心脏手术期间进入大脑的气泡大小分布。

Size distribution of air bubbles entering the brain during cardiac surgery.

作者信息

Chung Emma M L, Banahan Caroline, Patel Nikil, Janus Justyna, Marshall David, Horsfield Mark A, Rousseau Clément, Keelan Jonathan, Evans David H, Hague James P

机构信息

University of Leicester Department of Cardiovascular Sciences, Leicester, United Kingdom; University Hospitals of Leicester NHS Trust, Leicester, United Kingdom; Leicester Cardiovascular Biomedical Research Unit, Leicester, United Kingdom.

University of Leicester Department of Cardiovascular Sciences, Leicester, United Kingdom; University Hospitals of Leicester NHS Trust, Leicester, United Kingdom.

出版信息

PLoS One. 2015 Apr 2;10(4):e0122166. doi: 10.1371/journal.pone.0122166. eCollection 2015.

DOI:10.1371/journal.pone.0122166

PMID:25837519

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4383554/

Abstract

BACKGROUND

Thousands of air bubbles enter the cerebral circulation during cardiac surgery, but whether high numbers of bubbles explain post-operative cognitive decline is currently controversial. This study estimates the size distribution of air bubbles and volume of air entering the cerebral arteries intra-operatively based on analysis of transcranial Doppler ultrasound data.

METHODS

Transcranial Doppler ultrasound recordings from ten patients undergoing heart surgery were analysed for the presence of embolic signals. The backscattered intensity of each embolic signal was modelled based on ultrasound scattering theory to provide an estimate of bubble diameter. The impact of showers of bubbles on cerebral blood-flow was then investigated using patient-specific Monte-Carlo simulations to model the accumulation and clearance of bubbles within a model vasculature.

RESULTS

Analysis of Doppler ultrasound recordings revealed a minimum of 371 and maximum of 6476 bubbles entering the middle cerebral artery territories during surgery. This was estimated to correspond to a total volume of air ranging between 0.003 and 0.12 mL. Based on analysis of a total of 18667 embolic signals, the median diameter of bubbles entering the cerebral arteries was 33 μm (IQR: 18 to 69 μm). Although bubble diameters ranged from ~5 μm to 3.5 mm, the majority (85%) were less than 100 μm. Numerous small bubbles detected during cardiopulmonary bypass were estimated by Monte-Carlo simulation to be benign. However, during weaning from bypass, showers containing large macro-bubbles were observed, which were estimated to transiently affect up to 2.2% of arterioles.

CONCLUSIONS

Detailed analysis of Doppler ultrasound data can be used to provide an estimate of bubble diameter, total volume of air, and the likely impact of embolic showers on cerebral blood flow. Although bubbles are alarmingly numerous during surgery, our simulations suggest that the majority of bubbles are too small to be harmful.

摘要

背景

心脏手术期间有成千上万的气泡进入脑循环，但气泡数量多是否能解释术后认知功能下降目前存在争议。本研究基于经颅多普勒超声数据分析术中进入脑动脉的气泡大小分布和空气体积。

方法

分析了10例接受心脏手术患者的经颅多普勒超声记录，以检测是否存在栓塞信号。根据超声散射理论对每个栓塞信号的反向散射强度进行建模，以估计气泡直径。然后使用针对患者的蒙特卡洛模拟研究气泡簇对脑血流的影响，以模拟模型血管系统中气泡的积聚和清除。

结果

对多普勒超声记录的分析显示，手术期间进入大脑中动脉区域的气泡最少为371个，最多为6476个。据估计，这相当于空气总体积在0.003至0.12毫升之间。基于对总共18667个栓塞信号的分析，进入脑动脉的气泡中位直径为33μm（四分位间距：18至69μm）。尽管气泡直径范围约为5μm至3.5mm，但大多数（85%）小于100μm。通过蒙特卡洛模拟估计，体外循环期间检测到的大量小气泡是无害的。然而，在脱离体外循环期间，观察到含有大气泡的气泡簇，估计这些气泡簇会暂时影响多达2.2%的小动脉。

结论

对多普勒超声数据的详细分析可用于估计气泡直径、空气总体积以及栓塞簇对脑血流的可能影响。尽管手术期间气泡数量惊人，但我们的模拟表明，大多数气泡太小，不会造成危害。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/33cb/4383554/238aecfc8af4/pone.0122166.g001.jpg

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心脏手术期间进入大脑的气泡大小分布。

Size distribution of air bubbles entering the brain during cardiac surgery.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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