According to one embodiment, a liquid dispensing apparatus includes a base to which a liquid discharging device for discharging a liquid is to be mounted, an interface configured to communicate with an external device, a driving circuit to supply driving voltages to an actuator of the liquid discharging device, and a control unit configured to acquire a use history of the liquid discharging device from the external device through the interface, and cause the driving circuit to supply a discharge voltage to the actuator if the acquired use history indicates the liquid discharging device has not been used.

According to one embodiment, a liquid discharging device includes a storage unit storing a use history indicating whether the liquid discharging device has been previously used, and a discharging device mounted on a liquid dispensing apparatus and configured to discharge a liquid when supplied a discharge voltage in response to a discharge signal received from the liquid dispensing apparatus.

A method for coding and identification of biological samples for in vitro fertilization comprises the steps of applying to receptacles intended for unfertilized eggs and sperm, respectively, an identification code characteristic of the patient; placing unfertilized eggs and sperm, respectively, in the receptacles; storing, transporting and admixing the respective samples in receptacles which each carry the same code; and implanting the resulting embryo in the patient. The identification code may based on RFID technology, in which sample vessels (12) are codified by the application of an RFID tag (13).

The present invention provides improved methods, facilities and systems for parallel processing of biological cellular samples in an efficient and scalable manner. The invention enables parallel processing of biological cellular samples, such as patient samples, in a space and time efficient fashion. The methods, facilities and systems of the invention find particular utility in processing patient samples for use in cell therapy.

A method for optically reading information encoded in a microfluidic device, the microfluidic device including an input microchannel, microfluidic modules, and sets of nodes. Nodes of a first set connect the input microchannel to one of the microfluidic modules, and nodes of a second set connect the one of the microfluidic modules to another to form an ordered pair of the microfluidic modules, where the nodes of the first and second sets have different liquid pinning strengths. A liquid loaded into the input microchannel causes an ordered passage of the liquid through each of the microfluidic modules in an order determined by the liquid pinning strengths of the nodes. The passage of the liquid produces an optically readable dynamic pattern which evolves in accordance with the ordered passage of the liquid through the device.

A two-dimensional code is attached to a location of a reagent storage unit which is visually recognizable from the outside, and a coordinate position of the two-dimensional code in a coordinate system of the two-dimensional code and coordinate information of an installation position of a reagent bottle are held. After that, an image of the two-dimensional code is captured by a portable terminal so that a coordinate system of an image capture unit of the portable terminal is converted into the coordinate system of the two-dimensional code using AR technology. The coordinate information of the installation position of the reagent bottle in the coordinate system of the two-dimensional code is regarded as positional coordinates in the captured image on the basis of the conversion, thereby ascertaining the position of the reagent bottle on the captured image and displaying the ascertained position on a display unit.

A laboratory system has a plurality of bottom opening sample transport pods for carrying one or more cassettes with cell culture vessels therein may have an aseptic interior environment and may cooperate with cell culture growing/processing stations having load ports allowing transfer of the cassettes with cell culture vessels into the stations while maintaining the aseptic integrity of the interior of the pods and the cassette and cell culture vessels. Internal environmental monitoring and control, purging, and tracking as well as automated robotic operation may be provided.

An automatic analyzing apparatus includes a reagent depository, a wave radiator, a wave receiver, a switcher, and processing circuitry. The wave radiator sends a radio wave to a plurality of wireless tags. The wireless tags are comprised by respective reagent containers in the reagent depository or by respective reagent containers at a reagent retaining space. The wave receiver receives return radio waves from the wireless tags that have received the radio wave. The switcher changes a response state of one of the wireless tags. The processing circuitry specifies reagent information corresponding to the reagent container that comprises the response state-changed wireless tag, based on the return radio waves received before and after the response state is changed.

The system in at least one embodiment provides a tamper evident specimen sample lock that in a further embodiment includes an embedded storage medium. They system and method in at least one embodiment allows for efficiently and securely creating, maintaining, identifying, tracking, and controlling inventories (either prospective or retrospective) of biological and chemical sample containers and their contents, while eliminating potential loss and degradation associated with handling the samples. The system in at least one embodiment provides a sample container tray or cryogenic box having one or more integrated RFID readers within an associated smart lid that sense RFIDs associated with the individual samples thereby eliminating the need to remove, visually inspect, and/or handle the samples.

The present invention provides an automatic encoding device including a first electrode, a second electrode, and a third electrode. The first electrode and the second electrode are connected through a connecting point, so that an electric parameter between the first electrode and the second electrode changes according to a parameter needing to be corrected. The present invention further provides a method for applying the automatic encoding device to various biosensors and a method for manufacturing the automatic encoding device. Positions and the number of contacts for connecting the automatic encoding device and a detection system are fixed. Therefore, connection sites on the detection system are effectively utilized. On the other hand, the automatic encoding device in the present invention can provide different parameter information by only changing the positions of the connecting points on the electrodes, the process is simple and stable, and the probability of human errors is reduced.