Gather data, find pockets, dock small molecules with conversational AI. Try for free!

Coming soon

Molecular simulation toolkit

Physicochemical simulations and AI for interrogating biology at the atomistic scale.
Develop safe, effective drugs faster.

Learn more

Toolkit for in silico
drug discovery

Our toolkit enables scientists to interrogate biology using biological simulations, biophysics, and machine learning. With our toolkit, scientists can develop safe, effective drugs faster.

Our toolkit includes:

Atomistic ligand docking
Molecular properties AI: solubility, toxicity, etc.
Atomistic molecular dynamics

The toolkit is available through Jupyter notebooks in software blueprints on our cloud platform.

Toxicity

Adverse, off-target effects of compounds

Protein-ligand binding

How compounds bind proteins and how strongly they bind

Solubility & distribution

Ability of compounds to circulate to target tissues

Protein structure

3D configurations of polypeptides and complexes

Biophysical simulation

Simulation of how physicochemical forces drive biological behavior"

Machine Learning

Data-driven simulation of behaviors, from individual molecules to cells

01

Ligand docking and molecular properties

Docking places candidate molecules within a protein's binding pocket and estimates their binding affinities. By integrating physics and AI, our algorithms offer state-of-the-art accuracy and speed.
Dock compounds against multiple protein conformations.
Identify stable poses of compounds in binding pockets.
Estimate protein-ligand binding affinities.
Predict properties such as solubility, toxicity, and more.

02

Atomistic molecular dynamics

Molecular Dynamics simulations enable the study of multi-protein complexes, the discovery of hidden binding sites, and precise estimation of binding affinities between compounds and proteins.
Our tools combine physics simulation and AI, enabling:
Simulating proteins, small organic molecules, and protein-drug complexes.
Explicit solvent simulations using the AMBER and CHARMM force fields for accurately predicting protein folds.
AI-approximated quantum chemistry force field for accurately modeling small molecules.
State-of-the-art free energy perturbation (FEP) methods for accurately estimating binding affinities.
Enhanced sampling methods, such as replica and umbrella sampling, for efficiently estimating binding affinities.

PARTNERSHIPS

Your virtual drug discovery partner

Nothing is undruggable. Our virtual screening experts are skilled at challenging targets. Contact us to discuss how we can accelerate your drug discovery program.

Learn more

We value your privacy

We use statistics cookies to help us improve your experience of our website. By using our website, you consent to our use of cookies. To learn more, read our Privacy Policy and Cookie Policy.