Highly multiplexed imaging cytometry acquires the single-cell expression of selected proteins in a spatially-resolved fashion. These measurements can be visualized across multiple length-scales. First, pixel-level intensities represent the spatial distributions of feature expression with highest resolution. Second, after segmentation, expression values or cell-level metadata (e.g. cell-type information) can be visualized on segmented cell areas. This package contains functions for the visualization of multiplexed read-outs and cell-level information obtained by multiplexed imaging cytometry. The main functions of this package allow 1. the visualization of pixel-level information across multiple channels and 2. the display of cell-level information (expression and/or metadata) on segmentation masks.
cytomapper 1.2.1
This vignette gives an introduction to displaying highly-multiplexed imaging
cytometry data with the cytomapper
package. As an example, these instructions
display imaging mass cytometry (IMC) data. However, other imaging cytometry
approaches including multiplexed ion beam imaging (MIBI) (Angelo et al. 2014),
tissue-based cyclic immunofluorescence (t-CyCIF) (Lin et al. 2018) and iterative
indirect immunofluorescence imaging (4i) (Gut, Herrmann, and Pelkmans 2018), which produce pixel-level
intensities and optionally segmentation masks can be displayed using
cytomapper
.
IMC (Giesen et al. 2014) is a multiplexed imaging cytometry approach to measure spatial protein abundance. In IMC, tissue sections are stained with a mix of around 40 metal-conjugated antibodies prior to laser ablation with \(1\mu{}m\) resolution. The ablated material is transferred to a mass cytometer for time-of-flight detection of the metal ions (Giesen et al. 2014)(Mavropoulos et al., n.d.). In that way, hundreds of images (usually with an image size of around 1mm x 1mm) can be generated in a reasonable amount of time (Damond et al. 2019).
Raw IMC data are computationally processed using a segmentation pipeline (available at https://github.com/BodenmillerGroup/ImcSegmentationPipeline). This pipeline produces image stacks containing the raw pixel values for up to 40 channels, segmentation masks containing the segmented cells, cell-level expression and metadata information as well as a number of image-level meta information.
Cell-level expression and metadata can be processed and read into a
SingleCellExperiment
class object. For more information on the
SingleCellExperiment
object and how to create it, please see the
SingleCellExperiment package and the
Orchestrating Single-Cell Analysis with Bioconductor
workflow.
The cytomapper
package provides a new CytoImageList
class as a container for
multiplexed images or segmentation masks. For more information on this class,
refer to the CytoImageList section.
The main functions of this package include plotCells
and plotPixels
. The
plotCells
function requires the following object inputs to display cell-level
information (expression and metadata):
SingleCellExperiment
object, which contains the cells’ counts and metadataCytoImageList
object containing the segmentation masksThe plotPixels
function requires the following object inputs to display
pixel-level expression information:
CytoImageList
object containing the pixel-level information per channelSingleCellExperiment
object, which contains the cells’
counts and metadataCytoImageList
object containing the segmentation masksThe following section provides a quick example highlighting the functionality of
cytomapper
. For detailed information on reading in the data, refer to the
Reading in data section. More information on the required data
format is provided in the Data formats section. In the first
step, we will read in the provided toy dataset
data(pancreasSCE)
data(pancreasImages)
data(pancreasMasks)
The CytoImageList
object containing pixel-level intensities representing the
ion counts for five proteins can be displayed using the plotPixels
function:
plotPixels(image = pancreasImages, colour_by = c("H3", "CD99", "CDH"))
For more details on image normalization, cell outlining, and other pixel-level manipulations, refer to the Plotting pixel information section.
The CytoImageList
object containing segmentation masks, which represent cell
areas on the image can be displayed using the plotCells
function. Only the
segmentation masks are plotted when no other parameters are specified.
To colour and/or outline segmentation masks, a SingleCellExperiment
, an
img_id
and cell_id
entry need to be specified:
plotCells(mask = pancreasMasks, object = pancreasSCE,
cell_id = "CellNb", img_id = "ImageNb", colour_by = "CD99",
outline_by = "CellType")
plotCells(mask = pancreasMasks, object = pancreasSCE,
cell_id = "CellNb", img_id = "ImageNb",
colour_by = "CellType")
For more information on the data formats and requirements, refer to the
following section. More details on the plotCells
function are provided in the
Plotting cell information section.
The cytomapper
package combines objects of the
SingleCellExperiment class and the CytoImageList
class
(provided in cytomapper
) to visualize cell- and pixel-level information.
In the main functions of the package, image
refers to a CytoImageList
object
containing one or multiple multi-channel images where each channel represents
the pixel-intensity of one selected marker (proteins in the case of IMC). The
entry mask
refers to a CytoImageList
object containing one or multiple
segmentation masks. Segmentation masks are defined as one-channel images
containing integer values, which represent the cells’ ids or 0 (background).
Finally, the object
entry refers to a SingleCellExperiment
class object that
contains cell-specific expression values (in the assay
slots) and
cell-specific metadata in the colData
slot.
To link information between the SingleCellExperiment
and CytoImageList
objects, two slots need to be specified:
img_id
: a single character indicating the colData
(in the
SingleCellExperiment
object) and elementMetadata
(in the CytoImageList
object) entry that contains the image identifiers. These image ids have to match
between the SingleCellExperiment
object and the CytoImageList
object.cell_id
: a single character indicating the colData
entry that contains the
cell identifiers. These should be integer values corresponding to pixel-values
in the segmentation masks.The img_id
and cell_id
entry in the SingleCellExperiment
object need to be
accessible via:
head(colData(pancreasSCE)[,"ImageNb"])
## [1] 1 1 1 1 1 1
head(colData(pancreasSCE)[,"CellNb"])
## [1] 824 835 839 844 847 853
The img_id
entry in the CytoImageList
object need to be accessible via:
mcols(pancreasImages)[,"ImageNb"]
## [1] 1 2 3
mcols(pancreasMasks)[,"ImageNb"]
## [1] 1 2 3
For more information on the CytoImageList
class, please refer to the section
The CytoImageList object. For more information on the
SingleCellExperiment
object and how to create it, please see the
SingleCellExperiment package and the Orchestrating Single-Cell
Analysis with Bioconductor
workflow.
For visualization purposes, the cytomapper
package provides a toy dataset
containing 3 images of \(100\mu{m}\) x \(100\mu{m}\) dimensions (100 x 100 pixels).
The dataset contains 362 segmented cells and the expression values for 5
proteins: H3, CD99, PIN, CD8a, and CDH It represents a small subset of the data
presented in A Map of Human Type 1 Diabetes Progression by Imaging Mass
Cytometry.
This dataset was generated using imaging mass cytometry (Giesen et al. 2014). Raw output files (in .mcd format) were processed using the IMC segmentation pipeline, which produces tiff-stacks containing the pixel-level information of all measured markers, segmentation masks that contain the cells’ object ids as well as cell- and image-specific measurements. Cell-specific measurements include the mean marker intensity per cell and per marker, the cells’ position and size measurements.
Pixel-level intensities for all 5 markers (5 channels) are stored in the
pancreasImages
object. Entries to the CytoImageList
object and the rownames
of elementMetadata
match: E34_imc, G01_imc, and J02_imc. The elementMetadata
slot
(accesible via the mcols()
function) contains the image identifiers.
pancreasImages
## CytoImageList containing 3 image(s)
## names(3): E34_imc G01_imc J02_imc
## Each image contains 5 channel(s)
## channelNames(5): H3 CD99 PIN CD8a CDH
mcols(pancreasImages)
## DataFrame with 3 rows and 2 columns
## ImageName ImageNb
## <character> <integer>
## E34_imc E34 1
## G01_imc G01 2
## J02_imc J02 3
channelNames(pancreasImages)
## [1] "H3" "CD99" "PIN" "CD8a" "CDH"
imageData(pancreasImages[[1]])[1:15,1:5,1]
## [,1] [,2] [,3] [,4] [,5]
## [1,] 2.235787e+00 0.2537275 1.269632e+00 9.991982e-01 1.990020e+00
## [2,] 2.885528e+00 1.9900196 2.264642e+00 0.000000e+00 1.410924e+00
## [3,] 3.400943e+00 0.9950098 9.950098e-01 2.180066e+00 4.152935e-17
## [4,] 3.223832e+00 3.1750760 1.128341e+00 4.486604e+00 7.371460e-16
## [5,] 9.987666e-01 1.9900196 2.644036e-15 0.000000e+00 0.000000e+00
## [6,] 7.094598e-17 2.9412489 2.985029e+00 1.990020e+00 9.950098e-01
## [7,] 2.149031e-16 0.0000000 9.950098e-01 5.537247e-16 0.000000e+00
## [8,] 3.936259e+00 0.0000000 4.269442e-15 1.240777e+00 2.630806e+00
## [9,] 9.987666e-01 1.6437560 3.625816e+00 0.000000e+00 2.123351e+00
## [10,] 1.401616e-16 1.9900196 2.941249e+00 3.090500e+00 0.000000e+00
## [11,] 1.382069e+00 3.0258245 4.481710e-16 0.000000e+00 1.946239e+00
## [12,] 4.239594e+00 2.7720971 9.136457e-16 4.677541e+00 4.118345e+00
## [13,] 2.687521e+00 0.0000000 5.149176e+00 9.988809e-01 4.677541e+00
## [14,] 4.513364e+00 1.4666444 9.950098e-01 2.828813e+00 2.772097e+00
## [15,] 1.999239e+00 2.4616542 3.999584e+00 1.484527e+01 1.225784e+01
The corresponding segmentation masks are stored in the pancreasMasks
object
and can be read in from tiff images containing the segmentation masks (see next
section).
Segmentation masks are defined as one-channel images containing integer values,
which represent the cells’ ids or 0 (background).
pancreasMasks
## CytoImageList containing 3 image(s)
## names(3): E34_mask G01_mask J02_mask
## Each image contains 1 channel
mcols(pancreasMasks)
## DataFrame with 3 rows and 2 columns
## ImageName ImageNb
## <character> <integer>
## E34_mask E34 1
## G01_mask G01 2
## J02_mask J02 3
imageData(pancreasMasks[[1]])[1:15,1:5]
## [,1] [,2] [,3] [,4] [,5]
## [1,] 824 824 824 824 0
## [2,] 824 824 824 824 0
## [3,] 824 824 824 824 0
## [4,] 824 824 824 824 824
## [5,] 824 824 824 824 824
## [6,] 824 824 824 824 824
## [7,] 824 824 824 824 824
## [8,] 824 824 824 824 824
## [9,] 824 824 824 824 824
## [10,] 824 824 824 824 0
## [11,] 824 824 824 0 0
## [12,] 824 824 0 0 0
## [13,] 0 0 0 0 864
## [14,] 0 0 0 864 864
## [15,] 0 864 864 864 864
The IMC segmentation pipeline also generates cell-specific measurements. The
SingleCellExperiment
class offers an ideal container to store cell-specific
expression counts together with cell-specific metadata. For the toy dataset,
cell-specific mean marker intensities (counts
) and arcsinh-transformed mean
marker intensities (exprs
) are stored in the assays(pancreasSCE)
slot. All
cell-specific metadata are stored in the colData
slot of the corresponding
SingleCellExperiment
object: pancreasSCE
. For more information on the
metadata, please refer to the ?pancreasSCE
documentation. Of note: the
cell-type labels contained in the colData(pancreasSCE)$CellType
slot are
arbitrary and only partly represent biologically relevant cell-types.
pancreasSCE
## class: SingleCellExperiment
## dim: 5 362
## metadata(0):
## assays(2): counts exprs
## rownames(5): H3 CD99 PIN CD8a CDH
## rowData names(4): MetalTag Target clean_Target frame
## colnames(362): E34_824 E34_835 ... J02_4190 J02_4209
## colData names(9): ImageName Pos_X ... MaskName Pattern
## reducedDimNames(0):
## altExpNames(0):
names(colData(pancreasSCE))
## [1] "ImageName" "Pos_X" "Pos_Y" "Area" "CellType" "ImageNb"
## [7] "CellNb" "MaskName" "Pattern"
The pancreasSCE
object also contains further information on the measured
proteins via the rowData(pancreasSCE)
slot. Furthermore, the pancreasSCE
object contains the raw expression counts per cell in the form of mean pixel
value per cell and protein (accessible via counts(pancreasSCE)
). The
arcsinh-transformed (using a co-factor of 1) raw expression counts can be
obtained via assay(pancreasSCE, "exprs")
.
For more information on how to generate SingleCellExperiment
objects from
count-based data, see Orchestrating Single-Cell
Analysis with
Bioconductor.
The cytomapper
package provides the loadImages
function to conveniently read
images into a CytoImageList
object.
The loadImages
function returns a CytoImageList
object containing the
multi-channel images or segmentation masks. Refer to the ?loadImages
function
to see the full functionality.
As an example, we will read in multi-channel images and segmentation masks
provided by the cytomapper
package.
# Read in masks
path.to.images <- system.file("extdata", package = "cytomapper")
all_masks <- loadImages(path.to.images, pattern = "_mask.tiff")
all_masks
## CytoImageList containing 3 image(s)
## names(3): E34_mask G01_mask J02_mask
## Each image contains 1 channel
# Read in images
all_stacks <- loadImages(path.to.images, pattern = "_imc.tiff")
all_stacks
## CytoImageList containing 3 image(s)
## names(3): E34_imc G01_imc J02_imc
## Each image contains 5 channel(s)
To link images between the two CytoImageList
objects and the corresponding
SingleCellExperiment
object, the image ids need to be added to the
elementMetadata
slot of the CytoImageList
objects. From the experimental
setup, we know that the image named ‘E34_imc’ has image id ‘1’, G01_imc has id
‘2’, J02_imc has id ‘3’.
unique(pancreasSCE$ImageNb)
## [1] 1 2 3
mcols(all_masks)$ImageNb <- c("1", "2", "3")
mcols(all_stacks)$ImageNb <- c("1", "2", "3")
We can see that, in some cases, the pixel-values are not correctly scaled by the image encoding. The segmentation masks should only contain integer entries:
head(unique(as.numeric(all_masks[[1]])))
## [1] 0.01257343 0.00000000 0.01318379 0.01310750 0.01287861 0.01280232
The provided data was processed using CellProfiler (Carpenter et al. 2006).
By default, CellProfiler scales all pixel intensities between 0 and 1. This is
done by dividing each count by the maximum possible intensity value (see
MeasureObjectIntensity
for more info). In the case of 16-bit encoding (where 0 is a valid intensity),
this scaling value is 2^16-1 = 65535
. Therefore, pixel-intensites need to be
rescaled by this value. However, this scaling value can change and different
images can be scaled by different factors. The user needs make sure to select
the correct factors in more complex cases.
The cytomapper
package provides a ?scaleImages
function. The user needs to
manually scale images to obtain the correct pixel-values. Here, we scale the
segmentation masks by the factor for 16-bit encoding: 2^16-1
all_masks <- scaleImages(all_masks, 2^16-1)
head(unique(as.numeric(all_masks[[1]])))
## [1] 824 0 864 859 844 839
For this toy dataset, the multi-channel images are not affected by this scaling
factor. The final all_masks
object corresponds to the pancreasMasks
object
provided by cytomapper
.
To access the correct images in the multi-channel CytoImageList
object, the
user needs to set the correct channel names. For this, the cytomapper
package
provides the ?channelNames
getter and setter function:
channelNames(all_stacks) <- c("H3", "CD99", "PIN", "CD8a", "CDH")
The read-in data can now be used for visualization as explained in the Quick start section.
The cytomapper
package provides a new CytoImageList
class, which inherits
from the SimpleList
class. Each entry to
the CytoImageList
object is an Image
class object defined in the
EBImage package. A CytoImageList
object is
restricted to the following entries:
CytoImageList
object need to be uniquely namedCytoImageList
object can either be NULL
or should not contain
NA
or empty entries?Image
for more information)CytoImageList
objects that contain masks should only contain a single channel
The following paragraphs will explain further details on manipulating
CytoImageList
objects
All accessor functions defined for SimpleList
also work on CytoImageList
class objects. Element-wise metadata — in the case of the CytoImageList
object these are image-specific metadata — are saved in the elementMetadata
slot. This slot can be accessed via the mcols()
function:
mcols(pancreasImages)
## DataFrame with 3 rows and 2 columns
## ImageName ImageNb
## <character> <integer>
## E34_imc E34 1
## G01_imc G01 2
## J02_imc J02 3
mcols(pancreasImages)$PatientID <- c("Patient1", "Patient2", "Patient3")
mcols(pancreasImages)
## DataFrame with 3 rows and 3 columns
## ImageName ImageNb PatientID
## <character> <integer> <character>
## E34_imc E34 1 Patient1
## G01_imc G01 2 Patient2
## J02_imc J02 3 Patient3
Subsetting a CytoImageList
object works similar to a SimpleList
object:
pancreasImages[1]
## CytoImageList containing 1 image(s)
## names(1): E34_imc
## Each image contains 5 channel(s)
## channelNames(5): H3 CD99 PIN CD8a CDH
pancreasImages[[1]]
## Image
## colorMode : Grayscale
## storage.mode : double
## dim : 100 100 5
## frames.total : 5
## frames.render: 5
##
## imageData(object)[1:5,1:6,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 2.2357869 0.2537275 1.269632e+00 0.9991982 1.990020e+00 0.000000e+00
## [2,] 2.8855283 1.9900196 2.264642e+00 0.0000000 1.410924e+00 5.654589e-16
## [3,] 3.4009433 0.9950098 9.950098e-01 2.1800663 4.152935e-17 1.990020e+00
## [4,] 3.2238317 3.1750760 1.128341e+00 4.4866042 7.371460e-16 0.000000e+00
## [5,] 0.9987666 1.9900196 2.644036e-15 0.0000000 0.000000e+00 1.523360e+00
However, to facilitate subsetting and making sure that entry names are
transfered between objects, the cytomapper
package provides a number of getter
and setter functions:
Individual or multiple entries in a CytoImageList
object can be obtained or
replaced using the getImages
and setImages
functions, respectively.
cur_image <- getImages(pancreasImages, "E34_imc")
cur_image
## CytoImageList containing 1 image(s)
## names(1): E34_imc
## Each image contains 5 channel(s)
## channelNames(5): H3 CD99 PIN CD8a CDH
setImages(pancreasImages, "New_image") <- cur_image
pancreasImages
## CytoImageList containing 4 image(s)
## names(4): E34_imc G01_imc J02_imc New_image
## Each image contains 5 channel(s)
## channelNames(5): H3 CD99 PIN CD8a CDH
mcols(pancreasImages)
## DataFrame with 4 rows and 3 columns
## ImageName ImageNb PatientID
## <character> <integer> <character>
## E34_imc E34 1 Patient1
## G01_imc G01 2 Patient2
## J02_imc J02 3 Patient3
## New_image E34 1 Patient1
The setImages
function ensures that names are transfered from one to the other
object along the assignment operator:
names(cur_image) <- "Replacement"
setImages(pancreasImages, 2) <- cur_image
pancreasImages
## CytoImageList containing 4 image(s)
## names(4): E34_imc Replacement J02_imc New_image
## Each image contains 5 channel(s)
## channelNames(5): H3 CD99 PIN CD8a CDH
mcols(pancreasImages)
## DataFrame with 4 rows and 3 columns
## ImageName ImageNb PatientID
## <character> <integer> <character>
## E34_imc E34 1 Patient1
## Replacement E34 1 Patient1
## J02_imc J02 3 Patient3
## New_image E34 1 Patient1
However, if the image to replace is called by name, only the image and associated metadata is replaced:
setImages(pancreasImages, "J02_imc") <- cur_image
pancreasImages
## CytoImageList containing 4 image(s)
## names(4): E34_imc Replacement J02_imc New_image
## Each image contains 5 channel(s)
## channelNames(5): H3 CD99 PIN CD8a CDH
mcols(pancreasImages)
## DataFrame with 4 rows and 3 columns
## ImageName ImageNb PatientID
## <character> <integer> <character>
## E34_imc E34 1 Patient1
## Replacement E34 1 Patient1
## J02_imc E34 1 Patient1
## New_image E34 1 Patient1
Images can be deleted by setting the entry to NULL
:
setImages(pancreasImages, c("Replacement", "New_image")) <- NULL
pancreasImages
## CytoImageList containing 2 image(s)
## names(2): E34_imc J02_imc
## Each image contains 5 channel(s)
## channelNames(5): H3 CD99 PIN CD8a CDH
Of note: for plotting, the entries in the img_id
slot in the
CytoImageList
objects have to be unique.
The cytomapper
package also provides functions to obtain and replace channels.
This functionality is provided via the getChannels
and setChannels
functions:
cur_channel <- getChannels(pancreasImages, "H3")
cur_channel
## CytoImageList containing 2 image(s)
## names(2): E34_imc J02_imc
## Each image contains 1 channel(s)
## channelNames(1): H3
channelNames(cur_channel) <- "New_H3"
setChannels(pancreasImages, 1) <- cur_channel
pancreasImages
## CytoImageList containing 2 image(s)
## names(2): E34_imc J02_imc
## Each image contains 5 channel(s)
## channelNames(5): New_H3 CD99 PIN CD8a CDH
The setChannels
function does not allow combining and adding new channels. For
this task, the cytomapper
package provides the mergeChannels
section in the
next paragraph.
Channel names can be obtained and replaced using the channelNames
getter and
setter function:
channelNames(pancreasImages)
## [1] "New_H3" "CD99" "PIN" "CD8a" "CDH"
channelNames(pancreasImages) <- c("ch1", "ch2", "ch3", "ch4", "ch5")
pancreasImages
## CytoImageList containing 2 image(s)
## names(2): E34_imc J02_imc
## Each image contains 5 channel(s)
## channelNames(5): ch1 ch2 ch3 ch4 ch5
Furthermore, channels can be merged using the mergeChannels
function:
cur_channels <- getChannels(pancreasImages, 1:2)
channelNames(cur_channels) <- c("new_ch1", "new_ch2")
pancreasImages <- mergeChannels(pancreasImages, cur_channels)
pancreasImages
## CytoImageList containing 2 image(s)
## names(2): E34_imc J02_imc
## Each image contains 7 channel(s)
## channelNames(7): ch1 ch2 ch3 ch4 ch5 new_ch1 new_ch2
To perform custom operations on each individual entry to a CytoImageList
object, the S4Vectors package provides the endoapply
function.
While the lapply
function returns a list
object, the endoapply
function
provides an object of the same class of the input object.
This allows the user to apply all functions provided by the
EBImage package to individual entries within
the CytoImageList
object:
data("pancreasImages")
# Performing a gaussian blur
pancreasImages <- endoapply(pancreasImages, gblur, sigma = 1)
The cytomapper
package provides the plotPixels
function to plot pixel-level
intensities of marker proteins. The function requires a CytoImageList
object
containing a single or multiple multi-channel images. To colour images based on
channel name, the channelNames
of the object need to be set. Furthermore, to
outline cells, a CytoImageList
object containing segmentation masks and a
SingleCellExperiment
object containing cell-specific metadata need to be
provided.
By default, pixel values are coloured internally and scaled between the minimum
and maximum values across all displayed images. However, to manipulate pixel
values and to linearly scale values to a certain range, the cytomapper
package
provides a function for image normalization.
The normalize
function provided in the cytomapper
package internally calls
the normalize
function of the EBImage package. The main
difference between the two functions is the option to scale per image or
globally in the cytomapper
package (see ?'normalize,CytoImageList-method'
).
By default, the normalize
function linearly scales the images channel-wise
across all images and returns values between 0 and 1 (or the chosen ft
range):
data("pancreasImages")
# Default normalization
cur_images <- normalize(pancreasImages)
A CytoImageList
object can also be normalized image-wise:
# Image-wise normalization
cur_images <- normalize(pancreasImages, separateImages = TRUE)
To clip the image range, the user can provide a clipping range for all channels.
# Percentage-based clipping range
cur_images <- normalize(pancreasImages)
cur_images <- normalize(cur_images, inputRange = c(0, 0.9))
plotPixels(cur_images, colour_by = c("H3", "CD99", "CDH"))
Alternatively, channel-specific clipping can be performed:
# Channel-wise clipping
cur_images <- normalize(pancreasImages,
inputRange = list(H3 = c(0, 70), CD99 = c(0, 100)))
For more information on the normalization functionality provided by the
cytomapper
package, please refer to ?'normalize,CytoImageList-method'
.
The cytomapper
package supports the visualization of up to 6 channels and
displays a combined image by setting the colour_by
parameter.
See ?plotPixels
for examples.
To enhance individual channels, the brightness (b), contrast (c) and gamma (g)
can be set channel-wise via the bcg
parameter. These parameters are set in
form of a named list
object. Entry names need to correspond by channels
specified in colour_by
. Each entry takes a numeric vector of length three
where the first entry represents the brightness value, the second the contrast
factor and the third the gamma factor. Internally, the brightness value is added
to each channel; each channel is multiplied by the contrast factor and each
channel is exponentiated by the gamma factor.
data("pancreasImages")
# Increase contrast for the CD99 and CDH channel
plotPixels(pancreasImages,
colour_by = c("H3", "CD99", "CDH"),
bcg = list(CD99 = c(0,2,1),
CDH = c(0,2,1)))
The cells can be outlined when providing a CytoImageList
object containing the
corresponding segmentation masks and a character img_id
indicating the name of
the elementMetadata
slot that contains the image IDs.
The user can furthermore specify the metadata entry to outline cells by. For
this, a SingleCellExperiment
object containing the cell-specific metadata and
a cell_id
indicating the name of the colData
slot that contains the cell IDs
need to be provided:
plotPixels(pancreasImages, mask = pancreasMasks,
object = pancreasSCE, img_id = "ImageNb",
cell_id = "CellNb",
colour_by = c("H3", "CD99", "CDH"),
outline_by = "CellType")
The user can subset the images before calling the plotting functions:
cur_images <- getImages(pancreasImages, "J02_imc")
plotPixels(cur_images, colour_by = c("H3", "CD99", "CDH"))
For further information on subsetting functionality, please refer to the Accessors section.
The user can also customize the colours for selected features. The colour
parameter takes a named list
in which names correspond to the entries to
colour_by
. To colour continous features such as expression or continous
metadata entries (e.g. cell area, see next section), at least two colours for
interpolation need to be provided. These colours are passed to the
colorRampPalette
function for interpolation.
For details, please refer to the next Adjusting the colour
section
In the following sections, the plotCells
function will be introduced. This
function displays cell-level information on segmentation masks. It requires a
CytoImageList
object containing segmentation masks in the form of
single-channel images. Furthermore, to colour and outline cells, a
SingleCellExperiment
object containing cell-specific expression counts and
metadata needs to be provided.
By default, cell-specific expression values are coloured internally and scaled
marker-specifically between the minimum and maximum values across the full
SingleCellExperiment
.
Segmentation masks can be coloured based on the pixel-values averaged across the
area of each cell. In the SingleCellExperiment
object, these values can be
obtained from the counts()
slot. To colour segmentation masks based on
expression, the rownames
of the SingleCellExperiment
must be correctly
named. The cytomapper
package supports the visualization of up to 6 channels
and displays a combined image. However, in the case of displaying expression on
segmentation mask, the user should not display too many features.
See ?plotCells
for examples.
To visualize differently transformed counts, the plotCells
function allows
setting the exprs_values
parameter. In the toy dataset, the
assay(pancreasSCE, "exprs")
slot contains the arcsinh-transformed raw
expression counts.
plotCells(pancreasMasks, object = pancreasSCE,
img_id = "ImageNb", cell_id = "CellNb",
colour_by = c("CD8a", "PIN"),
exprs_values = "exprs")
The user can furthermore outline cells and specify the metadata entry to outline
cells by. See the previous Outlining section and ?plotCells
for examples.
Similar to the plotPixels
function, the user can subset the images before
plotting. For an example, please see the previous Subsetting
section and the Accessors section.
The user can also customize the colours for selected features and metadata. The
colour
parameter takes a named list
in which names correspond to the entries
to colour_by
and/or outline_by
. To colour continous features such as
expression or continous metadata entries (e.g. cell area), at least two colours
for interpolation need to be provided. These colours are passed to the
colorRampPalette
function for interpolation. To colour discrete entries, one
colour per entry needs to be specified in form of a named vector.
plotCells(pancreasMasks, object = pancreasSCE,
img_id = "ImageNb", cell_id = "CellNb",
colour_by = c("CD99", "CDH"),
outline_by = "CellType",
colour = list(CD99 = c("black", "red"),
CDH = c("black", "white"),
CellType = c(celltype_A = "blue",
celltype_B = "green",
celltype_C = "yellow")))
The next sections explain different ways to customise the visual output of the
cytomapper
package. To find more details on additional parameters that can be
set to customise the display, refer to ?'plotting-param'
.
The cytomapper
package matches cells contained in the SingleCellExperiment
to objects contained in the CytoImageList
segmentation masks object via cell
identifiers. These are integer values, which are unique to each object per
image.
By matching these IDs, the user can subset the SingleCellExperiment
object and
therefore only visualize the cells retained in the object:
cur_sce <- pancreasSCE[,colData(pancreasSCE)$CellType == "celltype_A"]
plotCells(pancreasMasks, object = cur_sce,
img_id = "ImageNb", cell_id = "CellNb",
colour_by = "CellType",
colour = list(CellType = c(celltype_A = "red")))
This feature is also helpful when visualising individual images. By default, the
legend will contain all metadata levels even those that are not contained
in the selected image. By subsetting the SingleCellExperiment
object to
contain only the cells of the selected image, the legend will only contain the
metadata levels of the selected cells.
The background of a segemntation mask is defined by the value 0
. To change the
background colour, the background_colour
parameter can be set. Furthermore,
cells that are not contained in the SingleCellExperiment
object can be
coloured by setting missing_colour
. For an example, see figure
1.
Depending on the cells’ and background colour, the scale bar and image title are
not visible. To change the visual display of the scale bar, a named list can be
passed to the scale_bar
parameter. The list should contain one or multiple of
the following entries: length
, label
, cex
, lwidth
, colour
, position
,
margin
, frame
. For a detailed explanation on the individual entries, please
refer to the scale_bar
section in ?'plotting-param'
.
Of note: By default, the length of the scale bar is defined in number of pixels. Therefore, the user needs to know the length (e.g. in \(\mu{m}\)) to label the scale bar correctly.
The image titles can be set using the image_title
parameter. Also here, the
user needs to provide a named list with one or multiple of follwing entries:
text
, position
, colour
, margin
, font
, cex
. The entry to text
needs
to be a character vector of the same length as the CytoImageList
object.
Plotting of the scale bar and image title can be suppressed by setting the
scale_bar
and image_title
parameters to NULL
.
For an example, see figure 1.
By default, the legend all all its contents are adjusted to the size of the
largest image in the CytoImageList
object. However, legend features can be
altered by setting the legend
parameter. It takes a named list containing one
or multiple of the follwoing entries: colour_by.title.font
,
colour_by.title.cex
, colour_by.labels.cex
, colour_by.legend.cex
,
outline_by.title.font
, outline_by.title.cex
, outline_by.labels.cex
,
outline_by.legend.cex
, margin
. For detailed explanation on the individual
entries, please refer to the legend
parameter in ?'plotting-param'
.
For an example, see figure 1.
To enhance the display of individual images, the cytomapper
package provides
the margin
parameter.
The margin
parameter takes a single numeric indicating the gap (in pixels)
between individual images.
For an example, see figure 1.
By default, features are scaled to the minimum and maximum per channel. This
behaviour facilitates visualization but does not allow the user to visually
compare absolute expression counts across channels. The default behaviour can be
suppressed by setting scale = FALSE
.
In this case, counts are linearly scaled to the minimum and maximum across all channels and across all displayed images.
For an example, see figure 1.
By default, colours are interpolated between pixels (see ?rasterImage
for
details). To suppress this default behaviour, the user can set interpolate = FALSE
.
plotCells(pancreasMasks, object = pancreasSCE,
img_id = "ImageNb", cell_id = "CellNb",
colour_by = "CD99",
outline_by = "CellType",
background_colour = "white",
missing_colour = "black",
scale_bar = list(length = 30,
label = expression("30 " ~ mu * "m"),
cex = 2,
lwidth = 10,
colour = "cyan",
position = "bottomleft",
margin = c(5,5),
frame = 3),
image_title = list(text = c("image_1", "image_2", "image_3"),
position = "topleft",
colour = "cyan",
margin = c(2,10),
font = 3,
cex = 2),
legend = list(colour_by.title.font = 2,
colour_by.title.cex = 1.2,
colour_by.labels.cex = 0.7,
outline_by.legend.cex = 0.3,
margin = 10),
margin = 2)
The user has the option to save the generated plots (see next section) or to get
the plots and/or coloured images returned. If return_plot
and/or
return_images
is set to TRUE
, cytomapper
returns a list object with one or
two entries: plot
and/or images
.
The display
parameter supports the entries display = "all"
(default), which
displays images in a grid-like fashion and display = "single"
, which display
images individually.
If the return_plot
parameter is set to TRUE
, cytomapper
internally calls
the recordPlot
function and returns a plot object. The user can additionally
set display = "single"
to get a list of plots returned.
If the return_images
parameter is set to TRUE
, cytomapper
returns a
SimpleList
object containing three-colour (red, green, blue) Image
objects.
cur_out <- plotPixels(pancreasImages, colour_by = c("H3", "CD99", "CDH"),
return_plot = TRUE, return_images = TRUE,
display = "single")
The returned plot objects now allows the plotting of individual images:
cur_out$plot$E34_imc
Furthermore, the user can directly plot the coloured images from the returned
SimpleList
object:
plot(cur_out$images$G01_imc)
However, when plotting solely the coloured images, the image title and scale bar will be lost.
Finally, the user can save the plot by specifying save_plot
. The save_plot
entry takes a list of two entries: filename
and scale
. The filename
should
be a character representing a valid file name ending with .png
, .tiff
or
.jpeg
. The scale
entry controls the resolution of the image (see
?"plotting-param"
for help). Increasing the scale parameter will increase the
resolution of the final image.
When setting display = "single"
, the cytomapper
package will save individual
images in individual files. The filename will be altered to the form
filename_x.png
where x
is the position of the image in the CytoImageList
object or legend
.
The cytomapper
package provides the cytomapperShiny
function to gate cells
based on their expression values and visualizes selected cells on their
corresponing images. This selection strategy can be useful if user-defined
cell-type labels should be generated for cell-type classification. For details,
please refer to the ?cytomapperShiny
manual or the Help
button within the
shiny application.
In brief, the cytomapperShiny
function takes a SingleCellExperiment
and
(optionally) either a CytoImageList
segmentation mask or a segmentation mask
AND a CytoImageList
multi-channel image object as input. The user needs to
further provide an img_id
and cell_id
entry (see above).
The user can specify the number of plots (maximal 12 plot, maximal 2 marker per
plot), select the individual images (specified in the img_id
entry) and the
different assay
slots of the SingleCellExperiment
object. Furthermore, for
each plot, up to two markers can be selected for visualziation and gating.
Gating is performed in a hierarchical fashion meaning that only the selected
cells are displayed on the following plot. As an example: if the user selects
certain cells in Plot 1
, the expression values of only those cells are
displayed in Plot 2
and so on. If the user selects only one marker, the
expression values are displayed as violin/beeswarm plots; if two markers are
specified, expression values are displayed as scatter plots.
If the user provides a CytoImageList
segmentation mask object, the plotCells
function is called internally to visualize marker expression as well as the
selected cells on the segmentation mask. Pixel-level information is diplayed if
the user provides a CytoImageList
multi-channel image object. In this setting,
the user also needs to provide a segmentation mask object to outline the
selected cells on the composite images.
As a final step, the user can download the selected cells in form of a
SingleCellExperiment
object. Furthermore, the user can specify a label for the
current selection. The gates are stored in the metadata(object)
entry. Of
note: the metadata that was stored in the original object can be accessed via
metadata(object)$metadata
.
We want to thank the Bodenmiller laboratory for feedback on the package and its functionality. Special thanks goes to Daniel Schulz and Jana Fischer for testing the package.
Nicolas created the first version of cytomapper
(named IMCMapper
). Nils and
Nicolas implemented and maintain the package. Nils and Tobias implemented and
maintain the cytomapperShiny
function.
## R version 4.0.3 (2020-10-10)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 18.04.5 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.12-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.12-bioc/R/lib/libRlapack.so
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## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## attached base packages:
## [1] parallel stats4 stats graphics grDevices utils datasets
## [8] methods base
##
## other attached packages:
## [1] cytomapper_1.2.1 SingleCellExperiment_1.12.0
## [3] SummarizedExperiment_1.20.0 Biobase_2.50.0
## [5] GenomicRanges_1.42.0 GenomeInfoDb_1.26.2
## [7] IRanges_2.24.1 S4Vectors_0.28.1
## [9] BiocGenerics_0.36.0 MatrixGenerics_1.2.0
## [11] matrixStats_0.57.0 EBImage_4.32.0
## [13] BiocStyle_2.18.1
##
## loaded via a namespace (and not attached):
## [1] viridis_0.5.1 viridisLite_0.3.0 svgPanZoom_0.3.4
## [4] shiny_1.6.0 assertthat_0.2.1 highr_0.8
## [7] BiocManager_1.30.10 sp_1.4-5 GenomeInfoDbData_1.2.4
## [10] vipor_0.4.5 tiff_0.1-6 yaml_2.2.1
## [13] gdtools_0.2.3 pillar_1.4.7 lattice_0.20-41
## [16] glue_1.4.2 digest_0.6.27 RColorBrewer_1.1-2
## [19] promises_1.1.1 XVector_0.30.0 colorspace_2.0-0
## [22] htmltools_0.5.1.1 httpuv_1.5.5 Matrix_1.3-2
## [25] pkgconfig_2.0.3 raster_3.4-5 bookdown_0.21
## [28] zlibbioc_1.36.0 purrr_0.3.4 xtable_1.8-4
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## [34] jpeg_0.1-8.1 later_1.1.0.1 tibble_3.0.5
## [37] generics_0.1.0 ggplot2_3.3.3 ellipsis_0.3.1
## [40] magrittr_2.0.1 crayon_1.3.4 mime_0.9
## [43] evaluate_0.14 beeswarm_0.2.3 shinydashboard_0.7.1
## [46] tools_4.0.3 lifecycle_0.2.0 stringr_1.4.0
## [49] munsell_0.5.0 locfit_1.5-9.4 DelayedArray_0.16.1
## [52] compiler_4.0.3 systemfonts_0.3.2 rlang_0.4.10
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## [58] bitops_1.0-6 rmarkdown_2.6 gtable_0.3.0
## [61] codetools_0.2-18 abind_1.4-5 DBI_1.1.1
## [64] R6_2.5.0 gridExtra_2.3 knitr_1.31
## [67] dplyr_1.0.3 fastmap_1.1.0 stringi_1.5.3
## [70] ggbeeswarm_0.6.0 Rcpp_1.0.6 vctrs_0.3.6
## [73] png_0.1-7 tidyselect_1.1.0 xfun_0.20
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