Our Vision

Architecting the
Biological Industrial Revolution.

Chondrule AI translates your prompts to proteins.
We are building a platform to design, synthesize, and validate custom proteins at the speed of AI.

Our Story

The power of de novo protein design - creating biological machines from scratch - has been the exclusive domain of elite academic labs and multi-billion dollar pharmaceutical giants.

While the protein-design world focused on therapeutics, the most pressing challenges of our century - climate change, food security, and materials innovation - remained largely unaddressed.

Chondrule was founded to change that. We are bridging the gap between the potential of de novo proteins and industrial reality. By abstracting the complexity of state-of-the-art protein design models, we make it possible for every engineer to design proteins that solve real-world problems.

Our Mission

"To democratize the expertise of the world’s leading protein design labs for every industrial researcher."

We believe that the next industrial revolution won't be made of silicon, but of programmable biomolecules.

The Chondrule Edge

Solving the three core bottlenecks of de novo protein design for industrial applications.

The Expertise Gap

The AI Architect

Most researchers know what they want their biomolecule to do, but not how to design it. Our AI Architect translates natural language industrial goals into high-fidelity computational pipeline for novel protein-based solutions.

The Orchestration Gap

Design Pipelines

The field moves too fast for any team to keep up. Chondrule dynamically assembles the optimal stack - integrating models like RFDiffusion, AlphaFold3, and BoltzGen.

The Infrastructure Gap

Managed Compute

State-of-the-art de novo protein design requires massive VRAM and complex DevOps. We handle the hardware scaling and pipeline execution so your team can focus on the science.

Industrial Focus

Built for the sectors that power our world.

Chondrule is committed to commercial-grade, physical-world impact. We focus the full strength of de novo protein design on the most critical bottlenecks in heavy industry and global supply chains.

NITROGEN FIXATION

Agriculture & Soil Resilience

Discovering and scaffolding novel nitrogenase-mimicking enzymes to facilitate room-temperature biological nitrogen fixation directly at the plant root interface, bypassing fossil-fuel-intensive Haber-Bosch processing.

RFdiffusion v3 (Active Site)ESMFoldLigandMPNN

-80%

ESTIMATED IMPACT

Dependency on Synthetic Nitrogen

STRUCTURED BIOMINERALIZATION

Advanced Bio-Materials

Architecting high-tensile structural biopolymers, carbon-negative concrete alternatives, and self-healing bio-cementation agents that replicate organic silica and calcium mineralization pathways.

CGFlow (Synthesis Mapping)AlphaFold 3YuelDesign Suite

10x

ESTIMATED IMPACT

Tensile Strength vs. Structural Steel

THERMOSTABLE ENZYME CATALYSTS

Climate & Decarbonization

Engineering high-thermostability carbonic anhydrase variants capable of operating inside chimney stack heat to accelerate industrial flue-gas carbon capture by orders of magnitude.

BoltzGen (Binder Design)RFdiffusion v2Boltz-2

98%

ESTIMATED IMPACT

Flue-Gas Carbon Scrubbing Efficiency

SELECTIVE METALLIC CHELATION

Resource Recovery & Biomining

Designing custom peptide sequences that selectively chelate and bind rare-earth elements and critical minerals from low-grade ores and industrial waste streams, eliminating toxic acid separation loops.

MapDiff (Flexible Scaffold)RFdiffusion v3 (Metal Bind)AlphaGenome

95%

ESTIMATED IMPACT

Reduction in Toxic Chemical Waste

Leadership Team