DRUGSENS is a R-package that allows users to automatically analyze QuPath™'s output data from imaging analysis. Here we include a QuPath™ script (the same that we regularly use) to run reproducible QuPath™-based image analysis, and some examples on how DRUGSENS can be used. For more detailed examples of QuPath™ scripting and usage please refer to QuPath™'s Documentation. This script should be placed into scripts manager within QuPath™. We tested this code with previous versions of QuPath™, but new versions should also be compatible. This package is complementary to the STAR protocol: Protocol for quantifying drug sensitivity in 3D patient-derived ovarian cancer models DOI: DOI: 10.1016/j.xpro.2024.103274.
devtools::install_git("https://git.scicore.unibas.ch/ovca-research/drugsens")
# OR
devtools::install_github("https://github.com/flalom/drugsens") # this is the GitLab's mirroring repo
devtools
is required to install DRUGSENS. If devtools
is not installed yet you can install it with:
# Install devtools from CRAN
install.packages("devtools")
# Or the development version from GitHub:
# install.packages("pak")
pak::pak("r-lib/devtools")
You can have a look at it devtools
This is the script used in the STAR protocol, regarding the QuPath imaging analysis.
/**
* This QuPath script will take a full image as an annotation
*
* 1. Change path to export data, line 41
* 2. Make sure that the channel order is DAPI, E-Cadherin, and Cleaved Caspase 3
* a) if this is not the case, change line 38 (setChannelNames) accordingly
* 3. Your QuPath project must contain classifiers called "Cleaved Caspase 3" and "E-Cadherin"
* If you do not have them, you can download them from our repository,
* or create them yourself:
* i) In a image, create a selection of the full image (run lines 52-59)
* ii) Detect cells (run line 61)
* iii) In the Annotation tab, create new classification classes (Add class) called "Cleaved Caspase 3" and "E-Cadherin"
* iv) Create classifiers (from the menu Classify > Object Classification > Create single measurement classifier)
* v) Name the new classifier "Cleaved Caspase 3", and use following parameters
* Object filter = Detections (all)
* Channel filter = Cleaved Caspase 3
* Measurement = Nucleus: Cleaved Caspase 3 mean
* Threshold = 200 (value may differ for your image)
* Above threshold = Cleaved Caspase 3
* vi) Name the new classifier "E-Cadherin", and use following parameters
* Object filter = Detections (all)
* Channel filter = E-Cadherin
* Measurement = Nucleus: E-Cadherin mean
* Threshold = 180 (value may differ for your image)
* Above threshold = E-Cadherin
* 4. Select Run -> Run for project
* It will go through all images in the project, run segmentation
* & apply those 2 classifiers we set up before.
*
* Note:
* You are encouraged to check and adjust the classifier before you run them on your own images.
* For this, follow steps 3.i) - 3.vi)
*/
import static qupath.lib.gui.scripting.QPEx.*
// Define the path for data export
def path = '<USER_DEFINED_PATH>'
setImageType('FLUORESCENCE');
setChannelNames ('DAPI', 'E-Cadherin', 'Cleaved Caspase 3')
def name = getProjectEntry().getImageName() + '.txt'
path = buildFilePath(path, '<PID>_<TISSUE>_',Sys.Date(),'_<SAMPLE_DOC>_<TREATMENT_INITIALS>_<CONCENTRATION>_<CONCENTRATION_UNITS>_<REPLICA_OR_NOT>_<TUMOR_MARKER>_<APOPTOTIC_MARKER>')
mkdirs(path)
path = buildFilePath(path, name)
// Create a new rectangle annotation & add it to the hierarchy
import qupath.lib.roi.RectangleROI
import qupath.lib.objects.PathAnnotationObject
def x_dim = getCurrentImageData().getServer().getWidth()
def y_dim = getCurrentImageData().getServer().getHeight()
def roi = new RectangleROI(0, 0, x_dim, y_dim)
def annotation = new PathAnnotationObject(roi)
addObject(annotation)
setSelectedObject(annotation)
runPlugin('qupath.imagej.detect.cells.WatershedCellDetection', '{"detectionImage": "DAPI", "requestedPixelSizeMicrons": 0.5, "backgroundRadiusMicrons": 8.0, "medianRadiusMicrons": 0.0, "sigmaMicrons": 2, "minAreaMicrons": 5.0, "maxAreaMicrons": 500.0, "threshold": 45.0, "watershedPostProcess": true, "cellExpansionMicrons": 7.5, "includeNuclei": true, "smoothBoundaries": true, "makeMeasurements": true}')
runObjectClassifier("Cleaved Caspase 3", "E-Cadherin")
saveAnnotationMeasurements(path)
print 'Results exported to ' + path
And this script for exporting the data:
/**
* QuPath script to export measurements from all analysed images in a project
*
* 1. Define columns you would like to export (line 28)
* 2. In line 17, specify the path where to save your results
*/
import qupath.lib.gui.tools.MeasurementExporter
import qupath.lib.objects.PathCellObject
import qupath.lib.objects.PathDetectionObject
import qupath.lib.objects.PathAnnotationObject
import qupath.lib.objects.PathRootObject
// Choose your *full* output path
def outputPath = "<PID>_<TISSUE>_',Sys.Date(),'_<SAMPLE_DOC>_<TREATMENT_INITIALS>_<CONCENTRATION>_<CONCENTRATION_UNITS>_<REPLICA_OR_NOT>_<TUMOR_MARKER>_<APOPTOTIC_MARKER>.csv"
// Get the list of all images in the current project
def project = getProject()
def imagesToExport = project.getImageList()
// Separate each measurement value in the output file with ","
def separator = ","
// Choose the columns that will be included in the export
// Note: if 'columnsToInclude' is empty, all columns will be included
def columnsToInclude = new String[]{"Image", "Name", "Class","Centroid X µm","Centroid Y µm","Nucleus: Area", "Nucleus: DAPI mean","Nucleus: E-Cadherin mean", "Nucleus: Cleaved Caspase 3 mean", "Cell: Area","Cell: E-Cadherin mean", "Cell: Cleaved Caspase 3 mean","Cytoplasm: E-Cadherin mean","Cytoplasm: Cleaved Caspase 3 mean","Nucleus/Cell area ratio"}
// Choose the type of objects that the export will process
// Other possibilities include:
// 1. PathAnnotationObject
// 2. PathDetectionObject
// 3. PathRootObject
// Note: import statements should then be modified accordingly
def exportType = PathCellObject.class
def outputFile = new File(outputPath)
// Create the measurementExporter and start the export
def exporter = new MeasurementExporter()
.imageList(imagesToExport) // Images from which measurements will be exported
.separator(separator) // Character that separates values
.includeOnlyColumns(columnsToInclude) // Columns are case-sensitive
.exportType(exportType) // Type of objects to export
.exportMeasurements(outputFile) // Start the export process
print "Done!"
We recommend making a new project when working with DRUGSENS
, to have clear and defined path. This will make the data analysis much easier and reproducible.
You can also set you working directory with setwd()
.
To make the QuPath script locally available within the working directory, with the currents date:
library("DRUGSENS")
generate_qupath_script()
This function will generate a script_for_qupath.txt
file with the code that one can copy/paste into the QuPath's script manager. All the sections that contain <> should be replaced with the user experimental information. The columnsToInclude
in the script should also be user defined, depending on the markers used.
It is very important that the file naming structure of the QuPath's output is maintained for DRUGSENS
to work correctly.
📝NOTE The column
Image
must be present in the data for DRUGSENS to parse the metadata correctly. Title style (This Is An Example) is fine, but if you have a drug combination refer to the formatting as described below Handling drug combinations.
This command will generate a config_DRUGSENS.txt
that should be edited to include the names of the cell markers that have been used by the experimenter.
In our case we replaced "PathCellObject"
with "onlyDAPIPositve"
.
make_run_config()
Once the file config_DRUGSENS.txt
has been modified; you can feed it back to R
; this will be done automatically once you run data_binding()
.
Now the list_of_relabeling
should be available in the R environment and it can be used by DRUGSENS
to work. list_of_relabeling
is a named list that is required for relabeling the markers name, that is often not user friendly.
In case the markers naming doesn't need corrections/relabeling you can leave the list_of_relabeling
unchanged (but one should still check it).
📝NOTE It is recommended having no spaces and using camelCase style for the list of cell markers:
- Start the name with a lowercase letter.
- Do not include spaces or underscores between words.
- Capitalize the first letter of each subsequent word.
We present here a few mock datasets, as example workflow. Those files can be explored from the user's R package path:
system.file("extdata/to_merge/", package = "DRUGSENS")
At first the data is a bunch of separate files which are difficult to make sense of; therefore as first step let's bind them together into a single R dataframe! The example data can be bound together with this command:
bind_data <- data_binding(path_to_the_projects_folder = system.file("extdata/to_merge/", package = "DRUGSENS"), files_extension_to_look_for = "csv")
You will be now able to View(bind_data)
. You should see all the image stacks from the QuPath in one dataframe. This dataframe will have all the metadata parsed from the Image
column value for every stack (image x) (this is the first column defined in the in columnsToInclude
within the script_for_qupath.txt
).
In this code snippets we show an example of mock data unique(bind_data$PID)
with PIDs: "A8759" "B36" "B37", "B38", "B39"
and tissue `"Spleen", "p.wash", "Ascites", "Eye"``. You will have all the metadata in one go and also for drug combinations!
⚠️ WARNING: As long as you keep the formatting as the above examples. The dates should also be in the format yyy-mm-dd. For the combinations of two drugs they should be written together with each of the different drug capilized (CarboplatinPaclitaxel) and the rest lowercased letters. For example CarboplatinPaclitaxel_100_uM_10_nM. This indicates a drug combination of Carboplatin 100_uM and Paclitaxel 10_nM. Each drug amount and each unit should always be separated by_
. The first 100_uM belongs to the Carboplatin and the 10_nM belongs to the Paclitaxel. Those constrains are due to the parsing of the strings into useful metadata. If some of the data is not present, you can use a.
separated by_
. If you need additional data parsing, please let us know by filing an issue on GitLab GitLab Issue.
This function will take the previous step's generated dataframe and it will counts image by image (sum the markers of every stack) for every sample the number of marker occurrences.
counts_dataframe <- make_count_dataframe(bind_data)
This function will take the previous step's generated dataframe (bind_data
) and it will generate some plots for every cell marker and for some key features from the QuPath metadata, such as nucleus area of cell and the mean of marker intensity. The script will generate separate folders for each PID in the dataset. There might be quite some plots, therefore you can isolate specific PID or specific treatment, if that is required. With fill_color_variable
different variables present in the metadata can be tested to visualize the data.
get_QC_plots_parsed_merged_data(bind_data,
fill_color_variable = "Tissue",
save_plots = TRUE)
# OR
get_QC_plots_parsed_merged_data(bind_data,
fill_color_variable = "Treatment_complete",
save_plots = TRUE)
This function will change the wider format into longer format keeping all the metadata
plotting_ready_dataframe <- change_data_format_to_longer(counts_dataframe)
Visualizing the results of the previous steps is essential to asses your experiment.
get_QC_plots(plotting_ready_dataframe, save_plots = TRUE, isolate_a_specific_patient = "B39")
Let's run DRUGSENS
with your data. DRUGSENS
is not very strict about the capitalization of the file name but is very strict on the position of the parameters. This to avoid potential parsing problems. Here how the labeled data should look like in your QuPath generated file. Here below is shown a the first row from the file A8759_drug1..conc2.csv
contained as example in system.file("extdata/to_merge/", package = "DRUGSENS")
A8759_p.wash_2020.11.10_DOC2001.10.05_compoundX34542_10000_uM_EpCAM_Ecad_cCasp3_(series 01).tif
That follows the structure suggested in the QuPath script
"<USER_DEFINED_PATH>/<PID>_<TISSUE>_',Sys.Date(),'_<SAMPLE_DOC>_<TREATMENT_INITIALS>_<CONCENTRATION>_<CONCENTRATION_UNITS>_<REPLICA_OR_NOT>_<TUMOR_MARKER>_<APOPTOTIC_MARKER>.csv"
⚠️ WARNING: It is highly recommended to follow the recommended naming structure to obtain the correct output. The dates should also be in the format yyy-mm-dd. For combinations of two drugs they should be written together with each of the different drug capilized (CarboplatinPaclitaxel) and the rest lowercased letters. For example CarboplatinPaclitaxel_100_uM_10_nM. This indicates a drug combination of Carboplatin 100_uM and Paclitaxel 10_nM. Each drug amount and each unit should always be separated by_
. The first 100_uM belongs to the Carboplatin and the 10_nM belongs to the Paclitaxel. Those constrains are due to the parsing of the string into useful metadata. If some of the data is not present, you can use a.
separated by_
.
These lines sets stage for DRUGSENS
to find the directory path where the microscopy image data are located. defined_path
is a predefined variable that should contain the base path. This makes it easier to access and manage the files during processing. It is convenient also to define the desired_file_extensions_of_the_files
, usually csv
is a good start.
defined_path <- "<USER_DEFINED_PATH>"
desired_file_extensions <- "csv"
You can then
bind_data <- data_binding(path_to_the_projects_folder = defined_path,
files_extension_to_look_for = desired_file_extensions, recursive_search = FALSE)
📝NOTEIt is recommended to run
data_binding()
withrecursive_search = FALSE
in the case that the target folder has subfolders that belong to other projects that use other cell markers.
Each file is read, and additional metadata is extracted. This will return a dataframe of all the csv files within the folder merged with some additional parsing, the metadata is parsed from the file name will be retrieved and appended to the data. Metadata such as:
- PID = A unique identifier assigned to each sample. This ID helps in distinguishing and tracking individual samples' data throughout the experiment.
- Date1 = The date on which the experiment or analysis was conducted. This field records when the data was generated or processed.
DOC
= The date when the biological sample was collected.Tissue
= Indicates the type of tissue from which the sample was derived. This could be a specific organ or cell typeImage_number
= Represents the order or sequence number of the image in a stack of imagesTreatment
= The name or type of drug treatment applied to the sampleConcentration
= The amount of the drug treatment applied (concentration), quantitatively described.ConcentrationUnits
= The units in which the drug concentration is measured, such as micromolar (uM) or nanomolar (nM)ReplicaOrNot
= Indicates whether the sample is a replica or repeat of a previous experimentName
= The standardized name of the cell markers as defined in theconfig_DRUGSENS.txt
file. This ensures consistency and accuracy in identifying and referring to specific cell markers.
plots <- get_QC_plots_parsed_merged_data(bind_data,
fill_color_variable = "Treatment_complete", save_plots = TRUE)
This plots shows the ratio of expressed markers in the various conditions, other variables (for `example Tissues` or `Treatment_complete`) can also be used. The data will be, by default, be saved in the current working directory in a folder called `figures` and will make subfolders for each PID present in the dataset.
.data
: The main dataset, expected to be a dataframe that has been preprocessed and formatted into a long format.list_of_columns_to_plot
: Specifies which columns in the data should be visualized. Defaults to all numeric columns if not provided.save_plots
: A boolean flag indicating whether the plots should be saved as files.saving_plots_folder
: The directory where plot files will be saved, with "figures" as the default.fill_color_variable
: Specifies a variable in the data to use for color-coding the plots, enhancing the visual distinction between different data groups.PID_column_name
, isolate_specific_drug, isolate_specific_patient: Parameters allowing for the isolation of data based on patient ID or specific treatment, facilitating targeted analysis.drug_column_name
: Defines the column that indicates the treatment or drug, with "Treatment" as the default.save_list_of_plots
,save_plots_in_patient_specific_subfolders
: Flags controlling the saving behavior of the plots, including the option to save in patient-specific subfolders for organized file management.p_height
,p_width
: Parameters to customize the height and width of the generated plots, ensuring they fit the desired visualization scale.
make_count_dataframe()
, is designed for processing microscopy data stored in a dataframe. It counts occurrences of different markers present in the dataset and computes additional metadata based on unique identifiers within each row.
cell_markers_counts_data <- make_count_dataframe(bind_data)
.data
: The input dataframe containing microscopy data.unique_name_row_identifier
: The name of the column in .data that contains unique identifiers for each row (default is "filter_image").name_of_the_markers_column
: The name of the column in .data that contains the names of the markers (default is "Name").
📝NOTE
make_count_dataframe()
accepts directly thebind_data
generated in the previous step, unless the fiels were modified, in that case the paramentersunique_name_row_identifier
andname_of_the_markers_column
should be passed to the function.
The data output will be a dataframe, with all the metadata coming from the previous preprocessing. At this point, you can you the data already, but you can additionally change the format from wider to longer. This is useful especially for plotting and more fine analysis.
change_data_format_to_longer
, transforms count data from a wide format to a longer format, making it more suitable for certain types of analysis or visualization.
.data
: The input dataframe containing count data in a wide format, typically generated from microscopy data processing.pattern_column_markers
: A pattern used to identify columns related to marker ratios (defaults to "_ratio_of_total_cells").unique_name_row_identifier
: The name of the column in .data that contains unique identifiers for each image (defaults to "filter_image").additional_columns
: A logical value indicating whether to include additional metadata columns in the longer format dataframe. It defaults to TRUE.
plotting_format <- change_data_format_to_longer(cell_markers_counts_data)
📝NOTE
change_data_format_to_longer()
accepts directly thecell_markers_counts_data
generated in the previous step, unless the fiels were modified, in that case the paramenterspattern_column_markers
andunique_name_row_identifier
andadditional_columns
should be passed to the function.
This will return a dataframe that can be easily used for plotting and additional analyses.
get_QC_plots, is designed for generating Quality Control (QC) plots from preprocessed microscopy data. It visualizes cell marker ratios across different treatments for each patient or a specific patient, aiding in the immediate assessment of data quality and trends. Input Parameters:
get_QC_plots(plotting_format, isolate_a_specific_patient = "A8759", save_plots = T)
More parameters can be specified to personalize the plot(s).
.data
: The preprocessed and merged dataframe, expected to be in a long format, typically obtained after processing through make_count_dataframe() and change_data_format_to_longer().patient_column_name
: Specifies the column in .data that contains patient identifiers (defaults to "PID").colors
: A vector of colors for the plots. Defaults to c("darkgreen", "red", "orange", "pink").save_plots
: A Boolean flag indicating whether to save the generated plots. If TRUE, plots are saved in the specified directory.folder_name
: The name of the folder where plots will be saved if save_plots is TRUE. Defaults to "figures".isolate_a_specific_patient
: If specified, QC plots will be generated for this patient only. Defaults to NULL, meaning plots will be generated for all patients.x_plot_var
: The variable to be used on the x-axis, typically indicating different treatments. Defaults to "Treatment_complete".
We welcome contributions from the community! Here are some ways you can contribute:
- Reporting bugs
- Suggesting enhancements
- Submitting pull requests for bug fixes or new features
To get started with development, follow these setup instructions:
Development Environment Setup
This project uses renv
for R package management to ensure reproducibility. To set up your development environment:
- Clone the repository to your local machine.
- Open the project in RStudio or start an R session in the project directory.
- Run
renv::restore()
to install the required R packages.
Renv will automatically activate and install the necessary packages as specified in the renv.lock
file.
If you encounter any bugs or have suggestions for improvements, please file an issue using our GitLab Issue. Be sure to include as much information as possible to help us understand and address the issue.
Please make sure to file the issue in the GitLab repo as this one in GitHub is a forward-only mirror repo.