Convolutional neural network analysis of recurrence plots for high resolution melting classification

Background and Objective: High resolution melting (HRM) analysis is a rapid and correct method for identification of species, such as, microorganism, bacteria, yeast, virus, etc. HRM data are produced us -ing real-time polymerase chain reaction (PCR) and unique for each species. Analysis of the HRM data is important for several applications, such as, for detection of diseases (e.g., influenza, zika virus, SARS-Cov-2 and Covid-19 diseases) in health, for identification of spoiled foods in food industry, for analysis of crime scene evidence in forensic investigation, etc. However, the characteristics of the HRM data can change due to the experimental conditions or instrumental settings. In addition, it becomes laborious and time-consuming process as the number of samples increases. Because of these reasons, the analysis and classification of the HRM data become challenging for species which have similar characteristics. Methods: To improve the classification accuracy of HRM data, we propose to use image (visual) represen-tation of HRM data, which we call HRM images, that are generated using recurrence plots, and propose convolutional neural network (CNN) based models for classifying HRM images. In this study, two different types of recurrence plots are generated, which are black-white recurrence plots (BW-RP) and gray scale recurrence plots (GS-RP) and four different CNN models are proposed for classifying HRM data. Results: The classification performance of the proposed methods are evaluated based on average classifi-cation accuracy and F1 score, specificity, recall, and precision values for each yeast species. When BW-RP representation of HRM data is used as input to the CNN models, the best classification accuracy of 95.2% is obtained. The classification accuracies of CNN models for melting curve and GS-RP data representations of HRM data are 90.13% and 86.13%, respectively. The classification accuracy of support vector machines (SVM) model that take melting curve representation of HRM data is 86.53%. Moreover, when BW-RP rep-resentation of HRM data is used as input to the CNN models, the F1 score, specificity, recall and precision values are the highest for almost all of species. Conclusions: Experimental results show that using BW-RP representation of HRM data improved the clas-sification accuracy of HRM data and CNN models that take these images as input outperformed CNN models that take melting curve and GS-RP representations of HRM data as inputs and SVM model that take melting curve representation of HRM data as input. (c) 2021 Elsevier B.V. All rights reserved.

Automated summary

The study proposed a method for classifying HRM data using HRM images generated from recurrence plots. By inputting black-white recurrence plot representations of HRM data into CNN models, high classification accuracy for species identification was achieved.