def analyze(imp, min_area):
MAXSIZE = 1000000000000
MINCIRCULARITY = 0.0
MAXCIRCULARITY = 1.
options = PA.SHOW_MASKS
temp_results = ResultsTable()
p = PA(options, PA.AREA + PA.MEAN, temp_results, min_area, MAXSIZE, MINCIRCULARITY, MAXCIRCULARITY)
p.setHideOutputImage(True)
p.analyze(imp)
if temp_results.getCounter() == 0:
areas = []
signals = []
else:
areas = list(temp_results.getColumn(0))
signals = list(temp_results.getColumn(1))
count = len(areas)
area = sum(areas)
total = 0
if area > 0:
total = sum([a*s for a,s in zip(areas, signals)]) / area
return p.getOutputImage(), count, area, total
def threshold(imPlus, edgeThreshold=2500):
mask = Duplicator().run(imPlus)
mask_stk = mask.getStack()
# First, we threshold based on edges
IJ.setThreshold(mask, edgeThreshold, 100000, "No Update")
for i in range(mask.getImageStackSize()):
mask_stk.getProcessor(i + 1).findEdges()
IJ.run(mask, "Make Binary", "method=Default background=Default black")
# Now, we need to clean up the binary images morphologically
IJ.run(mask, "Dilate", "stack")
IJ.run(mask, "Fill Holes", "stack")
IJ.run(mask, "Erode", "stack")
IJ.run(mask, "Erode", "stack")
# Finally, remove the small particles
stk = ImageStack(mask.getWidth(), mask.getHeight())
p = PA(PA.SHOW_MASKS, 0, None, 200, 100000)
p.setHideOutputImage(True)
for i in range(mask_stk.getSize()):
mask.setSliceWithoutUpdate(i + 1)
p.analyze(mask)
mmap = p.getOutputImage()
stk.addSlice(mmap.getProcessor())
mask.setStack(stk)
mask.setSliceWithoutUpdate(1)
mask.setTitle(mask_title(imPlus.getTitle()))
mask.show()
return mask
def segmentNuc(impc2):
impdup = Duplicator().run(impc2)
IJ.run(impdup, "8-bit", "")
IJ.run(impdup, "Gaussian Blur...", "sigma=1.5 stack")
# AutoThresholder().getThreshold(AutoThresholder.Method.valuOf('Otsu'), int[] histogram)
IJ.setAutoThreshold(impdup, "Otsu dark")
IJ.run(impdup, "Convert to Mask", "stack")
#IJ.setAutoThreshold(impdup, "Otsu dark")
#opt = PA.SHOW_MASKS + PA.SHOW_RESULTS + PA.EXCLUDE_EDGE_PARTICLES + PA.INCLUDE_HOLES # option for stack missing
opt = PA.SHOW_MASKS + PA.EXCLUDE_EDGE_PARTICLES + PA.INCLUDE_HOLES # option for stack missing
##area mean centroid bounding integrated stack redirect=None decimal=4
meas = Meas.AREA + Meas.MEAN + Meas.CENTROID + Meas.RECT + Meas.INTEGRATED_DENSITY + Meas.STACK_POSITION
rt = ResultsTable().getResultsTable()
pa = PA(opt, meas, rt, 10.0, 300000.0, 0, 1.0)
PA.processStack = True
pa.setHideOutputImage(True)
##run("Analyze Particles...", "size=800-Infinity circularity=0.00-1.00 pixel show=Masks display exclude include stack");
outstack = ImageStack(impdup.getWidth(), impdup.getHeight())
for i in range(1,impdup.getStackSize()+1):
impdup.setSlice(i)
pa.analyze(impdup)
impbin = pa.getOutputImage()
outstack.addSlice(impbin.getProcessor())
impbin = ImagePlus("out", outstack)
IJ.run(impbin, "Invert LUT", "")
#IJ.run(impbin, "Fill Holes", "stack")
return impbin, rt
def analyzeParticles(imp, minsize, maxsize, mincirc, maxcirc,
filename='Test.czi',
addROIManager=True,
headless=True,
exclude=True):
if addROIManager is True:
if exclude is False:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_MANAGER \
+ PA.ADD_TO_OVERLAY \
if exclude is True:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_MANAGER \
+ PA.ADD_TO_OVERLAY \
+ PA.EXCLUDE_EDGE_PARTICLES
if addROIManager is False:
if exclude is False:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_OVERLAY \
if exclude is True:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_OVERLAY \
+ PA.EXCLUDE_EDGE_PARTICLES
measurements = PA.STACK_POSITION \
+ PA.LABELS \
+ PA.AREA \
+ PA.RECT \
results = ResultsTable()
p = PA(options, measurements, results, minsize, maxsize, mincirc, maxcirc)
p.setHideOutputImage(True)
particlestack = ImageStack(imp.getWidth(), imp.getHeight())
for i in range(imp.getStackSize()):
imp.setSliceWithoutUpdate(i + 1)
ip = imp.getProcessor()
#IJ.run(imp, "Convert to Mask", "")
p.analyze(imp, ip)
mmap = p.getOutputImage()
particlestack.addSlice(mmap.getProcessor())
return particlestack, results
def process(inputpath, outputpath):
imp = IJ.openImage(inputpath)
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
IJ.setThreshold(imp, t1, 255)
#imp.show()
#WaitForUserDialog("Title", "Look at image").show()
IJ.run(imp, "Convert to Mask", "")
IJ.run(imp, "Watershed", "")
# Counts and measures the area of particles and adds them to a table called areas. Also adds them to the ROI manager
table = ResultsTable()
roim = RoiManager(True)
ParticleAnalyzer.setRoiManager(roim)
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER, Measurements.AREA,
table, 50, 9999999999999999, 0.2, 1.0)
pa.setHideOutputImage(True)
pa.analyze(imp)
imp.changes = False
imp.close()
areas = table.getColumn(0)
summary = {}
if areas:
summary['Image'] = filename
summary['Nuclei.count'] = len(areas)
summary['Area.Covered'] = sum(areas)
fieldnames = list(summary.keys())
with open(outputpath, 'a') as csvfile:
writer = csv.DictWriter(csvfile,
fieldnames=fieldnames,
extrasaction='ignore',
lineterminator='\n')
if os.path.getsize(outputDirectory + "/" + outputname + ".csv") < 1:
writer.writeheader()
writer.writerow(summary)
def countParticles(imp, roim, minSize, maxSize, minCircularity, maxCircularity): # Create a table to store the results table = ResultsTable() # Create the particle analyzer pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER, Measurements.AREA|Measurements.MEAN, table, minSize, maxSize, minCircularity, maxCircularity) #pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER, Measurements.AREA|Measurements.MEAN, table, 10, Double.POSITIVE_INFINITY, 0.5, 1.0) #pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER, Measurements.AREA|Measurements.MEAN, table, 5, 6, 0.5, 1.0) pa.setRoiManager(roim) pa.setHideOutputImage(True) if pa.analyze(imp): print "All ok" else: print "There was a problem in analyzing", blobs areas = table.getColumn(0) intensities = table.getColumn(1) if ( (areas!=None) and (intensities!=None)): for area, intensity in zip(areas,intensities): print str(area)+": "+str(intensity)
def countParticles(imp, roim, minSize, maxSize, minCircularity,
maxCircularity):
# Create a table to store the results
table = ResultsTable()
# Create the particle analyzer
pa = ParticleAnalyzer(
ParticleAnalyzer.ADD_TO_MANAGER,
Measurements.AREA | Measurements.MEAN | Measurements.ELLIPSE, table,
minSize, maxSize, minCircularity, maxCircularity)
pa.setRoiManager(roim)
pa.setHideOutputImage(True)
if pa.analyze(imp):
print "All ok"
else:
print "There was a problem in analyzing", blobs
areas = table.getColumn(0)
intensities = table.getColumn(1)
majors = table.getColumn(2)
def getParticleCenters(imp):
# Create a table to store the results
rt = ResultsTable()
paOpts = PA.SHOW_OUTLINES \
+ PA.INCLUDE_HOLES \
+ PA.EXCLUDE_EDGE_PARTICLES
measurements = PA.CENTROID + PA.CENTER_OF_MASS
MINSIZE = 1000
MAXSIZE = Double.POSITIVE_INFINITY
pa = PA(paOpts,measurements, rt, MINSIZE, MAXSIZE)
pa.setHideOutputImage(True)
if not pa.analyze(imp):
print "There was a problem in analyzing", imp
# The measured centroids are listed in the first column of the results table, as a float array:
centroids_x = rt.getColumn(rt.X_CENTROID)
centroids_y = rt.getColumn(rt.Y_CENTROID)
coms_x = rt.getColumn(rt.X_CENTER_OF_MASS)
coms_y = rt.getColumn(rt.Y_CENTER_OF_MASS)
return (centroids_x,centroids_y, coms_x, coms_y)
def removeSmallCCs(image):
MINSIZE = 1000
MAXSIZE = 1000000
options = PA.SHOW_ROI_MASKS
results = ResultsTable()
p = PA(options, PA.STACK_POSITION + PA.LABELS + PA.AREA + PA.PERIMETER + PA.CIRCULARITY, results, MINSIZE, MAXSIZE)
p.setHideOutputImage(True)
p.analyze(image)
mmap = p.getOutputImage()
mip = mmap.getProcessor()
mip.threshold(0)
img = ImagePlus("rods_processed", mip)
IJ.run(img, "8-bit", "")
IJ.run(img, "Make Binary", "method=Default background=Dark black")
return img
def process(subFolder, outputDirectory, filename):
imp = IJ.openImage(inputDirectory + subFolder + '/' +
rreplace(filename, "_ch00.tif", ".tif"))
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
ic = ImageConverter(imp)
ic.convertToGray8()
IJ.setThreshold(imp, 2, 255)
IJ.run(imp, "Convert to Mask", "")
IJ.run(imp, "Remove Outliers...",
"radius=5" + " threshold=50" + " which=Dark")
IJ.run(imp, "Remove Outliers...",
"radius=5" + " threshold=50" + " which=Bright")
imp.getProcessor().invert()
rm = RoiManager(True)
imp.getProcessor().setThreshold(0, 0, ImageProcessor.NO_LUT_UPDATE)
boundroi = ThresholdToSelection.run(imp)
rm.addRoi(boundroi)
if not displayImages:
imp.changes = False
imp.close()
images = [None] * 5
intensities = [None] * 5
blobsarea = [None] * 5
blobsnuclei = [None] * 5
bigAreas = [None] * 5
for chan in channels:
v, x = chan
images[x] = IJ.openImage(inputDirectory + subFolder + '/' +
rreplace(filename, "_ch00.tif", "_ch0" +
str(x) + ".tif"))
imp = images[x]
for roi in rm.getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.MEAN | Measurements.AREA)
intensities[x] = stats.mean
bigAreas[x] = stats.area
rm.close()
# Opens the ch00 image and sets default properties
imp = IJ.openImage(inputDirectory + subFolder + '/' + filename)
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
# Sets the threshold and watersheds. for more details on image processing, see https://imagej.nih.gov/ij/developer/api/ij/process/ImageProcessor.html
ic = ImageConverter(imp)
ic.convertToGray8()
IJ.run(imp, "Remove Outliers...",
"radius=2" + " threshold=50" + " which=Dark")
IJ.run(imp, "Gaussian Blur...", "sigma=" + str(blur))
IJ.setThreshold(imp, lowerBounds[0], 255)
if displayImages:
imp.show()
IJ.run(imp, "Convert to Mask", "")
IJ.run(imp, "Watershed", "")
if not displayImages:
imp.changes = False
imp.close()
# Counts and measures the area of particles and adds them to a table called areas. Also adds them to the ROI manager
table = ResultsTable()
roim = RoiManager(True)
ParticleAnalyzer.setRoiManager(roim)
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER, Measurements.AREA,
table, 15, 9999999999999999, 0.2, 1.0)
pa.setHideOutputImage(True)
#imp = impM
# imp.getProcessor().invert()
pa.analyze(imp)
areas = table.getColumn(0)
# This loop goes through the remaining channels for the other markers, by replacing the ch00 at the end with its corresponding channel
# It will save all the area fractions into a 2d array called areaFractionsArray
areaFractionsArray = [None] * 5
for chan in channels:
v, x = chan
# Opens each image and thresholds
imp = images[x]
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
ic = ImageConverter(imp)
ic.convertToGray8()
IJ.setThreshold(imp, lowerBounds[x], 255)
if displayImages:
imp.show()
WaitForUserDialog("Title",
"Adjust Threshold for Marker " + v).show()
IJ.run(imp, "Convert to Mask", "")
# Measures the area fraction of the new image for each ROI from the ROI manager.
areaFractions = []
for roi in roim.getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.AREA_FRACTION)
areaFractions.append(stats.areaFraction)
# Saves the results in areaFractionArray
areaFractionsArray[x] = areaFractions
roim.close()
for chan in channels:
v, x = chan
imp = images[x]
imp.deleteRoi()
roim = RoiManager(True)
ParticleAnalyzer.setRoiManager(roim)
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER,
Measurements.AREA, table, 15, 9999999999999999,
0.2, 1.0)
pa.analyze(imp)
blobs = []
for roi in roim.getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.AREA)
blobs.append(stats.area)
blobsarea[x] = sum(blobs)
blobsnuclei[x] = len(blobs)
if not displayImages:
imp.changes = False
imp.close()
roim.reset()
roim.close()
# Creates the summary dictionary which will correspond to a single row in the output csv, with each key being a column
summary = {}
summary['Image'] = filename
summary['Directory'] = subFolder
# Adds usual columns
summary['size-average'] = 0
summary['#nuclei'] = 0
summary['all-negative'] = 0
summary['too-big-(>' + str(tooBigThreshold) + ')'] = 0
summary['too-small-(<' + str(tooSmallThreshold) + ')'] = 0
# Creates the fieldnames variable needed to create the csv file at the end.
fieldnames = [
'Name', 'Directory', 'Image', 'size-average',
'too-big-(>' + str(tooBigThreshold) + ')',
'too-small-(<' + str(tooSmallThreshold) + ')', '#nuclei',
'all-negative'
]
# Adds the columns for each individual marker (ignoring Dapi since it was used to count nuclei)
summary["organoid-area"] = bigAreas[x]
fieldnames.append("organoid-area")
for chan in channels:
v, x = chan
summary[v + "-positive"] = 0
fieldnames.append(v + "-positive")
summary[v + "-intensity"] = intensities[x]
fieldnames.append(v + "-intensity")
summary[v + "-blobsarea"] = blobsarea[x]
fieldnames.append(v + "-blobsarea")
summary[v + "-blobsnuclei"] = blobsnuclei[x]
fieldnames.append(v + "-blobsnuclei")
# Adds the column for colocalization between first and second marker
if len(channels) > 2:
summary[channels[1][0] + '-' + channels[2][0] + '-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-positive')
# Adds the columns for colocalization between all three markers
if len(channels) > 3:
summary[channels[1][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[2][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[1][0] + '-' + channels[2][0] + '-' + channels[3][0] +
'-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[2][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-' +
channels[3][0] + '-positive')
# Loops through each particle and adds it to each field that it is True for.
areaCounter = 0
for z, area in enumerate(areas):
log.write(str(area))
log.write("\n")
if area > tooBigThreshold:
summary['too-big-(>' + str(tooBigThreshold) + ')'] += 1
elif area < tooSmallThreshold:
summary['too-small-(<' + str(tooSmallThreshold) + ')'] += 1
else:
summary['#nuclei'] += 1
areaCounter += area
temp = 0
for chan in channels:
v, x = chan
if areaFractionsArray[x][z] > areaFractionThreshold[
0]: #theres an error here im not sure why. i remember fixing it before
summary[chan[0] + '-positive'] += 1
if x != 0:
temp += 1
if temp == 0:
summary['all-negative'] += 1
if len(channels) > 2:
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
if areaFractionsArray[2][z] > areaFractionThreshold[2]:
summary[channels[1][0] + '-' + channels[2][0] +
'-positive'] += 1
if len(channels) > 3:
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
if areaFractionsArray[3][z] > areaFractionThreshold[3]:
summary[channels[1][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[2][z] > areaFractionThreshold[2]:
if areaFractionsArray[3][z] > areaFractionThreshold[3]:
summary[channels[2][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
summary[channels[1][0] + '-' + channels[2][0] +
'-' + channels[3][0] + '-positive'] += 1
# Calculate the average of the particles sizes
if float(summary['#nuclei']) > 0:
summary['size-average'] = round(areaCounter / summary['#nuclei'], 2)
# Opens and appends one line on the final csv file for the subfolder (remember that this is still inside the loop that goes through each image)
with open(outputDirectory + "/" + outputName + ".csv", 'a') as csvfile:
writer = csv.DictWriter(csvfile,
fieldnames=fieldnames,
extrasaction='ignore',
lineterminator='\n')
if os.path.getsize(outputDirectory + "/" + outputName + ".csv") < 1:
writer.writeheader()
writer.writerow(summary)
summary[color[i] + "-threshold-used"] = ImageProcessor.getMinThreshold(channel.getProcessor())
#Threshold and watershed
IJ.run(channel, "Convert to Mask", "")
IJ.run(channel, "Watershed", "")
table = ResultsTable()
roim = RoiManager(True)
ParticleAnalyzer.setRoiManager(roim)
#Analyses particles: finds all the objects that match criteria
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER | ParticleAnalyzer.EXCLUDE_EDGE_PARTICLES, Measurements.AREA, table, minimum_size, maximum_size, 0.1, 1.0)
pa.setHideOutputImage(True)
pa.analyze(channel)
if thresholdMode:
channel.show()
WaitForUserDialog("Title", "Look at threshold for" + color[i]).show()
#adds count to summary
if table.getColumnIndex("Area") != -1:
summary[color[i] + "-ROI-count"] = len(table.getColumn(table.getColumnIndex("Area")))
channel.changes = False
channel.close()
dupes.append(x)
seen[x] += 1
print(dupes)
for dupe in dupes:
# get centroidys
rt = ResultsTable();
#rm = RoiManager.getInstance();
#print(rm)
rm = RoiManager(False);
pa = ParticleAnalyzer((ParticleAnalyzer.ADD_TO_MANAGER | ParticleAnalyzer.SHOW_MASKS), (Measurements.CENTROID | Measurements.STACK_POSITION), rt, 500, 30000, 0.0, 1.0)
pa.setHideOutputImage(False)
keep_rois = [];
pa.analyze(imp);
IJ.run("Set Measurements...", "centroid redirect=None decimal=3");
frames = imp.getNFrames();
for fridx in range(0, frames):
rt.reset();
imp.setSliceWithoutUpdate(fridx + 1);
ip = imp.getProcessor();
if not pa.analyze(imp, ip):
raise Exception("something went wrong analysing particles!")
rt.show("centroids");
rm = RoiManager.getInstance();
if rm.getCount() > 0:
rois = rm.getRoisAsArray();
binorg.show()
# Count nucleus setting
MAXSIZE = imp3.getWidth()*imp3.getHeight();
MINSIZE = 100;
#options = PA.SHOW_ROI_MASKS \
# + PA.EXCLUDE_EDGE_PARTICLES \
# + PA.INCLUDE_HOLES \
# + PA.SHOW_RESULTS \
options = PA.INCLUDE_HOLES \
+ PA.CLEAR_WORKSHEET \
# + PA.SHOW_RESULTS \
rt = ResultsTable()
p = PA(options, PA.AREA + PA.STACK_POSITION, rt, MINSIZE, MAXSIZE)
p.setHideOutputImage(True)
# Morphological dilate
binner.setup('dilate', None)
clusters = 0
initialCells = 0
# dilate by 'SAMPLEITER'
for i in range(SAMPLEITER+1):
p.analyze(binimp)
cellcounts = rt.getCounter()
if i == 0:
initialCells = cellcounts
#IJ.log("iter:" + str(i) + " -- cell counts: " + str(cellcounts))
def __calRois(self, imp, indice) :
"""
Returns the ROIs of a slice given (identified with its n°) in a stack
"""
##imp=self.__dictImages[nameimages] # IL FAUT RÉCUPÉRER L'IMAGE DU STACK !!!!!
#if self.__batch : imp.hide()
#else : imp.show()
#imp.hide()
imp.show()
if self.__batch : imp.hide()
imp.setSlice(indice)
imp.killRoi()
ip = imp.getProcessor()
bs=BackgroundSubtracter()
#if str(self.__subback) == "0" or str(self.__subback) == "1" : self.__subback = bool(int(self.__subback))
#if self.__subback == True : IJ.run(imp, "Subtract Background...", "rolling="+str(self.__radius)+" light")
if self.__subback == True : bs.rollingBallBackground(ip, self.__radius, False, True, False, True, False)
if self.__runmacro :
imp.show()
imp.setSlice(indice)
imp.updateAndDraw()
IJ.runMacroFile(self.__macropath, imp.getTitle())
imp.updateAndDraw()
#if str(self.__manthresh) == "0" or str(self.__manthresh) == "1" : self.__manthresh = bool(int(self.__manthresh))
#if self.__manthresh : IJ.setThreshold(imp, self.__minthr, self.__maxthr)
if self.__manthresh :
ip.setThreshold(self.__minthr, self.__maxthr, ImageProcessor.RED_LUT)
else : self.__setThreshold(imp, indice)
rt=ResultsTable()
pa1=ParticleAnalyzer(ParticleAnalyzer.SHOW_MASKS+ParticleAnalyzer.EXCLUDE_EDGE_PARTICLES , Measurements.AREA, rt, self.__minArea, self.__maxArea, self.__minCirc, self.__maxCirc)
pa1.setHideOutputImage(True)
pa1.analyze(imp)
masks=pa1.getOutputImage()
masks.getProcessor().erode()
masks.getProcessor().dilate()
masks.getProcessor().invertLut()
masks.getProcessor().threshold(1)
rm = RoiManager.getInstance()
if (rm==None): rm = RoiManager()
rm.runCommand("reset")
#rm.hide()
pa2=ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER+ParticleAnalyzer.CLEAR_WORKSHEET+ParticleAnalyzer.EXCLUDE_EDGE_PARTICLES , Measurements.AREA, rt, self.__minArea, self.__maxArea, self.__minCirc, self.__maxCirc)
pa2.analyze(masks)
masks.close()
temparray=rm.getRoisAsArray()
for r in temparray :
tempnameroi=r.getName()
r.setPosition(indice)
r.setName(str(indice)+"-"+tempnameroi)
r.setStrokeWidth(1)
if len(self.__params) > 0 :
for k in self.__params:
#if k[0]=="Area": self.__minArea, self.__maxArea = str(k[1]), str(k[2])
if k[0]=="Area": self.__minArea, self.__maxArea = k[1], k[2]
for k in self.__params:
#if k[0]=="Circ": self.__minCirc, self.__maxCirc = str(k[1]), str(k[2])
if (k[0]=="Circ") and k[3] : self.__minCirc, self.__maxCirc = k[1], k[2]
else : self.__minCirc, self.__maxCirc = 0, 1
self.__rr.setRoisarray(temparray, imp)
self.__rr.setRange(indice, self.__params)
return self.__rr.includeRois
else : return temparray
def process(subDir, subsubDir, outputDirectory, filename):
subFolder = subDir + "/" + subsubDir
# Opens the d0 image and sets default properties
imp = IJ.openImage(inputDirectory + subFolder + '/' + filename)
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
# Sets the threshold and watersheds. for more details on image processing, see https://imagej.nih.gov/ij/developer/api/ij/process/ImageProcessor.html
ic = ImageConverter(imp)
ic.convertToGray8()
imp.updateAndDraw()
dup = imp.duplicate()
IJ.run(
dup, "Convolve...",
"text1=[-1 -1 -1 -1 -1\n-1 -1 -1 -1 -1\n-1 -1 24 -1 -1\n-1 -1 -1 -1 -1\n-1 -1 -1 -1 -1\n] normalize"
)
stats = dup.getStatistics(Measurements.MEAN | Measurements.MIN_MAX
| Measurements.STD_DEV)
dup.close()
blurry = (stats.mean < 18 and stats.stdDev < 22) or stats.max < 250
IJ.setThreshold(imp, lowerBounds[0], 255)
IJ.run(imp, "Convert to Mask", "")
IJ.run(imp, "Watershed", "")
if displayImages:
imp.show()
WaitForUserDialog("Title", "Look at image").show()
# Counts and measures the area of particles and adds them to a table called areas. Also adds them to the ROI manager
table = ResultsTable()
roim = RoiManager(True)
ParticleAnalyzer.setRoiManager(roim)
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER, Measurements.AREA,
table, 15, 9999999999999999, 0.2, 1.0)
pa.setHideOutputImage(True)
pa.analyze(imp)
if not displayImages:
imp.changes = False
imp.close()
areas = table.getColumn(0)
# This loop goes through the remaining channels for the other markers, by replacing the d0 at the end with its corresponding channel
# It will save all the area fractions into a 2d array called areaFractionsArray
areaFractionsArray = []
areaMeansArray = []
means = []
totalAreas = []
for chan in channels:
v, x = chan
# Opens each image and thresholds
imp = IJ.openImage(inputDirectory + subFolder + '/' +
filename.replace("d0.TIF", "d" + str(x) + ".TIF"))
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
ic = ImageConverter(imp)
ic.convertToGray8()
imp.updateAndDraw()
stats = imp.getStatistics(Measurements.MEAN)
means.append(stats.mean)
areaMeans = []
for roi in roim.getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.MEAN)
areaMeans.append(stats.mean)
IJ.setThreshold(imp, lowerBounds[x], 255)
IJ.run(imp, "Convert to Mask", "")
if displayImages:
imp.show()
WaitForUserDialog("Title", "Look at image").show()
stats = imp.getStatistics(Measurements.AREA_FRACTION)
totalAreas.append(stats.areaFraction)
# Measures the area fraction of the new image for each ROI from the ROI manager.
areaFractions = []
for roi in roim.getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.AREA_FRACTION)
areaFractions.append(stats.areaFraction)
# Saves the results in areaFractionArray
areaFractionsArray.append(areaFractions)
areaMeansArray.append(sum(areaMeans) / len(areaMeans))
if not displayImages:
imp.changes = False
imp.close()
roim.close()
# Figures out what well the image is a part of
ind = filename.index("p00_0_")
row = filename[ind + 6:ind + 7]
column = str(int(filename[ind + 7:ind + 9]))
# Creates the summary dictionary which will correspond to a single row in the output csv, with each key being a column
summary = {}
# Finds the name of the well from the nameArray 2d array
if row in nameArray:
if column in nameArray[row]:
summary['Name'] = nameArray[row][column]
summary['Image'] = filename
summary['Directory'] = subDir
summary['SubDirectory'] = subsubDir
summary['Row'] = row
summary['Column'] = column
# Adds usual columns
summary['size-average'] = 0
summary['#nuclei'] = 0
summary['all-negative'] = 0
summary['too-big-(>' + str(tooBigThreshold) + ')'] = 0
summary['too-small-(<' + str(tooSmallThreshold) + ')'] = 0
summary['image-quality'] = blurry
# Creates the fieldnames variable needed to create the csv file at the end.
fieldnames = [
'Name', 'Directory', 'SubDirectory', 'Image', 'Row', 'Column',
'size-average', 'image-quality',
'too-big-(>' + str(tooBigThreshold) + ')',
'too-small-(<' + str(tooSmallThreshold) + ')', '#nuclei',
'all-negative'
]
# Adds the columns for each individual marker (ignoring Dapi since it was used to count nuclei)
for chan in channels:
v, x = chan
summary[v + "-positive"] = 0
summary[v + "-intensity"] = means[x]
summary[v + "-area"] = totalAreas[x]
summary[v + "-intensity-in-nuclei"] = areaMeansArray[x]
summary[v + "-area-fraction-in-nuclei"] = sum(
areaFractionsArray[x]) / len(areaFractionsArray[x])
fieldnames.append(v + "-positive")
fieldnames.append(v + "-intensity")
fieldnames.append(v + "-area")
fieldnames.append(v + "-intensity-in-nuclei")
fieldnames.append(v + "-area-fraction-in-nuclei")
# Adds the column for colocalization between first and second marker
if len(channels) > 2:
summary[channels[1][0] + '-' + channels[2][0] + '-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-positive')
# Adds the columns for colocalization between all three markers
if len(channels) > 3:
summary[channels[1][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[2][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[1][0] + '-' + channels[2][0] + '-' + channels[3][0] +
'-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[2][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-' +
channels[3][0] + '-positive')
# Loops through each particle and adds it to each field that it is True for.
areaCounter = 0
if not (areas is None):
for z, area in enumerate(areas):
if not (area is None or summary is None):
if area > tooBigThreshold:
summary['too-big-(>' + str(tooBigThreshold) + ')'] += 1
elif area < tooSmallThreshold:
summary['too-small-(<' + str(tooSmallThreshold) + ')'] += 1
else:
summary['#nuclei'] += 1
areaCounter += area
temp = 0
for y, chan in enumerate(channels):
v, x = chan
if areaFractionsArray[y][z] > areaFractionThreshold:
summary[chan[0] + '-positive'] += 1
if x != 0:
temp += 1
if temp == 0:
summary['all-negative'] += 1
if len(channels) > 2:
if areaFractionsArray[1][z] > areaFractionThreshold:
if areaFractionsArray[2][z] > areaFractionThreshold:
summary[channels[1][0] + '-' + channels[2][0] +
'-positive'] += 1
if len(channels) > 3:
if areaFractionsArray[1][z] > areaFractionThreshold:
if areaFractionsArray[3][z] > areaFractionThreshold:
summary[channels[1][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[2][z] > areaFractionThreshold:
if areaFractionsArray[3][z] > areaFractionThreshold:
summary[channels[2][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[1][
z] > areaFractionThreshold:
summary[channels[1][0] + '-' +
channels[2][0] + '-' +
channels[3][0] + '-positive'] += 1
# Calculate the average of the particles sizes
if float(summary['#nuclei']) > 0:
summary['size-average'] = round(areaCounter / summary['#nuclei'], 2)
# Opens and appends one line on the final csv file for the subfolder (remember that this is still inside the loop that goes through each image)
with open(outputDirectory + "/" + outputName + ".csv", 'a') as csvfile:
writer = csv.DictWriter(csvfile,
fieldnames=fieldnames,
extrasaction='ignore',
lineterminator='\n')
if os.path.getsize(outputDirectory + "/" + outputName + ".csv") < 1:
writer.writeheader()
writer.writerow(summary)
def process(subFolder, outputDirectory, filename):
imp = IJ.openImage(inputDirectory + subFolder + '/' + filename)
imp.show()
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
ic = ImageConverter(imp)
dup = imp.duplicate()
dup_title = dup.getTitle()
ic.convertToGray8()
imp.updateAndDraw()
IJ.run("Threshold...")
IJ.setThreshold(218, 245)
IJ.run(imp, "Convert to Mask", "")
rm = RoiManager()
imp.getProcessor().setThreshold(0, 0, ImageProcessor.NO_LUT_UPDATE)
boundroi = ThresholdToSelection.run(imp)
rm.addRoi(boundroi)
imp.changes = False
imp.close()
images = [None] * 5
intensities = [None] * 5
blobsarea = [None] * 5
blobsnuclei = [None] * 5
cells = [None] * 5
bigareas = [None] * 5
IJ.run(dup, "Colour Deconvolution", "vectors=[H DAB]")
images[0] = getImage(dup_title + "-(Colour_1)")
images[1] = getImage(dup_title + "-(Colour_2)")
images[2] = getImage(dup_title + "-(Colour_3)")
images[2].close()
for chan in channels:
v, x = chan
imp = images[x]
imp.show()
for roi in rm.getRoiManager().getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.MEAN | Measurements.AREA)
intensities[x] = stats.mean
bigareas[x] = stats.area
rm.runCommand(imp, "Show None")
rm.close()
# Opens the ch00 image and sets default properties
imp = images[0].duplicate()
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
# Sets the threshold and watersheds. for more details on image processing, see https://imagej.nih.gov/ij/developer/api/ij/process/ImageProcessor.html
imp.show()
setTempCurrentImage(imp)
ic = ImageConverter(imp)
imp.updateAndDraw()
IJ.run(imp, "Gaussian Blur...", "sigma=" + str(blur))
imp.updateAndDraw()
imp.show()
IJ.run("Threshold...")
IJ.setThreshold(30, lowerBounds[0])
if displayImages:
imp.show()
WaitForUserDialog(
"Title", "Adjust threshold for nuclei. Current region is: " +
region).show()
IJ.run(imp, "Convert to Mask", "")
# Counts and measures the area of particles and adds them to a table called areas. Also adds them to the ROI manager
table = ResultsTable()
roim = RoiManager()
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER, Measurements.AREA,
table, 5, 9999999999999999, 0.05, 1.0)
pa.setHideOutputImage(True)
imp = IJ.getImage()
# imp.getProcessor().invert()
pa.analyze(imp)
imp.changes = False
imp.close()
areas = table.getColumn(0)
# This loop goes through the remaining channels for the other markers, by replacing the ch00 at the end with its corresponding channel
# It will save all the area fractions into a 2d array called areaFractionsArray
areaFractionsArray = [None] * 5
maxThresholds = []
for chan in channels:
v, x = chan
# Opens each image and thresholds
imp = images[x]
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
imp.show()
setTempCurrentImage(imp)
ic = ImageConverter(imp)
ic.convertToGray8()
imp.updateAndDraw()
rm.runCommand(imp, "Show None")
rm.runCommand(imp, "Show All")
rm.runCommand(imp, "Show None")
imp.show()
IJ.selectWindow(imp.getTitle())
IJ.run("Threshold...")
IJ.setThreshold(20, lowerBounds[x])
if displayImages:
WaitForUserDialog(
"Title", "Adjust threshold for " + v +
". Current region is: " + region).show()
ip = imp.getProcessor()
maxThresholds.append(ip.getMaxThreshold())
IJ.run(imp, "Convert to Mask", "")
# Measures the area fraction of the new image for each ROI from the ROI manager.
areaFractions = []
for roi in roim.getRoiManager().getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.AREA_FRACTION)
areaFractions.append(stats.areaFraction)
# Saves the results in areaFractionArray
areaFractionsArray[x] = areaFractions
roim.close()
for chan in channels:
v, x = chan
imp = images[x]
imp.deleteRoi()
imp.updateAndDraw()
setTempCurrentImage(imp)
roim = RoiManager()
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER,
Measurements.AREA, table, 15, 9999999999999999,
0.2, 1.0)
pa.analyze(imp)
blobs = []
cell = []
for roi in roim.getRoiManager().getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.AREA)
blobs.append(stats.area)
if stats.area > tooSmallThresholdDAB and stats.area < tooBigThresholdDAB:
cell.append(stats.area)
blobsarea[x] = sum(blobs)
blobsnuclei[x] = len(blobs)
cells[x] = len(cell)
imp.changes = False
imp.close()
roim.reset()
roim.close()
# Creates the summary dictionary which will correspond to a single row in the output csv, with each key being a column
summary = {}
summary['Image'] = filename
summary['Directory'] = subFolder
# Adds usual columns
summary['size-average'] = 0
summary['#nuclei'] = 0
summary['all-negative'] = 0
summary['too-big-(>' + str(tooBigThreshold) + ')'] = 0
summary['too-small-(<' + str(tooSmallThreshold) + ')'] = 0
# Creates the fieldnames variable needed to create the csv file at the end.
fieldnames = [
'Directory', 'Image', 'size-average',
'too-big-(>' + str(tooBigThreshold) + ')',
'too-small-(<' + str(tooSmallThreshold) + ')', '#nuclei',
'all-negative'
]
for row in info:
if row['Animal ID'] == filename.replace('s', '-').replace(
'p', '-').split('-')[0]:
for key, value in row.items():
fieldnames.insert(0, key)
summary[key] = value
# Adds the columns for each individual marker (ignoring Dapi since it was used to count nuclei)
summary["tissue-area"] = bigareas[0]
fieldnames.append("tissue-area")
for chan in channels:
v, x = chan
summary[v + "-HEMO-cells"] = 0
fieldnames.append(v + "-HEMO-cells")
summary[v + "-intensity"] = intensities[x]
fieldnames.append(v + "-intensity")
summary[v + "-area"] = blobsarea[x]
fieldnames.append(v + "-area")
summary[v + "-area/tissue-area"] = blobsarea[x] / bigareas[0]
fieldnames.append(v + "-area/tissue-area")
summary[v + "-particles"] = blobsnuclei[x]
fieldnames.append(v + "-particles")
summary[v + "-cells"] = cells[x]
fieldnames.append(v + "-cells")
summary[v + "-particles/tissue-area"] = blobsnuclei[x] / bigareas[0]
fieldnames.append(v + "-particles/tissue-area")
fieldnames.append(v + "-HEMO-Cells/tissue-area")
# Adds the column for colocalization between first and second marker
if len(channels) > 2:
summary[channels[1][0] + '-' + channels[2][0] + '-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-positive')
# Adds the columns for colocalization between all three markers
if len(channels) > 3:
summary[channels[1][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[2][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[1][0] + '-' + channels[2][0] + '-' + channels[3][0] +
'-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[2][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-' +
channels[3][0] + '-positive')
# Loops through each particle and adds it to each field that it is True for.
areaCounter = 0
for z, area in enumerate(areas):
if area > tooBigThreshold:
summary['too-big-(>' + str(tooBigThreshold) + ')'] += 1
elif area < tooSmallThreshold:
summary['too-small-(<' + str(tooSmallThreshold) + ')'] += 1
else:
summary['#nuclei'] += 1
areaCounter += area
temp = 0
for chan in channels:
v, x = chan
if areaFractionsArray[x][z] > areaFractionThreshold[0]:
summary[chan[0] + '-HEMO-cells'] += 1
if x != 0:
temp += 1
if temp == 0:
summary['all-negative'] += 1
if len(channels) > 2:
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
if areaFractionsArray[2][z] > areaFractionThreshold[2]:
summary[channels[1][0] + '-' + channels[2][0] +
'-positive'] += 1
if len(channels) > 3:
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
if areaFractionsArray[3][z] > areaFractionThreshold[3]:
summary[channels[1][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[2][z] > areaFractionThreshold[2]:
if areaFractionsArray[3][z] > areaFractionThreshold[3]:
summary[channels[2][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
summary[channels[1][0] + '-' + channels[2][0] +
'-' + channels[3][0] + '-positive'] += 1
# Calculate the average of the particles sizes
for chan in channels:
v, x = chan
summary[v + "-cells/tissue-area"] = summary[v + "-cells"] / bigareas[0]
if float(summary['#nuclei']) > 0:
summary['size-average'] = round(areaCounter / summary['#nuclei'], 2)
if displayImages:
fieldnames = ["Directory", "Image"]
for chan in channels:
v, x = chan
summary[v + "-threshold"] = maxThresholds[x]
fieldnames.append(v + "-threshold")
allMaxThresholds[v + "-" + region].append(maxThresholds[x])
# Opens and appends one line on the final csv file for the subfolder (remember that this is still inside the loop that goes through each image)
with open(outputName, 'a') as csvfile:
writer = csv.DictWriter(csvfile,
fieldnames=fieldnames,
extrasaction='ignore',
lineterminator='\n')
if os.path.getsize(outputName) < 1:
writer.writeheader()
writer.writerow(summary)
def process(subFolder, outputDirectory, filename):
#IJ.close()
imp = IJ.openImage(inputDirectory + subFolder + '/' +
rreplace(filename, "_ch00.tif", ".tif"))
imp.show()
# Get the pixel values from the xml file
for file in os.listdir(inputDirectory + subFolder):
if file.endswith('.xml'):
xml = os.path.join(inputDirectory + subFolder, file)
xml = "C:/Users/Harris/Desktop/test_xml_for_parsing_pixel.xml"
element_tree = ET.parse(xml)
root = element_tree.getroot()
for dimensions in root.iter('DimensionDescription'):
num_pixels = int(dimensions.attrib['NumberOfElements'])
if dimensions.attrib['Unit'] == "m":
length = float(dimensions.attrib['Length']) * 1000000
else:
length = float(dimensions.attrib['Length'])
pixel_length = length / num_pixels
else:
pixel_length = 0.8777017
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=" +
str(pixel_length) + " pixel_height=" + str(pixel_length) +
" voxel_depth=25400.0508001")
ic = ImageConverter(imp)
ic.convertToGray8()
#IJ.setThreshold(imp, 2, 255)
#Automatically selects the area of the organoid based on automated thresholding and creates a mask to be applied on
#all other images
IJ.setAutoThreshold(imp, "Mean dark no-reset")
IJ.run(imp, "Convert to Mask", "")
IJ.run(imp, "Analyze Particles...", "size=100000-Infinity add select")
rm = RoiManager.getInstance()
num_roi = rm.getCount()
for i in num_roi:
imp = getCurrentImage()
rm.select(imp, i)
IJ.setBackgroundColor(0, 0, 0)
IJ.run(imp, "Clear Outside", "")
IJ.run(imp, "Convert to Mask", "")
IJ.run(imp, "Remove Outliers...",
"radius=5" + " threshold=50" + " which=Dark")
IJ.run(imp, "Remove Outliers...",
"radius=5" + " threshold=50" + " which=Bright")
# Save the mask and open it
IJ.saveAs("tiff", inputDirectory + '/mask' + i)
mask = IJ.openImage(inputDirectory + '/mask' + i + '.tif')
if not displayImages:
imp.changes = False
imp.close()
images = [None] * 5
intensities = [None] * 5
blobsarea = [None] * 5
blobsnuclei = [None] * 5
bigAreas = [None] * 5
imp.close()
# Loop to open all the channel images
for chan in channels:
v, x = chan
images[x] = IJ.openImage(inputDirectory + subFolder + '/' +
rreplace(filename, "_ch00.tif", "_ch0" +
str(x) + ".tif"))
# Apply Mask on all the images and save them into an array
apply_mask = ImageCalculator()
images[x] = apply_mask.run("Multiply create 32 bit", mask,
images[x])
ic = ImageConverter(images[x])
ic.convertToGray8()
imp = images[x]
# Calculate the intensities for each channel as well as the organoid area
for roi in rm.getRoisAsArray():
imp.setRoi(roi)
stats_i = imp.getStatistics(Measurements.MEAN
| Measurements.AREA)
intensities[x] = stats_i.mean
bigAreas[x] = stats_i.area
rm.close()
# Opens the ch00 image and sets default properties
#Get the pixel values from the xml file
for file in os.listdir(subFolder):
if file.endswith('.xml'):
xml = os.path.join(inputDirectory + subFolder, file)
xml = "C:/Users/Harris/Desktop/test_xml_for_parsing_pixel.xml"
element_tree = ET.parse(xml)
root = element_tree.getroot()
for dimensions in root.iter('DimensionDescription'):
num_pixels = int(dimensions.attrib['NumberOfElements'])
if dimensions.attrib['Unit'] == "m":
length = float(dimensions.attrib['Length']) * 1000000
else:
length = float(dimensions.attrib['Length'])
pixel_length = length / num_pixels
else:
pixel_length = 0.8777017
imp = IJ.openImage(inputDirectory + subFolder + '/' + filename)
imp = apply_mask.run("Multiply create 32 bit", mask, imp)
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=" +
str(pixel_length) + "pixel_height=" + str(pixel_length) +
"voxel_depth=25400.0508001")
# Sets the threshold and watersheds. for more details on image processing, see https://imagej.nih.gov/ij/developer/api/ij/process/ImageProcessor.html
ic = ImageConverter(imp)
ic.convertToGray8()
IJ.run(imp, "Remove Outliers...",
"radius=2" + " threshold=50" + " which=Dark")
IJ.run(imp, "Gaussian Blur...", "sigma=" + str(blur))
IJ.setThreshold(imp, lowerBounds[0], 255)
if displayImages:
imp.show()
IJ.run(imp, "Convert to Mask", "")
IJ.run(imp, "Watershed", "")
if not displayImages:
imp.changes = False
imp.close()
# Counts and measures the area of particles and adds them to a table called areas. Also adds them to the ROI manager
table = ResultsTable()
roim = RoiManager(True)
ParticleAnalyzer.setRoiManager(roim)
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER,
Measurements.AREA, table, 15, 9999999999999999,
0.2, 1.0)
pa.setHideOutputImage(True)
# imp = impM
# imp.getProcessor().invert()
pa.analyze(imp)
areas = table.getColumn(0)
# This loop goes through the remaining channels for the other markers, by replacing the ch00 at the end with its corresponding channel
# It will save all the area fractions into a 2d array called areaFractionsArray
areaFractionsArray = [None] * 5
for chan in channels:
v, x = chan
# Opens each image and thresholds
imp = images[x]
IJ.run(
imp, "Properties...",
"channels=1 slices=1 frames=1 unit=um pixel_width=0.8777017 pixel_height=0.8777017 voxel_depth=25400.0508001"
)
ic = ImageConverter(imp)
ic.convertToGray8()
IJ.setThreshold(imp, lowerBounds[x], 255)
if displayImages:
imp.show()
WaitForUserDialog("Title",
"Adjust Threshold for Marker " + v).show()
IJ.run(imp, "Convert to Mask", "")
# Measures the area fraction of the new image for each ROI from the ROI manager.
areaFractions = []
for roi in roim.getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.AREA_FRACTION)
areaFractions.append(stats.areaFraction)
# Saves the results in areaFractionArray
areaFractionsArray[x] = areaFractions
roim.close()
for chan in channels:
v, x = chan
imp = images[x]
imp.deleteRoi()
roim = RoiManager(True)
ParticleAnalyzer.setRoiManager(roim)
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER,
Measurements.AREA, table, 15,
9999999999999999, 0.2, 1.0)
pa.analyze(imp)
blobs = []
for roi in roim.getRoisAsArray():
imp.setRoi(roi)
stats = imp.getStatistics(Measurements.AREA)
blobs.append(stats.area)
blobsarea[x] = sum(
blobs
) #take this out and use intial mask tissue area from the beginning
blobsnuclei[x] = len(blobs)
if not displayImages:
imp.changes = False
imp.close()
roim.reset()
roim.close()
imp.close()
# Creates the summary dictionary which will correspond to a single row in the output csv, with each key being a column
summary = {}
summary['Image'] = filename
summary['Directory'] = subFolder
# Adds usual columns
summary['size-average'] = 0
summary['#nuclei'] = 0
summary['all-negative'] = 0
summary['too-big-(>' + str(tooBigThreshold) + ')'] = 0
summary['too-small-(<' + str(tooSmallThreshold) + ')'] = 0
# Creates the fieldnames variable needed to create the csv file at the end.
fieldnames = [
'Name', 'Directory', 'Image', 'size-average',
'too-big-(>' + str(tooBigThreshold) + ')',
'too-small-(<' + str(tooSmallThreshold) + ')', '#nuclei',
'all-negative'
]
# Adds the columns for each individual marker (ignoring Dapi since it was used to count nuclei)
summary["organoid-area"] = bigAreas[x]
fieldnames.append("organoid-area")
for chan in channels:
v, x = chan
summary[v + "-positive"] = 0
fieldnames.append(v + "-positive")
summary[v + "-intensity"] = intensities[x]
fieldnames.append(v + "-intensity")
summary[v + "-blobsarea"] = blobsarea[x]
fieldnames.append(v + "-blobsarea")
summary[v + "-blobsnuclei"] = blobsnuclei[x]
fieldnames.append(v + "-blobsnuclei")
# Adds the column for colocalization between first and second marker
if len(channels) > 2:
summary[channels[1][0] + '-' + channels[2][0] + '-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-positive')
# Adds the columns for colocalization between all three markers
if len(channels) > 3:
summary[channels[1][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[2][0] + '-' + channels[3][0] + '-positive'] = 0
summary[channels[1][0] + '-' + channels[2][0] + '-' + channels[3][0] +
'-positive'] = 0
fieldnames.append(channels[1][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[2][0] + '-' + channels[3][0] + '-positive')
fieldnames.append(channels[1][0] + '-' + channels[2][0] + '-' +
channels[3][0] + '-positive')
# Loops through each particle and adds it to each field that it is True for.
areaCounter = 0
for z, area in enumerate(areas):
log.write(str(area))
log.write("\n")
if area > tooBigThreshold:
summary['too-big-(>' + str(tooBigThreshold) + ')'] += 1
elif area < tooSmallThreshold:
summary['too-small-(<' + str(tooSmallThreshold) + ')'] += 1
else:
summary['#nuclei'] += 1
areaCounter += area
temp = 0
for chan in channels:
v, x = chan
if areaFractionsArray[x][z] > areaFractionThreshold[
0]: # theres an error here im not sure why. i remember fixing it before
summary[chan[0] + '-positive'] += 1
if x != 0:
temp += 1
if temp == 0:
summary['all-negative'] += 1
if len(channels) > 2:
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
if areaFractionsArray[2][z] > areaFractionThreshold[2]:
summary[channels[1][0] + '-' + channels[2][0] +
'-positive'] += 1
if len(channels) > 3:
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
if areaFractionsArray[3][z] > areaFractionThreshold[3]:
summary[channels[1][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[2][z] > areaFractionThreshold[2]:
if areaFractionsArray[3][z] > areaFractionThreshold[3]:
summary[channels[2][0] + '-' + channels[3][0] +
'-positive'] += 1
if areaFractionsArray[1][z] > areaFractionThreshold[1]:
summary[channels[1][0] + '-' + channels[2][0] +
'-' + channels[3][0] + '-positive'] += 1
# Calculate the average of the particles sizes
if float(summary['#nuclei']) > 0:
summary['size-average'] = round(areaCounter / summary['#nuclei'], 2)
# Opens and appends one line on the final csv file for the subfolder (remember that this is still inside the loop that goes through each image)
with open(outputDirectory + "/" + outputName + ".csv", 'a') as csvfile:
writer = csv.DictWriter(csvfile,
fieldnames=fieldnames,
extrasaction='ignore',
lineterminator='\n')
if os.path.getsize(outputDirectory + "/" + outputName + ".csv") < 1:
writer.writeheader()
writer.writerow(summary)
IJ.run(imp, "Close All", "")
def analyzeParticles(imp,
minsize,
maxsize,
mincirc,
maxcirc,
#filename='Test.czi',
addROIManager=False,
#headless=False,
exclude=True):
if GraphicsEnvironment.isHeadless():
print('Headless Mode detected. Do not use ROI Manager.')
addROIManager = False
if addROIManager:
# get the ROI manager instance
rm = RoiManager.getInstance()
if rm is None:
rm = RoiManager()
rm.runCommand("Associate", "true")
if not exclude:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_MANAGER \
+ PA.ADD_TO_OVERLAY \
if exclude:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_MANAGER \
+ PA.ADD_TO_OVERLAY \
+ PA.EXCLUDE_EDGE_PARTICLES
if not addROIManager:
if not exclude:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_OVERLAY \
if exclude:
options = PA.SHOW_ROI_MASKS \
+ PA.SHOW_RESULTS \
+ PA.DISPLAY_SUMMARY \
+ PA.ADD_TO_OVERLAY \
+ PA.EXCLUDE_EDGE_PARTICLES
measurements = PA.STACK_POSITION \
+ PA.LABELS \
+ PA.AREA \
+ PA.RECT \
+ PA.PERIMETER \
+ PA.SLICE \
+ PA.SHAPE_DESCRIPTORS \
+ PA.CENTER_OF_MASS \
+ PA.CENTROID
results = ResultsTable()
p = PA(options, measurements, results, minsize, maxsize, mincirc, maxcirc)
p.setHideOutputImage(True)
particlestack = ImageStack(imp.getWidth(), imp.getHeight())
for i in range(imp.getStackSize()):
imp.setSliceWithoutUpdate(i + 1)
ip = imp.getProcessor()
# convert to a mask for the particle analyzer
ip.invert()
# do the particle analysis
p.analyze(imp, ip)
mmap = p.getOutputImage()
# add the slide to the full stack
particlestack.addSlice(mmap.getProcessor())
return particlestack, results
def analyze_homogeneity(image_title):
IJ.selectWindow(image_title)
raw_imp = IJ.getImage()
IJ.run(raw_imp, "Duplicate...", "title=Homogeneity duplicate")
IJ.selectWindow('Homogeneity')
hg_imp = IJ.getImage()
# Get a 2D image
if hg_imp.getNSlices() > 1:
IJ.run(hg_imp, "Z Project...", "projection=[Average Intensity]")
hg_imp.close()
IJ.selectWindow('MAX_Homogeneity')
hg_imp = IJ.getImage()
hg_imp.setTitle('Homogeneity')
# Blur and BG correct the image
IJ.run(hg_imp, 'Gaussian Blur...', 'sigma=' + str(HOMOGENEITY_RADIUS) + ' stack')
# Detect the spots
IJ.setAutoThreshold(hg_imp, HOMOGENEITY_THRESHOLD + " dark")
rm = RoiManager(True)
table = ResultsTable()
pa = ParticleAnalyzer(ParticleAnalyzer.ADD_TO_MANAGER,
ParticleAnalyzer.EXCLUDE_EDGE_PARTICLES,
Measurements.AREA, # measurements
table, # Output table
0, # MinSize
500, # MaxSize
0.0, # minCirc
1.0) # maxCirc
pa.setHideOutputImage(True)
pa.analyze(hg_imp)
areas = table.getColumn(table.getHeadings().index('Area'))
median_areas = compute_median(areas)
st_dev_areas = compute_std_dev(areas, median_areas)
thresholds_areas = (median_areas - (2 * st_dev_areas), median_areas + (2 * st_dev_areas))
roi_measurements = {'integrated_density': [],
'max': [],
'area': []}
IJ.setForegroundColor(0, 0, 0)
for roi in rm.getRoisAsArray():
hg_imp.setRoi(roi)
if REMOVE_CROSS and hg_imp.getStatistics().AREA > thresholds_areas[1]:
rm.runCommand('Fill')
else:
roi_measurements['integrated_density'].append(hg_imp.getStatistics().INTEGRATED_DENSITY)
roi_measurements['max'].append(hg_imp.getStatistics().MIN_MAX)
roi_measurements['integrated_densities'].append(hg_imp.getStatistics().AREA)
rm.runCommand('Delete')
measuremnts = {'mean_integrated_density': compute_mean(roi_measurements['integrated_density']),
'median_integrated_density': compute_median(roi_measurements['integrated_density']),
'std_dev_integrated_density': compute_std_dev(roi_measurements['integrated_density']),
'mean_max': compute_mean(roi_measurements['max']),
'median_max': compute_median(roi_measurements['max']),
'std_dev_max': compute_std_dev(roi_measurements['max']),
'mean_area': compute_mean(roi_measurements['max']),
'median_area': compute_median(roi_measurements['max']),
'std_dev_area': compute_std_dev(roi_measurements['max']),
}
# generate homogeinity image
# calculate interpoint distance in pixels
nr_point_columns = int(sqrt(len(measuremnts['mean_max'])))
# TODO: This is a rough estimation that does not take into account margins or rectangular FOVs
inter_point_dist = hg_imp.getWidth() / nr_point_columns
IJ.run(hg_imp, "Maximum...", "radius="+(inter_point_dist*1.22))
# Normalize to 100
IJ.run(hg_imp, "Divide...", "value=" + max(roi_measurements['max'] / 100))
IJ.run(hg_imp, "Gaussian Blur...", "sigma=" + (inter_point_dist/2))
hg_imp.getProcessor.setMinAndMax(0, 255)
# Create a LUT based on a predefined threshold
red = zeros(256, 'b')
green = zeros(256, 'b')
blue = zeros(256, 'b')
acceptance_threshold = HOMOGENEITY_ACCEPTANCE_THRESHOLD * 256 / 100
for i in range(256):
red[i] = (i - acceptance_threshold)
green[i] = (i)
homogeneity_LUT = LUT(red, green, blue)
hg_imp.setLut(homogeneity_LUT)
return hg_imp, measuremnts
def nucleusSegmentation(imp2):
""" Segmentation of nucleus image.
Nucleus are selected that:
1. No overlapping with dilated regions
2. close to circular shape. Deformed nuclei are rejected.
Outputs a binary image.
"""
#Convert to 8bit
ImageConverter(imp2).convertToGray8()
#blur slightly using Gaussian Blur
radius = 2.0
accuracy = 0.01
GaussianBlur().blurGaussian( imp2.getProcessor(), radius, radius, accuracy)
# Auto Local Thresholding
imps = ALT().exec(imp2, "Bernsen", 15, 0, 0, True)
imp2 = imps[0]
#ParticleAnalysis 0: prefiltering by size and circularity
rt = ResultsTable()
paOpt = PA.CLEAR_WORKSHEET +\
PA.SHOW_MASKS +\
PA.EXCLUDE_EDGE_PARTICLES +\
PA.INCLUDE_HOLES #+ \
# PA.SHOW_RESULTS
measOpt = PA.AREA + PA.STD_DEV + PA.SHAPE_DESCRIPTORS + PA.INTEGRATED_DENSITY
MINSIZE = 20
MAXSIZE = 10000
pa0 = PA(paOpt, measOpt, rt, MINSIZE, MAXSIZE, 0.8, 1.0)
pa0.setHideOutputImage(True)
pa0.analyze(imp2)
imp2 = pa0.getOutputImage() # Overwrite
imp2.getProcessor().invertLut()
#impNuc = imp2.duplicate() ## for the ring.
impNuc = Duplicator().run(imp2)
#Dilate the Nucleus Area
## this should be 40 pixels in Cihan's method, but should be smaller.
#for i in range(20):
# IJ.run(imp2, "Dilate", "")
rf = RankFilters()
rf.rank(imp2.getProcessor(), RIMSIZE, RankFilters.MAX)
#Particle Analysis 1: get distribution of sizes.
paOpt = PA.CLEAR_WORKSHEET +\
PA.SHOW_NONE +\
PA.EXCLUDE_EDGE_PARTICLES +\
PA.INCLUDE_HOLES #+ \
# PA.SHOW_RESULTS
measOpt = PA.AREA + PA.STD_DEV + PA.SHAPE_DESCRIPTORS + PA.INTEGRATED_DENSITY
rt1 = ResultsTable()
MINSIZE = 20
MAXSIZE = 10000
pa = PA(paOpt, measOpt, rt1, MINSIZE, MAXSIZE)
pa.analyze(imp2)
#rt.show('after PA 1')
#particle Analysis 2: filter nucleus by size and circularity.
#print rt1.getHeadings()
if (rt1.getColumnIndex('Area') > -1):
q1, q3, outlier_offset = getOutlierBound(rt1)
else:
q1 = MINSIZE
q3 = MAXSIZE
outlier_offset = 0
print imp2.getTitle(), ": no Nucleus segmented,probably too many overlaps"
paOpt = PA.CLEAR_WORKSHEET +\
PA.SHOW_MASKS +\
PA.EXCLUDE_EDGE_PARTICLES +\
PA.INCLUDE_HOLES #+ \
# PA.SHOW_RESULTS
rt2 = ResultsTable()
#pa = PA(paOpt, measOpt, rt, q1-outlier_offset, q3+outlier_offset, circq1-circoutlier_offset, circq3+circoutlier_offset)
pa = PA(paOpt, measOpt, rt2, q1-outlier_offset, q3+outlier_offset, 0.8, 1.0)
pa.setHideOutputImage(True)
pa.analyze(imp2)
impDilatedNuc = pa.getOutputImage()
#filter original nucleus
filteredNuc = ImageCalculator().run("AND create", impDilatedNuc, impNuc)
return filteredNuc
