A microfluidic device for performing physical, chemical or biological treatment to at least one packet without contamination.

A test system comprising a heating device for heating content comprising a mixture of a first and a second product, said device comprising a test container suitable for receiving the content, a receiving container suitable for receiving the test container, a coil comprising induction turns, and a current source suitable for supplying current to the induction turns. The heating device is such that the induction turns are attached to the receiving container and extend helically concentrically around the receiving container. The test system further comprises an arm for mixing the content of the test container and a mechanism for guiding the arm. A method for implementing such a test system.

The invention relates to a device for tabletting a powdered, liquid, pasty, encapsulated or granular active ingredient composition, having a magazine which has a plurality of active ingredient containers each with an individually controllable dosing device and a nozzle for the active ingredient outlet, wherein the magazine is adjustable between a plurality of setting positions relative to at least one die chamber, wherein in each of the setting positions at least one of the nozzles faces an opening of the die chamber. A corresponding method is further described.

A medical delivery device includes a first compartment configured to hold a first substance. The first compartment includes a first wall that includes a first ferrous material, and the first wall is configured to disintegrate and release the first substance into a patient in response to first electromagnetic radiation received by the first ferrous material. The medical delivery device also includes a second compartment attached to the first compartment and configured to hold a second substance. The second compartment includes a second wall that includes a second ferrous material, and the second wall is configured to disintegrate and release the second substance into the patient in response to second electromagnetic radiation received by the second ferrous material.

Instruments, methods, and kits are disclosed for performing fast thermocycling.

The present invention describes a versatile, robust and environmentally controlled platform with a linear temperature gradient for massively parallel chemical or biochemical processing. This apparatus is capable of probing the phase transition behavior of macromolecules in solution, both thermodynamically and kinetically. This includesbut is not limited toliquid/liquid phase transition behavior of antibody solutions and in situ gelation of thermo-responsive polymers. The device can be operated in a multiplex fashion using a controlled temperature gradient architecture and visualized by dark field microscopy or by other optical intensity measurements.

Systems, methods, and apparatuses are provided for self-contained nucleic acid preparation, amplification, and analysis.

Embodiments are directed to a removable cap with a top hole and a seal with a heat induction closure for sealing an opening of a container. Advantageously, the cap and the seal do not need to be removed for a probe to access contents of the container, when used in a diagnostic analyzer, thereby eliminating operator steps of cap removal and seal peeling/perforation. Automated opening of the cap and seal combination is provided by puncturing the seal. The seal retains its opened shape required for unobstructed, non-contact probe access to contents of the container. The seal is comprised of three layers: a first polymer sealing layer capable of being heat-sealed to a container; an aluminum foil layer on top of the first polymer sealing layer, configured to heat seal the first layer by inductive heating; and a second polymer layer on top of the aluminum foil layer for protection.

A system and method comprise positioning a medical device within a subject. The medical device includes a plurality of compartments and each of the plurality of compartments includes a ferrous material. Further, each of the plurality of compartments is configured to hold a substance. The system and method further include delivering electromagnetic radiation, by an electromagnetic radiation source, to the medical device and varying, by a controller, an amount of the electromagnetic radiation delivered by the electromagnetic radiation source for selectively heating the ferrous material of at least one of the plurality of compartments and selectively releasing the substance held in the at least one of the plurality of compartments for managing a condition.

A microfluidic platform including a microfluidic layer and a contact layer. The microfluidic layer is embedded with a microfluidic structure including a micro-channel and a fluidic sample contained in the micro-channel. The contact layer is able to be attached to the microfluidic layer, and includes a first heater for heating a first area of the microfluidic structure to a first temperature and a second heater for heating a second area of the microfluidic structure to a second temperature. The microfluidic layer and the contact layer rotate together during operation. A method for controlling a sample in the micro-channel of the microfluidic structure.