Optical Sciences

Biomolecules and nanostructures

The Optical Sciences group studies the interaction of light and matter at the nanoscale. We do this by exploring ways to shape light and its environment. It's what we call active and passive control. Our current focus is on the interaction of light with biomolecules and nanostructures. We are part of Twente University's Department of Science and Technology and member of the MESA+ institute.
We participate in the EU-COST actions MP1102: Coherent Raman microscopy (MicroCor) and CM1202: Supramolecular photocatalytic water splitting (PERSPECT-H2O)

 

Near-Field Fluorescence Microscopy An Optical Nanotool to Study Protein Organization at the Cell Membrane

(full pdf)

María F. García-Parajó, Bärbel I. de Bakker, Marjolein Koopman, Alessandra Cambi, Frank de Lange, Carl G. Figdor, and Niek F. van Hulst
NanoBiotechnology
Volume 1 Number 1 ISSN: 1551-1286 (Print) ISSN: 1551-1294 (Online) july 2005

The ability to study the structure and function of cell membranes and membrane components is fundamental to understanding cellular processes. This requires the use of methods capable of resolving structures with nanometer-scale resolution in intact or living cells. Although fluorescence microscopy has proven to be an extremely versatile tool in cell biology, its diffraction-limited resolution prevents the investigation of membrane compartmentalization at the nanometer scale. Near-field scanning optical microscopy (NSOM) is a relatively unexplored technique that combines both enhanced spatial resolution of probing microscopes and simultaneous measurement of topographic and optical signals. Because of the very small nearfield excitation volume, background fluorescence from the cytoplasm is effectively reduced, enabling the visualization of nano-scale domains on the cell membrane with single molecule detection sensitivity at physiologically relevant packing densities. In this article we discuss technological aspects concerning the implementation of NSOM for cell membrane studies and illustrate its unique advantages in terms of spatial resolution, background suppression, sensitivity, and surface specificity for the study of protein clustering at the cell membrane. Furthermore, we demonstrate reliable operation under physiological conditions, without compromising resolution or sensitivity, opening the road toward truly live cell imaging with unprecedented detail and accuracy.
Printable version