Why and how biofilms cause biofouling - the "hair-in-sink" - effect"

Why and how biofilms cause biofouling on membranes

An optimized protocol for the identification of diatoms, flagellated algae and pathogenic protozoa with phylochips

From nanocluster assays to optical biochips for nanobiotechnology

Nanocluster Optical Resonance Devices for Molecular Structure Transduction

Micro-arrays for the detection of the abundance and distribution of pathogenic protozoa

Cluster optical coding - from biochips to counterfeit security

Tuning the setup of sputter-coated multilayers in nanocluster-based signal-enhancing biochips for optimal performance in protein and DNA assays

Structural behavior of nanometric carbohydrate films transduced by a resonant technique

Robust nano cluster layers for structural amplified fluorescence biochips

Resonant nanocluster technology from optical coding and high quality security features to biochips

Phage display antibody-based proteomic device using resonance-enhanced detection

Fluorescence Techniques. Chapter 2.

Analysis in complex biological fluids. Chapter 9.

Nanofilms and nanoclusters - energy sources driving fluorophores of biochip bound labels.

High-throughput assays on the chip based on metal nano-cluster resonance.

Surface enhanced resonance of metal nano clusters: A novel tool for proteomics.

DNA biochips based on surface-ebhanced fluorescence (SEF) for high-throughput interaction studies.

Food-allergen assays on chip based on metal nano-cluster resonance.

Slide-format proteomic biochips based on surface-enhanced nanocluster-resonance.