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I have an image of 30 cells. I would like to detect the 30 cells in this image by tracking specifically their nuclei (blue). I think the idea is to either group a certain number of blue pixels and consider it as one nucleus (30 total), or only count the bluest pixels (again, 30 total).

The following code gets the coordinates of all of the blue pixels.

import numpy as np
import matplotlib.pyplot as plt
import matplotlib.image as mpimg

control = mpimg.imread('jpeg.jpg')
ys = control.shape[0]
xs = control.shape[1]
blue = np.nonzero(control[:,:,2])


print(blue[0], len(blue[0]))
print(blue[1], len(blue[1]))

plt.imshow(control,cmap = plt.get_cmap('gray'),interpolation='none')
plt.show()

This code returns:

[  0   0   0 ... 447 447 447] 19031
[112 113 114 ... 381 382 383] 19031

Clearly, 19031 is too big. I only want 30.

This is the image [1]: https://i.stack.imgur.com/VhX5o.jpg

  • Not sure what the objection to OpenCV is, but maybe try scikit-image scikit-image.org/docs/dev/auto_examples/segmentation/… – Mark Setchell Apr 8 '19 at 11:06
  • There are 200,000 pixels in your image and your algorithm for finding blue pixels reckons 10% of them are blue so that is something to address first. If you know the max size of a nucleus, you could take the first pair of coordinates and add them to a list of nucleii, then zero out all remaining coordinates less than that distance away. Then go to next non-zero coordinate and repeat. – Mark Setchell Apr 8 '19 at 11:43
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What you're looking for are 30 blobs, rather than pixels. Using Hough Circles is nice and easy.

import cv2
import numpy as np
import matplotlib.pyplot as plt

# load image
img = plt.imread('VhX5o.jpg')

# convert image to gray
gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)

# median blur
gray = cv2.medianBlur(gray, 5)

# Detect circles
circles = cv2.HoughCircles(gray, cv2.HOUGH_GRADIENT, 1.2, 10,
          param1=200,
          param2=30,
          minRadius=0,
          maxRadius=0)

print(len(circles))  # 30
circles = np.uint16(np.around(circles))

# filtered image returns just the (blue) nucleus blobs
filt_img = np.zeros(img.shape)
for i in circles[0,:]:
    cv2.circle(filt_img,(i[0],i[1]),2,(0,0,255), 3)
    cv2.circle(img,(i[0],i[1]),2,(0,0,255), 3)

# plot filt_img
plt.figure()
plt.imshow(filt_img)

# plot with circles drawn over original image
plt.imshow(img)

You can use the circle positions as the centroids for each of the nuclei.

Hope that helps!

For future cases, I'd also recommend scipy.ndimage.measurements.label() for detecting blobs.

Blobs detected are overlayed onto original image If anyone could recommend me how to upload both images as part of this post that would be great!

  • Ah. In which case, OP can just use ndi.measurements.label(img[:, :, 1]) and write something quick to get the circles in the middle. Or just rewrite the OpenCV code from scratch by checking out their source code if it's for school work or something like that. – Jeffrey Wardman Apr 8 '19 at 12:18
  • Thanks. I actually have 60 images like that showing moving cells. With opencv is it possible for me to sort of store the coordinates of each specific cell into a list? – Biohacker Apr 8 '19 at 12:29
  • No worries at all! Yes you can. With the code above, circles is already that; a list of centroids for each cell. If you're happy with my answer, I'd greatly appreciate if you accepted it :) – Jeffrey Wardman Apr 8 '19 at 13:27

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