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Visual intelligence to optimize industrial biology

Our Product

With AI-powered microscopy

Lir Labs’s mission is to provide real-time monitoring across industries using deployable automated microscopes.

Solving an analysis gap that costs billions annually

Lir labs helps optimize operations, avoid compliance violations and predicting systems behaviour.

The technology

Microscopy, Deep learning

& Automation

01

A simple black and white drawing of an eye with a curved eyelid and a circular iris.

Seeing

Industries using biological processes lack key insights to enable optimisation and automation. Our technology offers on-site continuous optical data on organic particle Morphology, Substrate Consumption, Species distribution, Ecosystem Quality and System Resilience

02

Predicting

Our rich, multi-modal data helps generate more accurate forecasts 48 hours in advance. moving existing water treatment systems into the new age of AI.

03

Protecting

Automated directions for operators to adjust energy, chemical dosing, and wasting rates. Resulting in up to 100k in savings every year for treatment plants using our system

Learn more

Close-up of turbulent water with foam and bubbles in a river or stream.

Applications

Applications across industry

Real-Time Diagnostics: Detect process upsets (like bulking) hours or days before traditional sensors.
Operational Savings: Reduce energy and chemical waste through precision-tuned treatment.
Regulatory Compliance: Maintain a continuous digital "audit trail" of discharge quality.
Activated Sludge Basins: The AI detects early signs of "sludge bulking" by identifying excessive filamentous growth or changes in floc structure (e.g., pinpoint flocs). This allows operators to adjust aeration or RAS (Return Activated Sludge) rates days before a settling failure occurs in the clarifiers.
Influent Monitoring: Rapidly identifies "toxic shocks" or unusual particle loads entering the plant, protecting the biomass from washout.
Effluent Monitoring: Provides a final, high-fidelity check for suspended solids and specific pathogens (like Vorticellaor Rotifers), ensuring total permit compliance and providing a digital audit trail of water quality.
Process Monitoring: Automated systems like Micro-Flow Imaging (MFI) detect near-transparent protein aggregates, silicone droplets, and air bubbles that traditional sensors miss. Computer vision models classify these particles by morphology, ensuring the "cell factory" is operating within tight quality specs.
Influent/Effluent Control: For biomanufacturing wastewater, these systems monitor for "escaped" genetically modified organisms (GMOs) or cell debris. AI can instantly differentiate between healthy biomass and cells undergoing apoptosis (programmed death), providing an early warning of batch failure or toxic discharge.
Contamination Defense: The system acts as a real-time shield, using deep learning to identify foreign bacteria or fungal contaminants at the micron level, ensuring that the specialized microbial communities in the plant’s treatment basins aren't overwhelmed by antibiotic-laden or highly acidic process waste.