Metallographic microscope can make accurate observation of cell structure

Based on the principle of optics, metallographic microscope can magnify tiny cell structure to the scale visible to the naked eye through the magnification of objective lens and eyepiece. The key lies in the high numerical aperture and high identification rate of objective lens, which makes the fine structure inside the cell clearly presented. In addition, metallographic microscope is also equipped with advanced lighting system and adjustment device to ensure sufficient and uniform light during observation, which further improves the accuracy and clarity of observation.
Accurate observation of cell structure
Cell nucleus and chromatin: metallographic microscope can clearly observe the morphology, size and position of cell nucleus, as well as the distribution and morphological changes of chromatin. This is of great significance for studying processes such as cell proliferation, differentiation and apoptosis.
Cell organelle: metallographic microscope can observe the morphology and structure of various cell organelles, such as mitochondria, endoplasmic reticulum, Golgi body, etc. These cell organelles play a key role in cell metabolism, material transport and secretion. By observing their morphological changes, the physiological state and pathological changes of cells can be inferred.
Cytoplasm and cytoskeleton: metallographic microscope can also observe the distribution of cytoplasm and the morphology of cytoskeleton. The cytoskeleton is a network structure composed of protein fibers, which plays an important role in maintaining the morphology and stability of cells. By observing the changes in the cytoskeleton, we can understand the response and adaptation mechanism of cells under stress or pathological conditions.
Cell connection and extracellular matrix: Metallographic microscope can also observe the connection between cells and the morphology of extracellular matrix. Cell connection plays an important role in maintaining the integrity and function of tissues, while the extracellular matrix provides a microenvironment for cell growth and differentiation. By observing these structures, we can gain a deeper understanding of the interaction and regulatory mechanism between cells and tissues.