Cerrito P B, Koenig S C, VanHimbergen D J, Jaber S F, Ewert D L, Spence P A
Jewish Hospital Cardiothoracic Surgical Research Institute at the University of Louisville, Department of Surgery, University of Louisville, School of Medicine, KY 40202, USA.
Eur J Cardiothorac Surg. 1999 Jul;16(1):88-93. doi: 10.1016/s1010-7940(99)00139-6.
The intra-operative assessment of the quality of anastomosis in minimally invasive coronary artery bypass surgery (CABG) is critical. Recent investigations demonstrated that flow probes used intra-operatively to assess anastomotic errors may give the surgeon a false sense of confidence as only severely stenotic anastomoses (>90%) could be reliably detected. We developed a neural network system using graft flow data and assessed its potential to improve anastomotic error detection.
Mammary to LAD grafts (n = 46) were constructed in mongrel dogs off-pump. Continuous beat-to-beat graft flow was recorded using transit-time flow probes. Various degrees of anastomotic stenoses (0-100%) were created by an additional suture. The degree of anastomotic stenosis was confirmed by postoperative angiography. A learning vector quantization neural network was created using heart rate, mean aortic pressure, mean systolic, maximum systolic, minimum systolic, mean diastolic, maximum diastolic, minimum diastolic, and mean graft flows. In addition, a spectral analysis of the flow waveforms was performed and the magnitude and phase of the first five harmonics were used to further develop the neural network.
The neural network pattern recognition system was 94% accurate in detecting any stenosis >50%. To validate the model, a testing set was used with 20% of the data values, and the accuracy remained at 100% above chance alone.
Pattern recognition of transit-time flow probe tracings using neural network systems can detect anastomotic errors significantly better than the surgeon's visual assessment, thereby improving the clinical outcome of minimally invasive CABG.
在微创冠状动脉旁路移植术(CABG)中,术中评估吻合口质量至关重要。最近的研究表明,术中用于评估吻合口错误的流量探头可能会给外科医生一种错误的信心,因为只有严重狭窄的吻合口(>90%)才能被可靠检测到。我们开发了一种利用移植物血流数据的神经网络系统,并评估其改善吻合口错误检测的潜力。
在杂种犬非体外循环下构建乳内动脉至左前降支移植物(n = 46)。使用渡越时间流量探头记录连续逐搏的移植物血流。通过额外缝合制造不同程度的吻合口狭窄(0 - 100%)。术后血管造影确认吻合口狭窄程度。利用心率、平均主动脉压、平均收缩压、最大收缩压、最小收缩压、平均舒张压、最大舒张压、最小舒张压和平均移植物血流创建学习向量量化神经网络。此外,对血流波形进行频谱分析,并使用前五个谐波的幅度和相位进一步开发神经网络。
神经网络模式识别系统在检测任何>50%的狭窄时准确率为94%。为验证该模型,使用了包含20%数据值的测试集,其准确率单独高于随机水平,仍保持在100%。
使用神经网络系统对渡越时间流量探头描记进行模式识别,在检测吻合口错误方面明显优于外科医生的视觉评估,从而改善微创CABG的临床结果。
