In Nanostring-Biostats/SpatialOmicsOverlay: Spatial Overlay for Omic Data from Nanostring GeoMx Data
knitr::opts_chunk$set(
message = FALSE,
warning = FALSE,
fig.width = 10,
fig.retina = 1
)
options(java.parameters = "-Xmx4g")
library(RBioFormats)
Overview
This vignette demonstrates how to use OME-TIFF files generated by the NanoString GeoMx® instrument to enhance the data visualization for a NanoString GeoMx experiment. SpatialOmicsOverlay was specifically made to visualize and analyze the free-handed nature of Region of Interest (ROI) selection in a GeoMx experiment, and the immunofluorescent-guided segmentation process. The overlay from the instrument is recreated in the R environment allowing for plotting overlays with data like ROI type or gene expression.
In this vignette, we will be walking through a mouse brain dataset from the Spatial Organ Atlas
Load Libraries
if (!requireNamespace("BiocManager", quietly=TRUE))
install.packages("BiocManager")
BiocManager::install("GeomxTools")
BiocManager::install("SpatialOmicsOverlay")
library(SpatialOmicsOverlay)
library(GeomxTools)
Download OME-TIFF from GeoMx
-
Open Chrome and access your GeoMx workspace remotely:
- Browse to https://geomx-#### where #### is the GeoMx instrument number; find this under Administration tab >> Network >> Machine Name.
-
In the GeoMx Scan Workspace, click the “Export Image” tab and export the image as an OME-TIFF. This will have to be done for each individual scan.
Data Ingestion
Files needed:
- OME-TIFF from GeoMx instrument (other OME-TIFFs should work with custom parsing functions)
- Lab Worksheet from instrument readout
- Annotation file(s)
- Lab Worksheet
- GeomxSet Object (see GeomxTools and GeoMxWorkflows for more info)
- Annotations from DSPDA
Reading in the SpatialOverlay object can be done with or without the image. We will start without the image as that can be added later.
If outline = TRUE, only ROI outline points are saved. This decreases memory needed and figure rendering time downstream. If ANY ROIs are segmented in the study, outline will be FALSE. In this particular example, there are segmented ROIs, so we set outline = FALSE.
In this example, we are downloading a TIFF image from AWS S3 but this variable is simply the file path to a OME-TIFF.
This function will be downloading a 13 GB file and will keep a 4 GB file in BiocFileCache. This download will take ~15 minutes but you will only have to download once
tifFile <- downloadMouseBrainImage()
tifFile
muBrainLW <- system.file("extdata", "muBrain_LabWorksheet.txt",
package = "SpatialOmicsOverlay")
muBrain <- readSpatialOverlay(ometiff = tifFile, annots = muBrainLW,
slideName = "D5761 (3)", image = FALSE,
saveFile = FALSE, outline = FALSE)
The readSpatialOverlay function is a wrapper to walk through all of the necessary steps to store the OME-TIFF file components. This function automates XML extraction & parsing, image extraction, and coordinate generation. These functions can also be run separately if desired (xmlExtraction, parseScanMetadata, parseOverlayAttrs, addImageOmeTiff, createCoordFile).
If you are getting a java.lang.OutOfMemoryError: Java heap space when running readSpatialOverlay(), restart your R session and try increasing the maximum heap size by supplying the -Xmx parameter before the Java Virtual Machine is initialized used by a dependency package RBioFormats. Run the code below before loading any other libraries. RBioFormats source
options(java.parameters = "-Xmx4g")
library(RBioFormats)
SpatialOverlay Accessors
SpatialOverlay objects hold data specific to the image and the ROIs. Here are a couple of functions to access the most important parts.
#full object
muBrain
#sample names
head(sampNames(muBrain))
#slide name
slideName(muBrain)
#metadata of ROI overlays
#Height, Width, X, Y values are in pixels
head(meta(overlay(muBrain)))
#coordinates of each ROI
head(coords(muBrain))
Plotting Without Image
After parsing, ROIs can be plotted without the image in the object. These plots are the highest resolution versions since there is no scaling down to the image size, and might take a little time to render. If the image is attached to the object, coordinates are automatically scaled down to the image size and plotted as if they are on top of the image.
While manipulating the figure, there is a low-resolution option for faster rendering times.
A scale bar is automatically calculated when plotting. This functionality can be turned off using scaleBar = FALSE. Scale bars can be fully customized using corner, textDistance, and variables that start with scaleBar: scaleBarWidth, scaleBarColor, etc.
plotSpatialOverlay(overlay = muBrain, hiRes = FALSE, legend = FALSE)
colorBy, by default, is Sample_ID but almost any annotation or data can be added instead, including gene expression, tissue morphology annotations, pathway score, etc. These annotations can come from a data.frame, matrix, GeomxSet object, or vector. Below we attach the gene expression for CALM1 from a GeomxSet object and color the segments by that value.
muBrainAnnots <- readLabWorksheet(lw = muBrainLW, slideName = "D5761 (3)")
muBrainGeomxSet <- readRDS(unzip(system.file("extdata", "muBrain_GxT.zip",
package = "SpatialOmicsOverlay")))
muBrain <- addPlottingFactor(overlay = muBrain, annots = muBrainAnnots,
plottingFactor = "segment")
muBrain <- addPlottingFactor(overlay = muBrain, annots = muBrainGeomxSet,
plottingFactor = "Calm1")
muBrain <- addPlottingFactor(overlay = muBrain, annots = 1:length(sampNames(muBrain)),
plottingFactor = "ROILabel")
muBrain
head(plotFactors(muBrain))
Customizing the graph
All generated figures are ggplot based so they can be easily customized using functions from that or similar grammar of graphs packages. For example, we can change the color scale to the viridis color palette.
Note: hiRes and outline figures use fill, lowRes uses color
plotSpatialOverlay(overlay = muBrain, hiRes = FALSE, colorBy = "Calm1",
scaleBarWidth = 0.3, scaleBarColor = "green") +
viridis::scale_color_viridis()+
ggplot2::labs(title = "Calm1 Expression in Mouse Brain")
Adding the Image
Images can be added automatically using readSpatialOverlay(image = TRUE) or added after reading in the object.
An OME-TIFF file is a pyramidal file, meaning that many sizes of an image are saved. The largest having the highest resolution and decreasing as the image gets smaller. Images are 1/2 the size as the previous resolution.
knitr::include_graphics("images/pyramidalTIFF.png")
The res variable says which resolution of the image to extract. 1 = largest image and the higher values get smaller. Each OME-TIFF has a different number of layers, with most having around 8. It is suggested to use the smallest res value, and highest resolution, your environment can handle. This is a trial and error process.
Using too big of an image will cause a java memory error. If this error occurs, increase your res value. Below is an example of the error you will receive if the resolution is too high for your system.
Error in .jcall("RBioFormats", "Ljava/lang/Object;", "readPixels", i, :
java.lang.NegativeArraySizeException: -2147483648
The resolution size will affect speed and image resolution through the rest of the analysis. To check the smallest resolution size available, for the fastest speeds, use checkValidRes(). For the rest of this tutorial we will be using res = 8 for vignette size restrictions, but res 4-6 is recommended.
#lowest resolution = fastest speeds
checkValidRes(ometiff = tifFile)
res <- 8
muBrain <- addImageOmeTiff(overlay = muBrain, ometiff = tifFile, res = res)
muBrain
showImage(muBrain)
plotSpatialOverlay(overlay = muBrain, colorBy = "segment", corner = "topcenter",
scaleBarWidth = 0.5, textDistance = 130, scaleBarColor = "cyan")
Visualization Marker Legends
There are 2 ways to add a legend to the graph showing the immunofluorescent visualization markers used.
The first is an easy way for data exploration, adding a legend to the ggplot object directly by setting flourLegend = TRUE.
plotSpatialOverlay(overlay = muBrain, colorBy = "segment", corner = "topcenter",
scaleBarWidth = 0.5, textDistance = 130, scaleBarColor = "cyan",
fluorLegend = TRUE)
The second requires more user manipulation but creates a more publication-ready figure. The flourLegend function creates a separate plot that can be added to the graph. The legend shape can be changed with nrow and the background can be changed using boxColor and alpha.
See ?draw_plot for more instructions on how to manipulate the legend position and scale.
library(cowplot)
gp <- plotSpatialOverlay(overlay = muBrain, colorBy = "segment",
corner = "bottomright")
legend <- fluorLegend(muBrain, nrow = 2, textSize = 4,
boxColor = "grey85", alpha = 0.3)
cowplot::ggdraw() +
cowplot::draw_plot(gp) +
cowplot::draw_plot(legend, scale = 0.105, x = 0.1, y = -0.25)
Image Manipulation
Flipping Axes
Images and overlays can be flipped across either axis to reorient the image. To flip both axes use flipY(flipX(overlay)). These functions update the coordinates and image rather than just affecting the figure. In this example, the original image is reversed from the traditional view of the mouse brain, so we shall flip the Y-axis.
muBrain <- flipY(muBrain)
plotSpatialOverlay(overlay = muBrain, colorBy = "segment", scaleBar = FALSE)
plotSpatialOverlay(overlay = flipX(muBrain), colorBy = "segment", scaleBar = FALSE)
Cropping
Images can be cropped 2 ways. The amount of area added to the cropped area in both methods can be defined by buffer. This adds a percentage of the final image size to each edge.
cropTissue automatically detects where the tissue is and removes non-tissue area from around the tissue.
muBrain <- cropTissue(overlay = muBrain, buffer = 0.05)
plotSpatialOverlay(overlay = muBrain, colorBy = "ROILabel", legend = FALSE, scaleBar = FALSE)+
viridis::scale_fill_viridis(option = "C")
cropSamples automatically crops the image around the ROIs given. Other ROIs in the cropped image can be kept in or ignored. Below we will crop to only ROIs that are unsegmented, hiding ROIs profiled which are segmented. Setting sampsOnly = TRUE hides the segmented ROIs which are within the plotted region.
samps <- muBrainAnnots$Sample_ID[muBrainAnnots$segment == "Full ROI" &
muBrainAnnots$slide.name == slideName(muBrain)]
muBrainCrop <- cropSamples(overlay = muBrain, sampleIDs = samps, sampsOnly = TRUE)
plotSpatialOverlay(overlay = muBrainCrop, colorBy = "Calm1", scaleBar = TRUE,
corner = "bottomleft", textDistance = 5)+
ggplot2::scale_fill_gradient2(low = "grey", high = "red",
mid = "yellow", midpoint = 2500)
muBrainCrop <- cropSamples(overlay = muBrain, sampleIDs = samps, sampsOnly = FALSE)
plotSpatialOverlay(overlay = muBrainCrop, colorBy = "segment", scaleBar = TRUE,
corner = "bottomleft", textDistance = 5)
Image Coloring
Image colors are typically determined before downloading the OME-TIFF from the instrument but can be recolored here.
This recoloring must be done on the 4 channel image before converting to RGB. The color code and min/max intensities determine the coloring of the RGB image. To view the current color definition use the fluor function.
The color can be a hex color or a valid R color name. The dye can either come from the Dye or DisplayName columns from fluor(overlay). To change a color use the changeImageColoring function.
chan4 <- add4ChannelImage(overlay = muBrain)
fluor(chan4)
chan4 <- changeImageColoring(overlay = chan4, color = "#32a8a4", dye = "FITC")
chan4 <- changeImageColoring(overlay = chan4, color = "magenta", dye = "Alexa 647")
chan4 <- changeColoringIntensity(overlay = chan4, minInten = 500,
maxInten = 10000, dye = "Cy5")
fluor(chan4)
# change 4 channel TIFF to RGB
chan4 <- recolor(chan4)
showImage(chan4)
Future Directions
In future releases of SpatialOmicsOverlay, we will be
- Ensuring capability with NanoString’s CosMx Spatial Molecular Imager outputs
- Adding ability to add graphing features on top of the image
- Adding image analysis capabilities
- Adding extraction of image data to use in ML/AI applications
sessionInfo()
Nanostring-Biostats/SpatialOmicsOverlay documentation built on Dec. 18, 2024, 9:26 a.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
knitr::opts_chunk$set( message = FALSE, warning = FALSE, fig.width = 10, fig.retina = 1 ) options(java.parameters = "-Xmx4g") library(RBioFormats)
Overview
This vignette demonstrates how to use OME-TIFF files generated by the NanoString GeoMx® instrument to enhance the data visualization for a NanoString GeoMx experiment. SpatialOmicsOverlay was specifically made to visualize and analyze the free-handed nature of Region of Interest (ROI) selection in a GeoMx experiment, and the immunofluorescent-guided segmentation process. The overlay from the instrument is recreated in the R environment allowing for plotting overlays with data like ROI type or gene expression.
In this vignette, we will be walking through a mouse brain dataset from the Spatial Organ Atlas
Load Libraries
if (!requireNamespace("BiocManager", quietly=TRUE)) install.packages("BiocManager") BiocManager::install("GeomxTools") BiocManager::install("SpatialOmicsOverlay")
library(SpatialOmicsOverlay) library(GeomxTools)
Download OME-TIFF from GeoMx
-
Open Chrome and access your GeoMx workspace remotely:
- Browse to https://geomx-#### where #### is the GeoMx instrument number; find this under Administration tab >> Network >> Machine Name.
-
In the GeoMx Scan Workspace, click the “Export Image” tab and export the image as an OME-TIFF. This will have to be done for each individual scan.
Data Ingestion
Files needed:
- OME-TIFF from GeoMx instrument (other OME-TIFFs should work with custom parsing functions)
- Lab Worksheet from instrument readout
- Annotation file(s)
- Lab Worksheet
- GeomxSet Object (see GeomxTools and GeoMxWorkflows for more info)
- Annotations from DSPDA
Reading in the SpatialOverlay object can be done with or without the image. We will start without the image as that can be added later.
If outline = TRUE, only ROI outline points are saved. This decreases memory needed and figure rendering time downstream. If ANY ROIs are segmented in the study, outline will be FALSE. In this particular example, there are segmented ROIs, so we set outline = FALSE.
In this example, we are downloading a TIFF image from AWS S3 but this variable is simply the file path to a OME-TIFF.
This function will be downloading a 13 GB file and will keep a 4 GB file in BiocFileCache. This download will take ~15 minutes but you will only have to download once
tifFile <- downloadMouseBrainImage() tifFile
muBrainLW <- system.file("extdata", "muBrain_LabWorksheet.txt", package = "SpatialOmicsOverlay") muBrain <- readSpatialOverlay(ometiff = tifFile, annots = muBrainLW, slideName = "D5761 (3)", image = FALSE, saveFile = FALSE, outline = FALSE)
The readSpatialOverlay function is a wrapper to walk through all of the necessary steps to store the OME-TIFF file components. This function automates XML extraction & parsing, image extraction, and coordinate generation. These functions can also be run separately if desired (xmlExtraction, parseScanMetadata, parseOverlayAttrs, addImageOmeTiff, createCoordFile).
If you are getting a java.lang.OutOfMemoryError: Java heap space when running readSpatialOverlay(), restart your R session and try increasing the maximum heap size by supplying the -Xmx parameter before the Java Virtual Machine is initialized used by a dependency package RBioFormats. Run the code below before loading any other libraries. RBioFormats source
options(java.parameters = "-Xmx4g") library(RBioFormats)
SpatialOverlay Accessors
SpatialOverlay objects hold data specific to the image and the ROIs. Here are a couple of functions to access the most important parts.
#full object muBrain #sample names head(sampNames(muBrain)) #slide name slideName(muBrain) #metadata of ROI overlays #Height, Width, X, Y values are in pixels head(meta(overlay(muBrain))) #coordinates of each ROI head(coords(muBrain))
Plotting Without Image
After parsing, ROIs can be plotted without the image in the object. These plots are the highest resolution versions since there is no scaling down to the image size, and might take a little time to render. If the image is attached to the object, coordinates are automatically scaled down to the image size and plotted as if they are on top of the image.
While manipulating the figure, there is a low-resolution option for faster rendering times.
A scale bar is automatically calculated when plotting. This functionality can be turned off using scaleBar = FALSE. Scale bars can be fully customized using corner, textDistance, and variables that start with scaleBar: scaleBarWidth, scaleBarColor, etc.
plotSpatialOverlay(overlay = muBrain, hiRes = FALSE, legend = FALSE)
colorBy, by default, is Sample_ID but almost any annotation or data can be added instead, including gene expression, tissue morphology annotations, pathway score, etc. These annotations can come from a data.frame, matrix, GeomxSet object, or vector. Below we attach the gene expression for CALM1 from a GeomxSet object and color the segments by that value.
muBrainAnnots <- readLabWorksheet(lw = muBrainLW, slideName = "D5761 (3)") muBrainGeomxSet <- readRDS(unzip(system.file("extdata", "muBrain_GxT.zip", package = "SpatialOmicsOverlay"))) muBrain <- addPlottingFactor(overlay = muBrain, annots = muBrainAnnots, plottingFactor = "segment") muBrain <- addPlottingFactor(overlay = muBrain, annots = muBrainGeomxSet, plottingFactor = "Calm1") muBrain <- addPlottingFactor(overlay = muBrain, annots = 1:length(sampNames(muBrain)), plottingFactor = "ROILabel") muBrain head(plotFactors(muBrain))
Customizing the graph
All generated figures are ggplot based so they can be easily customized using functions from that or similar grammar of graphs packages. For example, we can change the color scale to the viridis color palette.
Note: hiRes and outline figures use fill, lowRes uses color
plotSpatialOverlay(overlay = muBrain, hiRes = FALSE, colorBy = "Calm1", scaleBarWidth = 0.3, scaleBarColor = "green") + viridis::scale_color_viridis()+ ggplot2::labs(title = "Calm1 Expression in Mouse Brain")
Adding the Image
Images can be added automatically using readSpatialOverlay(image = TRUE) or added after reading in the object.
An OME-TIFF file is a pyramidal file, meaning that many sizes of an image are saved. The largest having the highest resolution and decreasing as the image gets smaller. Images are 1/2 the size as the previous resolution.
knitr::include_graphics("images/pyramidalTIFF.png")
The res variable says which resolution of the image to extract. 1 = largest image and the higher values get smaller. Each OME-TIFF has a different number of layers, with most having around 8. It is suggested to use the smallest res value, and highest resolution, your environment can handle. This is a trial and error process.
Using too big of an image will cause a java memory error. If this error occurs, increase your res value. Below is an example of the error you will receive if the resolution is too high for your system.
Error in .jcall("RBioFormats", "Ljava/lang/Object;", "readPixels", i, :
java.lang.NegativeArraySizeException: -2147483648
The resolution size will affect speed and image resolution through the rest of the analysis. To check the smallest resolution size available, for the fastest speeds, use checkValidRes(). For the rest of this tutorial we will be using res = 8 for vignette size restrictions, but res 4-6 is recommended.
#lowest resolution = fastest speeds checkValidRes(ometiff = tifFile) res <- 8 muBrain <- addImageOmeTiff(overlay = muBrain, ometiff = tifFile, res = res) muBrain showImage(muBrain)
plotSpatialOverlay(overlay = muBrain, colorBy = "segment", corner = "topcenter", scaleBarWidth = 0.5, textDistance = 130, scaleBarColor = "cyan")
Visualization Marker Legends
There are 2 ways to add a legend to the graph showing the immunofluorescent visualization markers used.
The first is an easy way for data exploration, adding a legend to the ggplot object directly by setting flourLegend = TRUE.
plotSpatialOverlay(overlay = muBrain, colorBy = "segment", corner = "topcenter", scaleBarWidth = 0.5, textDistance = 130, scaleBarColor = "cyan", fluorLegend = TRUE)
The second requires more user manipulation but creates a more publication-ready figure. The flourLegend function creates a separate plot that can be added to the graph. The legend shape can be changed with nrow and the background can be changed using boxColor and alpha.
See ?draw_plot for more instructions on how to manipulate the legend position and scale.
library(cowplot) gp <- plotSpatialOverlay(overlay = muBrain, colorBy = "segment", corner = "bottomright") legend <- fluorLegend(muBrain, nrow = 2, textSize = 4, boxColor = "grey85", alpha = 0.3) cowplot::ggdraw() + cowplot::draw_plot(gp) + cowplot::draw_plot(legend, scale = 0.105, x = 0.1, y = -0.25)
Image Manipulation
Flipping Axes
Images and overlays can be flipped across either axis to reorient the image. To flip both axes use flipY(flipX(overlay)). These functions update the coordinates and image rather than just affecting the figure. In this example, the original image is reversed from the traditional view of the mouse brain, so we shall flip the Y-axis.
muBrain <- flipY(muBrain) plotSpatialOverlay(overlay = muBrain, colorBy = "segment", scaleBar = FALSE) plotSpatialOverlay(overlay = flipX(muBrain), colorBy = "segment", scaleBar = FALSE)
Cropping
Images can be cropped 2 ways. The amount of area added to the cropped area in both methods can be defined by buffer. This adds a percentage of the final image size to each edge.
cropTissueautomatically detects where the tissue is and removes non-tissue area from around the tissue.
muBrain <- cropTissue(overlay = muBrain, buffer = 0.05) plotSpatialOverlay(overlay = muBrain, colorBy = "ROILabel", legend = FALSE, scaleBar = FALSE)+ viridis::scale_fill_viridis(option = "C")
cropSamplesautomatically crops the image around the ROIs given. Other ROIs in the cropped image can be kept in or ignored. Below we will crop to only ROIs that are unsegmented, hiding ROIs profiled which are segmented. SettingsampsOnly = TRUEhides the segmented ROIs which are within the plotted region.
samps <- muBrainAnnots$Sample_ID[muBrainAnnots$segment == "Full ROI" & muBrainAnnots$slide.name == slideName(muBrain)] muBrainCrop <- cropSamples(overlay = muBrain, sampleIDs = samps, sampsOnly = TRUE) plotSpatialOverlay(overlay = muBrainCrop, colorBy = "Calm1", scaleBar = TRUE, corner = "bottomleft", textDistance = 5)+ ggplot2::scale_fill_gradient2(low = "grey", high = "red", mid = "yellow", midpoint = 2500) muBrainCrop <- cropSamples(overlay = muBrain, sampleIDs = samps, sampsOnly = FALSE) plotSpatialOverlay(overlay = muBrainCrop, colorBy = "segment", scaleBar = TRUE, corner = "bottomleft", textDistance = 5)
Image Coloring
Image colors are typically determined before downloading the OME-TIFF from the instrument but can be recolored here.
This recoloring must be done on the 4 channel image before converting to RGB. The color code and min/max intensities determine the coloring of the RGB image. To view the current color definition use the fluor function.
The color can be a hex color or a valid R color name. The dye can either come from the Dye or DisplayName columns from fluor(overlay). To change a color use the changeImageColoring function.
chan4 <- add4ChannelImage(overlay = muBrain) fluor(chan4) chan4 <- changeImageColoring(overlay = chan4, color = "#32a8a4", dye = "FITC") chan4 <- changeImageColoring(overlay = chan4, color = "magenta", dye = "Alexa 647") chan4 <- changeColoringIntensity(overlay = chan4, minInten = 500, maxInten = 10000, dye = "Cy5") fluor(chan4) # change 4 channel TIFF to RGB chan4 <- recolor(chan4) showImage(chan4)
Future Directions
In future releases of SpatialOmicsOverlay, we will be
- Ensuring capability with NanoString’s CosMx Spatial Molecular Imager outputs
- Adding ability to add graphing features on top of the image
- Adding image analysis capabilities
- Adding extraction of image data to use in ML/AI applications
sessionInfo()
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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