Abstract: Systems and methods for laser capture microdissection are disclosed. An inverted microscope includes an illumination/laser beam delivery system that is adapted to both illuminate a sample and provide energy for laser capture microdissection of the sample. The systems and methods provide the advantages of increased speed and much lower rates of contamination.

Abstract: A thermoplastic film for LCM tissue transfer is thermally coupled to a broadband energy-absorbing material. The broadband energy-absorbing material may either be introduced into the film composition as a dopant or may be in thermal contact with the film.

Abstract: Systems and methods for laser capture microdissection are disclosed. An inverted microscope includes an illumination/laser beam delivery system that is adapted to both illuminate a sample and provide energy for laser capture microdissection of the sample. The systems and methods provide the advantages of increased speed and much lower rates of contamination.

Abstract: A thermoplastic film for LCM tissue transfer is thermally coupled to a broadband energy-absorbing material. The broadband energy-absorbing material may either be introduced into the film composition as a dopant or may be in thermal contact with the film.

Abstract: Systems and methods for laser capture microdissection are disclosed. An inverted microscope includes a translation stage joystick subsystem. The systems and methods provide the advantages of increased speed and much lower rates of contamination.

Abstract: Systems and methods for laser capture microdissection are disclosed. A method of laser capture microdissection includes providing a sample that is to undergo laser capture microdissection; positioning said sample within an optical axis of a laser capture microdissection instrument; providing a transfer film carrier having a substrate surface and a laser capture microdissection transfer film coupled to said substrate surface; placing said laser capture microdissection transfer film in juxtaposition with said sample with a pressure sufficient to allow laser capture microdissection transfer of a portion of said sample to said laser capture microdissection transfer film, without forcing nonspecific transfer of a remainder of said sample to said laser capture microdisection film; and then transferring a portion of said sample to said laser capture microdissection transfer film, without forcing nonspecific transfer of a remainder of said sample to said laser capture microdissection transfer film.

Abstract: Systems and methods for capturing and using a road map image for guiding microscopy and microdissection are disclosed. Systems for using a static reference road map image for navigation and analysis of a live image of a sample are provided. A road map camera for capturing a low resolution reference image of the sample is disclosed. Novel methods for computer-controlled navigation of the road map image are provided.

Abstract: Systems and methods for laser capture microdissection are disclosed. An inverted microscope includes a vacuum chuck subsystem that is adapted to hold a microscope slide down during the process of laser capture microdissection. The systems and methods provide the advantages of increased speed and much lower rates of contamination.

Abstract: The present invention generally discloses an extraction system that provides a locale for fluid processing and extraction on a post-microcapture transfer film. The extraction system includes a transfer film carrier and an extraction device forming a reservoir. The extraction system selectively excludes regions of the transfer film from the reservoir to advantageously reduce contamination due to matter adhered to the transfer film by non-specific transfer.

Abstract: Systems and methods for acquiring laser capture microdissection samples are disclosed. An integral portion of a biological reaction vessel includes a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to the substrate surface of the transfer film carrier. The systems and methods facilitate quick and accurate laser capture microdissection while simultaneously minimizing contamination.

Abstract: The present invention generally provides an improved transfer film having multiple layers for laser micro-capture of a sample. The transfer film for laser micro-capture includes distinct layers for expansion and adhesion in order to optimize the performance of the transfer film. A transfer film including a spring-back layer is also disclosed.

Abstract: A thermoplastic film for LCM tissue transfer is thermally coupled to a broadband energy-absorbing material. The broadband energy-absorbing material may either be introduced into the film composition as a dopant or may be in thermal contact with the film.

Abstract: Systems and methods for laser capture microdissection are disclosed. A method of laser capture microdissection includes providing a sample that is to undergo laser capture microdissection; positioning said sample within an optical axis of a laser capture microdissection instrument; providing a transfer film carrier having a substrate surface and a laser capture microdissection transfer film coupled to said substrate surface; placing said laser capture microdissection transfer film in juxtaposition with said sample with a pressure sufficient to allow laser capture microdissection transfer of a portion of said sample to said laser capture microdissection transfer film, without forcing nonspecific transfer of a remainder of said sample to said laser capture microdisection film; and then transferring a portion of said sample to said laser capture microdissection transfer film, without forcing nonspecific transfer of a remainder of said sample to said laser capture microdissection transfer film.

Abstract: Systems and methods for laser capture microdissection are disclosed. An inverted microscope includes an illumination/laser beam delivery system that is adapted to both illuminate a sample and provide energy for laser capture microdissection of the sample. The systems and methods provide the advantages of increased speed and much lower rates of contamination.

Abstract: Systems and methods for laser capture microdissection are disclosed.

Abstract: A laser capture microdissection lift-off substrate comprising a transparent thermoplastic film that is incorporated into substrate which may take the form of a cap or other structure associated with an analysis vessel or which may be used with a holder or other element of a LCM tissue sample transfer apparatus. The thermoplastic lift-off substrate film is held in a fixed position on the substrate which may be relative to a feature of a biological analysis vessel. The film may be affixed to a substrate which is a structure which goes into the vessel such that the sample is held in a fixed position relative to an observation port on the vessel.

Abstract: Systems and methods for acquiring laser capture microdissection samples are disclosed. A method of making a laser capture microdissection consumable includes providing a transfer film carrier having a substrate surface; and fabricating a laser capture microdissection transfer film on said substrate surface, wherein forming includes hot vacuum baking said laser capture microdissection transfer film. The systems and methods facilitate quick and accurate laser capture microdissection while simultaneously minimizing contamination.

Abstract: A laser capture microdissection lift-off substrate comprising a transparent thermoplastic film is incorporated into substrate which may take the form of a cap or other structure associated with an analysis vessel or which may be used with a holder or other element of a LCM tissue sample transfer apparatus. The thermoplastic lift-off substrate film is held in a fixed position on the substrate which may be relative to a feature of a biological analysis vessel. The film may be affixed to a substrate which is a structure which goes into the vessel such that the sample is held in a fixed position relative to an observation port on the vessel.

Abstract: A calibration method and device for a fluorescence spectrometer which uses fluorescence from a homogeneous solid state standard as the source of calibration fluorescence and wherein the solid state standard may be built into the optical scanner and the calibration may be automatically performed as a routine step when using the optical scanner. A gold standard establishes fluorescent units, and the fluorescence spectrometer is calibrated by reference to calibration standards, such as calibration rubies, which are themselves rated against the gold standard and built into the fluorescence spectrometer to provide an unchanging reference to the gold standard and by which simultaneous calibration of two or more channels of a multi-channel fluorescence spectrometer may be accomplished, including automatically calibrating a multi-channel optical scanner when it is turned on to achieve an acceptable level of sensitivity in each channel and to adjust for any relative shift in sensitivity between the channels.

Abstract: An amplitude-stable intracavity doubled laser comprises a pair of end mirrors defining a laser cavity having a length L. A laser medium having a gain region substantially smaller than the length L of the laser cavity is positioned within the laser cavity. A doubling crystal having a nonlinear conversion region substantially smaller than, the length L of the laser cavity is positioned within the laser cavity. A pump source is oriented to supply excitation energy to the laser medium. The laser medium and the doubling crystal located at positions within the laser cavity so as to cause the laser to lase in fewer than ten longitudinal modes and to output visible light with an amplitude noise of less than about 3% RMS on visible output from the laser.