Generative Library Builder

Overview

Build focused virtual libraries from cores, R-groups, reaction handles, and property constraints. It is in the Generative Molecular Design Pro category and is intended to generate, optimize, and prioritize molecules against target properties while keeping synthesis constraints visible.

When To Use It

• You need a focused workflow for generative library builder without leaving ChemistryAtlas.
• You want a result that can be saved, shared, or chained into another chemistry app.
• You want the calculation assumptions and limitations visible next to the output.

Inputs

• text - Chemistry input - type: textarea - Use formulas, names, SMILES-like text, reactions, or key=value options. Heavier engines will plug into this same app surface.

Recommended Workflow

• Define the scaffold, target profile, constraints, or seed molecules; generate candidates; filter by properties, alerts, novelty, and synthetic feasibility.
• Start with the smallest representative input, confirm the parser understood it, then scale to a larger list or workflow.
• Save the generated report when the result will feed a notebook entry, route review, model comparison, or team discussion.

Outputs

• A Markdown-style chemistry report with parsed inputs, assumptions, and calculated or predicted results.
• Structured tables when the app returns multiple compounds, reagents, routes, peaks, candidates, or model rows.
• Warnings, fallback notes, and sidecar availability messages when a specialized engine is not installed or not reachable.

Method And Backend Notes

This app has a runnable ChemistryAtlas backend path. Backend type: utility. ChemistryAtlas roadmap MVP: runnable report now; specialist cheminformatics/model backend plugs into this app surface next. Use the output as a structured starting point for chemistry judgment, follow-up calculation, or experimental planning.

How To Interpret Results

• Ranked candidates are design proposals, not validated leads; confirm novelty, IP space, safety, assay relevance, and route feasibility before investing synthesis time.
• Compare results across related molecules, controls, blanks, literature examples, or known reactions whenever possible.
• For decisions that affect safety, synthesis scale-up, biological testing, purchasing, or publication, verify with primary data and expert review.

Example Input

core=c1ccc([*:1])cc1
r=F,Cl,Me,OMe
max_products=4
mw_max=220

Common Checks Before Acting

• Confirm names, salts, stereochemistry, tautomers, protonation state, and hydration state.
• Check units, concentrations, equivalent definitions, and significant figures.
• Record external database versions, model versions, sidecar availability, and any manual edits made after the app output.

Related Apps

• Target-Property Molecule Generator (target-property-molecule-generator)
• Scaffold Hopping Designer (scaffold-hopping-designer)
• R-Group Optimization Pro (rgroup-optimization-pro)
• Multi-Objective Molecular Optimizer (multi-objective-molecular-optimizer)
• Synthesis-Aware Molecule Generator (synthesis-aware-molecule-generator)

Acknowledgements And Validation

• ChemistryAtlas documentation and UI were prepared for chemistry discovery workflows.
• Where available, calculations may use open-source cheminformatics, reaction-informatics, spectra, docking, or machine-learning engines such as RDKit-family tooling, ASKCOS-style sidecars, ChemProp, ms-pred/ICEBERG, PyScreener, and MolPAL.
• Always verify important results against primary literature, official SDS records, instrument software, validated models, and local laboratory procedures.