光磁成像光谱法(OMIS)原位检测血液中细菌的可行性研究

4open Pub Date : 2022-01-01 DOI:10.1051/fopen/2022008
Brittany Garry, Nikola Stoiljkovic, Zorana Jovic, R. Pavlovic, D. Getnet, S. Demons, Stuart D. Tyner, D. Zurawski, B. Swierczewski, D. Koruga, A. G. Bobrov, V. Antonic
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引用次数: 0

摘要

败血症是军队和民用医院的主要死亡原因之一。快速识别相关病原体是适当诊断、治疗和最终存活的关键步骤。当前的诊断工具要么非常笨重,无法部署,要么需要很长时间才能提供结果。鉴于这些障碍,迫切需要新的解决办法。光磁成像光谱(OMIS)是一种成功用于检测癌细胞和病毒的新技术。由于能记录样品材料的非成对电子和成对电子,OMIS具有很高的灵敏度。此外,该技术还将使用随机森林(RF)分类器和人工神经网络(ANN)算法的机器学习集成到该技术中,以增强检测。在此,我们评估了OMIS检测血液中细菌的可行性。方法:我们使用市售的人血中加入了来自临床分离物的确定浓度的耐多药金黄色葡萄球菌。高(H)、中(M)、低(L)浓度下细菌终浓度分别为1 × 106、1 × 105、1 × 104 CFU/mL。共采集240份样本(每浓度60份,无菌血(N) 60份)进行成像,采用随机森林分类器和人工神经网络对数据进行分析。分别获得训练集和验证集的图像,并用于与真阳性值进行比较(在营养琼脂上进行验证电镀)。结果:ANN算法每一个正确类别(N, L, M, H)的分类样本的平均得分为94%,而RF算法的准确率为93%(平均意味着在240个样本中选择了3次不同的40个样本,每次预测测试的样本混合物不同)。两个精度值的接近强烈表明输入数据(光与成对和未成对电子的相互作用)和输出数据(细菌的N、L、M、H浓度分类)是相关的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optomagnetic Imaging Spectroscopy (OMIS) for in situ detection of bacteria in blood – feasibility study
Introduction: Sepsis is one of the leading causes of death in military and civilian hospitals. Rapid identification of involved pathogens is a key step for appropriate diagnosis, treatment and ultimately survival. Current diagnostics tools are either very bulky and not deployment ready, or require a long time to provide results. Given these obstacles, new solutions are urgently needed. Optomagnetic Imaging Spectroscopy (OMIS) is novel technology successfully used for the detection of cancer cells and viruses. OMIS has high sensitivity due to recording the unpaired and paired electrons of sample material. Furthermore, machine learning that uses the algorithms random forest (RF) classifier and artificial neural network (ANN) is integrated into the technology to enhance detection. Here we evaluated the feasibility of OMIS for the detection of bacteria in blood. Methods: We used commercially available human blood spiked with a defined concentration multidrug resistant Staphylococcus aureus derived from a clinical isolate. Final concentrations of bacteria of 1 × 106, 1 × 105 and 1 × 104 CFU/mL corresponding to High (H), Medium (M) and Low (L) concentrations respectively. A total of 240 samples (60 samples per concentration as well as 60 samples of sterile blood (N)) was imaged, and the data were analyzed using random forest classifier and artificial neural network. Images for the training set and validation sets were separately obtained and used for comparison against true positive values (confirmatory plating on the nutrient agar). Results: The average score of classification samples in the correct category (N, L, M, H) one-by-one was 94% for the ANN algorithm, while for the RF algorithm accuracy was 93% (average means that three times different 40 samples (of 240 samples) were chosen, and each prediction test had different sample mixtures). The closeness of the two values of accuracy strongly indicates that the input data (interaction of light with paired and unpaired electrons) and output data (classification N, L, M, H concentration of bacteria) are correlated.
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