The disclosure describes assemblies and systems for use in reel-to-reel imaging of ultrathin samples. The assemblies and the systems disclosed herein are adapted for use with a plurality of detectors and are configured for use in a variety of electron microscopes. Also, methods of using such assemblies and systems are disclosed.

A plurality of accessory components for use in respective reel to reel sectioning, serial sectioning, and array tomography sectioning described herein incorporate mechanical and electro-mechanical engineering to provide accessory tools for attachment to and use with a microtome, as shown in several of the figures of this disclosure.

A sample sectioning device including a cutting mechanism that is operable to cut sections from a sample, a sample holder operable to move relative to the cutting mechanism, the sample holder having a first side and a second side, the first side faces the cutting mechanism and is dimensioned to receive a sample, a light source coupled to the sample holder, wherein the light source is operable to emit a light from the first side of the sample holder and through a sample positioned on the first side, and a generator operable to generate an electrical energy for providing power to the light source.

Methods, apparatuses and systems for facilitating automated or semi-automated collection of tissue samples cut by a microtome. In one example, a collection apparatus may be moved back and forth between respective positions at which the collection apparatus is operatively coupled to a microtome so as to collect cut tissue samples, or routine access to the microtome is provided. Relatively easy movement and positioning of the collection apparatus is facilitated, while at the same time ensuring structural stability and appropriate alignment and/or isolation between the collection apparatus and the microtome. A fluid reservoir receives samples cut by the microtome, and the collection apparatus may collect samples via a conveyor-like substrate disposed near/in the reservoir. A linear movement of the substrate may be controlled based on a cutting rate of the microtome, and the fluid level in the reservoir may be automatically maintained to facilitate effective sample collection.

The invention relates to a microtome, having a sectioning knife and having a specimen head (5) movable relative to the sectioning knife; having an electric drive system (16) for motorized movement of the specimen head (5); having a sensor (21) for detecting the presence of the specimen head (5) at a reference position (z1); and having a control device (18) for controlling the electric drive system (16) and for processing signals of the sensor (21), the control device (18) being configured to control the electric drive system (16) to move the specimen head (5) and to halt the specimen head (5) in reaction to detection of the presence of the specimen head (5) at the reference position (z1).

The present disclosure relates to methods and apparatuses for sectioning and imaging tissue or other samples, which are then automatically captured to enable subsequent analysis. The apparatus acts as a slice capture mechanism for serial sectioning microscopy in a fashion which enables subsequent interfacing with secondary microscopic interrogations or for processing with molecular diagnostic tools. The slices are spatially indexed to allow specific slices to be recalled from a library via automated handling techniques described herein.

Methods, apparatuses and systems for facilitating automated or semi-automated collection of tissue samples cut by a microtome. In one example, a collection apparatus may be moved back and forth between respective positions at which the collection apparatus is operatively coupled to a microtome so as to collect cut tissue samples, or routine access to the microtome is provided. Relatively easy movement and positioning of the collection apparatus is facilitated, while at the same time ensuring structural stability and appropriate alignment and/or isolation between the collection apparatus and the microtome. A fluid reservoir receives samples cut by the microtome, and the collection apparatus may collect samples via a conveyor-like substrate disposed near/in the reservoir. A linear movement of the substrate may be controlled based on a cutting rate of the microtome, and the fluid level in the reservoir may be automatically maintained to facilitate effective sample collection.

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, under-cutting 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.

Methods, apparatuses and systems for facilitating automated or semi-automated collection of tissue samples cut by a microtome. In one example, a collection apparatus may be moved back and forth between respective positions at which the collection apparatus is operatively coupled to a microtome so as to collect cut tissue samples, or routine access to the microtome is provided. Relatively easy movement and positioning of the collection apparatus is facilitated, while at the same time ensuring structural stability and appropriate alignment and/or isolation between the collection apparatus and the microtome. A fluid reservoir receives samples cut by the microtome, and the collection apparatus may collect samples via a conveyor-like substrate disposed near/in the reservoir. A linear movement of the substrate may be controlled based on a cutting rate of the microtome, and the fluid level in the reservoir may be automatically maintained to facilitate effective sample collection.

The disclosure relates to a microtome having a cutting knife, an object holder mounted on a slide, the slide being movable relative to the cutting knife in a cutting direction and in a thickness defining direction, movement of the slide in the thickness defining direction being performed by a first electric motor controlled by a control unit, movement of the slide in the cutting direction being performed by a second electric motor controlled by the control unit, wherein the control unit is configured to control the movement of the slide in the thickness defining direction and in the cutting direction.