Molfeat - Molecular Featurization Hub
Overview
Molfeat is a comprehensive Python library for molecular featurization that unifies 100+ pre-trained embeddings and hand-crafted featurizers. Convert chemical structures (SMILES strings or RDKit molecules) into numerical representations for machine learning tasks including QSAR modeling, virtual screening, similarity searching, and deep learning applications. Features fast parallel processing, scikit-learn compatible transformers, and built-in caching.
When to Use This Skill
This skill should be used when working with:
- Molecular machine learning: Building QSAR/QSPR models, property prediction
- Virtual screening: Ranking compound libraries for biological activity
- Similarity searching: Finding structurally similar molecules
- Chemical space analysis: Clustering, visualization, dimensionality reduction
- Deep learning: Training neural networks on molecular data
- Featurization pipelines: Converting SMILES to ML-ready representations
- Cheminformatics: Any task requiring molecular feature extraction
Installation
uv pip install molfeat
# With all optional dependencies
uv pip install "molfeat[all]"
Optional dependencies for specific featurizers:
molfeat[dgl]- GNN models (GIN variants)molfeat[graphormer]- Graphormer modelsmolfeat[transformer]- ChemBERTa, ChemGPT, MolT5molfeat[fcd]- FCD descriptorsmolfeat[map4]- MAP4 fingerprints
Core Concepts
Molfeat organizes featurization into three hierarchical classes:
1. Calculators (molfeat.calc)
Callable objects that convert individual molecules into feature vectors. Accept RDKit Chem.Mol objects or SMILES strings.
Use calculators for:
- Single molecule featurization
- Custom processing loops
- Direct feature computation
Example:
from molfeat.calc import FPCalculator
calc = FPCalculator("ecfp", radius=3, fpSize=2048)
features = calc("CCO") # Returns numpy array (2048,)
2. Transformers (molfeat.trans)
Scikit-learn compatible transformers that wrap calculators for batch processing with parallelization.
Use transformers for:
- Batch featurization of molecular datasets
- Integration with scikit-learn pipelines
- Parallel processing (automatic CPU utilization)
Example:
from molfeat.trans import MoleculeTransformer
from molfeat.calc import FPCalculator
transformer = MoleculeTransformer(FPCalculator("ecfp"), n_jobs=-1)
features = transformer(smiles_list) # Parallel processing
3. Pretrained Transformers (molfeat.trans.pretrained)
Specialized transformers for deep learning models with batched inference and caching.
Use pretrained transformers for:
- State-of-the-art molecular embeddings
- Transfer learning from large chemical datasets
- Deep learning feature extraction
Example:
from molfeat.trans.pretrained import PretrainedMolTransformer
transformer = PretrainedMolTransformer("ChemBERTa-77M-MLM", n_jobs=-1)
embeddings = transformer(smiles_list) # Deep learning embeddings
Quick Start Workflow
Basic Featurization
import datamol as dm
from molfeat.calc import FPCalculator
from molfeat.trans import MoleculeTransformer
# Load molecular data
smiles = ["CCO", "CC(=O)O", "c1ccccc1", "CC(C)O"]
# Create calculator and transformer
calc = FPCalculator("ecfp", radius=3)
transformer = MoleculeTransformer(calc, n_jobs=-1)
# Featurize molecules
features = transformer(smiles)
print(f"Shape: {features.shape}") # (4, 2048)
Save and Load Configuration
# Save featurizer configuration for reproducibility
transformer.to_state_yaml_file("featurizer_config.yml")
# Reload exact configuration
loaded = MoleculeTransformer.from_state_yaml_file("featurizer_config.yml")
Handle Errors Gracefully
# Process dataset with potentially invalid SMILES
transformer = MoleculeTransformer(
calc,
n_jobs=-1,
ignore_errors=True, # Continue on failures
verbose=True # Log error details
)
features = transformer(smiles_with_errors)
# Returns None for failed molecules
Choosing the Right Featurizer
For Traditional Machine Learning (RF, SVM, XGBoost)
Start with fingerprints:
# ECFP - Most popular, general-purpose
FPCalculator("ecfp", radius=3, fpSize=2048)
# MACCS - Fast, good for scaffold hopping
FPCalculator("maccs")
# MAP4 - Efficient for large-scale screening
FPCalculator("map4")
For interpretable models:
# RDKit 2D descriptors (200+ named properties)
from molfeat.calc import RDKitDescriptors2D
RDKitDescriptors2D()
# Mordred (1800+ comprehensive descriptors)
from molfeat.calc import MordredDescriptors
MordredDescriptors()
Combine multiple featurizers:
from molfeat.trans import FeatConcat
concat = FeatConcat([
FPCalculator("maccs"), # 167 dimensions
FPCalculator("ecfp") # 2048 dimensions
]) # Result: 2215-dimensional combined features
For Deep Learning
Transformer-based embeddings:
# ChemBERTa - Pre-trained on 77M PubChem compounds
PretrainedMolTransformer("ChemBERTa-77M-MLM")
# ChemGPT - Autoregressive language model
PretrainedMolTransformer("ChemGPT-1.2B")
Graph neural networks:
# GIN models with different pre-training objectives
PretrainedMolTransformer("gin-supervised-masking")
PretrainedMolTransformer("gin-supervised-infomax")
# Graphormer for quantum chemistry
PretrainedMolTransformer("Graphormer-pcqm4mv2")
For Similarity Searching
# ECFP - General purpose, most widely used
FPCalculator("ecfp")
# MACCS - Fast, scaffold-based similarity
FPCalculator("maccs")
# MAP4 - Efficient for large databases
FPCalculator("map4")
# USR/USRCAT - 3D shape similarity
from molfeat.calc import USRDescriptors
USRDescriptors()
For Pharmacophore-Based Approaches
# FCFP - Functional group based
FPCalculator("fcfp")
# CATS - Pharmacophore pair distributions
from molfeat.calc import CATSCalculator
CATSCalculator(mode="2D")
# Gobbi - Explicit pharmacophore features
FPCalculator("gobbi2D")
Common Workflows
Building a QSAR Model
from molfeat.trans import MoleculeTransformer
from molfeat.calc import FPCalculator
from sklearn.ensemble import RandomForestRegressor
from sklearn.model_selection import cross_val_score
# Featurize molecules
transformer = MoleculeTransformer(FPCalculator("ecfp"), n_jobs=-1)
X = transformer(smiles_train)
# Train model
model = RandomForestRegressor(n_estimators=100)
scores = cross_val_score(model, X, y_train, cv=5)
print(f"R² = {scores.mean():.3f}")
# Save configuration for deployment
transformer.to_state_yaml_file("production_featurizer.yml")
Virtual Screening Pipeline
from sklearn.ensemble import RandomForestClassifier
# Train on known actives/inactives
transformer = MoleculeTransformer(FPCalculator("ecfp"), n_jobs=-1)
X_train = transformer(train_smiles)
clf = RandomForestClassifier(n_estimators=500)
clf.fit(X_train, train_labels)
# Screen large library
X_screen = transformer(screening_library) # e.g., 1M compounds
predictions = clf.predict_proba(X_screen)[:, 1]
# Rank and select top hits
top_indices = predictions.argsort()[::-1][:1000]
top_hits = [screening_library[i] for i in top_indices]
Similarity Search
from sklearn.metrics.pairwise import cosine_similarity
# Query molecule
calc = FPCalculator("ecfp")
query_fp = calc(query_smiles).reshape(1, -1)
# Database fingerprints
transformer = MoleculeTransformer(calc, n_jobs=-1)
database_fps = transformer(database_smiles)
# Compute similarity
similarities = cosine_similarity(query_fp, database_fps)[0]
top_similar = similarities.argsort()[-10:][::-1]
Scikit-learn Pipeline Integration
from sklearn.pipeline import Pipeline
from sklearn.ensemble import RandomForestClassifier
# Create end-to-end pipeline
pipeline = Pip