Deep Learning in Label-free Cell Classification

Chen, Claire Lifan; Mahjoubfar, Ata; Tai, Li Chia; Blaby, Ian K.; Huang, Allen; Niazi, Kayvan; Jalali, Bahram

doi:10.1038/srep21471

Cited by 391 publications

(297 citation statements)

References 62 publications

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“…For example, due to cell-to-cell and cell-to-substrate adhesion, strategies for image segmentation such as threshold, watershed and edge-detection have been under development for decades, yet still a bottleneck of the automated image analysis in microscopy. This problem is of little effect in IFC where the cells are put in suspension and interrogated on a single-cell basis 63–67 . For blood cells, bone marrow cells, and many cancer cells flowing in the blood vessels, IFC is the most promising approach to study their morphological changes.…”

Section: Challenges: High-throughput and Real-time Image Analysismentioning

confidence: 99%

Review: imaging technologies for flow cytometry

et al. 2016

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High throughput single cell imaging is a critical enabling and driving technology in molecular and cellular biology, biotechnology, medicine and related areas. Imaging flow cytometry combines single-cell imaging capabilities of microscopy with the high-throughput capabilities of conventional flow cytometry. Recent advances in imaging flow cytometry are remarkably revolutionizing the single-cell analysis. This article describes recent imaging flow cytometry technologies and their challenges.

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Section: Challenges: High-throughput and Real-time Image Analysismentioning

confidence: 99%

Review: imaging technologies for flow cytometry

et al. 2016

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“…By stacking layers of linear convolutions with appropriate non-linearities 4 , abstract concepts can be learnt from high-dimensional input alleviating the challenging and time-consuming task of hand-crafting algorithms. Such DNNs are quickly entering the field of medical imaging and diagnosis [5][6][7][8][9][10][11][12][13][14][15] , outperforming state-of-the-art methods at disease detection or allowing one to tackle problems that had previously been out of reach. Applied at scale, such systems could considerably alleviate the workload of physicians by detecting patients at risk from a prescreening examination.…”

mentioning

confidence: 99%

Leveraging uncertainty information from deep neural networks for disease detection

Leibig

Allken

Berens

et al. 2016

Preprint

111

150

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Deep learning (DL) has revolutionized the field of computer vision and image processing. In medical imaging, algorithmic solutions based on DL have been shown to achieve high performance on tasks that previously required medical experts. However, DL-based solutions for disease detection have been proposed without methods to quantify and control their uncertainty in a decision. In contrast, a physician knows whether she is uncertain about a case and will consult more experienced colleagues if needed. Here we evaluate drop-out based Bayesian uncertainty measures for DL in diagnosing diabetic retinopathy (DR) from fundus images and show that it captures uncertainty better than straightforward alternatives. Furthermore, we show that uncertainty informed decision referral can improve diagnostic performance. Experiments across different networks, tasks and datasets show robust generalization. Depending on network capacity and task/dataset difficulty, we surpass 85% sensitivity and 80% specificity as recommended by the NHS when referring 0−20% of the most uncertain decisions for further inspection. We analyse causes of uncertainty by relating intuitions from 2D visualizations to the high-dimensional image space. While uncertainty is sensitive to clinically relevant cases, sensitivity to unfamiliar data samples is task dependent, but can be rendered more robust.In recent years, deep neural networks (DNNs) 1 have revolutionized computer vision 2 and gained considerable traction in challenging scientific data analysis problems 3 . By stacking layers of linear convolutions with appropriate non-linearities 4 , abstract concepts can be learnt from high-dimensional input alleviating the challenging and time-consuming task of hand-crafting algorithms. Such DNNs are quickly entering the field of medical imaging and diagnosis [5][6][7][8][9][10][11][12][13][14][15] , outperforming state-of-the-art methods at disease detection or allowing one to tackle problems that had previously been out of reach. Applied at scale, such systems could considerably alleviate the workload of physicians by detecting patients at risk from a prescreening examination. Surprisingly, however, DNN-based solutions for medical applications have so far been suggested without any risk-management. Yet, information about the reliability of automated decisions is a key requirement for them to be integrated into diagnostic systems in the healthcare sector 16 . No matter whether data is short or abundant, difficult diagnostic cases are unavoidable. Therefore, DNNs should report -in addition to the decision -an associated estimate of uncertainty 17 , in particular since some images may be more difficult to analyse and classify than others, both for the clinician and the model, and the transition from "healthy" to "diseased" is not always clear-cut.Automated systems are typically evaluated by their diagnostic sensitivity, specificity or area under receiver-operating-characteristic (ROC) curve, metrics which measure the overall performance on the test set. However, ...

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“…To reduce the speckle and spatial coherence, we generate the multiple light sources by the combination of rotating diffuser and vibrating multimode fiber bundle (MMFB). To overcome the complications for assessing the high-dimensional data and minimizing the diagnostic errors, machine learning automation systems is used [13,[22][23][24][25][26]. Also, the present system is based on slightly off-axis, which need only single interferogram to extract the phase information that will be very helpful for dynamic process such as RBC [20,21].…”

Section: Introductionmentioning

confidence: 99%

Development of full‐field optical spatial coherence tomography system for automated identification of malaria using the multilevel ensemble classifier

Singla

Srivastava

Mehta

2018

Journal of Biophotonics

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Malaria is a life-threatening infectious blood disease affecting humans and other animals caused by parasitic protozoans belonging to the Plasmodium type especially in developing countries. The gold standard method for the detection of malaria is through the microscopic method of chemically treated blood smears. We developed an automated optical spatial coherence tomographic system using a machine learning approach for a fast identification of malaria cells. In this study, 28 samples (15 healthy, 13 malaria infected stages of red blood cells) were imaged by the developed system and 13 features were extracted. We designed a multilevel ensemble-based classifier for the quantitative prediction of different stages of the malaria cells. The proposed classifier was used by repeating k-fold cross validation dataset and achieve a high-average accuracy of 97.9% for identifying malaria infected late trophozoite stage of cells. Overall, our proposed system and multilevel ensemble model has a substantial quantifiable potential to detect the different stages of malaria infection without staining or expert.

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Deep Learning in Label-free Cell Classification

Cited by 391 publications

References 62 publications

Review: imaging technologies for flow cytometry

Review: imaging technologies for flow cytometry

Leveraging uncertainty information from deep neural networks for disease detection

Development of full‐field optical spatial coherence tomography system for automated identification of malaria using the multilevel ensemble classifier

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