Some embodiments are directed to a dissection tool for mechanical removal of biological material from a tissue sample on a planar substrate, such a glass slide including a platform for supporting the glass slide and a positioning system configured to move the dissection tool and platform relative to each other and control their relative positions. The dissection tool has a longitudinal axis and is arranged at an oblique angle relative to the platform and a thin-walled gouging head that has a base portion. The gouging head includes opposing side portions which extend from the base portion in a direction away from the glass slide and which at least partly enclose a cavity within the gouging head for receiving biological material that is dissected when relative movement between the platform and the dissection tool causes a front face of the gouging head to gouge a track though the tissue sample.

A tissue processing chamber is disclosed. The tissue processing chamber includes at least one rotary blade housed within a tissue chamber and a drive shaft coupled to the rotary blades. Rotation of the drive shaft rotates the rotary blades and presses a tissue sample through a screen adjacent to the at least one rotary blade, wherein rotation of the at least one rotary blade presses processed tissue through the screen. The tissue processing device also includes a collection chamber coupled to the tissue chamber configured to collect the processed tissue.

The disclosure relates to a method of preparing a sample in a charged particle microscope. The method comprises the steps of providing a sample carrier having a mechanical support contour and a grid member connected thereto. The method comprises the step of connecting said sample carrier to a mechanical stage device of the charged particle microscope. Additionally, the method comprises the step of providing a sample, for example a chunk-shaped or lamella-shaped sample and connecting said sample to the grid member of the sample carrier. The method allows, in an embodiment, easy and reliable transfer of a sample between a bulk sample and a sample carrier.

The invention relates to an arrangement for preparing a plurality of samples for an analytical method, comprising a carousel with a solid housing and moveable receiving parts for the sample containers; a control for controlling the receiving parts in the carousel; and a sample receiving device for providing the sample for the analytical method. Said arrangement is characterized in that one or more stations for preparing samples are provided on the carousel, the receiving parts for the sample containers of the carousel can be positioned on said stations. Said arrangement also comprises a centrifuge with pairs of opposite lying receiving parts provided for the sample containers, and said receiving parts are arranged such that they can move on the centrifuge for the sample holder such that a transfer of a sample holder between a receiving part in the carousel and a receiving part in the centrifuge can be carried out. The control takes place by the same control which is also provided for controlling the carousel.

A measurement device includes mechanical support elements (101-104) for supporting a sample well, other mechanical support elements (105-109) for supporting a measurement head (112) suitable for optical measurements, and a control system (111) configured to control the measurement head to carry out at least two optical measurements from at least two different measurement locations inside the sample well, where each measurement location is a center point of a capture range from which radiation is captured in the respective optical measurement. The final measurement result is formed from the results of the at least two optical measurements in accordance with a pre-determined rule. The use of the at least two optical measurements from different measurement locations reduces measurement variation in situations where the sample well (153) contains a piece (158) of sample carrier.

A neurostimulation system is shown and described. The neurostimulation system may include a stimulation device implantable into a patient, a lead operatively coupled with the stimulation device, a first power cell providing power to the stimulation device where the first power cell is charged by an externally applied AC (High HF) magnetic field.

An area-specific tissue analysis (ASTA) method and system are disclosed for the precision harvesting and processing of tissue from acute brain slices (referred to herein as “brain chads”), e.g., for the purposes of cell and molecular biology/analysis. The exemplary ASTA system and method can sample tissue from hard-to-reach regions of the brain that has been cut acutely, e.g., into 100 to 500 microns-thick sections, for cell biological analysis.

An adhesion interface observation method is adapted to observe a region in vicinity of an adhesion interface following adhesion and curing of an adhesive that is coated on adhered members and adheres the adhered members to each other. The adhesion interface observation method includes: exposing the cured adhesive by removing one of the adhered members; forming an observation region by cutting a predetermined part of the adhesive by a predetermined thickness; obliquely cutting the observation region in an oblique direction that is inclined with respect to a thickness direction of the observation region; and observing, by a surface-enhanced Raman scattering spectroscopy, Raman scattering light generated by applying excitation light to an observation possible region that is positioned on a side, of a part of the observation region having been subjected to the oblique cutting, on which a thickness of the part of the observation region is small.

The microscope for monitoring objects after nano-cutting and for investigating structures of macro- and micro-carriers under low temperature comprises a punch having a cutting edge, drives driving the punch along two axes, a platform rotatable in a plane, a piezo-scanner for recording a sample image along three axes, a holder with a carrier of the sample, and a probe unit to which a probe is fastened. The piezo-scanner is fastened to the platform, the punch is able to interact with the sample, and the probe unit is mounted on the platform so as to be movable along one of the axes. The assembly includes a module for mechanical action on the cutting edge of the punch to modify the cutting surface, which module is fastened to the same platform to which the piezo-scanner with the object carrier and the probe unit are fastened.

An apparatus for processing biological material includes a supporting structure, provided with a seat and with a rotation device supplied with constraining means, and a container for biological material, provided with a shaped body, with a base, shaped to match the seat of the supporting structure, with at least one valve (24a) for extracting the biological material, and with movable cutting means equipped with coupling means for coupling to the constraining means of the rotation device, in such a way as to acquire a relative motion relative to the container.