Monitoring bubble growth in supersaturated blood and tissue ex vivo and the relevance to marine mammal bioeffects

Acoustics research letters online : ARLO Pub Date : 2005-06-24 DOI:10.1121/1.1930987

L. Crum, M. Bailey, J. Guan, Paul R. Hilmo, S. Kargl, T. Matula, O. Sapozhnikov

{"title":"Monitoring bubble growth in supersaturated blood and tissue ex vivo and the relevance to marine mammal bioeffects","authors":"L. Crum, M. Bailey, J. Guan, Paul R. Hilmo, S. Kargl, T. Matula, O. Sapozhnikov","doi":"10.1121/1.1930987","DOIUrl":null,"url":null,"abstract":"There have been several recent reports that active sonar systems can lead to serious bioeffects in marine mammals, particularly beaked whales, resulting in strandings, and in some cases, to their deaths. We have devised a series of experiments to determine the potential role of low-frequency acous- tic sources as a means to induce bubble nucleation and growth in supersatu- rated ex vivo bovine liver and kidney tissues, and blood. Bubble detection was achieved with a diagnostic ultrasound scanner. Under the conditions of this experiment, supersaturated tissues and blood led to extensive bubble produc- tion when exposed to short pulses of low frequency sound. right whales. 5 Although these cetaceans have not been associated with mass stranding events related to navy sonar systems, it is likely that other cetaceans will also undergo significant changes in behavior when subjected to high-intensity acoustic pulses. Rapid surfacing from a deep dive may lead to decompression sickness. In addition, it is known that exercising after diving can lead to decompression sickness in humans. 6 Analogously, abnormal extended activity resulting from sonar may induce decompression sickness in cetaceans. To address the role of direct bubble nucleation in tissue by a sound pulse, it is worthwhile to discuss the bioeffects induced by diagnostic ultrasound systems, used routinely worldwide to image the progress of healthy as well as pathological conditions in the human patient. It is no surprise, then, to recognize that ultrasound-induced bioeffects in human tissue have been studied extensively. To this date, no repeatable effects of diagnostic ultrasound exams have been reported in the general literature. This paucity of observable bioeffects was at first surprising because the acoustic pressure amplitudes used in imaging devices are in excess of the threshold for bubble nucleation and growth, i.e., cavitation—the most likely ultrasound-induced","PeriodicalId":87384,"journal":{"name":"Acoustics research letters online : ARLO","volume":"276 1","pages":"214-220"},"PeriodicalIF":0.0000,"publicationDate":"2005-06-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"34","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Acoustics research letters online : ARLO","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1121/1.1930987","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 34

Abstract

There have been several recent reports that active sonar systems can lead to serious bioeffects in marine mammals, particularly beaked whales, resulting in strandings, and in some cases, to their deaths. We have devised a series of experiments to determine the potential role of low-frequency acous- tic sources as a means to induce bubble nucleation and growth in supersatu- rated ex vivo bovine liver and kidney tissues, and blood. Bubble detection was achieved with a diagnostic ultrasound scanner. Under the conditions of this experiment, supersaturated tissues and blood led to extensive bubble produc- tion when exposed to short pulses of low frequency sound. right whales. 5 Although these cetaceans have not been associated with mass stranding events related to navy sonar systems, it is likely that other cetaceans will also undergo significant changes in behavior when subjected to high-intensity acoustic pulses. Rapid surfacing from a deep dive may lead to decompression sickness. In addition, it is known that exercising after diving can lead to decompression sickness in humans. 6 Analogously, abnormal extended activity resulting from sonar may induce decompression sickness in cetaceans. To address the role of direct bubble nucleation in tissue by a sound pulse, it is worthwhile to discuss the bioeffects induced by diagnostic ultrasound systems, used routinely worldwide to image the progress of healthy as well as pathological conditions in the human patient. It is no surprise, then, to recognize that ultrasound-induced bioeffects in human tissue have been studied extensively. To this date, no repeatable effects of diagnostic ultrasound exams have been reported in the general literature. This paucity of observable bioeffects was at first surprising because the acoustic pressure amplitudes used in imaging devices are in excess of the threshold for bubble nucleation and growth, i.e., cavitation—the most likely ultrasound-induced

查看原文本刊更多论文

体外监测过饱和血液和组织中的气泡生长及其与海洋哺乳动物生物效应的相关性

最近有几份报告称，主动声呐系统会对海洋哺乳动物，特别是喙鲸，造成严重的生物效应，导致搁浅，在某些情况下，甚至导致死亡。我们设计了一系列实验来确定低频声源作为一种诱导超饱和牛肝脏、肾脏组织和血液中气泡成核和生长的手段的潜在作用。气泡检测是通过诊断超声扫描仪实现的。在本实验条件下，当暴露于低频短脉冲声音时，组织和血液过饱和导致大量气泡产生。露脊鲸。尽管这些鲸类动物与海军声纳系统相关的大规模搁浅事件没有关联，但其他鲸类动物在受到高强度声脉冲的影响时，很可能也会发生显著的行为变化。从深潜中迅速浮出水面可能会导致减压病。此外，众所周知，潜水后的锻炼会导致人类患上减压病。类似地，声纳引起的异常伸展活动可能会引起鲸类动物的减压病。为了解决声音脉冲在组织中直接泡成核的作用，讨论由诊断超声系统引起的生物效应是值得的，诊断超声系统在世界范围内常规用于成像人类患者的健康和病理状况的进展。因此，认识到超声波在人体组织中引起的生物效应已经得到了广泛的研究，这并不奇怪。到目前为止，在一般文献中还没有报道诊断超声检查的可重复效果。这种可观察到的生物效应的缺乏起初是令人惊讶的，因为成像设备中使用的声压振幅超过了气泡成核和生长的阈值，即最可能由超声波引起的空化

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Acoustics research letters online : ARLO

自引率

0.00%

发文量