This pipeline aligns histology images to the Allen CCF.
A video demonstration of this tool is available here: https://www.youtube.com/watch?v=HKm_G17Wc6g
Requires
- Mouse: download the Allen CCF mouse atlas download here *
*(note on where these files came from: they are a re-formatted version of the original atlas, which has been processed with this script)
This was made with inspiration from SHARP-Track by Philip Shamash (https://github.com/cortex-lab/allenCCF, https://www.biorxiv.org/content/10.1101/447995v1). It mostly serves the same goals, but has different interfaces (most notably in the histology/CCF matching step) and saves some extra information (like the full CCF coordinates for each CCF slice), which was easier to build new compared to modifying the old.
All functions are listed in the 'demo_histology_pipeline.m' file.
AP_process_histology(im_path); % If size information in the OME-TIFF metadata, resize to CCF scale
AP_process_histology(im_path,resize_factor); % For user-specified resizing
- Downsample and white-balance slides
Colors will be automatically white-balanced, user indicates color of each channel
- Extract slice images from slides
Select slices to extract and save:
- slices will be automatically detected, left-clicking will select that slice
- right-clicking will draw a manual region to extract
- left-clicking on an existing selected region will unselect it
- spacebar moves to the next slide.
AP_rotate_histology(slice_path);
Draw reference line (midline) to center and rotate slices.
AP_grab_histology_ccf(tv,av,st,slice_path);
This function is to match histology slices to their corresponding CCF slices. The left plot is the histology slices (scrollable by 1/2), the right plot is the 3D CCF atlas which is rotatable with the arrow keys and scrollable in/out of the plane with the mouse wheel. Typical use would be:
- Match the rotation of the histology slices with the rotation of the CCF using the arrow keys. This is usually easiest using a slice with landmarks sensitive to asymmetries, e.g. the hippocampus or anterior commisure.
- Once the angle is set, the CCF slice location can be set with the scroll wheel. For each histology slice, scroll to the matching CCF slice and hit 'Enter' to set that slices' location.
- Once all histology slices are set, hit 'Escape' to save and quit
AP_auto_align_histology_ccf(tv,av,st,slice_path);
This function auto-aligns each corresponding histology and CCF slice by slice outline only
AP_manual_align_histology_ccf(tv,av,st,slice_path);
If the auto-alignment didn't work on some slices, they can be manually fixed with this function. Placing > 3 corresponding points on the histology and CCF slices creates a new alignment using those control points, and 'Escape' saves and quits.
After manual control-point alignment:
After the above steps, each histology slice is associated with a CCF slice, a transform between slices, and the location in CCF space for each slice. Some current uses for this:
AP_view_aligned_histology(st,slice_path);
Display the histology slices with overlaid boundaries, hover over region to display name
AP_view_aligned_histology_volume(tv,av,st,slice_path,1);
Threshold and display histology channel in 3D CCF space
AP_get_probe_histology(tv,av,st,slice_path);
Get trajectory of dyed probe in CCF coordinates and areas.
Enter the number of probes, draw lines on slices with visible tract marks corresponding to the probe (select the relevant probe by number, e.g. '1' to draw a line for probe 1), 'Escape' to save and quit
This will draw a line of best fit through the points and extract all brain areas along that trajectory. NOTE: it is unusual that the exact end of the probe can be visualized and accurately established from histology alone, so this step saves the entire trajectory and the next step aligns it to electrophysiology.
AP_align_probe_histology(st,slice_path,spike_times,spike_templates,template_depths);
This is a first-pass attempt at this function.
Match the trajectory of the probe through the CCF with electrophysiological signatures. This currently relies on kilosort-convention of variables: 'spike_times' n spikes x 1 vector of all spike times, 'spike_templates' n spikes x 1 vector of the templates corresponding to each spike time, and 'template_depths' n templates x 1 vector of the depth of each template.
This will plot the template depth vs spike rate (left), the multiunit correlation (center), and the CCF areas from the trajectory (right). Press (shift) up/down to scroll the CCF areas and match to electrophysiology landmarks. 'Escape' will save and quit.
The final useful output of this is a file/structure 'probe_ccf' which contains:
- probe_ccf.trajectory_coords: the 3D CCF coordinates of the probe trajectory
- probe_ccf.trajectory_areas: the annotated CCF areas for each point
- probe_ccf.probe_depths: the relative depth of the probe to that point (e.g. 0 is the top towards headstage of the probe and ~3840 is the tip of the probe). Note that this is reversed from the standard Kilosort output, which from 0 = tip to 3840 = top towards headstage.