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.

A method of sampling a multi-layered material and a micro-sampling tool are described. The sampling method includes penetrating a top surface of a material in a component of interest with a micro-cutting tool to a predetermined depth sufficient to include each layer of the multi-layered material and a portion of the base, without cutting through the full depth of the base, undercutting from the depth of penetration through the base to define a micro-sample of the multi-layered material, and removing the micro-sample with each layer of the multi-layered material intact. The micro-sampler includes a cutting tool calibrated to cut to a depth no greater than 2 mm, and in some aspects, no greater than 200 microns into a multi-layered material, the material having a top surface and a metallic or ceramic base and a container for removing and storing a micro-sample cut from the material with each layer of the multi-layered material and a portion of the base intact.

A method of sampling a multi-layered material and a micro-sampling tool are described. The sampling method includes penetrating a top surface of a material in a component of interest with a micro-cutting tool to a predetermined depth sufficient to include each layer of the multi-layered material and a portion of the base, without cutting through the full depth of the base, undercutting from the depth of penetration through the base to define a micro-sample of the multi-layered material, and removing the micro-sample with each layer of the multi-layered material intact. The micro-sampler includes a cutting tool calibrated to cut to a depth no greater than 2 mm, and in some aspects, no greater than 200 microns into a multi-layered material, the material having a top surface and a metallic or ceramic base and a container for removing and storing a micro-sample cut from the material with each layer of the multi-layered material and a portion of the base intact.

A microtomy system includes a tissue chuck configured to accept a tissue block and a microtome blade configured to remove one or more tissue sections from the tissue block, the microtome blade being axially offset from the tissue chuck along a horizontal axis, where the microtome blade and the tissue chuck are axially displaceable relative to one another along the horizontal axis. The system also includes a control system configured to receive information indicative of a relative axial location of the microtome blade to the tissue chuck along the horizontal axis, and to use a control loop to control the relative axial location of the microtome blade to the tissue chuck such that the one or more tissue sections have a desired thickness.

A microtomy system includes a tissue chuck configured to accept a tissue block and a microtome blade configured to remove one or more tissue sections from the tissue block, the microtome blade being axially offset from the tissue chuck along a horizontal axis, where the microtome blade and the tissue chuck are axially displaceable relative to one another along the horizontal axis. The system also includes a control system configured to receive information indicative of a relative axial location of the microtome blade to the tissue chuck along the horizontal axis, and to use a control loop to control the relative axial location of the microtome blade to the tissue chuck such that the one or more tissue sections have a desired thickness.

The present disclosure provides a moving and clamping device (200) for a blade holder (100) of a microtome. The blade holder (100) includes a blade receptacle (120) configured to receive and clamp a blade. The moving and clamping device (200) includes a rotary member (210) and a clamping member (220). The rotary member (210) is configured to drive the blade receptacle (120) to move in a direction perpendicular to a rotating axis of the rotary member (210), and the clamping member (220) is configured to be movable in the rotating axis of the rotary member (210), so as to operatively clamp or release the blade receptacle (120). The rotary member (210) is rotatably fitted over the clamping member (220). The present disclosure further provides a blade holder (100).

The present disclosure provides a moving and clamping device (200) for a blade holder (100) of a microtome. The blade holder (100) includes a blade receptacle (120) configured to receive and clamp a blade. The moving and clamping device (200) includes a rotary member (210) and a clamping member (220). The rotary member (210) is configured to drive the blade receptacle (120) to move in a direction perpendicular to a rotating axis of the rotary member (210), and the clamping member (220) is configured to be movable in the rotating axis of the rotary member (210), so as to operatively clamp or release the blade receptacle (120). The rotary member (210) is rotatably fitted over the clamping member (220). The present disclosure further provides a blade holder (100).

An integrated pathology system includes a tissue embedding module configured to embed a tissue sample into an embedding material to prepare a tissue block, a sectioning and slide creating module configured to remove one or more tissue sections from the tissue block and place the one or more tissue sections onto one or more slides, a staining module configured to stain the one or more tissue sections on the slides, and a cover-slipper module configured to place a cover onto the one or more stained tissue sections. The system further includes one or more transfer devices configured to integrate the modules and a processor in communication with the modules for controlling one or more processes performed by the modules and the one or more transfer devices for controlling the integration of the modules.

An integrated pathology system includes a tissue embedding module configured to embed a tissue sample into an embedding material to prepare a tissue block, a sectioning and slide creating module configured to remove one or more tissue sections from the tissue block and place the one or more tissue sections onto one or more slides, a staining module configured to stain the one or more tissue sections on the slides, and a cover-slipper module configured to place a cover onto the one or more stained tissue sections. The system further includes one or more transfer devices configured to integrate the modules and a processor in communication with the modules for controlling one or more processes performed by the modules and the one or more transfer devices for controlling the integration of the modules.

A protective housing for a microtome blade (4) includes a frame that holds the microtome blade (4) and a clip (2) that can be pivoted relative to the frame. In a first position, the clip (2) covers a cutting edge of the microtome blade (4) received in the frame. A microtome blade holder (6) is configured to receive an arrangement (100) composed of the protective housing and the microtome blade (4).