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Beijing Kairuiyong Technology Co., Ltd
Zeiss inverted microscope
NegotiableUpdate on 02/03
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Overview
Zeiss inverted microscope is widely used in fields such as cell biology, histology, and pathology, especially for studies that require observation of liquid samples or samples in large containers. They are very suitable for observing cell cultures, tissue sections, and other samples with flat bottoms.
Product Details
Zeiss inverted microscopeThe design of the microscope is different from traditional microscopes, especially in the configuration of the optical path and the way the sample is observed. The following is the basic principle of inverted microscope:
1. Optical path configuration
In an inverted microscope, the layout of the optical system is opposite to that of a traditional microscope. The optical path of traditional microscopes is to reach the sample through the objective lens from above, while inverted microscopes observe the sample through the objective lens from below. This design places the sample at the bottom of the microscope, while the light source and detection system are located at the top of the microscope.
2. Position of objective lens and light source
① In an inverted microscope, the objective lens is installed at the bottom of the microscope, below the sample. This allows the objective lens to observe from the bottom of the sample, making it suitable for samples with flat bottoms such as culture dishes and cell culture plates.
② The light source is located above the microscope and illuminates the bottom of the sample through an optical system such as a condenser. The light source usually includes LED or halogen lamps, providing uniform illumination.
3. Observation and imaging
① The sample is illuminated from the bottom, and the light penetrates upwards through the sample before being focused onto the image sensor or eyepiece through the objective lens. Inverted microscopes can use different illumination techniques such as bright field, phase contrast, and fluorescence to observe samples.
② After being imaged through an objective lens, the image is converted into a visible image through a lens system such as an eyepiece or digital camera. Inverted microscopes are typically equipped with advanced imaging systems that can support high-resolution and high contrast image acquisition.
4. Sample operation
The design of inverted microscopes is particularly suitable for applications that require frequent manipulation of samples. For example, in cell culture and in vivo observation, samples need to be placed under a microscope, which makes it easy to add reagents, adjust samples, and perform other operations.
5. Application
Inverted microscopes are widely used in fields such as cell biology, histology, and pathology, especially for studies that require observation of liquid samples or samples in large containers. They are very suitable for observing cell cultures, tissue sections, and other samples with flat bottoms.
1. Optical path configuration
In an inverted microscope, the layout of the optical system is opposite to that of a traditional microscope. The optical path of traditional microscopes is to reach the sample through the objective lens from above, while inverted microscopes observe the sample through the objective lens from below. This design places the sample at the bottom of the microscope, while the light source and detection system are located at the top of the microscope.
2. Position of objective lens and light source
① In an inverted microscope, the objective lens is installed at the bottom of the microscope, below the sample. This allows the objective lens to observe from the bottom of the sample, making it suitable for samples with flat bottoms such as culture dishes and cell culture plates.
② The light source is located above the microscope and illuminates the bottom of the sample through an optical system such as a condenser. The light source usually includes LED or halogen lamps, providing uniform illumination.
3. Observation and imaging
① The sample is illuminated from the bottom, and the light penetrates upwards through the sample before being focused onto the image sensor or eyepiece through the objective lens. Inverted microscopes can use different illumination techniques such as bright field, phase contrast, and fluorescence to observe samples.
② After being imaged through an objective lens, the image is converted into a visible image through a lens system such as an eyepiece or digital camera. Inverted microscopes are typically equipped with advanced imaging systems that can support high-resolution and high contrast image acquisition.
4. Sample operation
The design of inverted microscopes is particularly suitable for applications that require frequent manipulation of samples. For example, in cell culture and in vivo observation, samples need to be placed under a microscope, which makes it easy to add reagents, adjust samples, and perform other operations.
5. Application
Inverted microscopes are widely used in fields such as cell biology, histology, and pathology, especially for studies that require observation of liquid samples or samples in large containers. They are very suitable for observing cell cultures, tissue sections, and other samples with flat bottoms.
