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基于微生物特征的支持向量机区分侵袭性和慢性牙周炎。

Support vector machine-based differentiation between aggressive and chronic periodontitis using microbial profiles.

机构信息

Department of Periodontology, Guarulhos University, Guarulhos, SP, Brazil.

Department of Mathematics, Bar-Ilan University, Ramat-Gan, Israel.

出版信息

Int Dent J. 2018 Feb;68(1):39-46. doi: 10.1111/idj.12326. Epub 2017 Aug 2.

DOI:10.1111/idj.12326
PMID:28771699
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9378912/
Abstract

BACKGROUND

The existence of specific microbial profiles for different periodontal conditions is still a matter of debate. The aim of this study was to test the hypothesis that 40 bacterial species could be used to classify patients, utilising machine learning, into generalised chronic periodontitis (ChP), generalised aggressive periodontitis (AgP) and periodontal health (PH).

METHOD

Subgingival biofilm samples were collected from patients with AgP, ChP and PH and analysed for their content of 40 bacterial species using checkerboard DNA-DNA hybridisation. Two stages of machine learning were then performed. First of all, we tested whether there was a difference between the composition of bacterial communities in PH and in disease, and then we tested whether a difference existed in the composition of bacterial communities between ChP and AgP. The data were split in each analysis to 70% train and 30% test. A support vector machine (SVM) classifier was used with a linear kernel and a Box constraint of 1. The analysis was divided into two parts.

RESULTS

Overall, 435 patients (3,915 samples) were included in the analysis (PH = 53; ChP = 308; AgP = 74). The variance of the healthy samples in all principal component analysis (PCA) directions was smaller than that of the periodontally diseased samples, suggesting that PH is characterised by a uniform bacterial composition and that the bacterial composition of periodontally diseased samples is much more diverse. The relative bacterial load could distinguish between AgP and ChP.

CONCLUSION

An SVC classifier using a panel of 40 bacterial species was able to distinguish between PH, AgP in young individuals and ChP.

摘要

背景

不同牙周状况是否存在特定的微生物特征仍然存在争议。本研究旨在验证以下假设,即利用机器学习,40 种细菌是否可用于将患者分为广泛性慢性牙周炎(ChP)、广泛性侵袭性牙周炎(AgP)和牙周健康(PH)。

方法

从 AgP、ChP 和 PH 患者的龈下生物膜样本中采集 40 种细菌的含量,并用斑点杂交 DNA-DNA 杂交技术进行分析。然后进行了两个阶段的机器学习。首先,我们测试了 PH 和疾病之间的细菌群落组成是否存在差异,然后我们测试了 ChP 和 AgP 之间的细菌群落组成是否存在差异。在每次分析中,数据分为 70%的训练数据和 30%的测试数据。使用具有线性核和 Box 约束为 1 的支持向量机(SVM)分类器。分析分为两部分。

结果

总体而言,有 435 名患者(3915 个样本)纳入分析(PH = 53;ChP = 308;AgP = 74)。所有主成分分析(PCA)方向中健康样本的方差均小于牙周疾病样本的方差,这表明 PH 的细菌组成均匀,牙周疾病样本的细菌组成更加多样化。相对细菌负荷可区分 AgP 和 ChP。

结论

使用 40 种细菌组合的 SVC 分类器能够区分 PH、年轻人的 AgP 和 ChP。

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