flowcatchR 1.30.0
Compiled date: 2022-04-26
Last edited: 2018-01-14
License: BSD_3_clause + file LICENSE
This document offers an introduction and overview of the R/Bioconductor (R Core Team 2014, @Gentleman2004) package flowcatchR, which provides a flexible and comprehensive set of tools to detect and track flowing blood cells in time-lapse microscopy.
flowcatchR builds upon functionalities provided by the EBImage package (Pau et al. 2010), and extends them in order to analyze time-lapse microscopy images. Here we list some of the unique characteristics of the datasets flowcatchR is designed for:
Essential features flowcatchR delivers to the user are:
Frames
, ParticleSet
, and TrajectorySet
constituting the backbone of the proceduresThis guide includes a brief overview of the entire processing flow, from importing the raw images to the analysis of kinematic parameters derived from the identified trajectories. An example dataset will be used to illustrate the available features, in order to track blood platelets in consecutive frames derived from an intravital microscopy acquisition (also available in the package). All steps will be dissected to explore available parameters and options.
This vignette includes a brief overview of the entire processing flow, from importing the raw images to the analysis of kinematic parameters derived from the identified trajectories. An example dataset will be used to illustrate the available features, in order to track blood platelets in consecutive frames derived from an intravital microscopy acquisition (also available in the package). All steps will be dissected to explore available parameters and options.
flowcatchR is an R package distributed as part of the Bioconductor project. To install flowcatchR, please start R and type:
if (!requireNamespace("BiocManager", quietly=TRUE))
install.packages("BiocManager")
BiocManager::install("flowcatchR")
In case you might prefer to install the latest development version, this can be done with these two lines below:
install.packages("devtools") # if needed
devtools::install_github("federicomarini/flowcatchR")
Installation issues should be reported to the Bioconductor support site (http://support.bioconductor.org/).
The flowcatchR package was tested on a variety of datasets provided from cooperation partners, yet it may require some extra tuning or bug fixes. For these issues, please contact the maintainer - if required with a copy of the error messages, the output of sessionInfo
function:
maintainer("flowcatchR")
## [1] "Federico Marini <marinif@uni-mainz.de>"
Despite our best efforts to test and develop the package further, additional functions or interesting suggestions might come from the specific scenarios that the package users might be facing. Improvements of existing functions or development of new ones are always most welcome! We also encourage to fork the GitHub repository of the package (https://github.com/federicomarini/flowcatchR), develop and test the new feature(s), and finally generate a pull request to integrate it to the original repository.
The work underlying the development of flowcatchR has not been formally published yet. A manuscript has been submitted for peer-review. For the time being, users of flowcatchR are encouraged to cite it using the output of the citation
function, as it follows:
citation("flowcatchR")
##
## To cite the package 'flowcatchR' in publications use:
##
## Federico Marini, Harald Binder (2018). flowcatchR: Tools to analyze
## in vivo microscopy imaging data focused on tracking flowing blood
## cells. URL http://bioconductor.org/packages/flowcatchR/ doi:
## 10.18129/B9.bioc.flowcatchR
##
## A BibTeX entry for LaTeX users is
##
## @Manual{,
## title = {{flowcatchR}: Tools to analyze in vivo microscopy imaging data focused on
## tracking flowing blood cells},
## author = {Federico Marini and Harald Binder},
## year = {2018},
## url = {http://bioconductor.org/packages/flowcatchR/},
## doi = {10.18129/B9.bioc.flowcatchR},
## }
flowcatchR works primarily with sets of fluorescent time-lapse images, where the particles of interest are marked with a fluorescent label (e.g., red for blood platelets, green for leukocytes). Although different entry spots are provided (such as the coordinates of identified points in each frame via tab delimited files), we will illustrate the characteristics of the package starting from the common protocol starting point. In this case, we have a set of 20 frames derived from an intravital microscopy acquisition, which for the sake of practicality were already registered to reduce the unwanted specimen movements (Fiji (Schindelin, Arganda-Carreras, and Frise 2012) was used for this purpose).
library("flowcatchR")
## Loading required package: EBImage
data("MesenteriumSubset")
# printing summary information for the MesenteriumSubset object
MesenteriumSubset
## Frames
## colorMode : Color
## storage.mode : double
## dim : 271 131 3 20
## frames.total : 60
## frames.render: 20
##
## imageData(object)[1:5,1:6,1,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0.1647059 0.2117647 0.1882353 0.1803922 0.1607843 0.1333333
## [2,] 0.2352941 0.1882353 0.1803922 0.1568627 0.1411765 0.1372549
## [3,] 0.2352941 0.2000000 0.1764706 0.1490196 0.1333333 0.1333333
## [4,] 0.2352941 0.2117647 0.1764706 0.1529412 0.1411765 0.1411765
## [5,] 0.2313725 0.2078431 0.1725490 0.1411765 0.1294118 0.1411765
##
## Channel(s): all
To obtain the set of trajectories identified from the analysis of the loaded frames, a very compact one-line command is all that is needed:
# one command to seize them all :)
fullResults <- kinematics(trajectories(particles(channel.Frames(MesenteriumSubset,"red"))))
On a MAC OS X machine equipped with 2.8 Ghz Intel Core i7 processor and 16 GB RAM, the execution of this command takes 2.32 seconds to run (tests performed with the R package microbenchmark. On a more recent MacBook Pro (2017), the same benchmark took 1.78 seconds.
The following sections will provide additional details to the operations mentioned above, with more also on the auxiliary functions that are available in flowcatchR.
A set of images is acquired, after a proper microscopy setup has been performed. This includes for example a careful choice of spatial and temporal resolution; often a compromise must be met to have a good frame rate and a good SNR to detect the particles in the single frames. For a good review on the steps to be taken, please refer to Meijering’s work (Meijering and Smal 2008, @Meijering2012a).
flowcatchR provides an S4 class that can store the information of a complete acquisition, namely Frames
. The Frames
class extends the Image
class, defined in the EBImage package, and thus exploits the multi-dimensional array structures of the class. The locations of the images are stored as dimnames
of the Frames
object. To construct a Frames
object from a set of images, the read.Frames
function is used:
# initialization
fullData <- read.Frames(image.files="/path/to/folder/containing/images/", nframes=100)
# printing summary information for the Frames object
fullData
nframes
specifies the number of frames that will constitute the Frames
object, whereas image.files
is a vector of character strings with the full location of the (raw) images, or the path to the folder containing them (works automatically if images are in TIFF/JPG/PNG format). In this case we just loaded the full dataset, but for the demonstrational purpose of this vignette, we will proceed with the subset available in the MesenteriumSubset
object, which we previously loaded in Section 3.
It is possible to inspect the images composing a Frames
object with the function inspect.Frames
(Fig. 1).
inspect.Frames(MesenteriumSubset, nframes=9, display.method="raster")
By default, display.method
is set to browser
, as in the EBImage function display. This opens up a window in the predefined browser (e.g. Mozilla Firefox), with navigable frames (arrows on the top left corner). For the vignette, we will set it to raster
, for viewing them as raster graphics using R’s native functions.
Importantly, these image sets were already registered and rotated in such a way that the overall direction of the movement of interest flows from left to right, as a visual aid and also to fit with some assumptions that will be done in the subsequent step of particle tracking. To register the images, we recommend the general purpose tools offered by suites such as ImageJ/Fiji (Schneider, Rasband, and Eliceiri 2012, @Schindelin2012).
For the following steps, we will focus on the information contained in the red channel, corresponding in this case to blood platelets. We do so by calling the channel.Frames
function:
plateletsMesenterium <- channel.Frames(MesenteriumSubset, mode="red")
plateletsMesenterium
## Frames
## colorMode : Grayscale
## storage.mode : double
## dim : 271 131 20
## frames.total : 20
## frames.render: 20
##
## imageData(object)[1:5,1:6,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0.1647059 0.2117647 0.1882353 0.1803922 0.1607843 0.1333333
## [2,] 0.2352941 0.1882353 0.1803922 0.1568627 0.1411765 0.1372549
## [3,] 0.2352941 0.2000000 0.1764706 0.1490196 0.1333333 0.1333333
## [4,] 0.2352941 0.2117647 0.1764706 0.1529412 0.1411765 0.1411765
## [5,] 0.2313725 0.2078431 0.1725490 0.1411765 0.1294118 0.1411765
##
## Channel(s): red
This creates another instance of the class Frames
, and we inspect it in its first 9 frames (Fig.2).
inspect.Frames(plateletsMesenterium, nframes=9, display.method="raster")
Steps such as denoising, smoothing and morphological operations (erosion/dilation, opening/closing) can be performed thanks to the general functions provided by EBImage. flowcatchR offers a wrapper around a series of operations to be applied to all images in a Frames
object. The function preprocess.Frames
is called via the following command:
preprocessedPlatelets <- preprocess.Frames(plateletsMesenterium,
brush.size=3, brush.shape="disc",
at.offset=0.15, at.wwidth=10, at.wheight=10,
kern.size=3, kern.shape="disc",
ws.tolerance=1, ws.radius=1)
preprocessedPlatelets
## Frames
## colorMode : Grayscale
## storage.mode : integer
## dim : 271 131 20
## frames.total : 20
## frames.render: 20
##
## imageData(object)[1:5,1:6,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0 0 0 0 0 0
## [2,] 0 0 0 0 0 0
## [3,] 0 0 0 0 0 0
## [4,] 0 0 0 0 0 0
## [5,] 0 0 0 0 0 0
##
## Channel(s): red
The result of this is displayed in Fig.3. For a detailed explanation of the parameters to better tweak the performances of this segmentation step, please refer to the help of preprocess.Frames
. To obtain an immediate feedback about the effects of the operations performed in the full preprocessing phase, we can call again inspect.Frames
on the Frames
of segmented images (Fig.3.
inspect.Frames(preprocessedPlatelets, nframes=9, display.method="raster")
The frames could be cropped, if e.g. it is needed to remove background noise that might be present close to the edges. This is done with the function crop.Frames
.
croppedFrames <- crop.Frames(plateletsMesenterium,
cutLeft=6, cutRight=6,
cutUp=3, cutDown=3,
testing=FALSE)
croppedFrames
## Frames
## colorMode : Grayscale
## storage.mode : double
## dim : 260 126 20
## frames.total : 20
## frames.render: 20
##
## imageData(object)[1:5,1:6,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0.1803922 0.1568627 0.1372549 0.1372549 0.1333333 0.1176471
## [2,] 0.2039216 0.1843137 0.1490196 0.1254902 0.1215686 0.1215686
## [3,] 0.1843137 0.1764706 0.1568627 0.1294118 0.1176471 0.1019608
## [4,] 0.1921569 0.1568627 0.1529412 0.1333333 0.1254902 0.1333333
## [5,] 0.2000000 0.1647059 0.1490196 0.1450980 0.1333333 0.1411765
##
## Channel(s): red
If testing
is set to true, the function just displays the first cropped frame, to get a feeling whether the choice of parameters was adequate. Similarly, for the function rotate.Frames
the same behaviour is expected, whereas the rotation in degrees is specified by the parameter angle
.
rotatedFrames <- rotate.Frames(plateletsMesenterium, angle=30)
rotatedFrames
## Frames
## colorMode : Grayscale
## storage.mode : double
## dim : 300 249 20
## frames.total : 20
## frames.render: 20
##
## imageData(object)[1:5,1:6,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0 0 0 0 0 0
## [2,] 0 0 0 0 0 0
## [3,] 0 0 0 0 0 0
## [4,] 0 0 0 0 0 0
## [5,] 0 0 0 0 0 0
##
## Channel(s): red
If desired, it is possible to select just a subset of the frames belonging to a Frames
. This can be done via the select.Frames
function:
subsetFrames <- select.Frames(plateletsMesenterium,
framesToKeep=c(1:10,14:20))
subsetFrames
## Frames
## colorMode : Grayscale
## storage.mode : double
## dim : 271 131 17
## frames.total : 17
## frames.render: 17
##
## imageData(object)[1:5,1:6,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0.1647059 0.2117647 0.1882353 0.1803922 0.1607843 0.1333333
## [2,] 0.2352941 0.1882353 0.1803922 0.1568627 0.1411765 0.1372549
## [3,] 0.2352941 0.2000000 0.1764706 0.1490196 0.1333333 0.1333333
## [4,] 0.2352941 0.2117647 0.1764706 0.1529412 0.1411765 0.1411765
## [5,] 0.2313725 0.2078431 0.1725490 0.1411765 0.1294118 0.1411765
##
## Channel(s): red
If required, the user can decide to perform a normalization step (via normalizeFrames
), to correct for systematic variations in the acquisition conditions, in case the overall intensity levels change, e.g., when the acquisition spans long time scales. In this case, the median of the intensity sums is chosen as a scaling factor.
normFrames <- normalizeFrames(plateletsMesenterium,normFun = "median")
The user can choose any combination of the operations in order to segment the images provided as input, but preprocess.Frames
is a very convenient high level function for proceeding in the workflow. It is also possible, as it was shown in the introductory one-liner, to call just particles
on the raw Frames
object. In this latter case, particles
computes the preprocessed Frames
object according to default parameters. Still, in either situation, the output for this step is an object of the ParticleSet
class.
platelets <- particles(plateletsMesenterium, preprocessedPlatelets)
## Computing features in parallel...
## Done!
platelets
## An object of the ParticleSet class.
##
## Set of particles for 20 images
##
## Displaying a subset of the features of the 13 particles found in the first image...
## cell.0.m.cx cell.0.m.cy cell.0.m.majoraxis cell.0.m.eccentricity
## 1 186.70833 47.937500 8.916405 0.6353715
## 2 256.19048 35.857143 7.746554 0.4606665
## 3 251.09524 63.523810 8.552466 0.6843186
## 4 215.54688 51.828125 13.694783 0.8788344
## 5 15.82759 8.517241 7.548790 0.7570114
## cell.0.m.theta cell.0.s.area cell.0.s.perimeter cell.0.s.radius.mean
## 1 0.3380463 48 20 3.487042
## 2 0.9165252 42 19 3.194559
## 3 0.9370618 42 19 3.247531
## 4 0.7172299 64 28 4.308530
## 5 1.5439842 29 16 2.622403
##
## Particles identified on the red channel
The function particles
leverages on the multi-core architecture of the systems where the analysis is run, and this is implemented via BiocParallel (updated since Version 1.0.3).
As it can be seen from the summary information, each ParticleSet
stores the essential information on all particles that were detected in the original images, alongside with a complete set of features, which are computed by integrating the information from both the raw and the segmented frames.
A ParticleSet
can be seen as a named list, where each element is a data.frame
for a single frame, and the image source is stored as names
to help backtracking the operations performed, and the slot channel
is retained as selected in the initial steps.
It is possible to filter out particles according to their properties, such as area, shape and eccentricity. This is possible with the function select.particles
. The current implementation regards only the surface extension, but any additional feature can be chosen and adopted to restrict the number of candidate particles according to particular properties which are expected and/or to remove potential noise that went through the preprocessing phase.
selectedPlatelets <- select.particles(platelets, min.area=3)
## Filtering the particles...
selectedPlatelets
## An object of the ParticleSet class.
##
## Set of particles for 20 images
##
## Displaying a subset of the features of the 13 particles found in the first image...
## cell.0.m.cx cell.0.m.cy cell.0.m.majoraxis cell.0.m.eccentricity
## 1 186.70833 47.937500 8.916405 0.6353715
## 2 256.19048 35.857143 7.746554 0.4606665
## 3 251.09524 63.523810 8.552466 0.6843186
## 4 215.54688 51.828125 13.694783 0.8788344
## 5 15.82759 8.517241 7.548790 0.7570114
## cell.0.m.theta cell.0.s.area cell.0.s.perimeter cell.0.s.radius.mean
## 1 0.3380463 48 20 3.487042
## 2 0.9165252 42 19 3.194559
## 3 0.9370618 42 19 3.247531
## 4 0.7172299 64 28 4.308530
## 5 1.5439842 29 16 2.622403
##
## Particles identified on the red channel
This step can be done iteratively, with the help of the function add.contours
. If called with the parameter mode
set to particles
, then it will automatically generate a Frames
object, with the contours of all particles drawn around the objects that passed the segmentation (and filtering) step (Fig.4).
paintedPlatelets <- add.contours(raw.frames=MesenteriumSubset,
binary.frames=preprocessedPlatelets,
mode="particles")
inspect.Frames(paintedPlatelets, nframes=9, display.method="raster")
To connect the particles from one frame to the other, we perform first the detection of particles on all images. Only in a successive phase, we establish the links between the so identified objects. This topic will be covered in detail in the following section.
To establish the connections between particles, the function to be called is link.particles
. The algorithm used to perform the tracking itself is an improved version of the original implementation of Sbalzarini and Koumotsakos (Sbalzarini and Koumoutsakos 2005). To summarize the method, it is a fast and efficient self-initializing feature point tracking algorithm (using the centroids of the objects as reference) (Chenouard et al. 2014). The initial version is based on a particle matching algorithm, approached via a graph theory technique. It allows for appearances/disappearances of particles from the field of view, also temporarily as it happens in case of occlusions and objects leaving the plane of focus.
Our implementation adds to the existing one by redefining the cost function used in the optimization phase of the link assignment. It namely adds two terms, such as intensity variation and area variation, and mostly important implements a function to penalize the movements that are either perpendicular or backwards with respect to the oriented flow of cells. Small unwanted movements, which may be present even after the registration phase, are handled with two jitter terms in a defined penalty function. Multiplicative factors can further influence the penalties given to each term.
In its default value, the penalty function is created via the penaltyFunctionGenerator
. The user can exploit the parameter values in it to create a custom version of it, to match the particular needs stemming from the nature of the available data and phenomenon under inspection.
defaultPenalty <- penaltyFunctionGenerator()
print(defaultPenalty)
## function (angle, distance)
## {
## lambda1 * (distance/(1 - lambda2 * (abs(angle)/(pi + epsilon1))))
## }
## <bytecode: 0x556367863340>
## <environment: 0x556367863b90>
As mentioned above, to perform the linking of the particles, we use link.particles
. Fundamental parameters are L
and R
, named as in the original implementation. L
is the maximum displacement in pixels that a particle is expected to have in two consecutive frames, and R
is the value for the link range, i.e. the number of future frames to be considered for the linking (typically assumes values between 1 - when no occlusions are known to happen - and 3). An extended explanation of the parameters is in the documentation of the package.
linkedPlatelets <- link.particles(platelets,
L=26, R=3,
epsilon1=0, epsilon2=0,
lambda1=1, lambda2=0,
penaltyFunction=penaltyFunctionGenerator(),
include.area=FALSE)
linkedPlatelets
## An object of the LinkedParticleSet class.
##
## Set of particles for 20 images
##
## Particles are tracked throughout the subsequent 3 frame(s)
##
## Displaying a subset of the features of the 13 particles found in the first image...
## cell.0.m.cx cell.0.m.cy cell.0.m.majoraxis cell.0.m.eccentricity
## 1 186.70833 47.937500 8.916405 0.6353715
## 2 256.19048 35.857143 7.746554 0.4606665
## 3 251.09524 63.523810 8.552466 0.6843186
## 4 215.54688 51.828125 13.694783 0.8788344
## 5 15.82759 8.517241 7.548790 0.7570114
## cell.0.m.theta cell.0.s.area cell.0.s.perimeter cell.0.s.radius.mean
## 1 0.3380463 48 20 3.487042
## 2 0.9165252 42 19 3.194559
## 3 0.9370618 42 19 3.247531
## 4 0.7172299 64 28 4.308530
## 5 1.5439842 29 16 2.622403
##
## Particles identified on the red channel
As it can be seen, linkedPlatelets
is an object of the LinkedParticleSet
class, which is a subclass of the ParticleSet
class.
After inspecting the trajectories (see Section 7) it might be possible to filter a LinkedParticleSet
class object and subsequently reperform the linking on its updated version (e.g. some detected particles were found to be noise, and thus removed with select.particles
).
flowcatchR provides functions to export and import the identified particles, in order to offer an additional entry point for tracking and analyzing the trajectories (if particles were detected with other routines) and also to store separately the information per each frame about the objects that were primarily identified.
An example is provided in the lines below, with the functions export.particles
and read.particles
:
# export to csv format
export.particles(platelets, dir="/path/to/export/folder/exportParticleSet/")
# re-import the previously exported, in this case
importedPlatelets <- read.particles(particle.files="/path/to/export/folder/exportParticleSet/")
It is possible to extract the trajectories with the correspondent trajectories
function:
trajPlatelets <- trajectories(linkedPlatelets)
## Generating trajectories...
trajPlatelets
## An object of the TrajectorySet class.
##
## TrajectorySet composed of 20 trajectories
##
## Trajectories cover a range of 20 frames
## Displaying a segment of the first trajectory...
## xCoord yCoord trajLabel frame frameobjectID
## 1_1 186.7083 47.93750 1 1 1
## 1_2 186.9649 48.26316 1 2 4
## 1_3 186.8136 48.18644 1 3 2
## 1_4 186.2807 47.70175 1 4 1
## 1_5 186.6897 47.87931 1 5 2
## 1_6 186.8269 48.11538 1 6 2
## 1_7 186.9643 48.30357 1 7 1
## 1_8 186.6207 48.36207 1 8 3
## 1_9 186.3273 48.05455 1 9 3
## 1_10 186.9821 48.19643 1 10 3
##
## Trajectories are related to particles identified on the red channel
A TrajectorySet
object is returned in this case. It consists of a two level list for each trajectory, reporting the trajectory
as a data.frame
, the number of points npoints
(often coinciding with the number of nframes
, when no gaps ngaps
are present) and its ID
. A keep
flag is used for subsequent user evaluation purposes.
Before proceeding with the actual analysis of the trajectories, it is recommended to evaluate them by visual inspection. flowcatchR provides two complementary methods to do this, either plotting them (plot
or plot2D.TrajectorySet
) or drawing the contours of the points on the original image (add.contours
).
By plotting all trajectories in a 2D+time representation, it’s possible to have an overview of all trajectories.
The following command gives an interactive 3D (2D+time) view of all trajectories (Fig.5):
plot(trajPlatelets, MesenteriumSubset)
The plot2D.TrajectorySet
focuses on additional information and a different “point of view”, but can just display a two dimensional projection of the identified trajectories (Fig.6).
plot2D.TrajectorySet(trajPlatelets, MesenteriumSubset)
To have more insights on single trajectories, or on a subset of them, add.contours
offers an additional mode called trajectories
. Particles are drawn on the raw images with colours corresponding to the trajectory IDs. add.contours
plots by default all trajectories, but the user can supply a vector of the IDs of interest to override this behaviour.
paintedTrajectories <- add.contours(raw.frames=MesenteriumSubset,
binary.frames=preprocessedPlatelets,
trajectoryset=trajPlatelets,
mode="trajectories")
paintedTrajectories
## Frames
## colorMode : Color
## storage.mode : double
## dim : 271 131 3 20
## frames.total : 60
## frames.render: 20
##
## imageData(object)[1:5,1:6,1,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0.1647059 0.2117647 0.1882353 0.1803922 0.1607843 0.1333333
## [2,] 0.2352941 0.1882353 0.1803922 0.1568627 0.1411765 0.1372549
## [3,] 0.2352941 0.2000000 0.1764706 0.1490196 0.1333333 0.1333333
## [4,] 0.2352941 0.2117647 0.1764706 0.1529412 0.1411765 0.1411765
## [5,] 0.2313725 0.2078431 0.1725490 0.1411765 0.1294118 0.1411765
##
## Channel(s): all
As with any other Frames
object, it is recommended to take a peek at it via the inspect.Frames
function (Fig.7):
inspect.Frames(paintedTrajectories,nframes=9,display.method="raster")
To allow for a thorough evaluation of the single trajectories, export.Frames
is a valid helper, as it creates single images corresponding to each frame in the Frames
object. We first extract for example trajectory 11 (Fig.8) with the following command:
traj11 <- add.contours(raw.frames=MesenteriumSubset,
binary.frames=preprocessedPlatelets,
trajectoryset=trajPlatelets,
mode="trajectories",
trajIDs=11)
traj11
## Frames
## colorMode : Color
## storage.mode : double
## dim : 271 131 3 20
## frames.total : 60
## frames.render: 20
##
## imageData(object)[1:5,1:6,1,1]
## [,1] [,2] [,3] [,4] [,5] [,6]
## [1,] 0.1647059 0.2117647 0.1882353 0.1803922 0.1607843 0.1333333
## [2,] 0.2352941 0.1882353 0.1803922 0.1568627 0.1411765 0.1372549
## [3,] 0.2352941 0.2000000 0.1764706 0.1490196 0.1333333 0.1333333
## [4,] 0.2352941 0.2117647 0.1764706 0.1529412 0.1411765 0.1411765
## [5,] 0.2313725 0.2078431 0.1725490 0.1411765 0.1294118 0.1411765
##
## Channel(s): all
inspect.Frames(traj11, nframes=9, display.method="raster")
The data for trajectory 11 in the TrajectorySet
object can be printed to the terminal:
trajPlatelets[[11]]
## $trajectory
## xCoord yCoord trajLabel frame frameobjectID
## 11_1 186.5385 13.84615 11 1 11
## 11_2 186.5000 14.81250 11 2 12
## 11_3 186.4737 14.63158 11 3 11
## 11_4 186.0455 14.45455 11 4 9
## 11_5 186.5000 14.77778 11 5 11
## 11_6 186.5714 15.19048 11 6 12
## 11_7 186.7143 15.42857 11 7 11
## 11_8 186.4286 15.38095 11 8 12
## 11_9 186.0952 15.09524 11 9 11
## 11_10 186.6500 15.30000 11 10 13
## 11_11 186.5714 15.61905 11 11 14
## 11_12 186.7368 15.52632 11 12 12
## 11_13 186.8947 16.05263 11 13 12
## 11_14 186.5000 15.50000 11 14 15
## 11_15 186.8182 15.72727 11 15 13
## 11_16 186.9048 15.95238 11 16 11
## 11_17 186.8636 16.09091 11 17 12
## 11_18 187.0000 16.13636 11 18 11
## 11_19 186.6818 16.13636 11 19 15
## 11_20 186.5789 15.89474 11 20 16
##
## $npoints
## [1] 20
##
## $nframes
## [1] 20
##
## $ngaps
## [1] 0
##
## $keep
## [1] NA
##
## $ID
## [1] 11
After that, it can also be exported with the following command (the dir
parameter must be changed accordingly):
export.Frames(traj11, dir=tempdir(), nameStub="vignetteTest_traj11",
createGif=TRUE, removeAfterCreatingGif=FALSE)
export.Frames
offers multiple ways to export - animated gif (if ImageMagick
is available and installed on the system) or multiple jpeg/png images.
Of course the user might want to singularly evaluate each trajectory that was identified, and this can be done by looping over the trajectory IDs.
evaluatedTrajectories <- trajPlatelets
for(i in 1:length(trajPlatelets))
{
paintedTraj <- add.contours(raw.frames=MesenteriumSubset,
binary.frames=preprocessedPlatelets,
trajectoryset=trajPlatelets,
mode="trajectories",
col="yellow",
trajIDs=i)
export.Frames(paintedTraj,
nameStub=paste0("vignetteTest_evaluation_traj_oneByOne_",i),
createGif=TRUE, removeAfterCreatingGif=TRUE)
### uncomment the code below to perform the interactive evaluation of the single trajectories
# cat("Should I keep this trajectory? --- 0: NO, 1:YES --- no other values allowed")
# userInput <- readLines(n=1L)
# ## if neither 0 nor 1, do not update
# ## otherwise, this becomes the value for the field keep in the new TrajectoryList
# evaluatedTrajectories@.Data[[i]]$keep <- as.logical(as.numeric(userInput))
}
Always using trajectory 11 as example, we would set evaluatedTrajectories[[11]]$keep
to TRUE
, since the trajectory was correctly identified, as we just checked.
Once all trajectories have been selected, we can proceed to calculate (a set of) kinematic parameters, for a single or all trajectories in a TrajectorySet
object. The function kinematics
returns the desired output, respectively a KinematicsFeatures
object, a KinematicsFeaturesSet
, a single value or a vector (or list, if not coercible to vector) of these single values (one parameter for each trajectory).
allKinematicFeats.allPlatelets <- kinematics(trajPlatelets,
trajectoryIDs=NULL, # will select all trajectory IDs
acquisitionFrequency=30, # value in milliseconds
scala=50, # 1 pixel is equivalent to ... micrometer
feature=NULL) # all kinematic features available
## Warning in extractKinematics.traj(trajectoryset, i, acquisitionFrequency =
## acquisitionFrequency, : The trajectory with ID 17 had 3 or less points, no
## features were computed.
## Warning in extractKinematics.traj(trajectoryset, i, acquisitionFrequency =
## acquisitionFrequency, : The trajectory with ID 18 had 3 or less points, no
## features were computed.
## Warning in extractKinematics.traj(trajectoryset, i, acquisitionFrequency =
## acquisitionFrequency, : The trajectory with ID 20 had 3 or less points, no
## features were computed.
As it is reported from the output, the function raises a warning for trajectories which have 3 or less points, as they might be spurious detections. In such cases, no kinematic features are computed.
allKinematicFeats.allPlatelets
## An object of the KinematicsFeaturesSet class.
##
## KinematicsFeaturesSet composed of 20 KinematicsFeatures objects
##
## Available features (shown for the first trajectory):
## [1] "delta.x" "delta.t"
## [3] "delta.v" "totalTime"
## [5] "totalDistance" "distStartToEnd"
## [7] "curvilinearVelocity" "straightLineVelocity"
## [9] "linearityForwardProgression" "trajMSD"
## [11] "velocityAutoCorr" "instAngle"
## [13] "directChange" "dirAutoCorr"
## [15] "paramsNotComputed"
##
## Curvilinear Velocity: 0.009970094
## Total Distance: 5.682953
## Total Time: 570
##
## Average values (calculated on 3 trajectories where parameters were computed)
## Average Curvilinear Velocity: 0.1278174
## Average Total Distance: 56.08449
## Average Total Time: 518.8235
A summary for the returned object (in this case a KinematicsFeaturesSet
) shows some of the computed parameters.
By default, information about the first trajectory is reported in brief, and the same parameters are evaluated on average across the selected trajectories. The true values can be accessed in this case for each trajectory by the subset operator for lists ([[]]
), followed by the name of the kinematic feature (e.g., $totalDistance
).
A list of all available parameters is printed with an error message if the user specifies an incorrect name, such as here:
allKinematicFeats.allPlatelets <- kinematics(trajPlatelets, feature="?")
## Available features to compute are listed here below.
## Please select one among delta.x, delta.t, delta.v, totalTime,
## totalDistance, distStartToEnd, curvilinearVelocity,
## straightLineVelocity, linearityForwardProgression, trajMSD,
## velocityAutoCorr, instAngle, directChange or dirAutoCorr
When asking for a single parameter, the value returned is structured in a vector, such that it is straightforward to proceed with further analysis, e.g. by plotting the distribution of the curvilinear velocities (Fig.9).
allVelocities <- kinematics(trajPlatelets, feature="curvilinearVelocity")
hist(allVelocities, breaks=10, probability=TRUE, col="cadetblue",
xlab="Curvilinear Velocities Distribution",
main="Trajectory Analysis: Curvilinear Velocities")
lines(density(allVelocities, na.rm=TRUE), col="steelblue", lwd=2)
For this code chunk, we are suppressing the warning messages, as they would be exactly the same as in the former where all features were computed for each trajectory.
To enhance the Frames
objects and deliver an immediate feedback to the user, the function snap
leverages on both the raw and binary Frames
, as well as on the corresponding ParticleSet
and TrajectorySet
objects. It integrates the information available in all the mentioned objects, and it plots a modified instance of the Frames
object, identifying the particles closest to the mouse click, and showing additional trajectory-related information, such as the trajectory ID and the instantaneous velocity of the cell. The function can be called as in the command below:
snap(MesenteriumSubset,preprocessedPlatelets,
platelets,trajPlatelets,
frameID = 1,showVelocity = T)
An example output for the snap
is shown below in Fig.10, where the information (trajectory ID, as well as the velocity in the selected frame) is shown in yellow to offer a good contrast with the fluorescent image.
shinyFlow
Shiny ApplicationAdditionally, since Version 1.0.3, flowcatchR delivers shinyFlow
, a Shiny Web Application ((RStudio, Inc 2013)), which is built on the backbone of the analysis presented in this vignette, and is portable across all main operating systems. The user is thus invited to explore datasets and parameters with immediate reactive feedback, that can enable better understanding of the effects of single steps and changes in the workflow.
To launch the Shiny App, use the command below to open an external window either in the browser or in the IDE (such as RStudio):
shinyFlow()
A further integration are a number of Jupyter/IPython notebooks ((Pérez and Granger 2007)), as a way to provide easy reproducibility as well as communication of results, by combining plain text, commands and output in single documents. The R kernel used on the back-end was developed by Thomas Kluyver (https://github.com/takluyver/IRkernel), and instructions for the installation are available at the Github repository website. The notebooks are available in the installation folder of the package flowcatchR, which can be found with the command below.
list.files(system.file("extdata",package = "flowcatchR"),pattern = "*.ipynb")
## [1] "template_DetectionOfTransmigrationEvents.ipynb"
## [2] "template_flowcatchR_vignetteSummary.ipynb"
The notebooks are provided as template for further steps in the analysis. The user is invited to set up the IPython notebook framework as explained on the official website for the project (http://ipython.org/notebook.html). As of February, 3rd 2015, the current way to obtain the Jupyter environment is via the 3.0.dev
version, available via Github (https://github.com/ipython/ipython). The notebooks can be opened and edited by navigating to their location while the IPython notebook server is running; use the following command in the shell to launch it:
$ ipython notebook
Alternatively, these documents can be viewed with the nbviewer
tool, available at http://nbviewer.ipython.org/.
flowcatchR is now (as of September 2015) available also in Docker images that are the components of the dockerflow
proposal (https://github.com/federicomarini/dockerflow). This includes:
flowstudio
- https://github.com/federicomarini/flowstudio, a command-line/IDE interface to RStudio where flowcatchR and its dependencies are preinstalledflowshiny
- https://github.com/federicomarini/flowshiny a Shiny Server running the shinyFlow
web applicationflowjupy
- https://github.com/federicomarini/flowjupy, a Jupyter Notebook interfaceThese three images can be run simultaneously, provided the system where the containers are running supports the docker-compose
tool. For more information on how to install the single components, please refer to their repositories.
For more information on the method adapted for tracking cells, see Sbalzarini and Koumotsakos (2005) (Sbalzarini and Koumoutsakos 2005). For additional details regarding the functions of flowcatchR, please consult the documentation or write an email to marinif@uni-mainz.de.
Due to space limitations, the complete dataset for the acquired frames used in this vignette is not included as part of the flowcatchR package. If you would like to get access to it, you can write an email to marinif@uni-mainz.de.
This package was developed at the Institute of Medical Biostatistics, Epidemiology and Informatics at the University Medical Center, Mainz (Germany), with the financial support provided by the TRP-A15 Translational Research Project grant.
flowcatchR incorporates suggestions and feedback from the wet-lab biology units operating at the Center for Thrombosis and Hemostasis (CTH), in particular Sven Jäckel and Kerstin Jurk. Sven Jäckel also provided us with the sample acquisition which is available in this vignette.
We would like to thank the members of the Biostatistics division for valuable discussions, and additionally Isabella Zwiener for contributing to the first ideas on the project.
This vignette was generated using the following package versions:
## R version 4.2.0 RC (2022-04-19 r82224)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 20.04.4 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.15-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.15-bioc/R/lib/libRlapack.so
##
## locale:
## [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
## [3] LC_TIME=en_GB LC_COLLATE=C
## [5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
## [7] LC_PAPER=en_US.UTF-8 LC_NAME=C
## [9] LC_ADDRESS=C LC_TELEPHONE=C
## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## attached base packages:
## [1] stats graphics grDevices utils datasets methods base
##
## other attached packages:
## [1] flowcatchR_1.30.0 EBImage_4.38.0 BiocStyle_2.24.0
##
## loaded via a namespace (and not attached):
## [1] Rcpp_1.0.8.3 locfit_1.5-9.5 lattice_0.20-45
## [4] tidyr_1.2.0 fftwtools_0.9-11 png_0.1-7
## [7] assertthat_0.2.1 digest_0.6.29 utf8_1.2.2
## [10] mime_0.12 R6_2.5.1 tiff_0.1-11
## [13] evaluate_0.15 highr_0.9 httr_1.4.2
## [16] ggplot2_3.3.5 pillar_1.7.0 rlang_1.0.2
## [19] lazyeval_0.2.2 data.table_1.14.2 jquerylib_0.1.4
## [22] magick_2.7.3 rmarkdown_2.14 BiocParallel_1.30.0
## [25] stringr_1.4.0 htmlwidgets_1.5.4 RCurl_1.98-1.6
## [28] munsell_0.5.0 shiny_1.7.1 compiler_4.2.0
## [31] httpuv_1.6.5 xfun_0.30 pkgconfig_2.0.3
## [34] BiocGenerics_0.42.0 htmltools_0.5.2 tidyselect_1.1.2
## [37] tibble_3.1.6 bookdown_0.26 viridisLite_0.4.0
## [40] fansi_1.0.3 crayon_1.5.1 dplyr_1.0.8
## [43] later_1.3.0 bitops_1.0-7 grid_4.2.0
## [46] jsonlite_1.8.0 xtable_1.8-4 gtable_0.3.0
## [49] lifecycle_1.0.1 DBI_1.1.2 magrittr_2.0.3
## [52] scales_1.2.0 cli_3.3.0 stringi_1.7.6
## [55] promises_1.2.0.1 bslib_0.3.1 colorRamps_2.3
## [58] ellipsis_0.3.2 vctrs_0.4.1 generics_0.1.2
## [61] tools_4.2.0 glue_1.6.2 purrr_0.3.4
## [64] crosstalk_1.2.0 jpeg_0.1-9 abind_1.4-5
## [67] parallel_4.2.0 fastmap_1.1.0 yaml_2.3.5
## [70] colorspace_2.0-3 BiocManager_1.30.17 plotly_4.10.0
## [73] knitr_1.38 sass_0.4.1
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