A specimen holding and positioning apparatus operable to substantially non-movably maintain a specimen (e.g., an excised tissue specimen) in a fixed or stable orientation with respect to the apparatus during imaging operations (e.g., x-ray imaging), transport (e.g., from a surgery room to a pathologist's laboratory), and the like for use in facilitating accurate detection and diagnosis of cancers and/or other abnormalities of the specimen.

A workpiece having an identification code is arranged on a workpiece carrier having coded therein, by a pattern made from a plurality of mutually separate regions of different density, at least one character of the identification code. The workpiece and carrier are scanned together by computed tomography, the regions or part of the regions and the densities thereof in the computed tomography scan are ascertained, the scan is oriented in response to at least the location of a straight line through two of these regions, the character that is coded by way of the density pattern of the plurality of regions is determined in the scan, and the oriented scan is processed in response to the coded character.

A fluid sampler includes: a sample cell that includes: a substrate comprising: a first port; a second port in fluid communication with the first port; a viewing reservoir in fluid communication with the first port and the second port and that receives the fluid from the first port and communicates the fluid to the second port, the viewing reservoir including: a first view membrane; a second view membrane; and a pillar interposed between the first view membrane and second view membrane, the pillar separating the first view membrane from the second view membrane at a substantially constant separation distance such that a volume of the viewing reservoir is substantially constant and invariable with respect to a temperature and invariable with respect to a pressure to which the sample cell is subjected.

A sample holding device for studying light-driven reactions and a sample analysis method using the same are disclosed. The sample holding device comprises a main body, a supporting structure and a light source assembly. The main body has a channel which has a first end and a second end opposite to the first end, and a focusing lens which is located on the second end. The supporting structure is located on one end of the main body for sample supporting. The light source assembly is detachably disposed on the other end opposite to the end which is disposed with the supporting structure. The light source assembly emits a light beam into the first end of the channel. The light beam then irradiates the sample which locates on the supporting structure after passing through the focusing lens.

A device utilizing biosensors to enable rapid electrochemical sensing of one or more analytes in a container. The device comprises a holder which incorporates at least one reference electrode and at least one sensing electrode. The sensing electrode comprising an electrically conductive substrate which is coated in a first layer of a suitable electron acceptor and subsequently with a second layer incorporating a biorecognition molecule adsorbed or within a suitable electropolymer matrix or carrier.

Disclosed, is a sample preparation apparatus which is configured to prepare a material sample suitable for X-ray diffraction. The apparatus comprises a dished sample holder bottom configured to fit within an annular sample holder. The dished sample holder bottom has a concave dished surface which is adapted to distribute sample material under pressing forces. A method of preparing a material sample suitable for X-ray diffraction is also disclosed. The method comprises dosing a dished sample holder bottom which is configured to fit within an annular sample holder with sample material, wherein the dished sample holder bottom preferably has a concave dished surface which is adapted to distribute sample material under pressing forces.

An object, such as a tumor from a breast lumpectomy, is placed into an object positioning device that can hold the object without deforming it. Such a device can include a container with a deformable foam, gel, or other material. The object positioning device is moved into an imaging device. Images of the object within the object positioning device are acquired by the imaging device. The acquired images are stored, processed, or output on a display device. Information about the spatial orientation of the object with respect to a reference object is preserved.

A method for characterizing a sample combining an X-ray tomography characterization technique and a secondary ionization mass spectrometry characterization technique, includes: a step of providing a tip that includes first and second end surfaces, a first cylindrical region bearing the first end surface and a second region in contact with the first cylindrical region and becoming slimmer towards the second end surface; a step of machining the second region to obtain a sample holder including a flat surface, the flat surface forming an end surface of the sample holder, the area of the flat surface being less than the area of the first end surface; a step of placing the sample on the flat surface of the sample holder; a first step of characterization of the sample using an X-ray characterization technique; a second step of characterization of the sample using a secondary ionization mass spectrometry characterization technique.

A sample holder for holding a sample during an X-ray imaging process includes a sample placement surface on which the sample is placed for positioning the sample in a depth direction of the sample holder. The sample holder also includes a first alignment portion for aligning the sample in a width direction of the sample holder, and a second alignment portion for aligning the sample in a height direction of the sample holder.

An analysis apparatus comprises: a moveable stage assembly; a sample holder on a top surface of the stage assembly; a first photon source and a first photon detector or detector array, the first photon source being configured to emit a first beam of photons that intercepts the surface of a sample at a first location on the sample and the first photon detector or detector array being configured to detect photons that are emitted from the first location; and a second photon source and a second photon detector or detector array, the second photon source being configured to emit a second beam of photons that intercepts the surface of the sample at a second location on the sample, the second location being spaced apart from the first location, and the second photon detector or detector array being configured to detect photons that are emitted from the second location.