Chemical and Phenotypic Characterization

Label-free IR microscopy enables hyperspectral analysis of cellular responses to infections, drugs, and stressors under fixed or near-physiological conditions. It delivers non-destructive cellular and sub-cellular biochemical profiling with micrometric to sub-micrometric resolution for advanced phenotyping and diagnostics.

IR microscopy enables label-free hyperspectral mapping of tissues to study responses to pathogens, drugs, and disease progression. It provides non-destructive biochemical insights at the organ level, supporting advanced diagnostic and prognostic evaluation with micrometric spatial resolution.

Advanced FTIR and UV Resonance Raman techniques enable ultra-sensitive, label-free investigation of biomolecules and proteins. These approaches support real-time, in situ analysis of protein structure, folding, aggregation, and environmental effects with high molecular selectivity and micrometric resolution.

UV Resonant Raman spectroscopy enables selective, label-free probing of nucleic acids and DNA to study structural stability, motif formation, damage, and ligand interactions. It supports in situ and operando analysis of DNA- and RNA-based materials, advancing genetic research and drug development.

UV Resonant Raman spectroscopy enables label-free, in situ analysis of peptide hydration, folding, aggregation, and self-assembly. It provides high-sensitivity insights into peptide structural dynamics, supporting therapeutic peptide design and the study of protein misfolding processes across a wide range of conditions.

Rapid and sensitive pathogen recognition using IR spectroscopy, tailored for point-of-care diagnostics. Enhance the ability to quickly identify pathogens, significantly reducing response times in therapeutic strategy development and public health interventions.

Perform environmental and surface analysis for selective pathogen detection using UV Resonant Raman Spectroscopy, crucial for monitoring and controlling pathogen spread.

IR nanoscopy enables nanoscale mapping of molecular clusters and bio-nanomaterials, revealing their structure and chemistry. Hyperspectral near-field imaging provides unprecedented insight into biomolecular nano-assembly and interfaces, supporting the development of innovative therapeutic materials.