diffdock
GitHub基于扩散模型的分子对接工具,预测蛋白质-配体3D结合构象及置信度。支持PDB/SMILES输入、批量虚拟筛选。专用于结构预测,不预测亲和力,需结合打分函数评估。
Trigger Scenarios
Install
npx skills add synthetic-sciences/openscience --skill diffdock -g -y
SKILL.md
Frontmatter
{
"name": "diffdock",
"tags": [
"Molecular Docking",
"Drug Discovery",
"Deep Learning",
"Protein-Ligand"
],
"author": "Synthetic Sciences",
"license": "MIT license",
"version": "1.0.0",
"category": "chemistry",
"metadata": {
"skill-author": "Synthetic Sciences"
},
"description": "Diffusion-based molecular docking. Predict protein-ligand binding poses from PDB\/SMILES, confidence scores, virtual screening, for structure-based drug design. Not for affinity prediction.",
"dependencies": [
"torch>=1.12.0",
"fair-esm",
"torch-geometric",
"rdkit-pypi",
"biopython"
]
}
DiffDock: Molecular Docking with Diffusion Models
Overview
DiffDock is a diffusion-based deep learning tool for molecular docking that predicts 3D binding poses of small molecule ligands to protein targets. It represents the state-of-the-art in computational docking, crucial for structure-based drug discovery and chemical biology.
Core Capabilities:
- Predict ligand binding poses with high accuracy using deep learning
- Support protein structures (PDB files) or sequences (via ESMFold)
- Process single complexes or batch virtual screening campaigns
- Generate confidence scores to assess prediction reliability
- Handle diverse ligand inputs (SMILES, SDF, MOL2)
Key Distinction: DiffDock predicts binding poses (3D structure) and confidence (prediction certainty), NOT binding affinity (ΔG, Kd). Always combine with scoring functions (GNINA, MM/GBSA) for affinity assessment.
When to Use This Skill
This skill should be used when:
- "Dock this ligand to a protein" or "predict binding pose"
- "Run molecular docking" or "perform protein-ligand docking"
- "Virtual screening" or "screen compound library"
- "Where does this molecule bind?" or "predict binding site"
- Structure-based drug design or lead optimization tasks
- Tasks involving PDB files + SMILES strings or ligand structures
- Batch docking of multiple protein-ligand pairs
Related Skills
- molecular-docking: Full end-to-end pipeline including target prep, pocket detection, AutoDock Vina, scoring, and interaction analysis. Use when you need the complete workflow, not just DiffDock.
- denovo-design: For generating new molecules (not docking). Use diffdock afterwards to dock generated molecules.
Running DiffDock on Modal (Recommended for openscience)
Use Modal for on-demand GPU access without local GPU setup.
Prerequisites
# Verify Modal credentials (auto-injected by openscience)
[ -n "$MODAL_TOKEN_ID" ] && echo "MODAL_TOKEN_ID set" || echo "NOT SET"
[ -n "$MODAL_TOKEN_SECRET" ] && echo "MODAL_TOKEN_SECRET set" || echo "NOT SET"
If not set: connect Modal at https://app.syntheticsciences.ai -> Services, then restart openscience.
Modal DiffDock Wrapper
import modal
app = modal.App("diffdock")
diffdock_image = (
modal.Image.from_registry("rbgcsail/diffdock")
.pip_install("rdkit-pypi", "pandas", "biopython")
)
vol = modal.Volume.from_name("diffdock-results", create_if_missing=True)
@app.function(
image=diffdock_image,
gpu="A10G",
timeout=3600,
volumes={"/results": vol},
)
def dock(protein_path: str, ligand_smiles: str, samples: int = 10):
"""Run DiffDock docking on Modal GPU."""
import subprocess
cmd = [
"python", "-m", "inference",
"--config", "default_inference_args.yaml",
"--protein_path", protein_path,
"--ligand", ligand_smiles,
"--samples_per_complex", str(samples),
"--out_dir", "/results/docking_output/",
]
result = subprocess.run(cmd, capture_output=True, text=True)
vol.commit()
return {"stdout": result.stdout, "stderr": result.stderr, "returncode": result.returncode}
@app.function(
image=diffdock_image,
gpu="A10G",
timeout=7200,
volumes={"/results": vol},
)
def batch_dock(csv_path: str, samples: int = 10):
"""Run DiffDock batch docking on Modal GPU."""
import subprocess
cmd = [
"python", "-m", "inference",
"--config", "default_inference_args.yaml",
"--protein_ligand_csv", csv_path,
"--samples_per_complex", str(samples),
"--out_dir", "/results/batch_output/",
]
result = subprocess.run(cmd, capture_output=True, text=True)
vol.commit()
return {"stdout": result.stdout, "stderr": result.stderr, "returncode": result.returncode}
@app.local_entrypoint()
def main():
result = dock.remote("protein.pdb", "CC(=O)Oc1ccccc1C(=O)O", samples=10)
print(result)
GPU Selection
| Scenario | GPU | VRAM |
|---|---|---|
| Single docking (1 pair) | T4 or A10G | 16-24 GB |
| Batch docking (<50 complexes) | A10G | 24 GB |
| Large virtual screening (>100) | A100 40GB | 40 GB |
| Very large screening + embeddings | A100 80GB | 80 GB |
Cost Estimate
- Single docking: ~2-5 min on A10G = ~$0.04-0.09
- Batch of 50 compounds: ~30-60 min on A10G = ~$0.55-1.10
- Screen 1000 compounds: ~4-8 hrs on A100 = ~$13-27
CRITICAL: Present cost estimate to user before launching any GPU job.
Local Installation and Environment Setup
Check Environment Status
Before proceeding with DiffDock tasks, verify the environment setup:
# Use the provided setup checker
python scripts/setup_check.py
This script validates Python version, PyTorch with CUDA, PyTorch Geometric, RDKit, ESM, and other dependencies.
Installation Options
Option 1: Conda (Recommended)
git clone https://github.com/gcorso/DiffDock.git
cd DiffDock
conda env create --file environment.yml
conda activate diffdock
Option 2: Docker
docker pull rbgcsail/diffdock
docker run -it --gpus all --entrypoint /bin/bash rbgcsail/diffdock
micromamba activate diffdock
Important Notes:
- GPU strongly recommended (10-100x speedup vs CPU)
- First run pre-computes SO(2)/SO(3) lookup tables (~2-5 minutes)
- Model checkpoints (~500MB) download automatically if not present
Core Workflows
Workflow 1: Single Protein-Ligand Docking
Use Case: Dock one ligand to one protein target
Input Requirements:
- Protein: PDB file OR amino acid sequence
- Ligand: SMILES string OR structure file (SDF/MOL2)
Command:
python -m inference \
--config default_inference_args.yaml \
--protein_path protein.pdb \
--ligand "CC(=O)Oc1ccccc1C(=O)O" \
--out_dir results/single_docking/
Alternative (protein sequence):
python -m inference \
--config default_inference_args.yaml \
--protein_sequence "MSKGEELFTGVVPILVELDGDVNGHKF..." \
--ligand ligand.sdf \
--out_dir results/sequence_docking/
Output Structure:
results/single_docking/
├── rank_1.sdf # Top-ranked pose
├── rank_2.sdf # Second-ranked pose
├── ...
├── rank_10.sdf # 10th pose (default: 10 samples)
└── confidence_scores.txt
Workflow 2: Batch Processing Multiple Complexes
Use Case: Dock multiple ligands to proteins, virtual screening campaigns
Step 1: Prepare Batch CSV
Use the provided script to create or validate batch input:
# Create template
python scripts/prepare_batch_csv.py --create --output batch_input.csv
# Validate existing CSV
python scripts/prepare_batch_csv.py my_input.csv --validate
CSV Format:
complex_name,protein_path,ligand_description,protein_sequence
complex1,protein1.pdb,CC(=O)Oc1ccccc1C(=O)O,
complex2,,COc1ccc(C#N)cc1,MSKGEELFT...
complex3,protein3.pdb,ligand3.sdf,
Required Columns:
complex_name: Unique identifierprotein_path: PDB file path (leave empty if using sequence)ligand_description: SMILES string or ligand file pathprotein_sequence: Amino acid sequence (leave empty if using PDB)
Step 2: Run Batch Docking
python -m inference \
--config default_inference_args.yaml \
--protein_ligand_csv batch_input.csv \
--out_dir results/batch/ \
--batch_size 10
For Large Virtual Screening (>100 compounds):
Pre-compute protein embeddings for faster processing:
# Pre-compute embeddings
python datasets/esm_embedding_preparation.py \
--protein_ligand_csv screening_input.csv \
--out_file protein_embeddings.pt
# Run with pre-computed embeddings
python -m inference \
--config default_inference_args.yaml \
--protein_ligand_csv screening_input.csv \
--esm_embeddings_path protein_embeddings.pt \
--out_dir results/screening/
Workflow 3: Analyzing Results
After docking completes, analyze confidence scores and rank predictions:
# Analyze all results
python scripts/analyze_results.py results/batch/
# Show top 5 per complex
python scripts/analyze_results.py results/batch/ --top 5
# Filter by confidence threshold
python scripts/analyze_results.py results/batch/ --threshold 0.0
# Export to CSV
python scripts/analyze_results.py results/batch/ --export summary.csv
# Show top 20 predictions across all complexes
python scripts/analyze_results.py results/batch/ --best 20
The analysis script:
- Parses confidence scores from all predictions
- Classifies as High (>0), Moderate (-1.5 to 0), or Low (<-1.5)
- Ranks predictions within and across complexes
- Generates statistical summaries
- Exports results to CSV for downstream analysis
Confidence Score Interpretation
Understanding Scores:
| Score Range | Confidence Level | Interpretation |
|---|---|---|
| > 0 | High | Strong prediction, likely accurate |
| -1.5 to 0 | Moderate | Reasonable prediction, validate carefully |
| < -1.5 | Low | Uncertain prediction, requires validation |
Critical Notes:
- Confidence ≠ Affinity: High confidence means model certainty about structure, NOT strong binding
- Context Matters: Adjust expectations for:
- Large ligands (>500 Da): Lower confidence expected
- Multiple protein chains: May decrease confidence
- Novel protein families: May underperform
- Multiple Samples: Review top 3-5 predictions, look for consensus
For detailed guidance: Read references/confidence_and_limitations.md using the Read tool
Parameter Customization
Using Custom Configuration
Create custom configuration for specific use cases:
# Copy template
cp assets/custom_inference_config.yaml my_config.yaml
# Edit parameters (see template for presets)
# Then run with custom config
python -m inference \
--config my_config.yaml \
--protein_ligand_csv input.csv \
--out_dir results/
Key Parameters to Adjust
Sampling Density:
samples_per_complex: 10→ Increase to 20-40 for difficult cases- More samples = better coverage but longer runtime
Inference Steps:
inference_steps: 20→ Increase to 25-30 for higher accuracy- More steps = potentially better quality but slower
Temperature Parameters (control diversity):
temp_sampling_tor: 7.04→ Increase for flexible ligands (8-10)temp_sampling_tor: 7.04→ Decrease for rigid ligands (5-6)- Higher temperature = more diverse poses
Presets Available in Template:
- High Accuracy: More samples + steps, lower temperature
- Fast Screening: Fewer samples, faster
- Flexible Ligands: Increased torsion temperature
- Rigid Ligands: Decreased torsion temperature
For complete parameter reference: Read references/parameters_reference.md using the Read tool
Advanced Techniques
Ensemble Docking (Protein Flexibility)
For proteins with known flexibility, dock to multiple conformations:
# Create ensemble CSV
import pandas as pd
conformations = ["conf1.pdb", "conf2.pdb", "conf3.pdb"]
ligand = "CC(=O)Oc1ccccc1C(=O)O"
data = {
"complex_name": [f"ensemble_{i}" for i in range(len(conformations))],
"protein_path": conformations,
"ligand_description": [ligand] * len(conformations),
"protein_sequence": [""] * len(conformations)
}
pd.DataFrame(data).to_csv("ensemble_input.csv", index=False)
Run docking with increased sampling:
python -m inference \
--config default_inference_args.yaml \
--protein_ligand_csv ensemble_input.csv \
--samples_per_complex 20 \
--out_dir results/ensemble/
Integration with Scoring Functions
DiffDock generates poses; combine with other tools for affinity:
GNINA (Fast neural network scoring):
for pose in results/*.sdf; do
gnina -r protein.pdb -l "$pose" --score_only
done
MM/GBSA (More accurate, slower): Use AmberTools MMPBSA.py or gmx_MMPBSA after energy minimization
Free Energy Calculations (Most accurate): Use OpenMM + OpenFE or GROMACS for FEP/TI calculations
Recommended Workflow:
- DiffDock → Generate poses with confidence scores
- Visual inspection → Check structural plausibility
- GNINA or MM/GBSA → Rescore and rank by affinity
- Experimental validation → Biochemical assays
Limitations and Scope
DiffDock IS Designed For:
- Small molecule ligands (typically 100-1000 Da)
- Drug-like organic compounds
- Small peptides (<20 residues)
- Single or multi-chain proteins
DiffDock IS NOT Designed For:
- Large biomolecules (protein-protein docking) → Use DiffDock-PP or AlphaFold-Multimer
- Large peptides (>20 residues) → Use alternative methods
- Covalent docking → Use specialized covalent docking tools
- Binding affinity prediction → Combine with scoring functions
- Membrane proteins → Not specifically trained, use with caution
For complete limitations: Read references/confidence_and_limitations.md using the Read tool
Troubleshooting
Common Issues
Issue: Low confidence scores across all predictions
- Cause: Large/unusual ligands, unclear binding site, protein flexibility
- Solution: Increase
samples_per_complex(20-40), try ensemble docking, validate protein structure
Issue: Out of memory errors
- Cause: GPU memory insufficient for batch size
- Solution: Reduce
--batch_size 2or process fewer complexes at once
Issue: Slow performance
- Cause: Running on CPU instead of GPU
- Solution: Verify CUDA with
python -c "import torch; print(torch.cuda.is_available())", use GPU
Issue: Unrealistic binding poses
- Cause: Poor protein preparation, ligand too large, wrong binding site
- Solution: Check protein for missing residues, remove far waters, consider specifying binding site
Issue: "Module not found" errors
- Cause: Missing dependencies or wrong environment
- Solution: Run
python scripts/setup_check.pyto diagnose
Performance Optimization
For Best Results:
- Use GPU (essential for practical use)
- Pre-compute ESM embeddings for repeated protein use
- Batch process multiple complexes together
- Start with default parameters, then tune if needed
- Validate protein structures (resolve missing residues)
- Use canonical SMILES for ligands
Graphical User Interface
For interactive use, launch the web interface:
python app/main.py
# Navigate to http://localhost:7860
Or use the online demo without installation:
Resources
Helper Scripts (scripts/)
prepare_batch_csv.py: Create and validate batch input CSV files
- Create templates with example entries
- Validate file paths and SMILES strings
- Check for required columns and format issues
analyze_results.py: Analyze confidence scores and rank predictions
- Parse results from single or batch runs
- Generate statistical summaries
- Export to CSV for downstream analysis
- Identify top predictions across complexes
setup_check.py: Verify DiffDock environment setup
- Check Python version and dependencies
- Verify PyTorch and CUDA availability
- Test RDKit and PyTorch Geometric installation
- Provide installation instructions if needed
Reference Documentation (references/)
parameters_reference.md: Complete parameter documentation
- All command-line options and configuration parameters
- Default values and acceptable ranges
- Temperature parameters for controlling diversity
- Model checkpoint locations and version flags
Read this file when users need:
- Detailed parameter explanations
- Fine-tuning guidance for specific systems
- Alternative sampling strategies
confidence_and_limitations.md: Confidence score interpretation and tool limitations
- Detailed confidence score interpretation
- When to trust predictions
- Scope and limitations of DiffDock
- Integration with complementary tools
- Troubleshooting prediction quality
Read this file when users need:
- Help interpreting confidence scores
- Understanding when NOT to use DiffDock
- Guidance on combining with other tools
- Validation strategies
workflows_examples.md: Comprehensive workflow examples
- Detailed installation instructions
- Step-by-step examples for all workflows
- Advanced integration patterns
- Troubleshooting common issues
- Best practices and optimization tips
Read this file when users need:
- Complete workflow examples with code
- Integration with GNINA, OpenMM, or other tools
- Virtual screening workflows
- Ensemble docking procedures
Assets (assets/)
batch_template.csv: Template for batch processing
- Pre-formatted CSV with required columns
- Example entries showing different input types
- Ready to customize with actual data
custom_inference_config.yaml: Configuration template
- Annotated YAML with all parameters
- Four preset configurations for common use cases
- Detailed comments explaining each parameter
- Ready to customize and use
Best Practices
- Always verify environment with
setup_check.pybefore starting large jobs - Validate batch CSVs with
prepare_batch_csv.pyto catch errors early - Start with defaults then tune parameters based on system-specific needs
- Generate multiple samples (10-40) for robust predictions
- Visual inspection of top poses before downstream analysis
- Combine with scoring functions for affinity assessment
- Use confidence scores for initial ranking, not final decisions
- Pre-compute embeddings for virtual screening campaigns
- Document parameters used for reproducibility
- Validate results experimentally when possible
Citations
When using DiffDock, cite the appropriate papers:
DiffDock-L (current default model):
Stärk et al. (2024) "DiffDock-L: Improving Molecular Docking with Diffusion Models"
arXiv:2402.18396
Original DiffDock:
Corso et al. (2023) "DiffDock: Diffusion Steps, Twists, and Turns for Molecular Docking"
ICLR 2023, arXiv:2210.01776
Additional Resources
- GitHub Repository: https://github.com/gcorso/DiffDock
- Online Demo: https://huggingface.co/spaces/reginabarzilaygroup/DiffDock-Web
- DiffDock-L Paper: https://arxiv.org/abs/2402.18396
- Original Paper: https://arxiv.org/abs/2210.01776
Version History
- e9844a4 Current 2026-07-11 17:21
Dependencies
-
required
torch>=1.12.0 -
required
fair-esm -
required
torch-geometric -
required
rdkit-pypi - required biopython


