Neuropixels neural recording analysis. Load SpikeGLX/OpenEphys data, preprocess, motion correction, Kilosort4 spike sorting, quality metrics, Allen/IBL curation, AI-assisted visual analysis, for Neuropixels 1.0/2.0 extracellular electrophysiology. Use when working with neural recordings, spike sorting, extracellular electrophysiology, or when the user mentions Neuropixels, SpikeGLX, Open Ephys, Kilosort, quality metrics, or unit curation.
Comprehensive toolkit for analyzing Neuropixels high-density neural recordings using current best practices from SpikeInterface, Allen Institute, and International Brain Laboratory (IBL). Supports the full workflow from raw data to publication-ready curated units.
This skill should be used when:
| Probe | Electrodes | Channels | Notes |
|---|---|---|---|
| Neuropixels 1.0 | 960 | 384 | Requires phase_shift correction |
| Neuropixels 2.0 (single) | 1280 | 384 | Denser geometry |
| Neuropixels 2.0 (4-shank) | 5120 | 384 | Multi-region recording |
| Format | Extension | Reader |
|---|---|---|
| SpikeGLX | .ap.bin, .lf.bin, .meta | si.read_spikeglx() |
| Open Ephys | .continuous, .oebin | si.read_openephys() |
| NWB | .nwb | si.read_nwb() |
import spikeinterface.full as si
import neuropixels_analysis as npa
# Configure parallel processing
job_kwargs = dict(n_jobs=-1, chunk_duration='1s', progress_bar=True)
# SpikeGLX (most common)
recording = si.read_spikeglx('/path/to/data', stream_id='imec0.ap')
# Open Ephys (common for many labs)
recording = si.read_openephys('/path/to/Record_Node_101/')
# Check available streams
streams, ids = si.get_neo_streams('spikeglx', '/path/to/data')
print(streams) # ['imec0.ap', 'imec0.lf', 'nidq']
# For testing with subset of data
recording = recording.frame_slice(0, int(60 * recording.get_sampling_frequency()))
# Run full analysis pipeline
results = npa.run_pipeline(
recording,
output_dir='output/',
sorter='kilosort4',
curation_method='allen',
)
# Access results
sorting = results['sorting']
metrics = results['metrics']
labels = results['labels']
# Recommended preprocessing chain
rec = si.highpass_filter(recording, freq_min=400)
rec = si.phase_shift(rec) # Required for Neuropixels 1.0
bad_ids, _ = si.detect_bad_channels(rec)
rec = rec.remove_channels(bad_ids)
rec = si.common_reference(rec, operator='median')
# Or use our wrapper
rec = npa.preprocess(recording)
# Check for drift (always do this!)
motion_info = npa.estimate_motion(rec, preset='kilosort_like')
npa.plot_drift(rec, motion_info, output='drift_map.png')
# Apply correction if needed
if motion_info['motion'].max() > 10: # microns
rec = npa.correct_motion(rec, preset='nonrigid_accurate')
# Kilosort4 (recommended, requires GPU)
sorting = si.run_sorter('kilosort4', rec, folder='ks4_output')
# CPU alternatives
sorting = si.run_sorter('tridesclous2', rec, folder='tdc2_output')
sorting = si.run_sorter('spykingcircus2', rec, folder='sc2_output')
sorting = si.run_sorter('mountainsort5', rec, folder='ms5_output')
# Check available sorters
print(si.installed_sorters())
# Create analyzer and compute all extensions
analyzer = si.create_sorting_analyzer(sorting, rec, sparse=True)
analyzer.compute('random_spikes', max_spikes_per_unit=500)
analyzer.compute('waveforms', ms_before=1.0, ms_after=2.0)
analyzer.compute('templates', operators=['average', 'std'])
analyzer.compute('spike_amplitudes')
analyzer.compute('correlograms', window_ms=50.0, bin_ms=1.0)
analyzer.compute('unit_locations', method='monopolar_triangulation')
analyzer.compute('quality_metrics')
metrics = analyzer.get_extension('quality_metrics').get_data()
# Allen Institute criteria (conservative)
good_units = metrics.query("""
presence_ratio > 0.9 and
isi_violations_ratio < 0.5 and
amplitude_cutoff < 0.1
""").index.tolist()
# Or use automated curation
labels = npa.curate(metrics, method='allen') # 'allen', 'ibl', 'strict'
When using this skill with Claude Code, Claude can directly analyze waveform plots and provide expert curation decisions. For programmatic API access:
from anthropic import Anthropic
# Setup API client
client = Anthropic()
# Analyze uncertain units visually
uncertain = metrics.query('snr > 3 and snr < 8').index.tolist()
for unit_id in uncertain:
result = npa.analyze_unit_visually(analyzer, unit_id, api_client=client)
print(f"Unit {unit_id}: {result['classification']}")
print(f" Reasoning: {result['reasoning'][:100]}...")
Claude Code Integration: When running within Claude Code, ask Claude to examine waveform/correlogram plots directly - no API setup required.
# Generate comprehensive HTML report with visualizations
report_dir = npa.generate_analysis_report(results, 'output/')
# Opens report.html with summary stats, figures, and unit table
# Print formatted summary to console
npa.print_analysis_summary(results)
# Export to Phy for manual review
si.export_to_phy(analyzer, output_folder='phy_export/',
compute_pc_features=True, compute_amplitudes=True)
# Export to NWB
from spikeinterface.exporters import export_to_nwb
export_to_nwb(rec, sorting, 'output.nwb')
# Save quality metrics
metrics.to_csv('quality_metrics.csv')
rec.save(folder='preprocessed/')freq_min: Highpass cutoff (300-400 Hz typical)detect_threshold: Bad channel detection sensitivitypreset: 'kilosort_like' (fast) or 'nonrigid_accurate' (better for severe drift)batch_size: Samples per batch (30000 default)nblocks: Number of drift blocks (increase for long recordings)Th_learned: Detection threshold (lower = more spikes)snr_threshold: Signal-to-noise cutoff (3-5 typical)isi_violations_ratio: Refractory violations (0.01-0.5)presence_ratio: Recording coverage (0.5-0.95)Automated preprocessing script:
python scripts/preprocess_recording.py /path/to/data --output preprocessed/
Run spike sorting:
python scripts/run_sorting.py preprocessed/ --sorter kilosort4 --output sorting/
Compute quality metrics and apply curation:
python scripts/compute_metrics.py sorting/ preprocessed/ --output metrics/ --curation allen
Export to Phy for manual curation:
python scripts/export_to_phy.py metrics/analyzer --output phy_export/
Complete analysis template. Copy and customize:
cp assets/analysis_template.py my_analysis.py
# Edit parameters and run
python my_analysis.py
Detailed step-by-step workflow with explanations for each stage.
Quick function reference organized by module.
Comprehensive visualization guide for publication-quality figures.
| Topic | Reference |
|---|---|
| Full workflow | reference/standard_workflow.md |
| API reference | reference/api_reference.md |
| Plotting guide | reference/plotting_guide.md |
| Preprocessing | PREPROCESSING.md |
| Spike sorting | SPIKE_SORTING.md |
| Motion correction | MOTION_CORRECTION.md |
| Quality metrics | QUALITY_METRICS.md |
| Automated curation | AUTOMATED_CURATION.md |
| AI-assisted curation | AI_CURATION.md |
| Waveform analysis | ANALYSIS.md |
# Core packages
pip install spikeinterface[full] probeinterface neo
# Spike sorters
pip install kilosort # Kilosort4 (GPU required)
pip install spykingcircus # SpykingCircus2 (CPU)
pip install mountainsort5 # Mountainsort5 (CPU)
# Our toolkit
pip install neuropixels-analysis
# Optional: AI curation
pip install anthropic
# Optional: IBL tools
pip install ibl-neuropixel ibllib
project/
├── raw_data/
│ └── recording_g0/
│ └── recording_g0_imec0/
│ ├── recording_g0_t0.imec0.ap.bin
│ └── recording_g0_t0.imec0.ap.meta
├── preprocessed/ # Saved preprocessed recording
├── motion/ # Motion estimation results
├── sorting_output/ # Spike sorter output
├── analyzer/ # SortingAnalyzer (waveforms, metrics)
├── phy_export/ # For manual curation
├── ai_curation/ # AI analysis reports
└── results/
├── quality_metrics.csv
├── curation_labels.json
└── output.nwb