Abstract
The detection of Mycobacterium tuberculosis (Mtb) infection plays an important role in the control of tuberculosis (TB), one of the leading infectious diseases in the world. Recent advances in artificial intelligence-aided cellular image processing and analytical techniques have shown great promises in automated Mtb detection. However, current cell imaging protocols often involve costly and time-consuming fluorescence staining, which has become a major bottleneck for procedural automation. To solve this problem, we have developed a novel automated system (AutoCellANLS) for cell detection and the recognition of morphological features in the phase-contrast micrographs by using unsupervised machine learning (UML) approaches and deep convolutional neural networks (CNNs). The detection algorithm can adaptively and automatically detect single cells in the cell population by the improved level set segmentation model with the circular Hough transform (CHT). Besides, we have designed a Cell-net by using the transfer learning strategies (TLS) to classify the virulence-specific cellular morphological changes that would otherwise be indistinguishable to the naked eye. The novel system can simultaneously classify and segment microscopic images of the cell populations and achieve an average accuracy of 95.13% for cell detection, 95.94% for morphological classification, 94.87% for sensitivity, and 96.61% for specificity. AutoCellANLS is able to detect significant morphological differences between the infected and uninfected mammalian cells throughout the infection period (2 hpi/12 hpi/24 hpi). Besides, it has overcome the drawback of manual intervention and increased the accuracy by more than 11% compared to our previous work, which used AI-aided imaging analysis to detect mycobacterial infection in macrophages. AutoCellANLS is also efficient and versatile when tailored to different cell lines datasets (RAW264.7 and THP-1 cell). This proof-of concept study provides a novel venue to investigate bacterial pathogenesis at a macroscopic level and offers great promise in the diagnosis of bacterial infections.
Highlights
We have developed an automated AI framework for detecting morphological changes of the cells infected by mycobacteria without prior user training
The AutoCellANLS was designed for rapid cell detection and morphology classification based on phase-contrast images, and its adaptability, accuracy, and efficiency were verified with different cell line datasets
To further validate the performance of our network, the classification results were assessed by accuracy score, numbers of true positive (TP), false positive (FP), true negative (TN), and false negative(FN) as well as F1-score (Figure 6)
Summary
As the causative pathogen of tuberculosis disease (TB), Mycobacteria tuberculosis (Mtb) is one of the most dangerous bacteria for public health and causes millions of deaths worldwide [1,2]. The detection of Mtb is a critical step for global TB control. The most used strategy is to target Mtb specific antigens [3,4]. EsxA (6-kDa early secreted antigenic target, ESAT-6), a secreted substrate of the ESX-1 secretion system of Mtb, is an essential virulence factor of Mtb. EsxA is believed to mediate phagosome rupture and translocate
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