Ridges are eigenvalues of matrix of second order derivate of image, also known as hessian matrix.

Using the above information, you can easily write a ridge detector using functionality provided by scikit-image

```
from skimage.features import hessian_matrix, hessian_matrix_eigvals
def detect_ridges(gray, sigma=3.0):
hxx, hyy, hxy = hessian_matrix(gray, sigma)
i1, i2 = hessian_matrix_eigvals(hxx, hxy, hyy)
return i1, i2
```

Here, i1 returns local maxima ridges and i2 returns local minima ridges. You can tinker around with sigma values to get an appropriate solution.
Example:

Actually, in Python/OpenCV, you can do something like this

```
image = cv2.imread('retina.tif')
ridge_filter = cv2.ximgproc.RidgeDetectionFilter_create()
ridges = ridge_filter.getRidgeFilteredImage(image)
```

Parameters for `cv2.ximgproc.RidgeDetectionFilter_create`

include:

```
@param ddepth Specifies output image depth. Defualt is CV_32FC1
@param dx Order of derivative x, default is 1 .
@param dy Order of derivative y, default is 1 .
@param ksize Sobel kernel size , default is 3 .
@param out_dtype Converted format for output, default is CV_8UC1 .
@param scale Optional scale value for derivative values, default is 1 .
@param delta Optional bias added to output, default is 0 .
@param borderType Pixel extrapolation method, default is BORDER_DEFAULT
```

Source - https://docs.opencv.org/trunk/d4/d36/classcv_1_1ximgproc_1_1RidgeDetectionFilter.html