--- name: deepchem description: "Molecular machine learning toolkit. Property prediction (ADMET, toxicity), GNNs (GCN, MPNN), MoleculeNet benchmarks, pretrained models, featurization, for drug discovery ML." --- # DeepChem ## Overview DeepChem is a comprehensive Python library for applying machine learning to chemistry, materials science, and biology. Enable molecular property prediction, drug discovery, materials design, and biomolecule analysis through specialized neural networks, molecular featurization methods, and pretrained models. ## When to Use This Skill This skill should be used when: - Loading and processing molecular data (SMILES strings, SDF files, protein sequences) - Predicting molecular properties (solubility, toxicity, binding affinity, ADMET properties) - Training models on chemical/biological datasets - Using MoleculeNet benchmark datasets (Tox21, BBBP, Delaney, etc.) - Converting molecules to ML-ready features (fingerprints, graph representations, descriptors) - Implementing graph neural networks for molecules (GCN, GAT, MPNN, AttentiveFP) - Applying transfer learning with pretrained models (ChemBERTa, GROVER, MolFormer) - Predicting crystal/materials properties (bandgap, formation energy) - Analyzing protein or DNA sequences ## Core Capabilities ### 1. Molecular Data Loading and Processing DeepChem provides specialized loaders for various chemical data formats: ```python import deepchem as dc # Load CSV with SMILES featurizer = dc.feat.CircularFingerprint(radius=2, size=2048) loader = dc.data.CSVLoader( tasks=['solubility', 'toxicity'], feature_field='smiles', featurizer=featurizer ) dataset = loader.create_dataset('molecules.csv') # Load SDF files loader = dc.data.SDFLoader(tasks=['activity'], featurizer=featurizer) dataset = loader.create_dataset('compounds.sdf') # Load protein sequences loader = dc.data.FASTALoader() dataset = loader.create_dataset('proteins.fasta') ``` **Key Loaders**: - `CSVLoader`: Tabular data with molecular identifiers - `SDFLoader`: Molecular structure files - `FASTALoader`: Protein/DNA sequences - `ImageLoader`: Molecular images - `JsonLoader`: JSON-formatted datasets ### 2. Molecular Featurization Convert molecules into numerical representations for ML models. #### Decision Tree for Featurizer Selection ``` Is the model a graph neural network? ├─ YES → Use graph featurizers │ ├─ Standard GNN → MolGraphConvFeaturizer │ ├─ Message passing → DMPNNFeaturizer │ └─ Pretrained → GroverFeaturizer │ └─ NO → What type of model? ├─ Traditional ML (RF, XGBoost, SVM) │ ├─ Fast baseline → CircularFingerprint (ECFP) │ ├─ Interpretable → RDKitDescriptors │ └─ Maximum coverage → MordredDescriptors │ ├─ Deep learning (non-graph) │ ├─ Dense networks → CircularFingerprint │ └─ CNN → SmilesToImage │ ├─ Sequence models (LSTM, Transformer) │ └─ SmilesToSeq │ └─ 3D structure analysis └─ CoulombMatrix ``` #### Example Featurization ```python # Fingerprints (for traditional ML) fp = dc.feat.CircularFingerprint(radius=2, size=2048) # Descriptors (for interpretable models) desc = dc.feat.RDKitDescriptors() # Graph features (for GNNs) graph_feat = dc.feat.MolGraphConvFeaturizer() # Apply featurization features = fp.featurize(['CCO', 'c1ccccc1']) ``` **Selection Guide**: - **Small datasets (<1K)**: CircularFingerprint or RDKitDescriptors - **Medium datasets (1K-100K)**: CircularFingerprint or graph featurizers - **Large datasets (>100K)**: Graph featurizers (MolGraphConvFeaturizer, DMPNNFeaturizer) - **Transfer learning**: Pretrained model featurizers (GroverFeaturizer) See `references/api_reference.md` for complete featurizer documentation. ### 3. Data Splitting **Critical**: For drug discovery tasks, use `ScaffoldSplitter` to prevent data leakage from similar molecular structures appearing in both training and test sets. ```python # Scaffold splitting (recommended for molecules) splitter = dc.splits.ScaffoldSplitter() train, valid, test = splitter.train_valid_test_split( dataset, frac_train=0.8, frac_valid=0.1, frac_test=0.1 ) # Random splitting (for non-molecular data) splitter = dc.splits.RandomSplitter() train, test = splitter.train_test_split(dataset) # Stratified splitting (for imbalanced classification) splitter = dc.splits.RandomStratifiedSplitter() train, test = splitter.train_test_split(dataset) ``` **Available Splitters**: - `ScaffoldSplitter`: Split by molecular scaffolds (prevents leakage) - `ButinaSplitter`: Clustering-based molecular splitting - `MaxMinSplitter`: Maximize diversity between sets - `RandomSplitter`: Random splitting - `RandomStratifiedSplitter`: Preserves class distributions ### 4. Model Selection and Training #### Quick Model Selection Guide | Dataset Size | Task | Recommended Model | Featurizer | |-------------|------|-------------------|------------| | < 1K samples | Any | SklearnModel (RandomForest) | CircularFingerprint | | 1K-100K | Classification/Regression | GBDTModel or MultitaskRegressor | CircularFingerprint | | > 100K | Molecular properties | GCNModel, AttentiveFPModel, DMPNNModel | MolGraphConvFeaturizer | | Any (small preferred) | Transfer learning | ChemBERTa, GROVER, MolFormer | Model-specific | | Crystal structures | Materials properties | CGCNNModel, MEGNetModel | Structure-based | | Protein sequences | Protein properties | ProtBERT | Sequence-based | #### Example: Traditional ML ```python from sklearn.ensemble import RandomForestRegressor # Wrap scikit-learn model sklearn_model = RandomForestRegressor(n_estimators=100) model = dc.models.SklearnModel(model=sklearn_model) model.fit(train) ``` #### Example: Deep Learning ```python # Multitask regressor (for fingerprints) model = dc.models.MultitaskRegressor( n_tasks=2, n_features=2048, layer_sizes=[1000, 500], dropouts=0.25, learning_rate=0.001 ) model.fit(train, nb_epoch=50) ``` #### Example: Graph Neural Networks ```python # Graph Convolutional Network model = dc.models.GCNModel( n_tasks=1, mode='regression', batch_size=128, learning_rate=0.001 ) model.fit(train, nb_epoch=50) # Graph Attention Network model = dc.models.GATModel(n_tasks=1, mode='classification') model.fit(train, nb_epoch=50) # Attentive Fingerprint model = dc.models.AttentiveFPModel(n_tasks=1, mode='regression') model.fit(train, nb_epoch=50) ``` ### 5. MoleculeNet Benchmarks Quick access to 30+ curated benchmark datasets with standardized train/valid/test splits: ```python # Load benchmark dataset tasks, datasets, transformers = dc.molnet.load_tox21( featurizer='GraphConv', # or 'ECFP', 'Weave', 'Raw' splitter='scaffold', # or 'random', 'stratified' reload=False ) train, valid, test = datasets # Train and evaluate model = dc.models.GCNModel(n_tasks=len(tasks), mode='classification') model.fit(train, nb_epoch=50) metric = dc.metrics.Metric(dc.metrics.roc_auc_score) test_score = model.evaluate(test, [metric]) ``` **Common Datasets**: - **Classification**: `load_tox21()`, `load_bbbp()`, `load_hiv()`, `load_clintox()` - **Regression**: `load_delaney()`, `load_freesolv()`, `load_lipo()` - **Quantum properties**: `load_qm7()`, `load_qm8()`, `load_qm9()` - **Materials**: `load_perovskite()`, `load_bandgap()`, `load_mp_formation_energy()` See `references/api_reference.md` for complete dataset list. ### 6. Transfer Learning Leverage pretrained models for improved performance, especially on small datasets: ```python # ChemBERTa (BERT pretrained on 77M molecules) model = dc.models.HuggingFaceModel( model='seyonec/ChemBERTa-zinc-base-v1', task='classification', n_tasks=1, learning_rate=2e-5 # Lower LR for fine-tuning ) model.fit(train, nb_epoch=10) # GROVER (graph transformer pretrained on 10M molecules) model = dc.models.GroverModel( task='regression', n_tasks=1 ) model.fit(train, nb_epoch=20) ``` **When to use transfer learning**: - Small datasets (< 1000 samples) - Novel molecular scaffolds - Limited computational resources - Need for rapid prototyping Use the `scripts/transfer_learning.py` script for guided transfer learning workflows. ### 7. Model Evaluation ```python # Define metrics classification_metrics = [ dc.metrics.Metric(dc.metrics.roc_auc_score, name='ROC-AUC'), dc.metrics.Metric(dc.metrics.accuracy_score, name='Accuracy'), dc.metrics.Metric(dc.metrics.f1_score, name='F1') ] regression_metrics = [ dc.metrics.Metric(dc.metrics.r2_score, name='R²'), dc.metrics.Metric(dc.metrics.mean_absolute_error, name='MAE'), dc.metrics.Metric(dc.metrics.root_mean_squared_error, name='RMSE') ] # Evaluate train_scores = model.evaluate(train, classification_metrics) test_scores = model.evaluate(test, classification_metrics) ``` ### 8. Making Predictions ```python # Predict on test set predictions = model.predict(test) # Predict on new molecules new_smiles = ['CCO', 'c1ccccc1', 'CC(C)O'] new_features = featurizer.featurize(new_smiles) new_dataset = dc.data.NumpyDataset(X=new_features) # Apply same transformations as training for transformer in transformers: new_dataset = transformer.transform(new_dataset) predictions = model.predict(new_dataset) ``` ## Typical Workflows ### Workflow A: Quick Benchmark Evaluation For evaluating a model on standard benchmarks: ```python import deepchem as dc # 1. Load benchmark tasks, datasets, _ = dc.molnet.load_bbbp( featurizer='GraphConv', splitter='scaffold' ) train, valid, test = datasets # 2. Train model model = dc.models.GCNModel(n_tasks=len(tasks), mode='classification') model.fit(train, nb_epoch=50) # 3. Evaluate metric = dc.metrics.Metric(dc.metrics.roc_auc_score) test_score = model.evaluate(test, [metric]) print(f"Test ROC-AUC: {test_score}") ``` ### Workflow B: Custom Data Prediction For training on custom molecular datasets: ```python import deepchem as dc # 1. Load and featurize data featurizer = dc.feat.CircularFingerprint(radius=2, size=2048) loader = dc.data.CSVLoader( tasks=['activity'], feature_field='smiles', featurizer=featurizer ) dataset = loader.create_dataset('my_molecules.csv') # 2. Split data (use ScaffoldSplitter for molecules!) splitter = dc.splits.ScaffoldSplitter() train, valid, test = splitter.train_valid_test_split(dataset) # 3. Normalize (optional but recommended) transformers = [dc.trans.NormalizationTransformer( transform_y=True, dataset=train )] for transformer in transformers: train = transformer.transform(train) valid = transformer.transform(valid) test = transformer.transform(test) # 4. Train model model = dc.models.MultitaskRegressor( n_tasks=1, n_features=2048, layer_sizes=[1000, 500], dropouts=0.25 ) model.fit(train, nb_epoch=50) # 5. Evaluate metric = dc.metrics.Metric(dc.metrics.r2_score) test_score = model.evaluate(test, [metric]) ``` ### Workflow C: Transfer Learning on Small Dataset For leveraging pretrained models: ```python import deepchem as dc # 1. Load data (pretrained models often need raw SMILES) loader = dc.data.CSVLoader( tasks=['activity'], feature_field='smiles', featurizer=dc.feat.DummyFeaturizer() # Model handles featurization ) dataset = loader.create_dataset('small_dataset.csv') # 2. Split data splitter = dc.splits.ScaffoldSplitter() train, test = splitter.train_test_split(dataset) # 3. Load pretrained model model = dc.models.HuggingFaceModel( model='seyonec/ChemBERTa-zinc-base-v1', task='classification', n_tasks=1, learning_rate=2e-5 ) # 4. Fine-tune model.fit(train, nb_epoch=10) # 5. Evaluate predictions = model.predict(test) ``` See `references/workflows.md` for 8 detailed workflow examples covering molecular generation, materials science, protein analysis, and more. ## Example Scripts This skill includes three production-ready scripts in the `scripts/` directory: ### 1. `predict_solubility.py` Train and evaluate solubility prediction models. Works with Delaney benchmark or custom CSV data. ```bash # Use Delaney benchmark python scripts/predict_solubility.py # Use custom data python scripts/predict_solubility.py \ --data my_data.csv \ --smiles-col smiles \ --target-col solubility \ --predict "CCO" "c1ccccc1" ``` ### 2. `graph_neural_network.py` Train various graph neural network architectures on molecular data. ```bash # Train GCN on Tox21 python scripts/graph_neural_network.py --model gcn --dataset tox21 # Train AttentiveFP on custom data python scripts/graph_neural_network.py \ --model attentivefp \ --data molecules.csv \ --task-type regression \ --targets activity \ --epochs 100 ``` ### 3. `transfer_learning.py` Fine-tune pretrained models (ChemBERTa, GROVER) on molecular property prediction tasks. ```bash # Fine-tune ChemBERTa on BBBP python scripts/transfer_learning.py --model chemberta --dataset bbbp # Fine-tune GROVER on custom data python scripts/transfer_learning.py \ --model grover \ --data small_dataset.csv \ --target activity \ --task-type classification \ --epochs 20 ``` ## Common Patterns and Best Practices ### Pattern 1: Always Use Scaffold Splitting for Molecules ```python # GOOD: Prevents data leakage splitter = dc.splits.ScaffoldSplitter() train, test = splitter.train_test_split(dataset) # BAD: Similar molecules in train and test splitter = dc.splits.RandomSplitter() train, test = splitter.train_test_split(dataset) ``` ### Pattern 2: Normalize Features and Targets ```python transformers = [ dc.trans.NormalizationTransformer( transform_y=True, # Also normalize target values dataset=train ) ] for transformer in transformers: train = transformer.transform(train) test = transformer.transform(test) ``` ### Pattern 3: Start Simple, Then Scale 1. Start with Random Forest + CircularFingerprint (fast baseline) 2. Try XGBoost/LightGBM if RF works well 3. Move to deep learning (MultitaskRegressor) if you have >5K samples 4. Try GNNs if you have >10K samples 5. Use transfer learning for small datasets or novel scaffolds ### Pattern 4: Handle Imbalanced Data ```python # Option 1: Balancing transformer transformer = dc.trans.BalancingTransformer(dataset=train) train = transformer.transform(train) # Option 2: Use balanced metrics metric = dc.metrics.Metric(dc.metrics.balanced_accuracy_score) ``` ### Pattern 5: Avoid Memory Issues ```python # Use DiskDataset for large datasets dataset = dc.data.DiskDataset.from_numpy(X, y, w, ids) # Use smaller batch sizes model = dc.models.GCNModel(batch_size=32) # Instead of 128 ``` ## Common Pitfalls ### Issue 1: Data Leakage in Drug Discovery **Problem**: Using random splitting allows similar molecules in train/test sets. **Solution**: Always use `ScaffoldSplitter` for molecular datasets. ### Issue 2: GNN Underperforming vs Fingerprints **Problem**: Graph neural networks perform worse than simple fingerprints. **Solutions**: - Ensure dataset is large enough (>10K samples typically) - Increase training epochs (50-100) - Try different architectures (AttentiveFP, DMPNN instead of GCN) - Use pretrained models (GROVER) ### Issue 3: Overfitting on Small Datasets **Problem**: Model memorizes training data. **Solutions**: - Use stronger regularization (increase dropout to 0.5) - Use simpler models (Random Forest instead of deep learning) - Apply transfer learning (ChemBERTa, GROVER) - Collect more data ### Issue 4: Import Errors **Problem**: Module not found errors. **Solution**: Ensure DeepChem is installed with required dependencies: ```bash pip install deepchem # For PyTorch models pip install deepchem[torch] # For all features pip install deepchem[all] ``` ## Reference Documentation This skill includes comprehensive reference documentation: ### `references/api_reference.md` Complete API documentation including: - All data loaders and their use cases - Dataset classes and when to use each - Complete featurizer catalog with selection guide - Model catalog organized by category (50+ models) - MoleculeNet dataset descriptions - Metrics and evaluation functions - Common code patterns **When to reference**: Search this file when you need specific API details, parameter names, or want to explore available options. ### `references/workflows.md` Eight detailed end-to-end workflows: 1. Molecular property prediction from SMILES 2. Using MoleculeNet benchmarks 3. Hyperparameter optimization 4. Transfer learning with pretrained models 5. Molecular generation with GANs 6. Materials property prediction 7. Protein sequence analysis 8. Custom model integration **When to reference**: Use these workflows as templates for implementing complete solutions. ## Installation Notes Basic installation: ```bash pip install deepchem ``` For PyTorch models (GCN, GAT, etc.): ```bash pip install deepchem[torch] ``` For all features: ```bash pip install deepchem[all] ``` If import errors occur, the user may need specific dependencies. Check the DeepChem documentation for detailed installation instructions. ## Additional Resources - Official documentation: https://deepchem.readthedocs.io/ - GitHub repository: https://github.com/deepchem/deepchem - Tutorials: https://deepchem.readthedocs.io/en/latest/get_started/tutorials.html - Paper: "MoleculeNet: A Benchmark for Molecular Machine Learning"