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spikoclust_sort.m
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spikoclust_sort.m
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function [cluster spikeless]=spikoclust_sort(EPHYS_DATA,FS,varargin)
%CLI-driven Gaussian mixture model-based spike sorting
%
% [cluster spikeless]=spikoclust_spikesort(EPHYS_DATA,varargin)
%
% EPHYS_DATA
% data for spike sorting (samples x trials x channels)
%
% FS
% sampling rate of data
%
% the following may be specified as parameter/value pairs:
%
% interpolate_f
% interpolation factor used for spike alignment (cubic splines, default: 8, i.e. upsample by factor of 8)
%
% sort_f
% downsample factor after alignment for clustering (default: interpolate_f, i.e. spikes upsampled then downsampled to original fs)
%
% tetrode_channels
% channels may act as a putative n-trode (can specify an arbitrary number of channels),
% defaults to manual cluster cutting
%
% car_exclude
% carelectrodes to exclude from noise estimate
%
% noise_removal
% noise rejection method ('car' for common average 'nn' for nearest neighbor, or 'none',
% default: 'none')
%
% freq_range
% vector with two elements to specify the frequency range (one element specifies low pass, default: [500 8e3])
%
% filt_type
% filter type (default: 'bandpass', options 'low','high','bandpass')
%
% filt_order
% filter order (Butterworth, default: 6)
%
% gui_clust
% gui assisted clustering? (default: 0)
%
% sigma_t
% multiple of variance estimate for automatic threshold setting (uses the Quiroga formulation, default: 4)
%
% modelselection
% method of choosing the number of components for GMM clustering (default: icl, options,
% 'BIC' for Bayes Information, 'mml' for minimum message length, 'icl' for BIC-ICL)
%
% spike_window
% seconds before and after threshold crossing to store (in seconds, default: [.0005 .0005])
%
% clust_check
% vector of number of components to use in GMM clustering (default: [1:10])
%
% pcs
% number of principal components to use in GMM clustering (default: 2)
%
% garbage
% include a garbage-collecting uniform density in GMM clustering (0 or 1, default: 1)
%
% smem
% use split-and-merge algorithm for GMM clustering (0, 1, or 2 for FREE smem, default: 1)
%
% maxnoisetraces
% maximum number of noise traces to use in spike whitening (default: 1e6)
%
% align_feature
% method for spike alignment ('min','max', or 'com', default: 'min');
%
% noise
% denoising method ('car' for common average, 'none' for none, default: 'none');
%
% jitter
% maximum jitter for spike realignment in samples (default: 10)
%
% noisewhiten
% whiten noise using Cholesky decomposition (0 or 1, default: 1)
%
% wavelet_denoise
% denoise using wavelets (0 or 1, default: 0)
%
% decomp_level
% parameter for wavelet denoising (default: 7)
%
% the following outputs are returned by the script:
%
% cluster
% structure that contains clustering results, each field is a cell array, where cell n is the results for cluster n
%
% spikeless
% spike data with the spikes removed
%
%
% see also spikoclust_autosort.m,spikoclust_guisort.m,spikoclust_spike_detect.m
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% PARAMETER COLLECTION %%%%%%%%%%%%%%%%%
% TODO: remove multi-channel support
if nargin<1
error('ephysPipeline:suavis:notenoughparams','Need 1 arguments to continue, see documentation');
end
if isvector(EPHYS_DATA)
EPHYS_DATA=EPHYS_DATA(:);
end
nparams=length(varargin);
if mod(nparams,2)>0
error('ephysPipeline:argChk','Parameters must be specified as parameter/value pairs!');
end
noise_removal='none'; % none, nn for nearest neighbor, or car for common average
car_exclude=[]; % exclude any channels for common average?
% 300 Hz E high-pass, see Quiroga et al. 2013
freq_range=[400]; % bandpassing <10e3 distorted results, reasoning that >800 Hz is fine for spikes < 1ms long
filt_type='high'; % high,low or bandpass
filt_order=3; % filter order
filt_name='e'; % filter type, e for elliptic and b for butterworth
gui_clust=0; % use GUI?
tetrode_channels=[];
sigma_t=4; % multiple of noise estimate for spike threshold (generally 3-4, using Quiroga's method)
jitter=10; % max jitter in samples for spike re-alignment (4 is reasonable
align_feature='min'; % how to align spike waveforms can be min, max or com for center-of-mass
interpolate_f=8; % interpolate factor (fs*interpolate_f)
sort_f=[]; % if empty, downsamples back to original fs (advised to leave empty)
detect_method='n'; % p for pos n for neg b for both
car_trim=40; % common average using the trimmed mean (car_trim/2 is percent cut off from either edge)
decomp_level=7; % wavelet decomposition level (not used unless wavelet_denoise is set to 1)
wavelet_denoise=0; % wavelet denoise?
spike_window=[.0005 .0005]; % window to the left and right of the detected spike time to use for sorting
clust_check=1:8; % number of neurons to check for
pcs=2; % number of principal components to use
garbage=1; % use a garbage collecting uniform density in the mixture?
smem=1; % split-and-merge or standard EM?
spikeworkers=1; % only used in other packages, can safely ignore
modelselection='icl'; % how to select the number of neurons, 'bic', 'aic', or 'icl' (bic or icl recommended)
maxnoisetraces=1e6; % not recommended to change, upper bound on number of noise traces used for noise whitening
noisewhiten=1; % enable noise whitening?
gap_check=0; % determine cluster number using gap statistic
% remove eps generation, too slow here...
for i=1:2:nparams
switch lower(varargin{i})
case 'noise_removal'
noise_removal=varargin{i+1};
case 'sigma_t'
sigma_t=varargin{i+1};
case 'car_exclude'
car_exclude=varargin{i+1};
case 'filt_type'
filt_type=varargin{i+1};
case 'filt_name'
filt_name=varargin{i+1};
case 'decomp_level'
decomp_level=varargin{i+1};
case 'freq_range'
freq_range=varargin{i+1};
case 'spikesort'
spikesort=varargin{i+1};
case 'gui_clust'
gui_clust=varargin{i+1};
case 'align_feature'
align_feature=varargin{i+1};
case 'jitter'
jitter=varargin{i+1};
case 'interpolate_f'
interpolate_f=varargin{i+1};
case 'spike_window'
spike_window=varargin{i+1};
case 'sort_f'
sort_f=varargin{i+1};
case 'maxnoisetraces'
maxnoisetaces=varargin{i+1};
case 'filt_order'
filt_order=varargin{i+1};
case 'clust_check'
clust_check=varargin{i+1};
case 'car_trim'
car_trim=varargin{i+1};
case 'pcs'
pcs=varargin{i+1};
case 'garbage'
garbage=varargin{i+1};
case 'smem'
smem=varargin{i+1};
case 'spikeworkers'
spikeworkers=varargin{i+1};
case 'modelselection'
modelselection=varargin{i+1};
case 'wavelet_denoise'
wavelet_denoise=varargin{i+1};
case 'noisewhiten'
noisewhiten=varargin{i+1};
case 'decomp_level'
decomp_level=varargin{i+1};
case 'detect_method'
detect_method=varargin{i+1};
case 'gap_check'
gap_check=varargin{i+1};
end
end
if isempty(sort_f)
sort_f=interpolate_f;
disp(['Setting sort downsample factor to spike upsample factor: ' num2str(sort_f)]);
end
interpolate_fs=FS*interpolate_f;
sort_fs=interpolate_fs/sort_f;
downfact=interpolate_fs/sort_fs;
if mod(downfact,1)~=0
error('ephyspipeline:templatesortexact:baddownfact',...
'Need to downsample by an integer factor');
end
[samples,ntrials,ncarelectrodes]=size(EPHYS_DATA);
if ncarelectrodes==1 & strcmp(noise_removal,'car')
disp('Turning off CAR, number of electrodes is 1');
noise_removal='none';
car_exclude=[];
end
channels=1:ncarelectrodes;
TIME=[1:samples]./FS; % time vector for plotting
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SIGNAL CONDITIONING %%%%%%%%%%%%%%%%
sort_data=spikoclust_denoise_signal(EPHYS_DATA,channels,channels,'method',noise_removal,'car_exclude',car_exclude,'car_trim',car_trim);
sort_data=spikoclust_condition_signal(sort_data,'s','freq_range',...
freq_range,'filt_type',filt_type,'filt_order',filt_order,'filt_name',filt_name,...
'wavelet_denoise',wavelet_denoise,'decomp_level',decomp_level);
if length(channels)>1
tetrode_channels=channels(2:end);
end
clear EPHYS_DATA;
[samples,ntrials,newchannels]=size(sort_data);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SPIKE DETECTION %%%%%%%%%%%%%%%%%%%%
disp('Entering spike detection...');
disp(['Alignment method: ' align_feature]);
disp(['Interpolate FS: ' num2str(interpolate_fs)]);
% need a noise cutoff...let's start with 3*std or Quiroga's measure
disp(['Electrode ' num2str(channels)])
if ~isempty(tetrode_channels)
disp(['Will use tetrode channels ' num2str(tetrode_channels) ' for sorting']);
end
% collect spikes
nchannels=size(sort_data,3);
spikethreshold=sigma_t*median(abs(sort_data(:,:,1))/.6745);
spikes=spikoclust_spike_detect(sort_data,spikethreshold,FS,'visualize','n','align_feature',align_feature,...
'jitter',jitter,'window',spike_window,'method',detect_method);
spikeless{1}=spikoclust_spike_remove(sort_data(:,:,1),spikes);
totalspikes=length(spikes.times);
for i=2:nchannels
tmp_thresh=sigma_t*median(abs(sort_data(:,:,i))/.6745);
tmp_spikes=spikoclust_spike_detect(sort_data(:,:,i),tmp_thresh,FS,'visualize','n','align_feature',align_feature,...
'jitter',jitter,'window',spike_window,'method',detect_method);
spikeless{i}=spikoclust_spike_remove(sort_data(:,:,i),tmp_spikes);
end
disp([ num2str(totalspikes) ' total spikes']);
clear sort_data;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% store unwhitened times and use the unwhitened spikes for spike times
spikes.storewindows=spikes.windows;
disp(['Channel ' num2str(channels)]);
if noisewhiten
disp('Noise-whitening spikes...');
spikes=spikoclust_noisewhiten(spikes,spikeless,'maxnoisetraces',maxnoisetraces);
end
% upsample and align, then downsample for sorting!!!
spikes=spikoclust_upsample_align(spikes,'interpolate_fs',interpolate_fs,'align_feature',align_feature);
[nsamples,ntrials,nchannels]=size(spikes.windows);
spikes.windows=downsample(reshape(permute(spikes.windows,[1 3 2]),[],ntrials),downfact);
spikes.storewindows=reshape(permute(spikes.storewindows,[1 3 2]),[],ntrials);
if ~gui_clust
[labels model cluster_data]=spikoclust_autosort(spikes,'clust_check',clust_check,...
'pcs',pcs,'workers',spikeworkers,'garbage',garbage,'smem',smem,'modelselection',modelselection,'gap_check',gap_check);
else
[labels model cluster_data]=...
spikoclust_guisort(spikes,'pcs',pcs,'workers',spikeworkers,'garbage',garbage,'smem',smem,...
'modelselection',modelselection);
end
OUTLIERS=spikes.storewindows(:,labels==0);
% now assess the cluster quality ,
% take each cluster and check the FP and FN rate
[cluster.windows cluster.times cluster.trials cluster.spikedata cluster.isi cluster.stats]=...
spikoclust_cluster_quality(spikes.storewindows,spikes.times,cluster_data,labels,spikes.trial,model);
cluster.model=model;
cluster.outliers=OUTLIERS;
cluster.parameters.fs=FS;
cluster.parameters.interpolate_fs=interpolate_fs;
cluster.parameters.sort_fs=sort_fs;
cluster.parameters.threshold=spikethreshold;
cluster.parameters.tetrode_channels=tetrode_channels;
cluster.parameters.spike_window=spike_window;
cluster.parameters.align_feature=align_feature;
cluster.parameters.n_pcs=pcs;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% IFR, SMOOTH RATE %%%%%%%%%%%%%%%%%%%
uniq_clusters=1:length(cluster.windows);
nclust=length(uniq_clusters);