Map the poison.
Drone hyperspectral scans and micro-bore samples become a spatial chemistry model: every heavy metal plume, hydrocarbon pocket and water pathway in one living map.
An AI biofoundry that designs luminous fungal ecosystems to metabolize toxic soil—and return dead industrial land to life.
Most remediation excavates poisoned soil and moves it somewhere else. We train living networks to digest the problem in place.
Explore protocol→Feed us a soil scan. MYC Core simulates 8.4 million fungal genomes, then prints a living remediation culture tuned to the exact chemistry of your site.
Drone hyperspectral scans and micro-bore samples become a spatial chemistry model: every heavy metal plume, hydrocarbon pocket and water pathway in one living map.
MYC Core explores millions of safe phenotype combinations and searches for the exact enzymatic pathways able to bind, digest or isolate the target contaminants.
Robotic bioreactors grow kilometer-scale starter cultures inside biodegradable lattice capsules—ready to root themselves into industrial soil.
Embedded biosensors report metabolism in real time. The model adjusts hydration, nutrient pulses and mesh expansion until toxicity falls below ecological thresholds.
Former electroplating corridor · 42 hectares
Decommissioned refinery basin · 119 hectares
Windborne saline margin · 67 hectares
Mine tailing shelf · 204 hectares
A dead hectare should not stay dead for three generations.
reduction in bioavailable heavy metals across pilot cultures
average time from contaminated soil to stable ecological substrate
less embodied carbon than excavation-and-landfill remediation
Send a site name and contact. Our field team will return a preliminary culture path within two working days.