Cardiorespiratory changes in beluga in response to acoustic noise

Lyamin, Oleg I.; Korneva, Svetlana M.; Рожнов, В. В.; Mukhametov, L. M.

doi:10.1134/s0012496611050218

Cited by 12 publications

(9 citation statements)

References 10 publications

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“…A shore crab (Carcinus maenas) was reported to require higher levels of dissolved oxygen when exposed to ship-noise playback in a controlled environment compared to those held under ambient-noise, showing a sign of increased metabolic rate (Wale et al, 2013). Increased physiological activity was also reported in white whales (D. leucas) after exposure of underwater noise from shipping industry (Lyamin et al, 2011). Richardson et al (1995) reported different typologies of acoustic noises generated by the marine industry.…”

Section: Sound Pressure Limits Exposures and Impactsmentioning

confidence: 99%

Acoustic Noise Pollution From Marine Industrial Activities: Exposure and Impacts

Kuşku¹,

Yiğit²,

Ergün³

et al. 2018

Aquat Res

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The improvements in marine technological developments propagate urbanization in the ocean environment. The construction or operational activities of marine structures such as energy plants, oil platforms, pipelines , sea-tunnel passages, or cable-stayed suspension bridges, and vessel traffic are sources of underwater noise pollution. How underwater sounds such as piling, pole drilling, or machinery noises may affect the marine live is mostly ignored in marine construction, and there is lack of information regarding underwater sound effects on marine live in the oceans. Recently, a remarkable interest is developing concerning underwater sound effects, especially in aquaculture facilities, with experimentation of musical stimuli or various noises caused by pumps or filter systems on behavior and stress responses of fish in culture conditions. With the increase of urbanization and progressive development of marine industries, more and more pressure from human-generated (anthropogenic) underwater sound pollution may threaten marine mammals, fish species and invertebrates from underwater noises that in terms might be called as "Underwater Noise Pollution". The future of marine life and that of human being, and the dramatic increase of underwater sound pollution is a new debate that needs to be controlled in a sustainable way with environmentsound approaches. Therefore the potential effects of various sound sources derived from marine industrial activities have been reviewed in this study.

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Section: Sound Pressure Limits Exposures and Impactsmentioning

confidence: 99%

Acoustic Noise Pollution From Marine Industrial Activities: Exposure and Impacts

Kuşku¹,

Yiğit²,

Ergün³

et al. 2018

Aquat Res

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show abstract

“…In this study, dolphin B's respiration rate increased even under low-level sound exposure in the first 5 min but not in dolphin A, although both dolphins' cortisol levels elevated significantly after highlevel sound exposure. It was suggested that respiratory rate of dolphins may not be a sensitive indicator of stress during noise presentation (Lyamin et al, 2011). Further research is warranted to understand if dominant individual shows more obvious response on respiration rate.…”

Section: Discussionmentioning

confidence: 99%

Anthropogenic Sound Exposure-Induced Stress in Captive Dolphins and Implications for Cetacean Health

et al. 2021

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Many cetaceans are exposed to increasing pressure caused by anthropogenic activities in their marine environment. Anthropogenic sound has been recognized as a possible stressor for cetaceans that may have impacts on health. However, the relationship between stress, hormones, and cytokines secretion in cetaceans is complex and not fully understood. Moreover, the effects of stress are often inconsistent because the character, intensity, and duration of the stressors are variable. For a better understanding of how anthropogenic sounds affect the psychophysiology of cetaceans, the present study compared the changes of cortisol concentration and cytokine gene transcriptions in blood samples and behaviors of captive bottlenose dolphins (Tursiops truncatus) after sound exposures. The sound stimuli were 800 Hz pure-tone multiple impulsive sound for 30 min at three different sound levels (estimated mean received SPL: 0, 120, and 140 dB re 1 μPa) that likely cause no permanent and temporary hearing threshold shift in dolphins. Six cytokine genes (IL-2Rα, IL-4, IL-10, IL-12, TNF-α, and IFN-γ) were selected for analysis. Cortisol levels and IL-10 gene transcription increased and IFNγ/IL-10 ratio was lower after a 30-min high-level sound exposure, indicating the sound stimuli used in this study could be a stressor for cetaceans, although only minor behavior changes were observed. This study may shed light on the potential impact of pile driving-like sounds on the endocrine and immune systems in cetaceans and provide imperative information regarding sound exposure for free-ranging cetaceans.

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“…In white whales ( Delphinapterus leucas ), the norepinephrine, epinephrine and dopamine levels were found to increase significantly after high-level sound exposures (>100 kPa) from a seismic water gun (impulse peak pressure levels ranged from approximately 8 to 200 kPa or 198–226 dB re 1 μPa peak pressure) compared to low-level sound exposures (<100 kPa) or controls without noise exposure, representing a nervous activation effect of noise exposure [ 81 ]. In white whales ( D. leucas ), a physiological activation, tachycardia, caused by ship noise exposure was detected as well [ 86 ]. Similarly, in bottlenose dolphins ( T. truncates ), a significant increase in aldosterone and a significant decrease in monocytes were found after exposure to seismic air-gun noise (44–207 kPa or 213–226 dB re 1 μPa peak pressure) [ 81 ].…”

Section: The Effects Of Anthropogenic Noise On Marine Organismsmentioning

confidence: 99%

“…A study carried out by Celi et al showed that ship noise exposure led to a significant decrease in the total haemocyte count (THC) and phenoloxidase (PO) activity in cell-free haemolymph, as well as a significant increase in the haemolymphatic protein concentration and heat shock protein 27 (Hsp 27) expression in haemocyte lysate of the European spiny lobster ( Palinurus elephas ), suggesting that noise has impacts on immunity as well [ 87 ]. Noise exposure also led to a depression in the immune system in the white whale ( D. leucas ), with a decrease in alkaline phosphatase level and increase in γ-glutamyltransferase level [ 86 ]. Similarly, when lined seahorses ( H. erectus ) were exposed in loud noise tanks, heterophils constituted a significantly greater proportion of their leukocyte population and their heterophil:lymphocyte ratio (H:L ratio) was significantly greater than when in quiet tanks.…”

Section: The Effects Of Anthropogenic Noise On Marine Organismsmentioning

confidence: 99%

Noise in the Sea and Its Impacts on Marine Organisms

Peng

Zhao

Liu

2015

IJERPH

120

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With the growing utilization and exploration of the ocean, anthropogenic noise increases significantly and gives rise to a new kind of pollution: noise pollution. In this review, the source and the characteristics of noise in the sea, the significance of sound to marine organisms, and the impacts of noise on marine organisms are summarized. In general, the studies about the impact of noise on marine organisms are mainly on adult fish and mammals, which account for more than 50% and 20% of all the cases reported. Studies showed that anthropogenic noise can cause auditory masking, leading to cochlear damage, changes in individual and social behavior, altered metabolisms, hampered population recruitment, and can subsequently affect the health and service functions of marine ecosystems. However, since different sampling methodologies and unstandarized measurements were used and the effects of noise on marine organisms are dependent on the characteristics of the species and noise investigated, it is difficult to compare the reported results. Moreover, the scarcity of studies carried out with other species and with larval or juvenile individuals severely constrains the present understanding of noise pollution. In addition, further studies are needed to reveal in detail the causes for the detected impacts.

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Cardiorespiratory changes in beluga in response to acoustic noise

Cited by 12 publications

References 10 publications

Acoustic Noise Pollution From Marine Industrial Activities: Exposure and Impacts

Acoustic Noise Pollution From Marine Industrial Activities: Exposure and Impacts

Anthropogenic Sound Exposure-Induced Stress in Captive Dolphins and Implications for Cetacean Health

Noise in the Sea and Its Impacts on Marine Organisms

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