This document summarizes research on using deep convolutional neural networks to automatically analyze microscopy images. The goals are to expedite the analysis of high-content microscopy data and automate tasks like cell counting and classification. The researchers trained and tested models using TensorFlow on microscopy images to classify cells, achieving over 75% accuracy. This level of automation could benefit biological research by reducing human errors and speeding up analysis of large image datasets.
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Automated Analysis of Microscopy Images using Deep Convolutional Neural Network
1. AUTOMATED ANALYSIS OF MICROSCOPY IMAGES USING
DEEP CONVOLUTIONAL NEURAL NETWORKS
Yaser M. Banadaki1*, Adetayo Okunoye2, and Safura Sharifi3,
1Department of Computer Science, Southern University, Baton Rouge, LA 70813
2Department of Computer Science, University of Georgia, Athens, GA 30602
3Department of Physics, University of Illinois Urbana Champaign, IL 61820
2. RESEARCH
GOALS
• To analyze deep convolutional neural network as an important tool
for the expedited analysis of high‐content microscopy image data
analysis.
• To automate interpretations of medical data which are being done
manually by medical experts including cell counting and
classifications – Processes that are time-intensive, cumbersome
and prone to human errors.
• To train and classify microscopy cellular images using TensorFlow
and achieve a result that outperforms other existing traditional
classification methods.
3. WHAT IS DEEP
CONVOLUTIONAL
NEURAL NETWORK?
In deep learning,
a convolutional neural
network (CNN) is a class
of deep neural networks, most
applied to analyzing visual
imagery. It simply means a
convolution neural network
with many layers.
4. QUICK OVERVIEW
• This work automated and analyzed
the tedious task of cell detection,
classification, and counting in
microscopy images.
• We employed DCNN to develop an
automated method for analyzing the
complex high-content microscopy
data that outperforms conventional
cell segmentation, classification, and
counting techniques.
• This would greatly benefit biological
research and the field of medicine
because of the tremendous
improvement in the detection of
complex cell morphologies.
5. • The notion of applying deep learning-based algorithms to biological and medical
imaging is a fascinating and growing research area. Deep Convolutional Neural
Networks (DCNN) and transfer learning approach has recently shown
remarkable success in image-based data analysis resulting in a tremendous
improvement in automated detection of complex morphologies
6. QUICK OVERVIEW
Deep learning technology applied to medical
imaging is the most disruptive technology
since the advent of digital imaging.
This research focuses on developing an
accurate, fast and fully automated
computational technique to analyze large-
scale high-throughput microscopy images
for fast phenotyping of functionally diverse
cell populations that outperforms
conventional cell segmentation,
classification and counting techniques.
7. QUICK OVERVIEW
• Automating the tedious task of cell
detection, classification, and counting in
microscopy images would greatly benefit
biological research as the approach
reduces the possibility of subjective
errors associated with semi-manual or
manual methods. Also, it supports
biomedical experimental works using
machine learning algorithm to
automatically improve the medical
image segmentation and classification in
the recognition and quantitative analysis
of microscopy image data.
8. THE BUILDING
BLOCKS OF DCNN
• Multi-Layer Perceptrons
(MLPs) are among the most
fundamental building blocks
in Artificial Neural Networks
(ANNs). It refers to a set of
computational models that
are loosely inspired by the
human brain. In general,
they consist of two important
elements, namely, artificial
neurons (nodes) and
synapses (weights) that
connect them. LeCun, [18]
10. METHODS
• The microscopy image
analysis requires the use
of deep convolutional
neural network model for
thorough learning,
classification and testing
of the given images. In
this work, we have
adopted the use of tensor
flow (Google’s open source
software for machine
learning) for training and
classification
13. RESULT
• This shows the result
of the simulation using
2500 datasets from each
category of the blood
samples. The classified
blood samples are
basophil, homophile,
lymphocyte, monocyte,
and neutrophil. The
graph shows that the
maximum test accuracy
of 76 percent can be
achieved using the
number of the training
samples in our dataset.
14. RESULT
This shows the prediction confidence of 10 randomly test images of four blood cells. We tested
the trained model with ten blood cell samples of mixed categories for identification of the type
of blood cells. It can be noticed that the model predicted neutrophils and monocyte with high
confidence margins.
15. CONCLUSION
• The annotation of the cells with complex morphology in the images and then the training
process of the model is time-consuming. However, the learned model would reduce the
runtime for cell classifications by orders of magnitudes. The deep convolutional neural
network and transfer learning approach used in the Inception v3 model has specifically
outperformed the binary classifier ensemble across all localization leading to an average
precision score of over 75% in classifying four white blood cells. The paper addressed the
pressing application of artificial intelligence is in the 21st century by enabling the
automated and quantitative analysis of microscopy images – bridging the gap between
existing image analysis techniques in biology and the novel data analytics techniques.
16. REFERENCES
• 1 Kraus, O.Z., Ba, J.L., and Frey, B.J.: ‘Classifying and segmenting microscopy images
with deep multiple instance learning’, Bioinformatics, 2016, 32, (12), pp. i52-i59
• 2 Dürr, O., and Sick, B.: ‘Single-cell phenotype classification using deep convolutional
neural networks’, Journal of biomolecular screening, 2016, 21, (9), pp. 998-1003
• 3 Pärnamaa, T., and Parts, L.: ‘Accurate classification of protein subcellular localization
from high-throughput microscopy images using deep learning’, G3: Genes, Genomes,
Genetics, 2017, 7, (5), pp. 1385-1392
• 4 Sadanandan, S.K., Ranefall, P., Le Guyader, S., and Wählby, C.: ‘Automated training
of deep convolutional neural networks for cell segmentation’, Scientific reports, 2017, 7,
(1), pp. 1-7
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neural network and compressed sensing’, arXiv preprint arXiv:1708.03307, 2017
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Biophotonics international, 2004, 11, (7), pp. 36-427. Sommer, C.; Straehle, C. N.;
Koethe, U.; Hamprecht, F. A. In Ilastik: Interactive learning and segmentation toolkit,
ISBI, 2011; p 8
• 7 Dataset, B.: ‘https://github.com/Shenggan/BCCD_Dataset’
• 8 Abadi, M., Agarwal, A., Barham, P., Brevdo, E., Chen, Z., Citro, C., Corrado, G.,
Davis, A., Dean, J., and Devin, M.: ‘Tensorflow: Large-scale machine learning on
heterogeneous distributed systems’, 2015