Abstract: For forming and shifting a light intensity distribution in a focal area of an objective lens, portions of coherent input light are one by one directed into non-identical two-dimensional pupil areas of a pupil of the objective lens. Each of the portions of coherent input light is collimated in the pupil. The pupil areas include a pair of two pupil areas which are axially symmetrically arranged on opposite sides of an optical axis of the objective lens. At least one of the two discrete portions of coherent input light that are directed into the pair of pupil areas is separately modulated with regard to its phase by means of an electro optical modulator such as to form the light intensity distribution in the focal area with a local intensity minimum delimited by intensity maxima and to shift the local intensity minimum laterally with regard to the optical axis.

Abstract: The invention relates to novel fluorescent dyes with multiple negatively charged groups in their ionized form which are 9-aminoacridines or 1-aminopyrene shaving of one of the following general formulae A-E: or salts or protonated forms thereof, wherein the ionizable groups are typically selected from the following: OH, SH, COOH, SO3H, OSO3H, SO2NHCN, P(O)(OH)2, P(O) (OH)2. The invention further relates to the use of these dyes as fluorescent tags, in particular for reducing sugars and glycans, and to carbohydrate-dye conjugates comprising these dyes as well as to methods for preparing the same.

Abstract: Sulfonated 2(7)-aminoacridone and 1-aminopyrene dyes and their use as fluorescent tags, in particular for carbohydrate analysis The invention relates to fluorescent dyes with multiple negatively charged groups in their ionized form which are aminoacridone sulfonamides or 1-aminopyrenes having of one of the following general formulae A-D: Formula (A), Formula (B), Formula (C), Formula (D), wherein the ionizable groups X are typically selected from the following: SH, COOH, SO3H, OSO3H, OP(O)(OH)2, OP(O)(OH)Ra, P(O)(OH)2, P(O)(OH)Ra, where Ra?C1-C4alkyl or substituted C1-C4alkyl. The invention further relates to the use of these dyes as fluorescent tags, in particular for reducing sugars and glycans.

Abstract: Disclosed are photoactivable fluorescent dye compounds of formula I: wherein: n=0, 1, 2, 3; X is selected from O, CRR?, SiRR? and GeRR?, where R and R? represent independently alkyl, cycloalkyl, alkenyl, alkynyl or aryl; Y is H, SO3H or SO3M, with M being a positively charged counterion, in particular selected from NH4+ and cations of organic ammonium compounds; R1 is H, CO2H, C(O)NH-linker-CO2H, C(O)O-ligand, C(O)NH-ligand or C(O)NH-linker-ligand; R2 may represent H, unsubstituted or substituted alkyl (including cycloalkyl); R3 and R4 may represent independently H or F; R5 is H, Me, CO2H, C(O)NH-linker-CO2H, C(O)O-ligand, C(O)NH-ligand or C(O)NH-linker-ligand; wherein the ligand moiety at each occurrence represents a reactive group or tag, capable to form a covalent or non-covalent bond or molecular complex with a target chemical entity or substance. Methods of using the compounds in imaging of fixed and living cells are also disclosed.

Abstract: A method of spatially measuring a plurality of nano-scale structures in a sample comprises the steps of: marking the individual structures at different locations with fluorescent markers, coupling the individual structures to individual positioning aids whose positions in the sample are known, exciting the fluorescent markers with excitation light for emission of fluorescence light, wherein an intensity distribution of the excitation light has a local minimum, arranging the local minimum at different positions in a close-up range around the position of respective positioning aid whose dimensions are not larger than the diffraction limit at the wavelength of the excitation light, registering the fluorescence light emitted out of the sample separately for the individual fluorescent markers and for the different positions of the minimum, and determining positions of the individual fluorescent markers in the sample from the intensities of the fluorescence light registered.

Abstract: For forming and shifting a light intensity distribution in a focal area of an objective lens, portions of coherent input light are one by one directed into non-identical two-dimensional pupil areas of a pupil of the objective lens. Each of the portions of coherent input light is collimated in the pupil. The pupil areas include a pair of two pupil areas which are axially symmetrically arranged on opposite sides of an optical axis of the objective lens. At least one of the two discrete portions of coherent input light that are directed into the pair of pupil areas is separately modulated with regard to its phase by means of an electro optical modulator such as to form the light intensity distribution in the focal area with a local intensity minimum delimited by intensity maxima and to shift the local intensity minimum laterally with regard to the optical axis.

Abstract: For spatial high resolution determining a position of a singularized molecule, which is excitable with excitation light for emission of luminescence light, in n spatial dimensions in a sample, the excitation light is directed onto the sample with an intensity distribution, which has a zero point and intensity increasing regions adjoining the zero point on both sides in each of the n spatial dimensions. The zero point is arranged at not more than n×3 different positions. The luminescence light emitted by the singularized molecule is separately registering for each of the different positions of the zero point. The position of the singularized molecule in the n spatial dimensions in the sample is deduced from intensities of the luminescence light separately registered for the not more than n×3 different positions of the zero point.

Abstract: For high spatial resolution imaging a structure marked with luminescence markers, light that has an effect on the emission of luminescence light by the luminescence markers is directed onto a sample with an intensity distribution having a central zero point. Scan areas of the sample are scanned with the zero point. Luminescence light emitted out of a local area including the zero point is registered and assigned to the respective location of the zero point in the sample. Several copies of an object of interest are arranged in the scan areas and subjected to varying surrounding conditions. The individual scan areas are scanned with the respective zero point at least two times at two different stages of reactions to the varying surrounding conditions. Dimensions of the scan areas are limited such that they are not larger than 75% of a distance of intensity maxima delimiting the zero point.

Abstract: For spatial high resolution determining a position of a singularized molecule, which is excitable with excitation light for emission of luminescence light, in a sample, the excitation light is provided with an intensity distribution comprising an intensity increasing region with a known strictly monotonic course of an intensity of the luminescence light over a distance of the singularized molecule to a model point of the intensity distribution. The model point is arranged at different preliminary positions such that the intensity increasing region extends over a preliminary local area of the sample including the singularized molecule. From intensity values including intensities of the luminescence light separately registered for the preliminary positions of the model point, a further local area is determined which includes the singularized molecule and which is smaller than the preliminary local area. These steps are repeated using the last further local area as the next preliminary local area.

Abstract: For spatial high resolution determining a position of a singularized molecule, which is excitable with excitation light for emission of luminescence light, in n spatial dimensions in a sample, a preliminary local area including the singularized molecule is determined The excitation light is directed onto the sample with an intensity distribution, which has a zero point and intensity increasing regions adjoining the zero point on both sides in each of the n spatial dimensions. At first, the zero point is arranged at preliminary positions on known sides of the preliminary local area. Then, present positions of the zero point are successively shifted into the preliminary local area in each of the n spatial dimensions depending on photons of the luminescence light which is quasi-simultaneously separately registered for the present positions of the zero point in that the zero point is repeatedly shifted between the present positions of the zero point.

Abstract: A method of spatially measuring a plurality of nano-scale structures in a sample comprises the steps of: marking the individual structures at different locations with fluorescent markers, coupling the individual structures to individual positioning aids whose positions in the sample are known, exciting the fluorescent markers with excitation light for emission of fluorescence light, wherein an intensity distribution of the excitation light has a local minimum, arranging the local minimum at different positions in a close-up range around the position of respective positioning aid whose dimensions are not larger than the diffraction limit at the wavelength of the excitation light, registering the fluorescence light emitted out of the sample separately for the individual fluorescent markers and for the different positions of the minimum, and determining positions of the individual fluorescent markers in the sample from the intensities of the fluorescence light registered.

Abstract: A method of spatially measuring a plurality of nano-scale structures in a sample comprises the steps of: marking the individual structures at different locations with fluorescent markers, coupling the individual structures to individual positioning aids whose positions in the sample are known, exciting the fluorescent markers with excitation light for emission of fluorescence light, wherein an intensity distribution of the excitation light has a local minimum, arranging the local minimum at different positions in a close-up range around the position of respective positioning aid whose dimensions are not larger than the diffraction limit at the wavelength of the excitation light, registering the fluorescence light emitted out of the sample separately for the individual fluorescent markers and for the different positions of the minimum, and determining positions of the individual fluorescent markers in the sample from the intensities of the fluorescence light registered.

Abstract: The invention relates to novel cell-penetrating fluorescent dyes with secondary alcohol functionalities having one of the following general formulae I-III and 4: The invention also relates to the use of these compounds for optical microscopy and imaging techniques.

Abstract: For spatial high resolution determining a position of a singularized molecule, which is excitable with excitation light for emission of luminescence light, in a sample, the excitation light is provided with an intensity distribution comprising an intensity increasing region with a known strictly monotonic course of an intensity of the luminescence light over a distance of the singularized molecule to a model point of the intensity distribution. The model point is arranged at different preliminary positions such that the intensity increasing region extends over a preliminary local area of the sample including the singularized molecule. From intensity values including intensities of the luminescence light separately registered for the preliminary positions of the model point, a further local area is determined which includes the singularized molecule and which is smaller than the preliminary local area. These steps are repeated using the last further local area as the next preliminary local area.

Abstract: For spatial high resolution determining a position of a singularized molecule, which is excitable with excitation light for emission of luminescence light, in n spatial dimensions in a sample, a preliminary local area including the singularized molecule is determined The excitation light is directed onto the sample with an intensity distribution, which has a zero point and intensity increasing regions adjoining the zero point on both sides in each of the n spatial dimensions. At first, the zero point is arranged at preliminary positions on known sides of the preliminary local area. Then, present positions of the zero point are successively shifted into the preliminary local area in each of the n spatial dimensions depending on photons of the luminescence light which is quasi-simultaneously separately registered for the present positions of the zero point in that the zero point is repeatedly shifted between the present positions of the zero point.

Abstract: For spatial high resolution determining a position of a singularized molecule, which is excitable with excitation light for emission of luminescence light, in n spatial dimensions in a sample, the excitation light is directed onto the sample with an intensity distribution, which has a zero point and intensity increasing regions adjoining the zero point on both sides in each of the n spatial dimensions. The zero point is arranged at not more than n×3 different positions. The luminescence light emitted by the singularized molecule is separately registering for each of the different positions of the zero point. The position of the singularized molecule in the n spatial dimensions in the sample is deduced from intensities of the luminescence light separately registered for the not more than n×3 different positions of the zero point.

Abstract: For high spatial resolution imaging a structure marked with luminescence markers, light that has an effect on the emission of luminescence light by the luminescence markers is directed onto a sample with an intensity distribution having a central zero point. Scan areas of the sample are scanned with the zero point. Luminescence light emitted out of a local area including the zero point is registered and assigned to the respective location of the zero point in the sample. Several copies of an object of interest are arranged in the scan areas and subjected to varying surrounding conditions. The individual scan areas are scanned with the respective zero point at least two times at two different stages of reactions to the varying surrounding conditions. Dimensions of the scan areas are limited such that they are not larger than 75% of a distance of intensity maxima delimiting the zero point.

Abstract: A method of spatially measuring a plurality of nano-scale structures in a sample comprises the steps of: marking the individual structures at different locations with fluorescent markers, coupling the individual structures to individual positioning aids whose positions in the sample are known, exciting the fluorescent markers with excitation light for emission of fluorescence light, wherein an intensity distribution of the excitation light has a local minimum, arranging the local minimum at different positions in a close-up range around the position of respective positioning aid whose dimensions are not larger than the diffraction limit at the wavelength of the excitation light, registering the fluorescence light emitted out of the sample separately for the individual fluorescent markers and for the different positions of the minimum, and determining positions of the individual fluorescent markers in the sample from the intensities of the fluorescence light registered.

Abstract: For high spatial resolution imaging a structure in a sample, the structure being marked with luminescence markers, light that has an effect on the emission of luminescence light by the luminescence markers is directed onto the sample with an intensity distribution having a zero point and intensity maxima neighboring the zero point in at least one direction. A scan area which is a part of the sample is scanned with the zero point. Luminescence light emitted out of a local area including the zero point is registered and assigned to the respective location of the zero point in the sample. Dimensions of the scan area, in at least one direction in which the intensity maxima are neighboring the zero point, are limited such that they are not larger than 75% of a distance of the intensity maxima in the at least one direction.

Abstract: A scanning luminescence light microscope for spatial high resolution imaging a structure marked with a luminescent marker comprises a light source for luminescence inhibition light and for further light; a light shaping and aligning device; and a detector registering luminescence light emitted by the luminescent marker. The device, by means of two optical gratings and an objective lens, forms two crossing line gratings of the luminescence inhibition light, and two crossing line gratings of the further light so that local intensity minima of an overall intensity distribution of the luminescence inhibition light are delimited in at least two directions, and that local intensity maxima or local intensity minima of an overall intensity distribution of the further light coincide with the local intensity minima of the luminescence inhibition light. Further, the device moves the overall intensity distributions of the further light and the luminescence inhibition light to scan the structure.