The present invention relates to the technical field of identification on adulterated meat, and in particular, to a method for identifying raw meat and high-quality fake meat based on a gradual linear array change of a component. The present invention spatially characterizes changing rules of featured components in the meat with the utilization of sensitivities of the visible/near-infrared spectral signals to changes of the components in the meat and the advantage that spectral scanning can acquire optical signals of the samples spatially and consecutively, further constructs the identification model according to differences in components and spectra of a region of interest in the hyperspectral image by taking a derivative for characterizing rates of change of the featured components.

A blade clamping device for a microtome is provided. The blade clamping device includes: a base part; a pressure plate rotatably connected to the base part via a rotation shaft; a clamping pin received in the base part, and configured to extend out of the base part and push the pressure plate to rotate, so as to clamp a blade between the base part and the pressure plate; and a drive unit received in the base part, connected to the clamping pin and configured to drive the clamping pin to extend out of the base part.

A blade clamping device for a microtome is provided. The blade clamping device includes: a base part; a pressure plate rotatably connected to the base part via a rotation shaft; a clamping pin received in the base part, and configured to extend out of the base part and push the pressure plate to rotate, so as to clamp a blade between the base part and the pressure plate; and a drive unit received in the base part, connected to the clamping pin and configured to drive the clamping pin to extend out of the base part.

The present invention relates to systems and methods for sequential operation of staining, imaging and sectioning of tissue samples by a processing system. After each layer of the sample is removed by the sectioning system, the system automatically stains the exposed surface of a sample to a depth to enable imaging of the remaining tissue. The system then repeats the sectioning, staining and imaging steps in sequence to image the sample.

The present invention relates to systems and methods for sequential operation of staining, imaging and sectioning of tissue samples by a processing system. After each layer of the sample is removed by the sectioning system, the system automatically stains the exposed surface of a sample to a depth to enable imaging of the remaining tissue. The system then repeats the sectioning, staining and imaging steps in sequence to image the sample.

Apparatuses for cutting tissue include an oscillator assembly and a clamp. The oscillator assembly defines a resonance frequency and includes a frame, an excitation element, and a blade. The frame has an upper portion and a lower portion, and the lower portion is configured to oscillate relative to the upper portion. The excitation element is coupled with the lower portion of the frame, and the excitation element is selectively operable to provide an excitation signal to the oscillator assembly sufficient to cause the oscillator assembly to oscillate at the resonance frequency. The blade is coupled with the lower portion for sectioning tissue. The clamp is selectively moveable along the frame to alter the resonance frequency of the oscillator assembly.

Apparatuses for cutting tissue include an oscillator assembly and a clamp. The oscillator assembly defines a resonance frequency and includes a frame, an excitation element, and a blade. The frame has an upper portion and a lower portion, and the lower portion is configured to oscillate relative to the upper portion. The excitation element is coupled with the lower portion of the frame, and the excitation element is selectively operable to provide an excitation signal to the oscillator assembly sufficient to cause the oscillator assembly to oscillate at the resonance frequency. The blade is coupled with the lower portion for sectioning tissue. The clamp is selectively moveable along the frame to alter the resonance frequency of the oscillator assembly.

A sectioning system includes a chuck assembly configured to receive a tissue block, a cutting assembly configured to remove a tissue section from the tissue block, at least one sensor configured to sense data regarding dynamics of one or more components of at least one of the chuck assembly or the cutting assembly, and a control system. The control system is configured to receive data from the at least one sensor, determine whether the data from the at least one sensor shows normal behavior of the one or more components of at least one of the chuck assembly or the cutting assembly, and output a signal if it is determined the data from the at least one sensor does not show normal behavior of the one or more components.

A sectioning system includes a chuck assembly configured to receive a tissue block, a cutting assembly configured to remove a tissue section from the tissue block, at least one sensor configured to sense data regarding dynamics of one or more components of at least one of the chuck assembly or the cutting assembly, and a control system. The control system is configured to receive data from the at least one sensor, determine whether the data from the at least one sensor shows normal behavior of the one or more components of at least one of the chuck assembly or the cutting assembly, and output a signal if it is determined the data from the at least one sensor does not show normal behavior of the one or more components.

A method is proposed for generating a series of ultra-thin sections of a microscopic sample (10), wherein the sections (11) are detached from the sample (10) using an ultramicrotome (100) and wherein the sections (11), which are detached from the sample (10) are caused to float on a liquid surface and are thereafter transferred onto a solid carrier element (20). For at least for some of the sections (11) detached from the sample (10) a position and an orientation on the solid carrier element (20) are determined by monitoring the placement of these sections (11) onto the solid carrier element (20) using a monitoring system (400) comprising a camera (410), obtaining monitoring data. A method (2000) for the three-dimensional reconstruction of a microscopic sample (10), a microtome system and a computer program are also part of the present invention.