Laser capture microdissection

Laser capture microdissection (LCM), also called microdissection, laser microdissection (LMD), or laser-assisted microdissection (LMD or LAM), is a method for isolating specific cells of interest from microscopic regions of tissue/cells/organisms (dissection on a microscopic scale with the help of a laser). Laser capture microdissection (LCM), also called microdissection, laser microdissection (LMD), or laser-assisted microdissection (LMD or LAM), is a method for isolating specific cells of interest from microscopic regions of tissue/cells/organisms (dissection on a microscopic scale with the help of a laser). Laser-capture microdissection (LCM) is a method to procure subpopulations of tissue cells under direct microscopic visualization. LCM technology can harvest the cells of interest directly or can isolate specific cells by cutting away unwanted cells to give histologically pure enriched cell populations. A variety of downstream applications exist: DNA genotyping and loss-of-heterozygosity (LOH) analysis, RNA transcript profiling, cDNA library generation, proteomics discovery and signal-pathway profiling. The total time required to carry out this protocol is typically 1–1.5 h. A laser is coupled into a microscope and focuses onto the tissue on the slide. By movement of the laser by optics or the stage the focus follows a trajectory which is predefined by the user. This trajectory, also called element, is then cut out and separated from the adjacent tissue. After the cutting process, an extraction process has to follow if an extraction process is desired. More recent technologies utilize non-contact microdissection. There are several ways to extract tissue from a microscope slide with a histopathology sample on it. Press a sticky surface onto the sample and tear out. This extracts the desired region, but can also remove particles or unwanted tissue on the surface, because the surface is not selective. Melt a plastic membrane onto the sample and tear out. The heat is introduced, for example, by a red or infrared (IR) laser onto a membrane stained with an absorbing dye. As this adheres the desired sample onto the membrane, as with any membrane that is put close to the histopathology sample surface, there might be some debris extracted. Another danger is the introduced heat: Some molecules like DNA, RNA, or protein don't allow to be heated too much or at all for the goal of being isolated as purely as possible. For transport without contact. There are three different approaches. Transport by gravity using an upright microscope (called GAM, gravity-assisted microdissection) or transport by laser pressure catapult; the most recent generation utilizes a technology based on laser induced forward transfer (LIFT). With cut-and-capture, a cap coated with an adhesive is positioned directly on the thinly cut (5-8 µm) tissue section, the section itself resting on a thin membrane (polyethylene naphthalene). An IR laser gently heats the adhesive on the cap fusing it to the underlying tissue and an UV laser cuts through tissue and underlying membrane. The membrane-tissue entity now adheres to the cap and the cells on the cap can be used in downstream applications (DNA, RNA, protein analysis). Under a microscope using a software interface, a tissue section (typically 5-50 micrometres thick) is viewed and individual cells or clusters of cells are identified either manually or in semi-automated or more fully automated ways allowing the imaging and then automatic selection of targets for isolation. Currently six primary isolation/collection technologies exist using a microscope and device for cell isolation. Four of these typically use an ultraviolet pulsed laser (355 nm) for the cutting of the tissues directly or the membranes/film, and sometimes in combination with an IR laser responsible for heating/melting a sticky polymer for cellular adhesion and isolation. IR laser provides a more gentle approach to microdissection. A fifth ultraviolet laser based technology uses special slides coated with an energy transfer coating which, when activated by the laser pulse, propels the tissue or cells into a collection cap. The laser cutting width is usually less than 1 µm, thus the target cells are not affected by the laser beam. Even live cells are not damaged by the laser cutting and are viable after cutting for cloning and reculturing as appropriate. The various technologies differ in the collection process, possible imaging methods (fluorescence microscopy/bright field microscopy/differential interference contrast microscopy/phase contrast microscopy/ etc.) and the types of holders and tissue preparation needed before the imaging and isolation. Most are primarily dedicated micro-dissection systems, and some can be used as research microscopes as well, only one technology (#2 here, Leica) uses an upright microscope, limiting some of the sample handling capabilities somewhat, especially for live cell work. The first technology (used by Carl Zeiss PALM) cuts around the sample then collects it by a 'catapulting' technology. The sample can be catapulted from a slide or special culture dish by a defocused U.V laser pulse which generates a photonic force to propel the material off the slide/dish, a technique sometimes called Laser Micro-dissection Pressure Catapulting (LMPC). The dissected material is sent upward (up to several millimetres) to a microfuge tube cap or other collector which contains either a buffer or a specialized tacky material in the tube cap that the tissue will adhere to. This active catapulting process avoids some of the static problems when using membrane-coated slides.