Plaque detection method for imaging of cells

What is claimed is: 1 . A plaque detection method, comprising the steps of: using above focus images to detect the presence of live cells without detecting the lysed cell materials; using below focus images wherein virtual dark regions exist which are similar to cell shadows as seeds in a segmentation process; using contours around each resulting shape to obtain a subset that are more likely to be part of the cell population to define a cell map; creating a distance map in which each pixel value is the distance of that pixel from the nearest pixel of the cell map; thresholding the distance map to create a first image of the places which are relatively far from the cells; and creating a second image with a smaller distance threshold to get an image that mimics the edges of the cells. 2 . The method according to claim 1 , further comprising applying a localized adaptive threshold process to the above focus images to produce a map of spots where intensity has concentrated. 3 . The method according to claim 1 , further comprising using parameters of shape and size to filter these contours to a subset that are more likely to be part of the cell population. 4 . The method according to claim 1 , further comprising rendering the contours that remain onto an image and detect regions that are empty. 5 . The method according to claim 1 , further comprising using the first image as a set of seeds for an additional application of a watershed algorithm and using the second image as the topography. 6 . A plaque detection apparatus, comprising the at least one processor programmed to receive above focus images to detect the presence of live cells without detecting the lysed cell materials; receiving below focus images wherein virtual dark regions exist which are similar to cell shadows as seeds in a segmentation process; using contours around each resulting shape to obtain a subset that are more likely to be part of the cell population to define a cell map; creating a distance map in which each pixel value is the distance of that pixel from the nearest pixel of the cell map; thresholding the distance map to create a first image of the places which are relatively far from the cells; and creating a second image with a smaller distance threshold to get an image that mimics the edges of the cells. 7 . The apparatus according to claim 6 , wherein the at least one processor applies a localized adaptive threshold process to the above focus images to produce a map of spots where intensity has concentrated. 8 . The apparatus according to claim 6 , wherein the at least one processor uses parameters of shape and size to filter these contours to a subset that are more likely to be part of the cell population. 9 . The apparatus according to claim 6 , wherein the at least one processor renders the contours that remain onto an image and detect regions that are empty. 10 . The apparatus according to claim 6 , wherein the at least one processor uses the first image as a set of seeds for an additional application of a watershed algorithm and uses the second image as the topography. 11 . A plaque detection method, comprising the steps of: using above focus images to detect the presence of live cells without detecting the lysed cell materials; applying a localized adaptive threshold process to the images to produce a map of spots where intensity has concentrated; using below focus images wherein virtual dark regions exist which are similar to cell shadows; using bright spots in the below focus images as seeds in a segmentation process; defining contours around each resulting shape; using parameters of shape and size to filter these contours to a subset that are more likely to be part of the cell population; rendering the contours that remain onto an image and detect regions that are empty; creating a distance map in which each pixel value is the distance of that pixel from the nearest pixel of the cell map; thresholding the distance map to create a first image of the places which are relatively far from the cells; creating a second image with a smaller distance threshold to get an image that mimics the edges of the cells; using the first image as a set of seeds for an additional application of a watershed algorithm; and using the second image as the topography.