This julia library provides functionality regarding cell counting in microscopy images. It relies on Knet.jl to train fully convolutional neural networks to recognize and count cell structures.

Note that this project is currently in early stages of development and might be unusable -- depending on the mood of the author.

In order to use DCellC.jl, you need a working version of julia 0.6. Further dependencies are

Knet.jl
Colors.jl
ImageFiltering.jl
JLD2.jl.

They should be fetched automatically when installing this package via

Pkg.clone("https://github.com/tscode/DCellC.jl.git")

from a julia 0.6 REPL.

Good Question

Counting the number of cells in microscopy images of all kinds (migration assays, ...) is a pervasive problem in the quantitative study of biological phenomena. Since the process of manual counting is vexing -- and pulverizing countless hours of potentially productive work for students and assistants in the live sciences all over the world -- a number of tools have been developed to automate this process and make it more reliable.

Classical image processing approaches to this task, like CellProfiler, CELLCOUNTER, or the Imagej plugin Cell-Counter have been developed and achive remarkable results for certain tasks of microscopic image analysis. Drawbacks of these tools are the manual fine tuning that is generally required in order for them to work fine.

In the recent years, with the advent of machine learning techniques for various image processing applications, different methods for identifying and counting cells, based on neural networks, have been proposed. This project, DCellC.jl, gathers much of its ideas from the publications (Xie, Noble, Zisserman; 2015) and (Pan, Yang, Li, et al.; 2018). The basic thought is that fully convolutional neural networks should be able to filter images for instances of similar cell-shaped realizations. The network is taught to produce "proximity maps" (an image of black dots wherever the network thinks a cell is lurking) out of the original images by means of convolutions with trainable convolution kernels. This reduces finding cells to a classical regression problem: Minimize the distance between the proximity maps and the true labels by adapting the network's weights.

Depending on the quality of the training data (labeled microscopy images with center positions for the cells) these methods can be used to recover a majority of the cells with little parameter tuning at all (or so I hope). Furthermore, it should (theoretically) work on various kinds of microscopic images, and have a strong robustness to focus on relevant information, such that pre or post-processing steps should be unnecessary.

• Everything