Matthias Geissbuehler

How to display data by color schemes compatible with red-green color perception deficiencies

Visualization of data concerns most scientists. The use of color is required in order to display multidimensional information. In addition, color encoding a univariate image can improve the interpretation significantly. However up to 10% of the adult male population are affected by a red-green color perception deficiency which hampers the correct interpretation and appreciation of color encoded information. This work attempts to give guidelines on how to display a given dataset in a balanced manner. Three novel color maps are proposed providing readers with normal color perception a maximum of color contrast while being a good compromise for readers with color perception deficiencies.

Triplet Imaging of Oxygen Consumption During the Contraction of a Single Smooth Muscle Cell (A7r5)

The measurement of tissue and cell oxygenation is important for understanding cell metabolism. We have addressed this problem with a novel optical technique, called triplet imaging, that exploits oxygen-induced triplet lifetime changes and is compatible with a variety of fluorophores. A modulated excitation of varying pulse widths allows the extraction of the lifetime of the essentially dark triplet state using a high-fluorescence signal intensity. This enables the monitoring of fast kinetics of oxygen concentration in living cells combined with high temporal and spatial resolution. First, the oxygen-dependent triplet-state quenching of tetramethylrhodamine is validated and then calibrated in an L-ascorbic acid titration experiment demonstrating the linear relation between triplet lifetime and oxygen concentration according to the Stern-Volmer equation. Second, the method is applied to a biological cell system, employing as reporter a cytosolic fusion protein of beta-galactosidase with SNAP-tag labeled with tetramethylrhodamine. Oxygen consumption in single smooth muscle cells A7r5 during an [Arg(8)]-vasopressin-induced contraction is measured. The results indicate a consumption leading to an intracellular oxygen concentration that decays monoexponentially with time. The proposed method has the potential to become a new tool for investigating oxygen metabolism at the single cell and the subcellular level.

Transient State Monitoring by Total Internal Reflection Fluorescence Microscopy

Triplet, photo-oxidized and other photoinduced, long-lived states of fluorophores are sensitive to the local environment and thus attractive for microenvironmental imaging purposes. In this work, we introduce an approach where these states are monitored in a total internal reflection (TIR) fluorescence microscope, via the characteristic variations of the time-averaged fluorescence occurring in response to different excitation modulation schemes. The surface-confined TIR excitation field generates a signal from the fluorescent molecules close to the glass surface. Thereby, a high selectivity and low background noise is obtained, and in combination with low duty cycles of excitation, the overall photodegradation of the fluorescent molecules of the sample can be kept low. To verify the approach, the kinetics of the triplet and radical states of the dye Rhodamine 110 were imaged and analyzed in aqueous solutions at different concentrations of dissolved oxygen and of the reducing agent ascorbic acid. The experimental results were compared to data from corresponding fluorescence correlation spectroscopy (FCS) measurements and simulations based on finite element analysis. The approach was found to accurately determine relative populations and dynamics of triplet and photo-oxidized states, overcoming passage time limitations seen in FCS measurements. The method circumvents the need for time resolution in the fluorescence detection, allowing simultaneous readout over the whole surface area subject to excitation. It can be applied over a broad range of concentrations and does not require a strong fluorescence brightness of the sample molecules. Given the sensitivity of the triplet and photo-oxidized states to oxygen concentrations and not the least to local redox environments, we expect the approach to become an attractive tool for imaging cell metabolism.

Assessment of transferrin recycling by Triplet Lifetime Imaging in living cells

An optical method is presented that allows the measurement of the triplet lifetime of a fluorescent molecule. This is a characteristic specific to each fluorophore. Based on differences in triplet lifetimes of two fluorescent species (autofluorescence versus label), this novel approach measures relative quantities of a transmembrane receptor and associated fluorescently labeled ligand during its recycling in living cells. Similarly to fluorescence-lifetime based methods, our approach is almost insensitive to photobleaching. A simple theory for unmixing two known triplet lifetimes is presented along with validation of the method by measurements of transferrin recycling in a model system based on chinese hamster ovarian cells (CHO). Transferrin is the delivery carrier for Fe3+ to the cell.

Imaging of G protein-coupled receptors in solid-supported planar membranes at the single molecule level

Odorant receptors are an excellent example of natural superiority in specifically binding specific, small and hydrophobic molecules. They are of particular interest in the development of a sensor platform for G protein-coupled receptors (GPCRs). Odorant receptors (OR5) of Rattus norvegicus were incorporated into model membranes by in vitro synthesis and vectorial incorporation for achieving natural receptor function. The vectorial insertion of OR5 into the planar membrane and their lateral distribution, their interactions and their mobility within the membrane are of great importance for ligand-receptor interaction. We applied total internal reflection fluorescence (TIRF) microscopy and image analysis to assess the insertion and the OR5 distribution as well as the lateral mobility of these receptors at the single molecule level. The vectorial incorporation of OR5 into planar lipid membranes was investigated with TIRF microscopy and image segmentation. With increasing expression time, the OR5 incorporation density and aggregation increased linearly by about 0.02μm-2min-1. The expression and incorporations of single OR5s were completed within about 8 minutes. The mobility of the incorporated receptors was measured with fluorescence correlation spectroscopy (FCS) and fluorescence recovery after photo-bleaching (FRAP). These measurements revealed that the incorporated receptors were immobilized with this class of lipid membranes.

k-Microscopy: resolution beyond the diffraction limit

We present a novel Fourier domain method for microscopic imaging - so-called k-microscopy - with lateral resolution independent of the detection numerical aperture. The concept is based on sample illumination by a lateral fringe-pattern of varying spatial frequency, which probes the lateral spatial frequency or k- spectrum of the sample structure. The illumination pattern is realized by interference of two collimated coherent beams. Wavelength tuning is employed for modulation of the fringe spacing. The uniqueness of the proposed system is that a single point detector is sufficient to collect the total light corresponding to a particular position in the sample k-space. By shifting the phase of the interference pattern, we get full access to the complex frequencies. An inverse Fourier transformation of the acquired band in the frequency- or k-space will reconstruct the sample. The resulting lateral resolution will be defined by the temporal coherence length associated with the detected light source spectrum as well as by the illumination angle. The feasibility of the concept has been demonstrated in 1D.

Assessing the Cellular Uptake Pathway for Poly-Lysine Analogues using Triplet Lifetime Imaging

Research on synthetic delivery vectors is of major interest for cell imaging and manipulation, as they allow an efficient transfer of nucleic acids, therapeutic proteins or small drugs into the cells. We have developed a library of L-lysine analogues that allow for highly efficient gene delivery with low cytotoxicity. However little is known on the exact mechanism of uptake and the final intracellular destination of the synthetic carriers. Therefore we have developed a novel optical technique based on a modulated excitation allowing for intracellular imaging of the triplet-lifetime and -yield of fluorophores attached to the delivery vector. Both these parameters are highly dependant on the intracellular environment thus provide insight into the subcellular localization of the labelled carrier. The method combines high temporal and spatial resolution and is compatible with a multiplicity of fluorophores. We performed series of model experiments to compare the triplet lifetime and triplet yield behaviour during the natural uptake mechanism to a series of controlled conditions. The latter include microinjection of fluorescently labelled carriers directly into the cytoplasm and cell nucleus as well as in vitro measurements under conditions mimicking physiological, acidic, or DNA rich environments. To validate our technique the results from the triplet imaging were compared with two complementary methods: carrier localization by subcellular fractionation and confocal laser scanning microscopy. --- Reference --- Geissbuehler et al. Triplet imaging of Oxygen consumption during the contraction of a single smooth muscle cell (A7r5). Biophysical Journal (2010) vol. 98 (2) pp. 339-349

Fast focus field calculations

We present a method for fast calculation of the electromagnetic field near the focus of an objective with a high numerical aperture (NA). Instead of direct integration, the vectorial Debye diffraction integral is evaluated with the fast Fourier transform for calculating the electromagnetic field in the entire focal region. We generalize this concept with the chirp z transform for obtaining a flexible sampling grid and an additional gain in computation speed. Under the conditions for the validity of the Debye integral representation, our method yields the amplitude, phase and polarization of the focus field for an arbitrary paraxial input field in the aperture of the objective. Our fast calculation method is particularly useful for engineering the point-spread function or for fast image deconvolution. We present several case studies by calculating the focus fields of high NA oil immersion objectives for various amplitude, polarization and phase distributions of the input field. In addition, the calculation of an extended polychromatic focus field generated by a Bessel beam is presented. This extended focus field is of particular interest for Fourier domain optical coherence tomography because it preserves a lateral resolution of a few micrometers over an axial distance in the millimeter range.