Microscope Manufacturers

68 Microscope manufacturers listed.
Microscopes are instruments used to magnify and visualize small objects and details that are not visible to the naked eye. The leading manufacturers of Microscopes are listed below. Narrow down on the list of companies based on their location and capabilities.
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What are Microscopes?

A microscope is an optical instrument that magnifies small objects, allowing us to see details that are invisible to the naked eye. It is widely used in biology, medicine, material science, and other fields to observe cells, microorganisms, tissues, and other tiny structures.


Components

The optical components of a microscope are essential for observing, magnifying, and imaging specimens on a slide. Here's a detailed explanation of each part and its function:

  • Eyepiece (Ocular Lens): Positioned at the top of the microscope, the eyepiece is where you look through to view the specimen. It magnifies the image produced by the objective lenses. Eyepieces commonly have magnifications of 10x or 15x, though they can range from 5x to 30x. They provide secondary magnification to the image.
  • Eyepiece Tube: This is the holder for the eyepiece, positioned just above the objective lenses. In binocular microscopes, the eyepiece tube can be adjustable or rotatable to accommodate different eye distances for optimal viewing. Monocular microscopes usually have a fixed eyepiece tube.
  • Diopter Adjustment: Found in binocular microscopes, this knob allows for individual focusing of each eyepiece. It compensates for differences in vision between the viewer's eyes, ensuring a clear image in each eyepiece.
  • Nosepiece (Revolving Turret): This rotating component holds the objective lenses and allows for easy switching between different magnifications. Located just above the stage, the nosepiece can be turned to select the desired objective lens, thus changing the magnification of the image.
  • Objective Lenses: These lenses are closest to the specimen and are mounted on the nosepiece. They provide the primary magnification of the specimen. Microscopes typically have 3 to 4 objective lenses with magnifications such as 4x, 10x, 40x, and 100x. Objective lenses are color-coded and vary in size according to their power. High-power lenses (40x and 100x) often feature retractable ends and may be oil immersion lenses for enhanced resolution.
  • Adjustment Knobs
    • Fine Adjustment Knob: Used for precise focusing by moving the stage very slowly. It fine-tunes the image clarity, especially useful at high magnifications.
    • Coarse Adjustment Knob: Used for rapid focusing, moving the stage up or down quickly. It is primarily used to bring the specimen into general focus at lower magnifications.
  • Stage: The platform where the specimen slide is placed. It includes stage clips to hold the slide in place. Mechanical stages allow precise control of the slide's position using mechanical knobs, reducing the need for manual adjustments.
  • Stage Control Knobs: These knobs control the movement of the stage, allowing the slide to be shifted horizontally (left/right) and vertically (forward/backward) to position the specimen accurately within the field of view.
  • Aperture: The hole in the stage through which light passes to illuminate the specimen.
  • Microscopic Illuminator: Provides the light source for the microscope. It can be a built-in electric bulb or a mirror reflecting light from an external source. Common types include tungsten-halogen, xenon, and mercury vapor lamps, selected based on required light intensity and wavelength.
  • Condenser: Focuses light from the illuminator onto the specimen. Located beneath the stage, it enhances image clarity and contrast, especially at high magnifications. High-quality microscopes may use an Abbe condenser for superior performance.
  • Diaphragm (Iris): Controls the amount of light reaching the specimen by adjusting the light beam's size and intensity. It is positioned under the stage and works with the condenser to improve image contrast and quality.
  • Condenser Focus Knob: Adjusts the height of the condenser to focus the light precisely on the specimen, affecting image sharpness.
  • Abbe Condenser: A high-performance condenser used in advanced microscopes, allowing for very high magnifications (above 400x). It provides enhanced control over light focus and image resolution.
  • Rack Stop: Prevents the stage from moving too close to the objective lenses, protecting both the specimen and the lenses from damage.
  • Light Switch: Controls the power to the illuminator, turning it ON or OFF.
  • Brightness Adjustment: Regulates the light intensity by adjusting the voltage supplied to the light bulb, allowing for the control over the brightness of the illumination.

Working

Basically, a microscope consists of two subsystems: an illumination system that illuminates the sample and an imaging system that produces a magnified image of the light interacting with the sample, which can then be viewed with the eye or using a camera system.

Early microscopes used sunlight for illumination, which was collected by mirrors and reflected onto the specimen. Modern microscopes, however, typically use artificial light sources such as light bulbs, LEDs, or lasers. These sources offer more reliable and controllable illumination, which can be tailored to specific applications. In contemporary systems, a condenser lens gathers light from the source, shapes it, and filters it optically before focusing it onto the sample. Proper shaping and filtering of the light are crucial for achieving high resolution and contrast. This process involves controlling the illuminated area of the sample and the angle at which the light strikes it. Optical filters can modify the light's spectrum and polarization to emphasize particular features of the sample.

The imaging system captures the light that interacts with the sample and produces a magnified image. This involves two main optical components: the objective lens, which collects light from the sample, and the eyepiece, which directs the collected light to the observer's eye or a camera system. Additionally, imaging systems may include apertures and filters to select specific portions of the light, such as light scattered from the sample or light of a certain color or wavelength. This type of filtering helps highlight features that might be obscured when all light from the sample is imaged.

Different Techniques in Microscopy

  • Brightfield Microscopy (BFM): Brightfield microscopy is the simplest optical microscopy technique. It illuminates the sample from above or below and collects the transmitted or reflected light to form an image. Contrast and color in brightfield images result from variations in absorption and reflection within the sample. While early brightfield microscopes were used to study microorganisms and cells, modern versions are still widely employed for observing transparent samples such as thin materials or microelectronics.
  • Darkfield Microscopy: Darkfield microscopy highlights light scattered by the sample rather than directly transmitted or reflected light. By blocking the direct illumination light, this technique enhances the visibility of small structures that scatter light. It provides excellent contrast for small features but requires high illumination power, which can sometimes damage the sample.
  • Phase Contrast Microscopy: Phase contrast microscopy visualizes changes in the optical phase of light as it passes through transparent samples, such as cells, which otherwise produce little contrast in brightfield microscopy. By converting phase shifts into brightness variations, this technique allows detailed observation of transparent specimens.
  • Differential Interference Contrast Microscopy (DICM): DICM is similar to phase contrast microscopy but provides higher resolution and reduced artifacts. It uses polarized light to create contrast by detecting phase differences between two polarized beams passing through the sample. This technique produces three-dimensional images with high contrast and is ideal for viewing living cells and other transparent samples.
  • Polarizing Microscopy: In polarized light microscopy, the sample is illuminated with polarized light, and the detection system is also sensitive to polarization. This technique is used to study birefringent samples, which alter the polarization of light passing through them, revealing variations in crystal thickness and refractive index.
  • Fluorescence Microscopy: Fluorescence microscopy images samples that emit light upon excitation with shorter wavelengths. This technique uses filters to block excitation light and only allow emitted fluorescence to pass through, making it possible to observe specific fluorescent markers or particles within a sample. It can achieve "super-resolution" with techniques like fluorescence tagging and advanced illumination methods.
  • Immunofluorescence microscopy: Immunofluorescence microscopy is a specific change in fluorescence microscopy that is primarily used to visualize biomolecules within the cells of microorganisms. Here, antibodies labeled with fluorescent markers or inherently fluorescent bind to biomolecules of interest, revealing their location.
  • Confocal Microscopy: Confocal microscopy scans a point of illumination across the sample and detects light from that specific point, allowing for high-resolution imaging with reduced background noise. This method creates 2D image slices at different depths, which can be combined to form a 3D image of the sample.
  • Two-Photon Microscopy (TPM): Two-photon microscopy uses two-photon absorption to excite fluorescence, allowing for deeper tissue penetration and reduced photobleaching compared to single-photon excitation. It produces high-resolution images by scanning point-by-point, similar to confocal microscopy, but with improved imaging capabilities for thicker samples.
  • Light Sheet Microscopy: Light sheet microscopy illuminates the sample with a thin sheet of light perpendicular to the observation direction. It captures 2D images of thin sections of the sample and reconstructs a 3D image by taking multiple slices. This technique is particularly useful for imaging transparent biological samples.
  • Total Internal Reflection Fluorescence Microscopy (TIRF): TIRF microscopy uses evanescent light from total internal reflection to excite fluorescence in a very thin section of the sample, about 100 nm thick. This technique is ideal for studying surface interactions and weak fluorescence signals close to the sample interface.
  • Expansion Microscopy: Expansion microscopy involves chemically expanding samples to increase their size and improve resolution. This technique allows detailed imaging of previously hidden features by expanding the sample up to 50 times its original size, making it possible to use standard microscopy methods.

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