A New Few-Shot Learning Method of Bacterial Colony Counting Based on the Edge Computing Device

Zhang, Beini; Zhou, Zhentao; Cao, Wei; Qi, Xirui; Xu, Chunxiao; Wen, Weijia

doi:10.3390/biology11020156

Cited by 16 publications

(11 citation statements)

References 33 publications

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“…In addition, Rattray et al investigated the identification of Pseudomonas aeruginosa strains from colony image data from clinical and environmental samples for a robust, repeatable detection of phenotype on the level of individual strains, and they reported an average validation accuracy of 92.9% and an average test accuracy of 90.7% for the classification of individual strains [ 69 ]. A new few-shot learning method of bacterial colony counting was also described to be useful for Escherichia coli on Plate Count Agar (PCA) with YOLOv3 models, aiding colony-forming unit (CFU) counting and bacterial quantification in the clinical laboratory [ 70 ].…”

Section: Resultsmentioning

confidence: 99%

Harnessing of Artificial Intelligence for the Diagnosis and Prevention of Hospital-Acquired Infections: A Systematic Review

Baddal,

Taner,

Uzun Ozsahin

2024

Diagnostics

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Healthcare-associated infections (HAIs) are the most common adverse events in healthcare and constitute a major global public health concern. Surveillance represents the foundation for the effective prevention and control of HAIs, yet conventional surveillance is costly and labor intensive. Artificial intelligence (AI) and machine learning (ML) have the potential to support the development of HAI surveillance algorithms for the understanding of HAI risk factors, the improvement of patient risk stratification as well as the prediction and timely detection and prevention of infections. AI-supported systems have so far been explored for clinical laboratory testing and imaging diagnosis, antimicrobial resistance profiling, antibiotic discovery and prediction-based clinical decision support tools in terms of HAIs. This review aims to provide a comprehensive summary of the current literature on AI applications in the field of HAIs and discuss the future potentials of this emerging technology in infection practice. Following the PRISMA guidelines, this study examined the articles in databases including PubMed and Scopus until November 2023, which were screened based on the inclusion and exclusion criteria, resulting in 162 included articles. By elucidating the advancements in the field, we aim to highlight the potential applications of AI in the field, report related issues and shortcomings and discuss the future directions.

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Section: Resultsmentioning

confidence: 99%

Harnessing of Artificial Intelligence for the Diagnosis and Prevention of Hospital-Acquired Infections: A Systematic Review

Baddal,

Taner,

Uzun Ozsahin

2024

Diagnostics

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“…Furthermore, CNN will automatically seize a grasp of filters without explicitly mentioning them [4]. These filters can be of help to draw correct and relevant features from the input data.…”

Section: Convolutional Neural Network (Cnn)mentioning

confidence: 99%

“…As we know, nowadays parallel training task plays an important role in pre-training of big model including Bidirectional Encoder Representations from Transformer (BERT) and Generative Pre-Training (GPT). The basic procedure of parallel training can be depicted as when faced with large amounts of data, plenty of GPU is needed to speed up the calculation targeted at current pre-training task, and our task is to design a series of scheduling policies in order to put the GPU resource to better use and cut down the vacancy and waste of the GPU hash rate [4][5][6]. It can be split up into two different types named Data-parallel based method and Model-parallel based method.…”

Section: Introductionmentioning

confidence: 99%

Deep learning networks for microbiology images recognition

Chen

2023

Third International Conference on Artificial Intelligence and Computer Engineering (ICAICE 2022)

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As we know, recently deep learning networks have gained currency for some time under the background of the rise of big model, and it has been widely used for various areas including microbiology images recognition. Nowadays deep learning network models are also divided into many different types, and many new models are proposed every year to achieve better performance. After introducing their specific principles and composition structure, this paper compares three common different deep learning networks named Deep neural network notation (DNN), Convolutional Neural network (CNN) and Recurrent Neural network (RNN), and introduces the recently emerging model named Residual network (Resnet), starting from a specific situation which calls for garbage classification. Moreover, during this experiment, it also gives the method V pipe a try which differs a lot from the former method, and receives good results worth celebrating.

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“…Cascade R-CNN achieved the highest mean average precision (MAP) of 52.3% and 59.4% on intersection over union (IoU) ranging from 0.5 to 0.95. Furthermore, a lightweight improved YOLOv3 [ 24 ] network based on the few-shot learning strategy was proposed [ 25 ]. The network was trained and validated using only five raw images, resulting in an improvement in average accuracy from 64.3% to 97.4% and a significant decrease in the false negative rate from 32.1% to 1.5%.…”

Section: Introductionmentioning

confidence: 99%

U2-Net and ResNet50-Based Automatic Pipeline for Bacterial Colony Counting

Cao,

Zeng,

Wang

et al. 2024

Microorganisms

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In this paper, an automatic colony counting system based on an improved image preprocessing algorithm and convolutional neural network (CNN)-assisted automatic counting method was developed. Firstly, we assembled an LED backlighting illumination platform as an image capturing system to obtain photographs of laboratory cultures. Consequently, a dataset was introduced consisting of 390 photos of agar plate cultures, which included 8 microorganisms. Secondly, we implemented a new algorithm for image preprocessing based on light intensity correction, which facilitated clearer differentiation between colony and media areas. Thirdly, a U2-Net was used to predict the probability distribution of the edge of the Petri dish in images to locate region of interest (ROI), and then threshold segmentation was applied to separate it. This U2-Net achieved an F1 score of 99.5% and a mean absolute error (MAE) of 0.0033 on the validation set. Then, another U2-Net was used to separate the colony region within the ROI. This U2-Net achieved an F1 score of 96.5% and an MAE of 0.005 on the validation set. After that, the colony area was segmented into multiple components containing single or adhesive colonies. Finally, the colony components (CC) were innovatively rotated and the image crops were resized as the input (with 14,921 image crops in the training set and 4281 image crops in the validation set) for the ResNet50 network to automatically count the number of colonies. Our method achieved an overall recovery of 97.82% for colony counting and exhibited excellent performance in adhesion classification. To the best of our knowledge, the proposed “light intensity correction-based image preprocessing→U2-Net segmentation for Petri dish edge→U2-Net segmentation for colony region→ResNet50-based counting” scheme represents a new attempt and demonstrates a high degree of automation and accuracy in recognizing and counting single-colony and multi-colony targets.

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A New Few-Shot Learning Method of Bacterial Colony Counting Based on the Edge Computing Device

Cited by 16 publications

References 33 publications

Harnessing of Artificial Intelligence for the Diagnosis and Prevention of Hospital-Acquired Infections: A Systematic Review

Harnessing of Artificial Intelligence for the Diagnosis and Prevention of Hospital-Acquired Infections: A Systematic Review

Deep learning networks for microbiology images recognition

U2-Net and ResNet50-Based Automatic Pipeline for Bacterial Colony Counting

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