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Pathological analysis of pathological specimens;
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Quantitative estimation of the degree of pathology of pathological specimens;
SEIZET Technology(Shen Zhen) Co.,LTD.
The process of linical medicine often need to evaluates the patient's etiology, pathogenesis and pathological process from the overall perspective of the patient's clinical manifestations, and then determines the diagnosis, and minimizes and cures the disease through prevention and treatment. However, if a comprehensive and quantitative analysis of the patient's pathological specimens can be performed, it will undoubtedly play a guiding role in finding the cause of the disease, pathological analysis, estimation of the extent of the disease and preoperative consultation.
Pathological analysis of pathological specimens;
Quantitative estimation of the degree of pathology of pathological specimens;
High-resolution images at all levels can be obtained, real-time observation, three-dimensional imaging, complete visible spectrum support, and ultra-high-resolution imaging in all dimensions. At present, it has been used in the research of cell morphology, three-dimensional structure reorganization, dynamic change process, etc., and provides practical research methods such as quantitative fluorescence measurement, quantitative image analysis, etc., combined with other related biotechnologies, in morphology, physiology, immunology, genetics It has been widely used in the field of molecular cell biology.
The 3D line spectrum confocal sensor is used to measure the thickness, flatness, micro-topography, micro-defects, warpage, etc. of objects. It is suitable for various high-precision measurement scenarios, such as high reflection, mirror surface, transparency, bending, tilt, Diffuse reflection, color, roughness, high contrast, can also measure the thickness and voids of transparent coatings. SZ-Spec series line spectrum confocal 3D imaging system is mainly used to solve the problem of 3D contour precision measurement, and meet the measurement and inspection needs of semiconductor, 3D glass, precision dispensing, precision parts and so on.
Breaking through the dimensional limitation of traditional optical imaging, ultra-high resolution microscopic imaging can be achieved from multiple dimensions such as three-dimensional space, time and spectrum, and it is widely used in the fields of life sciences such as gene sequencing and clinical pathology.
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