О программе
Навык medchem предоставляет фильтры медицинской химии для отбора соединений в процессе разработки лекарств. Он позволяет разработчикам применять правила лекарственного подобия, каталоги структурных предупреждений и метрики сложности для приоритизации молекулярных библиотек в больших масштабах. Используйте его для фильтрации соединений с помощью установленных руководств, таких как правила Липинского, предупреждения PAINS и пользовательский язык запросов медицинской химии.
Быстрая установка
Claude Code
Рекомендуетсяnpx skills add K-Dense-AI/claude-scientific-skills -a claude-code/plugin add https://github.com/K-Dense-AI/claude-scientific-skillsgit clone https://github.com/K-Dense-AI/claude-scientific-skills.git ~/.claude/skills/medchemСкопируйте и вставьте эту команду в Claude Code для установки этого навыка
Документация
Medchem
Overview
Medchem is a Python library from datamol-io for molecular filtering and prioritization in drug discovery. Apply literature-derived drug-likeness rules, named alert catalogs, complexity thresholds, chemical-group detection, and a custom query language to triage compound libraries at scale. Filters are context-specific guidelines — combine with domain expertise and target knowledge.
Version note: Examples target medchem 2.0.5 (PyPI stable, Nov 2024). Requires Python ≥3.9. Depends on datamol and RDKit (installed automatically). RuleFilters and structural filter classes return pandas DataFrames. Lilly demerits require optional native binaries (mamba install lilly-medchem-rules).
When to Use This Skill
This skill should be used when:
- Applying drug-likeness rules (Lipinski, Veber, CNS, lead-like) to compound libraries
- Filtering molecules by structural alerts, PAINS, or NIBR screening-deck rules
- Prioritizing compounds for hit-to-lead or lead optimization
- Calculating complexity metrics against ZINC-derived thresholds
- Detecting functional groups or named substructure catalogs
- Building multi-criteria filters with the medchem query language
Installation
uv pip install medchem datamol
Optional — Eli Lilly demerit filter (requires conda-forge native binaries):
mamba install -c conda-forge lilly-medchem-rules
Core Capabilities
1. Medicinal Chemistry Rules
Apply established drug-likeness rules via medchem.rules.
List available rules:
import medchem as mc
mc.rules.RuleFilters.list_available_rules_names()
# ['rule_of_five', 'rule_of_five_beyond', 'rule_of_four', 'rule_of_three', ...]
Single rule on one molecule:
import datamol as dm
import medchem as mc
smiles = "CC(=O)OC1=CC=CC=C1C(=O)O" # aspirin
mc.rules.basic_rules.rule_of_five(smiles) # True
mc.rules.basic_rules.rule_of_cns(smiles) # True
mc.rules.basic_rules.rule_of_veber(smiles) # True
Multiple rules with RuleFilters (returns a DataFrame):
import datamol as dm
import medchem as mc
mols = [dm.to_mol(s) for s in smiles_list]
rfilter = mc.rules.RuleFilters(
rule_list=["rule_of_five", "rule_of_oprea", "rule_of_cns", "rule_of_leadlike_soft"]
)
df = rfilter(mols=mols, n_jobs=-1, progress=True, keep_props=False)
# Columns: mol, pass_all, pass_any, rule_of_five, rule_of_oprea, ...
passing = df[df["pass_all"]]
Use keep_props=True to include computed descriptors (mw, clogp, tpsa, etc.) in the result.
2. Structural Alert Filters
Detect problematic patterns with medchem.structural. Both classes return DataFrames with pass_filter, status, and reasons columns.
Common alerts (ChEMBL-derived rule sets):
import medchem as mc
alert_filter = mc.structural.CommonAlertsFilters()
df = alert_filter(mols=mol_list, n_jobs=-1, progress=True)
# df columns: mol, pass_filter, status, reasons
clean = df[df["pass_filter"]]
NIBR filters (Novartis screening-deck curation):
nibr_filter = mc.structural.NIBRFilters()
df = nibr_filter(mols=mol_list, n_jobs=-1, progress=True)
# df columns: mol, pass_filter, status, severity, reasons, n_covalent_motif, special_mol
Compounds with severity >= 10 are excluded by default (see NIBR paper).
3. Named Catalog Filters (PAINS, Brenk, etc.)
Use medchem.catalogs.NamedCatalogs for RDKit FilterCatalog instances, or the functional API:
import medchem as mc
# List available named catalogs
mc.catalogs.list_named_catalogs()
# ['tox', 'pains', 'pains_a', 'brenk', 'nibr', 'zinc', ...]
# Functional API — True means molecule passes (no alert match)
passes = mc.functional.alert_filter(mols=mol_list, alerts=["pains"], n_jobs=-1)
# Or via catalog objects
passes = mc.functional.catalog_filter(
mols=mol_list,
catalogs=[mc.catalogs.NamedCatalogs.pains()],
n_jobs=-1,
)
4. Functional API
medchem.functional provides one-call wrappers that return boolean masks (True = passes):
import medchem as mc
mc.functional.rules_filter(mols=mol_list, rules=["rule_of_five", "rule_of_cns"], n_jobs=-1)
mc.functional.nibr_filter(mols=mol_list, max_severity=10, n_jobs=-1)
mc.functional.alert_filter(mols=mol_list, alerts=["pains", "brenk"], n_jobs=-1)
mc.functional.complexity_filter(mols=mol_list, complexity_metric="bertz", limit="99", n_jobs=-1)
Other helpers: catalog_filter, chemical_group_filter, lilly_demerit_filter (requires optional binaries), macrocycle_filter, bredt_filter, protecting_groups_filter, and more.
5. Chemical Groups
Detect functional groups and curated pattern collections via medchem.groups:
import medchem as mc
# Browse available group collections
mc.groups.list_default_chemical_groups()
# ['privileged_scaffolds', 'common_warhead_covalent_inhibitors', 'rings_in_drugs', ...]
group = mc.groups.ChemicalGroup(groups=["privileged_scaffolds"])
group.has_match(mol) # bool
group.get_matches(mol) # dict of group → atom indices
group.filter(mols) # molecules matching the group
# Returns molecules that do NOT match the group
mc.functional.chemical_group_filter(mols=mol_list, chemical_group=group, n_jobs=-1)
Custom groups can be loaded from a file via groups_db (CSV with smiles/smarts, name, group columns).
6. Molecular Complexity
Compare complexity metrics to precomputed ZINC-15 percentile thresholds:
import medchem as mc
# Single molecule
cf = mc.complexity.ComplexityFilter(limit="99", complexity_metric="bertz")
cf(mol) # True if below 99th-percentile threshold
# Batch via functional API
mc.functional.complexity_filter(
mols=mol_list,
complexity_metric="bertz", # also: sas, qed, whitlock, barone, smcm, twc
limit="99",
n_jobs=-1,
)
# Direct metric functions
mc.complexity.WhitlockCT(mol)
mc.complexity.BaroneCT(mol)
7. Scaffold Constraints
medchem.constraints.Constraints matches a core scaffold and applies per-atom constraint functions — not simple MW/LogP ranges. For property bounds, use RuleFilters, descriptors via mc.rules.list_descriptors(), or the query language.
import datamol as dm
import medchem as mc
core = dm.to_mol("c1ccccc1")
constraints = mc.constraints.Constraints(
core=core,
constraint_fns={"query": lambda mol, atom_idx, query: ...},
)
constraints(mol)
8. Medchem Query Language
Build multi-criteria filters with medchem.query.QueryFilter:
import medchem as mc
# Rule + alert combination
qf = mc.query.QueryFilter('MATCHRULE("rule_of_five") AND NOT HASALERT("pains")')
mask = qf(mols=mol_list, n_jobs=-1) # list[bool]
# CNS-like with property bounds
qf = mc.query.QueryFilter('MATCHRULE("rule_of_cns") AND HASPROP("tpsa", <=, 90)')
mask = qf(mols=mol_list, n_jobs=-1)
Query syntax:
MATCHRULE("rule_of_five")— apply a named ruleHASALERT("pains")— match a named catalog (pains,brenk,nibr,tox, …)HASPROP("mw", <, 500)— compare a descriptor (unquoted comparator)HASGROUP("privileged_scaffolds")— match a chemical groupHASSUBSTRUCTURE("c1ccccc1")— substructure match- Operators:
AND,OR,NOT
List available descriptors: mc.rules.list_descriptors()
Workflow Patterns
Pattern 1: Initial Triage of a Compound Library
import datamol as dm
import medchem as mc
import pandas as pd
df = pd.read_csv("compounds.csv")
mols = [dm.to_mol(s) for s in df["smiles"]]
# Drug-likeness rules
rules_df = mc.rules.RuleFilters(rule_list=["rule_of_five", "rule_of_veber"])(mols=mols, n_jobs=-1)
# PAINS + common alerts via query
qf = mc.query.QueryFilter('MATCHRULE("rule_of_five") AND NOT HASALERT("pains")')
pass_mask = qf(mols=mols, n_jobs=-1)
df["passes_rules"] = rules_df["pass_all"].values
df["drug_like"] = pass_mask
filtered_df = df[df["drug_like"]]
filtered_df.to_csv("filtered_compounds.csv", index=False)
Pattern 2: Lead Optimization Filtering
import medchem as mc
rules_df = mc.rules.RuleFilters(rule_list=["rule_of_leadlike_soft"])(mols=candidates, n_jobs=-1)
nibr_df = mc.structural.NIBRFilters()(mols=candidates, n_jobs=-1)
complex_mask = mc.functional.complexity_filter(
mols=candidates, complexity_metric="bertz", limit="95", n_jobs=-1
)
passes = (
rules_df["pass_all"]
& nibr_df["pass_filter"]
& complex_mask
)
Pattern 3: Detect Functional Groups
import medchem as mc
group = mc.groups.ChemicalGroup(groups=["common_warhead_covalent_inhibitors"])
matches = [group.has_match(mol) for mol in mol_list]
warhead_mols = [mol for mol, m in zip(mol_list, matches) if m]
Best Practices
- Context matters — marketed drugs often violate Ro5; prodrugs and natural products are common exceptions.
- Combine filters — rules, alert catalogs, and complexity thresholds work best together.
- Use parallelization — pass
n_jobs=-1for libraries >1000 molecules. - Check return types —
RuleFiltersand structural classes return DataFrames; functional helpers return boolean arrays. - Lilly demerits are optional — install
lilly-medchem-rulesseparately; default max demerits is 160 in the functional API. - Document decisions — retain
status,reasons, andseveritycolumns for audit trails.
Resources
references/api_guide.md
Module-by-module API reference with signatures, return types, and patterns.
references/rules_catalog.md
Catalog of available rules, alert sets, complexity metrics, and filter selection guidelines.
scripts/filter_molecules.py
Batch filtering script for CSV/TSV/SDF/SMILES inputs with configurable rules, alerts, and complexity thresholds.
uv run python scripts/filter_molecules.py input.csv \
--rules rule_of_five,rule_of_cns --pains --nibr --output filtered.csv
Documentation
- Official docs: https://medchem-docs.datamol.io/
- GitHub: https://github.com/datamol-io/medchem
- PyPI: https://pypi.org/project/medchem/ (2.0.5)
GitHub репозиторий
Frequently asked questions
What is the medchem skill?
medchem is a Claude Skill by K-Dense-AI. Skills package instructions and resources that Claude loads on demand, so Claude can perform medchem-related tasks without extra prompting.
How do I install medchem?
Use the install commands on this page: add medchem to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does medchem belong to?
medchem is in the Other category, tagged ai.
Is medchem free to use?
Yes. medchem is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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