使用POCUS测量心输出量的准确性:将人工智能引入日常护理。

IF 3.4 Q2 Medicine
Faisal Shaikh, Jon-Emile Kenny, Omar Awan, Daniela Markovic, Oren Friedman, Tao He, Sidharth Singh, Peter Yan, Nida Qadir, Igor Barjaktarevic
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引用次数: 3

摘要

背景:休克管理需要快速可靠的手段来监测液体复苏的血流动力学效果。即时超声(POCUS)是一种相对快速和非侵入性的成像技术,能够在急性环境中捕获心输出量(CO)的变化。然而,POCUS受到操作员技能和解释变化的困扰。人工智能可以帮助医疗保健专业人员在超声成像过程中获得更客观和精确的测量,从而提高不同经验用户的可用性。在这项可行性研究中,我们比较了新手POCUS用户使用手动技术测量CO的表现和一种新的自动化辅助技术,该技术提供实时反馈,以纠正图像采集,以获得最佳的主动脉流出速度测量。方法:28名经验有限的初级重症监护学员对一名健康志愿者进行手动和自动化辅助CO测量。用左心室流出道(LVOT)速度时间积分(VTI)和LVOT直径测量CO。研究对象获得的测量结果与经认证的超声心动图师的测量结果进行了比较。采用Spearman等级相关和Bland-Altman配对分析进行比较分析。结果:充分的图像采集是100%可行的。手动和自动VTI值之间的相关性不显著(p = 0.11),两组的平均值都低估了经认证的超声心动图师获得的平均值。与人工测量相比,学员队列中VTI的自动测量具有更高的重复性,更窄的测量范围(6.2对10.3 cm),更低的标准偏差(1.98对2.33 cm)。委员会认证的超声心动图师、自动和手动VTI追踪的评分者的变异系数分别为11.5%、13.6%和15.4%。结论:我们的研究表明,新的自动化辅助VTI是可行的,可以减少变异,同时提高CO测量的精度。这些结果支持在常规重症监护超声中使用人工智能增强图像采集,并可能在评估CO对血流动力学干预的反应方面发挥作用。进一步调查人工智能辅助超声系统在临床设置是必要的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Measuring the accuracy of cardiac output using POCUS: the introduction of artificial intelligence into routine care.

Measuring the accuracy of cardiac output using POCUS: the introduction of artificial intelligence into routine care.

Measuring the accuracy of cardiac output using POCUS: the introduction of artificial intelligence into routine care.

Measuring the accuracy of cardiac output using POCUS: the introduction of artificial intelligence into routine care.

Background: Shock management requires quick and reliable means to monitor the hemodynamic effects of fluid resuscitation. Point-of-care ultrasound (POCUS) is a relatively quick and non-invasive imaging technique capable of capturing cardiac output (CO) variations in acute settings. However, POCUS is plagued by variable operator skill and interpretation. Artificial intelligence may assist healthcare professionals obtain more objective and precise measurements during ultrasound imaging, thus increasing usability among users with varying experience. In this feasibility study, we compared the performance of novice POCUS users in measuring CO with manual techniques to a novel automation-assisted technique that provides real-time feedback to correct image acquisition for optimal aortic outflow velocity measurement.

Methods: 28 junior critical care trainees with limited experience in POCUS performed manual and automation-assisted CO measurements on a single healthy volunteer. CO measurements were obtained using left ventricular outflow tract (LVOT) velocity time integral (VTI) and LVOT diameter. Measurements obtained by study subjects were compared to those taken by board-certified echocardiographers. Comparative analyses were performed using Spearman's rank correlation and Bland-Altman matched-pairs analysis.

Results: Adequate image acquisition was 100% feasible. The correlation between manual and automated VTI values was not significant (p = 0.11) and means from both groups underestimated the mean values obtained by board-certified echocardiographers. Automated measurements of VTI in the trainee cohort were found to have more reproducibility, narrower measurement range (6.2 vs. 10.3 cm), and reduced standard deviation (1.98 vs. 2.33 cm) compared to manual measurements. The coefficient of variation across raters was 11.5%, 13.6% and 15.4% for board-certified echocardiographers, automated, and manual VTI tracing, respectively.

Conclusions: Our study demonstrates that novel automation-assisted VTI is feasible and can decrease variability while increasing precision in CO measurement. These results support the use of artificial intelligence-augmented image acquisition in routine critical care ultrasound and may have a role for evaluating the response of CO to hemodynamic interventions. Further investigations into artificial intelligence-assisted ultrasound systems in clinical settings are warranted.

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来源期刊
Ultrasound Journal
Ultrasound Journal Health Professions-Radiological and Ultrasound Technology
CiteScore
6.80
自引率
2.90%
发文量
45
审稿时长
22 weeks
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