A compact microscope including an enclosure, a support element, a primary optical support element located within the enclosure and supported by the support element, at least one vibration isolating mount between the support element and the primary optical support element, a sample stage supported on the primary optical support element to support a sample, a return optical system to receive returned light from a sample and transmit returned light to a detection apparatus, wherein the return optical system is mounted on the primary optical support element, and wherein the compact microscope include a at least one of the following elements; a) an objective lens system, b) a temperature-control system, and c) the return optical system being operable to separate returned light into at least a first wavelength band and a second wavelength band.

In a light microscope (1) for cryomicroscopy, encompassing at least an objective (2) and a sample stage (3) having a cutout (7) for a coolable holder (8) for a sample carrier mount, the cutout (7) being covered by a cover (6), the sample stage (3) is displaceable in two horizontal directions (4). The cover (6) rests floatingly on the sample stage (3), and the objective (2) passes through a cutout (12), corresponding to the objective (2), in the cover (6). The method for cooling a holder (8) for a sample carrier mount in a light microscope (1) for cryomicroscopes, by means of a flow of liquid nitrogen through a cooling conduit (15), open at at least one end, in the holder (8), is notable for the fact that the quantity of liquid nitrogen is dimensioned so that all of the nitrogen is present in gaseous form at at least one open end (16) of the cooling conduit (15).

In a light microscope (1) for cryomicroscopy, encompassing at least an objective (2) and a sample stage (3) having a cutout (7) for a coolable holder (8) for a sample carrier mount, the cutout (7) being covered by a cover (6), the sample stage (3) is displaceable in two horizontal directions (4). The cover (6) rests floatingly on the sample stage (3), and the objective (2) passes through a cutout (12), corresponding to the objective (2), in the cover (6). The method for cooling a holder (8) for a sample carrier mount in a light microscope (1) for cryomicroscopes, by means of a flow of liquid nitrogen through a cooling conduit (15), open at at least one end, in the holder (8), is notable for the fact that the quantity of liquid nitrogen is dimensioned so that all of the nitrogen is present in gaseous form at at least one open end (16) of the cooling conduit (15).

The present invention relates to an apparatus for simultaneous imaging and execution of contact-free directed hydrodynamic flow in a specimen with at least one light source, in particular a laser, adapted to dynamically heat the interior and/or a surface of the specimen, a microscope with an objective adapted to image at least a part of the specimen and to guide, in particular focus, a light beam of the light source, in particular a laser beam, into and/or onto the specimen to heat at least one specified location of the specimen, means for manipulating the specified location, and a sample chamber for the specimen that is accessible for imaging radiation and the light beam to allow simultaneous imaging and manipulation of the sample via the objective. Furthermore the present invention is directed to a method for simultaneous imaging and executing contact-free directed hydrodynamic flow in a specimen wherein, at least one light source, in particular a laser, dynamically heats the interior and/or a surface of the specimen via a light beam, in particular via a laser beam, the beam of the at least one light source is directed to the specimen through an objective of a microscope, the light beam is variably guided, in particular focused, to specified locations of the specimen inducing a hydrodynamic flow in the specimen, and imaging the specimen via the same objective as used for introduction of the light beam.

The present invention relates to an apparatus for simultaneous imaging and execution of contact-free directed hydrodynamic flow in a specimen with at least one light source, in particular a laser, adapted to dynamically heat the interior and/or a surface of the specimen, a microscope with an objective adapted to image at least a part of the specimen and to guide, in particular focus, a light beam of the light source, in particular a laser beam, into and/or onto the specimen to heat at least one specified location of the specimen, means for manipulating the specified location, and a sample chamber for the specimen that is accessible for imaging radiation and the light beam to allow simultaneous imaging and manipulation of the sample via the objective. Furthermore the present invention is directed to a method for simultaneous imaging and executing contact-free directed hydrodynamic flow in a specimen wherein, at least one light source, in particular a laser, dynamically heats the interior and/or a surface of the specimen via a light beam, in particular via a laser beam, the beam of the at least one light source is directed to the specimen through an objective of a microscope, the light beam is variably guided, in particular focused, to specified locations of the specimen inducing a hydrodynamic flow in the specimen, and imaging the specimen via the same objective as used for introduction of the light beam.

Provided are systems and methods for analyte detection and analysis. A system can comprise an open substrate. The open substrate may be configured to rotate or otherwise move. The open substrate can comprise an array of individually addressable locations, with analytes immobilized thereto. The substrate may be spatially indexed to identify nucleic acid molecules from one or more sources, and/or sequences thereof, with the respective one or more sources. A solution comprising a plurality of probes may be directed across the array to couple at least one of the plurality of probes with at least one of the analytes to form a bound probe. A detector can be configured to detect a signal from the bound probe via scanning of the substrate while minimizing temperature fluctuations of the substrate or optical aberrations caused by bubbles.

A wavelength de-multiplexing system that receives a wavelength multiplexed signal and generates electrical signals corresponding to the optical signals is disclosed. The optical receiver module includes a lens, a lens unit, and an optical de-multiplexer (O-DeMux). The lens converts the wavelength multiplexed signal into a quasi-collimated beam. The lens unit narrows a diameter of the quasi-collimated beam. The O-DeMux de-multiplexes the narrowed quasi-collimated beam coming from the lens unit by wavelength selective filters (WSFs) each having optical distances from the lens unit different from each other.

A wavelength de-multiplexing system that receives a wavelength multiplexed signal and generates electrical signals corresponding to the optical signals is disclosed. The optical receiver module includes a lens, a lens unit, and an optical de-multiplexer (O-DeMux). The lens converts the wavelength multiplexed signal into a quasi-collimated beam. The lens unit narrows a diameter of the quasi-collimated beam. The O-DeMux de-multiplexes the narrowed quasi-collimated beam coming from the lens unit by wavelength selective filters (WSFs) each having optical distances from the lens unit different from each other.

A device for mounting an object holder on a carrier that can be inserted into a cryostat includes at least one clamping element may be provided for non-positive connection of the object holder with the carrier. The at least one clamping element is arranged to enable damage-free mounting of the object holder on the carrier even in the case of large temperature changes, so that reproducible measuring conditions are created at large temperature changes. The at least one clamping element may be drive-connected via a lever to a piezoelectric element, which may be subjected to voltage by a control device as a function of temperature and of a bearing specification and is supported against the object holder or the carrier.

A device for mounting an object holder on a carrier that can be inserted into a cryostat includes at least one clamping element may be provided for non-positive connection of the object holder with the carrier. The at least one clamping element is arranged to enable damage-free mounting of the object holder on the carrier even in the case of large temperature changes, so that reproducible measuring conditions are created at large temperature changes. The at least one clamping element may be drive-connected via a lever to a piezoelectric element, which may be subjected to voltage by a control device as a function of temperature and of a bearing specification and is supported against the object holder or the carrier.