Our market areas
Free radicals biosensing with fluorescent nanodiamonds offer transformative capabilities across pharmaceutical, biotechnology, academic, and translational research by enabling unprecedented, real-time, and subcellular insights into biological processes.
Academic & Translational Research
Uncover the unseen. We equip researchers with high-resolution, real-time tools to decode oxidative mechanisms in living systems—driving discovery from cell signaling to disease origin with unmatched precision and reproducibility.
From discovery to application:
- Study mitochondrial stress and dynamic ROS generation
- Explore free radical regulation in disease models
- Validate oxidative biomarkers for translational use
- Profile single-cell responses to genetic perturbations
- Bridge basic discoveries to theragnostic applications
Pharmaceutics & Biotechnology
Enhance your pipeline. Our platform delivers functional insights into oxidative pathways, drug effects, and toxicity offering dynamic biomarkers to optimize target engagement, combination strategies, and responder selection.
From discovery to application:
- Real-time drug efficacy and redox response tracking
- Early toxicity screening via ROS stress readouts
- Identify free radical driven therapeutic windows
- Quantify mitochondrial function under drug exposure
- Stratify free radical sensitive patient populations
Healthcare & Life Science
Advance precision medicine. Our technology enables subcellular quantification of oxidative stress in pathologies like cancer, CVD, and neurodegeneration. Supporting diagnosis, treatment guidance, and monitoring across the disease continuum.
From discovery to application:
- Detect free radical imbalance in early disease stages
- Differentiate inflammatory vs degenerative conditions
- Predict treatment response using oxidative markers
- Monitor drug action in real-time
- Support personalized intervention strategies
Clinical applications
Quantum Nuova opens new possibilities for clinical and translational science by enabling real-time, subcellular detection of oxidative stress, a key driver across many diseases. By capturing functional free radical activity at the single-cell level, it supports biomarker discovery, patient stratification, and therapy response prediction in several critical fields:
Monitor cellular stress linked to neuronal and glial cell damage through free radical biomarkers
