. R. 10 – Environmental Factors and Growth in Fish Physiology (eds. Hoar, W. S., Randall, D. J. & Brett, J. R.) 599–675 (Academic Press, 1979).
Forsberg, O. I. The influence of various feeding regimes on oxygen consumption and excretion of carbon dioxide and nitrogen in post-smolt Atlantic salmon Salmo salar L. Aquac Res. 28, 29–41 (1997).
Folkedal, O., Torgersen, T., Nilsson, J. & Oppedal, F. Habituation fee and capability of Atlantic salmon (Salmo salar) parr to sudden transitions from darkness to gentle. Aquaculture 307, 170–172 (2010).
Forsberg, O. I. Oxygen consumption of post-smolt Atlantic salmon throughout crowding and dealing with stress. Aquac Int. 3, 55–59 (1995).
Agbeti, W. E. Okay. et al. Swimming at Increasing Speeds in Steady and Unsteady Flows of Atlantic Salmon Salmo salar: Oxygen Consumption, Locomotory Behaviour and Overall Dynamic Body Acceleration. Biology 13, 393 (2024).
Johansson, D. et al. The Interaction between Water Currents and Salmon Swimming Behaviour in Sea Cages. PLOS ONE. 9, e97635 (2014).
Hvas, M. & Bui, S. Energetic prices of ectoparasite an infection in Atlantic salmon. J. Exp. Biol. 225, jeb243300 (2022).
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