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main.asv
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%% Use each section of this main script to output all results and figures for the manuscript.
%
% 2023/09/27
%
% If this code is used in a publication, please cite the manuscript:
% "CARLA: Adjusted common average referencing for cortico-cortical evoked potential data"
% by H Huang, G Ojeda Valencia, NM Gregg, GM Osman, MN Montoya,
% GA Worrell, KJ Miller, and D Hermes.
%
% CARLA manuscript package: main script
% Copyright (C) 2023 Harvey Huang
%
% This program is free software: you can redistribute it and/or modify
% it under the terms of the GNU General Public License as published by
% the Free Software Foundation, either version 3 of the License, or
% (at your option) any later version.
%
% This program is distributed in the hope that it will be useful,
% but WITHOUT ANY WARRANTY; without even the implied warranty of
% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
% GNU General Public License for more details.
%
% You should have received a copy of the GNU General Public License
% along with this program. If not, see <https://www.gnu.org/licenses/>.
%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% Unless specified, each section of code below can be run directly from this script to generate all outputs.
% The scripts listed may also be opened so that individual sections within can be separately examined and run.
% Note that in output filenames, "zminmean" refers to zeta in the manuscript
%
% Subject CCEP and anatomical data will be available in BIDS format upon manuscript publication.
% In the meantime, all results on simulated data can be reproduced with the appropriate section below.
%
%% Configure paths and dependencies
% Make sure you are currently working in the root manuscript directory (CARLA)
addpath('functions');
% Data should be downloaded from OpenNeuro and copied to a folder here (./data)
dataPath = 'data';
% Add paths to other dependencies. Change the dummy paths listed here to where they are located on your system.
addpath(genpath('path/to/mnl_ieegBasics'));
addpath(genpath('path/to/matmef'));
addpath('path/to/mnl_seegview');
addpath(genpath('path/to/vistasoft'));
addpath('path/to/spm12'); addpath(fullfile('path/to/spm12', 'config'));
addpath(genpath('path/to/freesurfer/7.1.1/matlab'));
addpath(genpath('path/to/gifti'));
% To save figures as vectorized objects
set(0, 'DefaultFigureRenderer', 'painters');
%% i) Generate T1 MRI slices with stimulation site electrodes overlaid (Figures 4A, 6C)
% This was done using sliceGUI.m in the mnl_seegview repository:
% https://github.com/MultimodalNeuroimagingLab/mnl_seegview
% Define paths to defaced T1 MRI and matching electrodes table
niiPath = fullfile(dataPath, 'derivatives', 'freesurfer', 'sub-1', 'sub-1_ses-mri01_T1w_acpc_deFaced.nii');
electrodes = fullfile(dataPath, 'sub-1', 'ses-ieeg01', 'ieeg', 'sub-1_ses-ieeg01_electrodes.tsv');
% Run sliceGUI, and manually interact with it
sliceGUI(niiPath, electrodes);
%% Table 1: Calculate the number of measurement electrodes (channels) used in each subject
% outputs are directly printed to command window
tab1_dispNumElectrodes
%% Figure 1: Save simulated CCEP channels and their theoretical components
% outputs saved to .\output\simComponents
fig1_simCCEPComponents
%% Figure 2: Methods illustration of how CARLA works, on single-trial simulated CCEP data
% outputs saved to .\output\simulationTrial
fig2_CARLAonSingleTrial
%% Figure 3: Save example of enveloped sinusoids used to simulate evoked potentials
% outputs saved to .\output\EPConstruct
fig3_EPConstruct
%% Figure 4: Simulate 50 channels with responsiveness varying from 0 to 50, with 30 repetitions each, and apply CARLA
% First run this to generate outputs for each number of responsive channels
% outputs saved to .\output\simLoop
Aglobal = 0; % no global signal desired (0 amplitude)
simCCEPLoop;
% Then, keeping Aglobal in the workspace, run this to make summary figures (4C, D), as well as identify median candidates for 4A, B
% .\output\simLoop will be renamed .\output\simLoopNoGlob, where outputs are saved.
summarizeSimCCEPLoop
%% Figure 5: Apply CARLA to real data (sub 1, stim site 1)
% Configure the subject, data run, and stim site
sub = 'sub-1';
run = 2;
site = 'RMO8-RMO9';
% which channels to plot in panel F
chs2Plot = [100, 203];
% outputs saved to .\output\realCCEPs\. These correspond to figures 5B-F. To generate 5A (stim site overlaid on T1 MRI), see section i), above.
applyCARLARealCCEPs
%% Figure S1: Simulate datasets with fewer total channels (25, 20, 15, 10) and calculate CARLA accuracy
figS1_simCCEPTotalChs
%% Figure S2: Simulate datasets with lower signal-to-noise ratio (SNR) and calculate CARLA accuracy
brownCoefRange
%% Figure S3: Average channel responses for sub 1, stim site 1 after applying CAR vs. CARLA
% This supplemental figure is a direct addendum to Figure 5, showing the mean signal for the first 50 channels after rereferencing by CARLA or CAR
% Run after the previous section, keeping all workspace variables
figS3_compareCARvCARLA
%% Figure S4: Apply CARLA to real data at another 4 stim sites in subjects 1-4
% config parameters for each subject shown in S1
config = struct('sub', {'sub-1', 'sub-2', 'sub-3', 'sub-4'}, ...
'run', {1, 12, 3, 2}, ...
'site', {'ROC11-ROC12', 'RZ4-RZ5', 'LA2-LA3', 'RO3-RO4'});
chs2Plot = 1; % dummy value, no individual channels are plotted in Figure S1
for ii = 1:length(config)
sub = config(ii).sub;
run = config(ii).run;
site = config(ii).site;
% outputs saved to .\output\realCCEPs\.
% Omission of the middle section of sorted channels (subjects 1-3) in Figure S1 was done manually in illustrator.
applyCARLARealCCEPs
end
%% Figure S5: Save simulated CCEP channels, this time with a global signal, and their theoretical components
% outputs saved to .\output\simComponentsGlobal
figS5_simCCEPComponentsGlobalSig
%% Figure 6A, B Simulate 50 channels with responsiveness from 0 to 50, like Figure 4, but now with a global signal added
% First run this to generate outputs for each number of responsive channels
% outputs saved to .\output\simLoop
Aglobal = 25; % global signal with mean amplitude 25
simCCEPLoop;
% Then, keeping Aglobal in the workspace, run this to make summary figure (6B), and to identify a trial candidate for 6A
% .\output\simLoop will be renamed .\output\simLoopWithGlob, where outputs are saved.
summarizeSimCCEPLoop
% To generate figure 6C, see section i) on using sliceGUI, above.
%% Figure 6D-F: Apply CARLA to real data containing global signal (sub 1, stim site 2)
% Configure the subject, data run, and stim site
sub = 'sub-1';
run = 3;
site = 'RK5-RK6';
% which channels to plot in panel F
chs2Plot = [23, 51, 205];
% outputs saved to .\output\realCCEPs\
applyCARLARealCCEPs
%% Figure 7: Loop through stimulation sites in each subject and compute optimal CARLA cutoff
% This also calculates the cross-channel R-squared values for all possible adjusted common average sizes, to be summarized in Figure 8
% First run this script. Outputs are saved to .\output\realCCEPsLoop\.
applyCARLARealCCEPsLoop
% Then run this script to generate outputs for Figure 7
fig7_summarizeCARLARealCCEPs
%% Figure 8: Calculate cross-channel R-squared values for no CAR vs different types of fixed CARs vs CARLA
% outputs saved to .\output\realCCEPsLoop\.
fig8_summarizeInterChCorr