Three-Dimensional Reconstruction of Erythrocytes by Corrective Realignment of the Transmission Electron Microscopy Cross-Section Images (CAT#: STEM-MIT-0025-LJX)

Introduction

The detailed kinetics study of erythrocyte deformability is useful for the early diagnosis of blood diseases and for monitoring the blood rheology. Present solutions for a three-dimensional (3D) reconstruction of erythrocytes has a limited potential. The morphologic relationship between adjacent ETIs can be evaluated using the transmission electron image of erythrocytes, and a 3D model of erythrocytes can be generated.

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Principle Applications Procedure Materials Notes

Principle

Transmission electron microscopy (TEM) is to project the accelerated and concentrated electron beam onto a very thin sample, and the electron collides with the atoms in the sample and changes the direction, thus generating the stereo scattering Angle. The size of the scattering Angle is related to the density and thickness of the sample, so the image can be formed with different shades. The image can be enlarged, focused and displayed on imaging devices such as fluorescent screens, film and photosensitive coupling components. The resolution of transmission electron microscope is much higher than that of optical microscope, can reach 0.1~0.3nm, magnification of tens of thousands to millions of times. Therefore, transmission electron microscopy can be used to observe the fine structure of the sample.

Applications

Microscopic imaging in materials science or biology.

Procedure

1. Sampling
2. Preparation of slices
3. Staining (Select according to the specific experimental situation)
4. Observation

Materials

• Sample Type:
Erythrocytes

Notes

Pay attention to air humidity
Voltage needs to be stabilized

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