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torchdrug

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PyTorch-native graph neural networks for molecules and proteins. Use when building custom GNN architectures for drug discovery, protein modeling, or knowledge g

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TorchDrug

Overview

TorchDrug is a comprehensive PyTorch-based machine learning toolbox for drug discovery and molecular science. Apply graph neural networks, pre-trained models, and task definitions to molecules, proteins, and biological knowledge graphs, including molecular property prediction, protein modeling, knowledge graph reasoning, molecular generation, retrosynthesis planning, with 40+ curated datasets and 20+ model architectures.

When to Use This Skill

This skill should be used when working with:

Data Types:

  • SMILES strings or molecular structures
  • Protein sequences or 3D structures (PDB files)
  • Chemical reactions and retrosynthesis
  • Biomedical knowledge graphs
  • Drug discovery datasets

Tasks:

  • Predicting molecular properties (solubility, toxicity, activity)
  • Protein function or structure prediction
  • Drug-target binding prediction
  • Generating new molecular structures
  • Planning chemical synthesis routes
  • Link prediction in biomedical knowledge bases
  • Training graph neural networks on scientific data

Libraries and Integration:

  • TorchDrug is the primary library
  • Often used with RDKit for cheminformatics
  • Compatible with PyTorch and PyTorch Lightning
  • Integrates with AlphaFold and ESM for proteins

Getting Started

Installation

TorchDrug 0.2.1 (latest on PyPI, July 2023) requires Python 3.7–3.10 and PyTorch 1.8–2.0. Install PyTorch and torch-scatter / torch-cluster first (wheel URL depends on your PyTorch and CUDA versions — see installation docs).

uv pip install torch
# Match torch/CUDA in the URL, e.g. torch-2.0.0+cu118 or cpu
uv pip install torch-scatter torch-cluster -f https://pytorch-geometric.com/whl/torch-2.0.0+cu118.html
uv pip install torchdrug==0.2.1

On Apple Silicon, compile scatter/cluster from source; TorchDrug runs on CPU only (no MPS). Conda: conda install torchdrug -c milagraph -c conda-forge -c pytorch -c pyg.

Quick Example

import torch
from torchdrug import datasets, models, tasks
from torch.utils.data import DataLoader

# Load molecular dataset
dataset = datasets.BBBP("~/molecule-datasets/")
train_set, valid_set, test_set = dataset.split()

# Define GNN model
model = models.GIN(
    input_dim=dataset.node_feature_dim,
    hidden_dims=[256, 256, 256],
    edge_input_dim=dataset.edge_feature_dim,
    batch_norm=True,
    readout="mean"
)

# Create property prediction task
task = tasks.PropertyPrediction(
    model,
    task=dataset.tasks,
    criterion="bce",
    metric=["auroc", "auprc"]
)

# Train with PyTorch
optimizer = torch.optim.Adam(task.parameters(), lr=1e-3)
train_loader = DataLoader(train_set, batch_size=32, shuffle=True)

for epoch in range(100):
    for batch in train_loader:
        loss = task(batch)
        optimizer.zero_grad()
        loss.backward()
        optimizer.step()

Core Capabilities

1. Molecular Property Prediction

Predict chemical, physical, and biological properties of molecules from structure.

Use Cases:

  • Drug-likeness and ADMET properties
  • Toxicity screening
  • Quantum chemistry properties
  • Binding affinity prediction

Key Components:

  • 20+ molecular datasets (BBBP, HIV, Tox21, QM9, etc.)
  • GNN models (GIN, GAT, SchNet)
  • PropertyPrediction and MultipleBinaryClassification tasks

Reference: See references/molecular_property_prediction.md for:

  • Complete dataset catalog
  • Model selection guide
  • Training workflows and best practices
  • Feature engineering details

2. Protein Modeling

Work with protein sequences, structures, and properties.

Use Cases:

  • Enzyme function prediction
  • Protein stability and solubility
  • Subcellular localization
  • Protein-protein interactions
  • Structure prediction

Key Components:

  • 15+ protein datasets (EnzymeCommission, GeneOntology, PDBBind, etc.)
  • Sequence models (ESM, ProteinBERT, ProteinLSTM)
  • Structure models (GearNet, SchNet)
  • Multiple task types for different prediction levels

Reference: See references/protein_modeling.md for:

  • Protein-specific datasets
  • Sequence vs structure models
  • Pre-training strategies
  • Integration with AlphaFold and ESM

3. Knowledge Graph Reasoning

Predict missing links and relationships in biological knowledge graphs.

Use Cases:

  • Drug repurposing
  • Disease mechanism discovery
  • Gene-disease associations
  • Multi-hop biomedical reasoning

Key Components:

  • General KGs (FB15k, WN18) and biomedical (Hetionet)
  • Embedding models (TransE, RotatE, ComplEx)
  • KnowledgeGraphCompletion task

Reference: See references/knowledge_graphs.md for:

  • Knowledge graph datasets (including Hetionet with 45k biomedical entities)
  • Embedding model comparison
  • Evaluation metrics and protocols
  • Biomedical applications

4. Molecular Generation

Generate novel molecular structures with desired properties.

Use Cases:

  • De novo drug design
  • Lead optimization
  • Chemical space exploration
  • Property-guided generation

Key Components:

  • Autoregressive generation
  • GCPN (policy-based generation)
  • GraphAutoregressiveFlow
  • Property optimization workflows

Reference: See references/molecular_generation.md for:

  • Generation strategies (unconditional, conditional, scaffold-based)
  • Multi-objective optimization
  • Validation and filtering
  • Integration with property prediction

5. Retrosynthesis

Predict synthetic routes from target molecules to starting materials.

Use Cases:

  • Synthesis planning
  • Route optimization
  • Synthetic accessibility assessment
  • Multi-step planning

Key Components:

  • USPTO-50k reaction dataset
  • CenterIdentification (reaction center prediction)
  • SynthonCompletion (reactant prediction)
  • End-to-end Retrosynthesis pipeline

Reference: See references/retrosynthesis.md for:

  • Task decomposition (center ID → synthon completion)
  • Multi-step synthesis planning
  • Commercial availability checking
  • Integration with other retrosynthesis tools

6. Graph Neural Network Models

Comprehensive catalog of GNN architectures for different data types and tasks.

Available Models:

  • General GNNs: GCN, GAT, GIN, RGCN, MPNN
  • 3D-aware: SchNet, GearNet
  • Protein-specific: ESM, ProteinBERT, GearNet
  • Knowledge graph: TransE, RotatE, ComplEx, SimplE
  • Generative: GraphAutoregressiveFlow

Reference: See references/models_architectures.md for:

  • Detailed model descriptions
  • Model selection guide by task and dataset
  • Architecture comparisons
  • Implementation tips

7. Datasets

40+ curated datasets spanning chemistry, biology, and knowledge graphs.

Categories:

  • Molecular properties (drug discovery, quantum chemistry)
  • Protein properties (function, structure, interactions)
  • Knowledge graphs (general and biomedical)
  • Retrosynthesis reactions

Reference: See references/datasets.md for:

  • Complete dataset catalog with sizes and tasks
  • Dataset selection guide
  • Loading and preprocessing
  • Splitting strategies (random, scaffold)

Common Workflows

Workflow 1: Molecular Property Prediction

Scenario: Predict blood-brain barrier penetration for drug candidates.

Steps:

  1. Load dataset: datasets.BBBP()
  2. Choose model: GIN for molecular graphs
  3. Define task: PropertyPrediction with binary classification
  4. Train with scaffold split for realistic evaluation
  5. Evaluate using AUROC and AUPRC

Navigation: references/molecular_property_prediction.md → Dataset selection → Model selection → Training

Workflow 2: Protein Function Prediction

Scenario: Predict enzyme function from sequence.

Steps:

  1. Load dataset: datasets.EnzymeCommission()
  2. Choose model: ESM (pre-trained) or GearNet (with structure)
  3. Define task: PropertyPrediction with multi-class classification
  4. Fine-tune pre-trained model or train from scratch
  5. Evaluate using accuracy and per-class metrics

Navigation: references/protein_modeling.md → Model selection (sequence vs

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Вложенные файлы

references/core_concepts.mdreferences/datasets.mdreferences/knowledge_graphs.mdreferences/models_architectures.mdreferences/molecular_generation.mdreferences/molecular_property_prediction.mdreferences/protein_modeling.mdreferences/retrosynthesis.md

FAQ

Что делает скилл torchdrug?

PyTorch-native graph neural networks for molecules and proteins. Use when building custom GNN architectures for drug discovery, protein modeling, or knowledge graph reasoning. Best for custom model development, protein property prediction, retrosynthesis. For pre-trained models and diverse featurizers use deepchem; for benchmark datasets use pytdc.

Как установить скилл torchdrug?

Скопируй папку скилла в ~/.claude/skills (вкладка Claude Code выше делает это одной командой), либо поставь как плагин.

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Нет, скилл состоит только из инструкций (SKILL.md), без исполняемых скриптов.

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