Systems, methods, and collection devices are disclosed for rapid, local PCR testing. The PCR testing system may be configured for use with a disposable sample collection device that includes a swab configured for collecting a biological sample from a patient; and a sample container configured to receive the swab and separate a bulk quantity of the biological sample from the swab for containment in a bulk collection chamber, which is located with the sample container, wherein the sample container is configured to meter a selected volume of the biological sample into a PCR sample tube, which contains a lyophilized master mix, releasably attachable to the sample container.

A secondary solid waste container for solid waste of an analyzer is disclosed. The secondary solid waste container comprises side walls and an impact absorbing member. The side walls comprise an upper end and a lower end. The impact absorbing member is connected to the side walls such that the impact absorbing member extends between the side walls and is spaced apart from the lower end with respect to a direction from the lower end to the upper end. The impact absorbing member is configured to absorb an impact from solid waste of the analyzer. An analyzer and a method for removing solid waste of an analyzer are also disclosed.

With respect to a clean air device, in order to provide a device structure and an air cleaning unit inspecting method capable of supplying clean air through a filter and also capable of measuring the amount of dust in a workroom space in which blown air forms a laminar flow such that an increase in the amount of dust can be accurately detected, the clean air device comprises an air cleaning unit, a rectifying unit arranged downstream of the air cleaning unit configured to rectify air blown from the air cleaning unit and form a laminar flow, and a workroom arranged downstream of the rectifying unit, wherein at least one suction port is provided on a wall surface in a space formed between the air cleaning unit and the rectifying unit, configured to draw out the air in the space to an exterior.

The Benchtop Laboratory Apparatus Automation System, hereafter referred to as BLAAS, is designed for automation of common laboratory benchtop devices such as pipette tip boxes, waste containers, sample tubes and trays, and reagent or solvent containers. The BLAAS consists of a microprocessor, sensor and physical actuator attached to the benchtop device. A user's hand approaching the device will be detected and the system will respond by opening the device, allowing hands-free access to the contents. After a short delay, the top closes again after the hand clears the device. A light will illuminate to indicate when the device is actively opening, and parameters like the speed of the movement, the stop positions of the servo and the time the device remains open can be adjusted.

The present invention provides a measured containment control system fitted to a laboratory containment device 1. These devices can have a variety of coherent enclosure configurations in terms of size and geometry. User access to these devices can be by means of either an opening or the use of gloves with, in this latter case, typically filtration of the intake and exhaust ventilation. The system comprises further at least one sensor 6, an exhaust duct 5 or exhaust outlet connected to the laboratory containment device 1 for ventilation, an air flow control means 2 for controlling the exhaust air volume in the exhaust duct 5 and a control unit 13 connected to at least one sensor 6 and to the air flow control means 2. The control unit 13 is arranged to receive signals from at least one sensor 6 constantly and adjusting, based on these signals, the air flow control means 2 to change the exhaust air volume from the laboratory containment device 1.

A contained drum discharge system comprising a drum and connected with a lifting mechanism, wherein the drum includes a primary liner bag having the toxic powdery material to be disposed, contained within the secondary liner bag, and a tertiary liner bag enclosing the secondary liner bag; a transparent glove box; a hopper connected at a top of the glove box and with a vacuum transfer system of a material processing reactor; and a control unit connected with the glove box via a rotation mechanism and with the lifting mechanism of the drum. The glove box includes a plurality of glove ports connected with respective glove attachments; a plurality of thrashout ports with door; a sealing gasket to connect with the drum; a first liner port; a second liner port and a third liner port.

Systems, methods, and collection devices are disclosed for rapid, local PCR testing. The system may include a PCR testing module, memory configured to store computer-executable instructions, and at least one computer processor configured to access the memory and execute the computer executable instructions to: (i) receive an order for a PCR diagnostic test; (ii) associate a sample collection device (SCD) received by the PCR testing module with the order for a PCR diagnostic test; (iii) instruct the PCR testing module to conduct the PCR diagnostic test on a biological specimen in the SCD received by the PCR testing module; and (iv) cause presentation of results of the PCR diagnostic test.

An automated, large-scale, energy-efficient biological material storage and retrieval system stores large quantities of samples in trays. The system includes a heat exchanger to capture and recycle residual energy, a movable wall, a storage compartment, a multi-tray shuttle compartment with shuttle, a plenum to maintain air temperature between compartments and along the sections within the storage compartment, a mechanism to open and close dividers between compartments, and a tray connector to release or attach one or more trays within a compartment configured to minimize energy loss during operation.

There is provided a pipette tip disposal assembly. The assembly comprises a receiving element adapted to support an end of at least one pipette tip, the at least one pipette tip being toppled in use from the receiving element along a first direction; and a container positioned to receive the at least one toppled pipette tip, the at least one pipette tip falling towards a base of the container on being received by the container. The base of the container has a first linear dimension aligned with the first direction corresponding to the length of a pipette tip.

Systems and methods are disclosed for rapid PCR testing. Example embodiments may include a PCR testing module that includes a housing having a PCR machine disposed therein; a sample input station on the housing, wherein the sample input station is configured to receive a sample collection device (SCD) comprising a biological specimen sample provided by the patient; an SCD processing mechanism configured to transfer a lysed microportion of the biological specimen sample into a PCR sample tube attached to the SCD; at least one mechanism configured to separate the PCR sample tube from the SCD and transfer the PCR sample tube to the PCR machine; and a controller configured to (i) use the PCR machine to conduct a PCR test on contents of the PCR sample tube, and (ii) generate results of the PCR test.