SpatialQPFs

This repo provides the source code related to the SpatialQPFs R library that is reported in the manuscript "SpatialQPFs: An R package for deciphering cell-cell spatial relationship" by Xiao Li.

Primary SpatailQPFs functions

Function	Description
Data_Vis()	Visualizes the input cell level data, including raw spatial map of individual cells and smoothed spatial density map
Point_pattern_data_uni()	Main function to generate spatial features using point process data (single cell type).
Point_pattern_data_bi()	Main function to generate spatial features using point process data (pairwise cell types).
Point_pattern_data_ITLR()	This is a function that discriminates a target cell population into 2 subgroups, in spatial relationships with the reference cell population. In case of lymphocytes and tumor cells, the lymphocytes are discriminated into intra-tumoral lymphocytes and adjacent-tumoral lymphocytes.
Areal_data()	Main function to generate spatial features using areal data.
Geostatistics_data()	Main function to generate spatial features using geostatistical data.

Example workflow

1. installation

For first-time use, installation can be completed in the user's local computing environment.

## the folder contain the source code names "SpatialQPFs" in the user's local directory
devtools::install("your_path/SpatialQPFs", dependencies = TRUE, repos="https://cloud.r-project.org/")

Then, the package can be loaded:

library("SpatialQPFs")

2. Input data visualization

The utilization of the $SpatialQPFs$ functionality begins by importing cell-level input data (currently only support $.csv$ file, more input format will be supported in the future release). Preliminary steps, including identifying tumor regions of interest (ROIs), segmenting and classifying cells, are performed before invoking SpatialQPFs.

To visualize the spatial distribution of the input tabular data within the original tissue space and its derived spatial density map, users can call Data_Vis() function. For example, by specifying cell_type = "Lymphocyte" users can plot the lymphocyte population. The argument path and file accept strings that indicate the directory address where the file is saved and the name of the CSV file. Additionally, cell_class_var, x_var and y_var specify the column names from the input CSV file that contain the X, Y-coordinates of cell centroids and the corresponding cell type. See function manual for further details.

Data_Vis(path = folder_path, file = file_name, cell_class_var = "cell_class", 
         x_var = "coordinate_X", y_var = "coordinate_Y", cell_type = "Lymphocyte")  

3. Point pattern analysis

Point process data analysis methods can be conducted by implementing three functions:

• Point_pattern_data_uni(): This function generates spatial features for a single cell type population.
• Point_pattern_data_bi(): It computes the spatial interaction for a pair of cell types.
• Point_pattern_data_ITLR(): This function discriminates a target cell population into subgroups based on their spatial relationships with the reference cell population

Additional plots for other point process data analysis methods are presented at Tutorial-of-SpatialQPFs.html.

Point_pattern_data_uni(path = folder_path, file = file_name, 
                       cell_class_var = "cell_class", x_var = "coordinate_X", 
                       y_var = "coordinate_Y", cell_type = "Lymphocyte", 
                       scale = 200, myplot = T)

Point_pattern_data_bi(path = folder_path, file = file_name,  
                      cell_class_var = "cell_class", x_var = "coordinate_X", 
                      y_var = "coordinate_Y", from_type = "Lymphocyte", 
                      to_type = "Tumor", scale = 200, myplot = T)

Point_pattern_data_ITLR(path = folder_path, file = file_name, 
                        cell_class_var = "cell_class", x_var = "coordinate_X", 
                        y_var = "coordinate_Y", from_type = "Lymphocyte", 
                        to_type = "Tumor", micron_per_pixel = 0.5, myplot = T)

4. Areal data analysis

The analysis of areal data can be performed using the Areal_data() function. Note that, this function conducts the transformation from point process data to areal data behind the scenes, by partitioning the underlying space into square lattices. Users can specify the desired side length of the square lattices as 2*scale.

Other areal data analysis plots can be found in Tutorial-of-SpatialQPFs.html.

Areal_data(path = folder_path, file = file_name,
           cell_class_var = "cell_class", x_var = "coordinate_X", 
           y_var = "coordinate_Y", from_type = "Lymphocyte", 
           to_type = "Tumor", scale = 200, myplot = T)     

5. Geostatistical data analysis

The analysis of geostatistical data can be conducted using the Geostatistics_data() function. In the current version of SpatialQPFs , both semi-variogram and cross-variogram are implemented to illustrate the spatial correlation of either a single cell type or a pair of different cell types, respectively.

Further plots for alternative geostatistical data analysis methods are demonstrated at Tutorial-of-SpatialQPFs.html.

Geostatistics_data(path = folder_path, file = file_name, 
                   cell_class_var = "cell_class", x_var = "coordinate_X", 
                   y_var = "coordinate_Y",  from_type = "Lymphocyte", 
                   to_type = "Tumor", scale = 200, myplot = T)