A diagnostic and treatment assembly, configured to diagnose and treat cellular disease. The diagnostic and treatment assembly has a radio wave generator communicatively coupled to a carrier modulator and a radio wave amplifier. An impedance matching system is electrically coupled to the radio wave amplifier. A reflected wave sensor is electrically coupled to the impedance matching system. A radiator applicator is electrically coupled to the reflected wave sensor. A vector impedance analyzer is electrically coupled to the radio wave amplifier. An information collector data network is electrically coupled to the vector impedance analyzer. A data logger is communicatively coupled to the carrier modulator, the vector impedance analyzer, and the reflected wave sensor. The diagnostic and treatment assembly operates in a low-power mode to diagnose a cellular disease and in a high-power mode to treat the cellular disease.

A sample storage device may include: a storage chamber; paired rail sections separated in separating direction and extending in an extending direction; an antenna array substrate extending between the rail sections and having antennas; paired slide sections separated from each other in the separating direction and disposed at a position opposite to the antenna array substrate with respect to the rail sections and, so as to be slidable in the extending direction relative to the rail sections, respectively; a support plate transparent to radio waves, extending between the slide sections; and a storage box containable a plurality of containers each holding a sample and a radio tag, the storage box to be set on the support plate such that radio waves can be transmitted between the radio tag and corresponding one of the plurality of antennas.

A system for processing biological material includes a first module and at least a second module, in which each of said first and second modules has at least the following identical characteristics: a size and a shape of a housing; a storage device being rotatably located within said housing; and a plurality of plate slots located in the storage device for receiving plates or containers carrying pipette tips, cell cultures or liquids. The first and second modules are selected from a process module, a storage module, an incubator, a freezer, a plastic-ware store, a refrigerator or a centrifuge.

A sample identification system for an automated sampling device is described. A system embodiment includes, but is not limited to, a sample holder having a plurality of apertures configured to receive a plurality of sample vessels therein, the sample holder having one or more corresponding sample holder identifiers positioned proximate to the sample holder; and an identifier capture device configured to detect the one or more sample holder identifiers positioned proximate to the sample holder and generate a data signal in response thereto, the data signal corresponding to at least an orientation of the sample holder relative to a surface on which the sample holder is positioned.

Disclosed is a system with (a) a microplate comprising a metallic material for heating one or more samples during thermocycling. The microplate comprises one or more barcodes on a side of the microplate. The system may comprise a barcode reader for reading the one or more barcode. The system may also comprise a first temperature block configured to receive the microplate and/ or provide a denaturing temperature to the one or more samples contained in the microplate, during the thermocycling. The system may also comprise a second temperature block configured to receive the microplate and/or provide an extension temperature to the one or more samples contained in the microplate, during the thermocycling. The system may also comprise a conveyor configured to move the microplate between a sensing device, the first temperature block, and the second temperature block, during the thermocycling.

Embodiments of the present invention provide systems and methods for tagging and acoustically characterizing containers.

Lateral flow analyte test systems having a defined geometry that positions a light source at a position relative to a test strip so that a captured image of the test strip is not convoluted with specular reflection, and that permits the light source to illuminate the desired portion of the test strip without the creation of a shadow in the image by the optics of the test strip reader.

A diagnostic and treatment assembly, configured to diagnose and treat cellular disease. The diagnostic and treatment assembly has a radio wave generator communicatively coupled to a carrier modulator and a radio wave amplifier. An impedance matching system is electrically coupled to the radio wave amplifier. A reflected wave sensor is electrically coupled to the impedance matching system. A radiator applicator is electrically coupled to the reflected wave sensor. A vector impedance analyzer is electrically coupled to the radio wave amplifier. An information collector data network is electrically coupled to the vector impedance analyzer. A data logger is communicatively coupled to the carrier modulator, the vector impedance analyzer, and the reflected wave sensor. The diagnostic and treatment assembly operates in a low-power mode to diagnose a cellular disease and in a high-power mode to treat the cellular disease.

The present disclosure presents systems and methods of specimen container labeling and tracking. One such method comprises linking a pair of identification numbers with one another within a specimen test order in an electronic medical record system in advance of the pair of identification numbers being printed on a double sided container label; receiving a first machine readable identifier on a first side of the label before a specimen is collected; transmitting a first identification number represented by a scanned first machine readable identifier to the record system; receiving a second machine readable identifier on a second side of the label after the specimen is collected; transmitting a second identification number represented by a scanned second machine readable identifier to the record system; and authorizing the specimen to be tested after verifying that the second identification number is associated with the specimen test order and/or the first machine readable identifier.

A sample identification system for an automated sampling device is described. A system embodiment includes, but is not limited to, a sample holder having a plurality of apertures configured to receive a plurality of sample vessels therein, the sample holder having one or more corresponding sample holder identifiers positioned proximate to the sample holder; and an identifier capture device configured to detect the one or more sample holder identifiers positioned proximate to the sample holder and generate a data signal in response thereto, the data signal corresponding to at least an orientation of the sample holder relative to a surface on which the sample holder is positioned.