Version Compatibility
Reference examples tested with: RDKit 2024.03+
Before using code patterns, verify installed versions match. If versions differ:
- Python:
pip show <package>thenhelp(module.function)to check signatures
If code throws ImportError, AttributeError, or TypeError, introspect the installed package and adapt the example to match the actual API rather than retrying.
Reaction Enumeration
"Generate a combinatorial library from my building blocks" → Enumerate virtual compound libraries by applying reaction SMARTS transformations to sets of building-block molecules, producing and validating all product combinations for a defined synthetic route.
- Python:
AllChem.ReactionFromSmarts(),rxn.RunReactants()(RDKit)
Generate virtual compound libraries using reaction SMARTS.
Reaction SMARTS Basics
from rdkit import Chem
from rdkit.Chem import AllChem
# Define reaction (reactants >> products with atom mapping)
# Amide coupling: carboxylic acid + amine -> amide
amide_rxn = AllChem.ReactionFromSmarts(
'[C:1](=[O:2])O.[N:3]>>[C:1](=[O:2])[N:3]'
)
# Validate reaction definition
n_errors = amide_rxn.Validate()
if n_errors[0] == 0:
print('Reaction is valid')
# Run reaction
acid = Chem.MolFromSmiles('CC(=O)O')
amine = Chem.MolFromSmiles('CCN')
products = amide_rxn.RunReactants((acid, amine))
# products is a tuple of tuples: ((product1,), (product2,), ...)
for prod_set in products:
for prod in prod_set:
Chem.SanitizeMol(prod)
print(Chem.MolToSmiles(prod))
Common Reaction SMARTS
REACTIONS = {
'amide_coupling': '[C:1](=[O:2])O.[N:3]>>[C:1](=[O:2])[N:3]',
'reductive_amination': '[C:1]=O.[N:2]>>[C:1][N:2]',
'suzuki': '[c:1][Br].[c:2][B](O)O>>[c:1][c:2]',
'buchwald': '[c:1][Br].[N:2]>>[c:1][N:2]',
'ester_formation': '[C:1](=[O:2])O.[O:3]>>[C:1](=[O:2])[O:3]',
'michael_addition': '[C:1]=[C:2]C(=O).[C:3]>>[C:1][C:2]([C:3])C(=O)',
}
Combinatorial Library Enumeration
Goal: Generate all possible products from a combinatorial reaction of building-block sets.
Approach: Enumerate all reactant combinations via Cartesian product, apply the reaction SMARTS to each, sanitize products, and deduplicate by canonical SMILES.
from rdkit import Chem
from rdkit.Chem import AllChem
from itertools import product
def enumerate_library(rxn_smarts, reactant_lists, deduplicate=True):
'''
Enumerate products from combinatorial reaction.
Args:
rxn_smarts: Reaction SMARTS string
reactant_lists: List of lists of SMILES for each reactant position
deduplicate: Remove duplicate products
Returns:
List of unique product SMILES
'''
rxn = AllChem.ReactionFromSmarts(rxn_smarts)
# Validate reaction
if rxn.Validate()[0] != 0:
raise ValueError('Invalid reaction SMARTS')
products = []
seen = set()
# Generate all combinations
for reactants in product(*reactant_lists):
mols = [Chem.MolFromSmiles(s) for s in reactants]
if None in mols:
continue
try:
prods = rxn.RunReactants(tuple(mols))
for prod_set in prods:
for prod in prod_set:
try:
Chem.SanitizeMol(prod)
smiles = Chem.MolToSmiles(prod)
if deduplicate:
if smiles not in seen:
seen.add(smiles)
products.append(smiles)
else:
products.append(smiles)
except Exception:
continue # Skip invalid products
except Exception:
continue
return products
# Example: Amide library
acids = ['CC(=O)O', 'c1ccccc1C(=O)O', 'OC(=O)CC(=O)O']
amines = ['CCN', 'c1ccc(N)cc1', 'NCCN']
products = enumerate_library(
'[C:1](=[O:2])O.[N:3]>>[C:1](=[O:2])[N:3]',
[acids, amines]
)
print(f'Generated {len(products)} unique products')
Multi-Step Synthesis
Goal: Enumerate products from a multi-step synthetic route with intermediate building blocks at each step.
Approach: Iteratively apply each reaction SMARTS to the current product pool and the next set of building blocks, carrying forward intermediates through the synthesis chain.
def multi_step_enumeration(building_blocks, reaction_sequence):
'''
Enumerate products from multi-step synthesis.
Args:
building_blocks: Dict of {step: [smiles_list]}
reaction_sequence: List of reaction SMARTS
'''
current = building_blocks[0]
for step, rxn_smarts in enumerate(reaction_sequence):
next_bbs = building_blocks.get(step + 1, [])
if not next_bbs:
break
current = enumerate_library(rxn_smarts, [current, next_bbs])
print(f'Step {step + 1}: {len(current)} intermediates')
return current
Product Validation
Goal: Filter enumerated products to remove invalid, oversized, or reactive compounds.
Approach: Parse each product SMILES, check molecular weight against a maximum, screen for reactive functional groups via SMARTS, and verify valence sanity.
from rdkit import Chem
from rdkit.Chem import AllChem, Descriptors
def validate_products(smiles_list, mw_max=500, remove_reactive=True):
'''
Validate and filter enumerated products.
'''
valid = []
reactive_smarts = [
'[N+]([O-])=O', # Nitro
'[Cl,Br,I]', # Halogens (optional)
'C#N', # Nitrile
]
reactive_patterns = [Chem.MolFromSmarts(s) for s in reactive_smarts]
for smiles in smiles_list:
mol = Chem.MolFromSmiles(smiles)
if mol is None:
continue
# Check MW
if Descriptors.MolWt(mol) > mw_max:
continue
# Check reactive groups
if remove_reactive:
has_reactive = any(mol.HasSubstructMatch(p) for p in reactive_patterns)
if has_reactive:
continue
# Check valence
try:
Chem.SanitizeMol(mol)
except Exception:
continue
valid.append(smiles)
return valid
Reaction Templates
def apply_template(core_smiles, r_groups, attachment_smarts='[*:1]'):
'''
Apply R-group decoration to a core scaffold.
Args:
core_smiles: Core with attachment point (e.g., '*c1ccccc1')
r_groups: List of R-group SMILES
attachment_smarts: SMARTS for attachment point
'''
products = []
for rg in r_groups:
# Simple string replacement for single attachment
product_smiles = core_smiles.replace('*', rg, 1)
mol = Chem.MolFromSmiles(product_smiles)
if mol:
try:
Chem.SanitizeMol(mol)
products.append(Chem.MolToSmiles(mol))
except Exception:
continue
return products
# Example: Decorate benzene core
core = '*c1ccccc1'
r_groups = ['C', 'CC', 'C(=O)O', 'O']
decorated = apply_template(core, r_groups)
Related Skills
- molecular-io - Save enumerated libraries
- molecular-descriptors - Filter by properties
- admet-prediction - Screen for drug-likeness