Abstract: A sensor device includes a substrate having a die attached to the substrate. The die includes an array of sensors and an array of wells cooperatively disposed over the array of sensors. The array of wells is exposed by the substrate. The sensor device further includes a flow cell secured to the substrate and defining a flow space disposed over the die and accessible to the array of wells. The flow cell defines a plurality of separate volumes. Each separate volume of the plurality of separate volumes has an inlet and an outlet. The plurality of separate volumes are separated by dividers. The dividers cover a set of wells of the array of wells.

Abstract: Various embodiments of a sequencing system capable of rapidly imaging samples at multiple wavelengths are provided herein. In one embodiment, the system includes a fast-indexing filter wheel having a plurality of excitation and emission filters capable of being rapidly rotated into and out of communication with an excitation source (e.g., an arc lamp, a laser. For example, the filter wheel can be configured to index in an amount of time falling within a range of about 40 ms to about 60 ms, preferably 50 ms. The system can also be configured to account for vibrations resulting from the quick starts and stops of the fast-indexing filter wheel as well as vibrations resulting from other sources. Various methods of rapidly imaging a sample at multiple wavelengths are also provided herein.

Abstract: A heating apparatus comprising a support base and a microplate having a first surface and an opposing second surface. The microplate is positioned adjacent the support base and comprises a plurality of wells formed in the first surface thereof. Each of the plurality of wells is sized to receive an assay therein. A sapphire crystalline transparent window is positioned adjacent the microplate opposing the support base. A heating device heats the transparent window in response to a control system.

Abstract: Various embodiments of a sequencing system capable of rapidly imaging samples at multiple wavelengths are provided herein. In one embodiment, the system includes a fast-indexing filter wheel having a plurality of excitation and emission filters capable of being rapidly rotated into and out of communication with an excitation source (e.g., an arc lamp, a laser. For example, the filter wheel can be configured to index in an amount of time falling within a range of about 40 ms to about 60 ms, preferably 50 ms. The system can also be configured to account for vibrations resulting from the quick starts and stops of the fast-indexing filter wheel as well as vibrations resulting from other sources. Various methods of rapidly imaging a sample at multiple wavelengths are also provided herein.

Abstract: A heating apparatus comprising a support base and a microplate having a first surface and an opposing second surface. The microplate is positioned adjacent the support base and comprises a plurality of wells formed in the first surface thereof. Each of the plurality of wells is sized to receive an assay therein. A sapphire crystalline transparent window is positioned adjacent the microplate opposing the support base. A heating device heats the transparent window in response to a control system.

Abstract: A heating apparatus comprising a support base and a microplate having a first surface and an opposing second surface. The microplate is positioned adjacent the support base and comprises a plurality of wells formed in the first surface thereof. Each of the plurality of wells is sized to receive an assay therein. A sapphire crystalline transparent window is positioned adjacent the microplate opposing the support base. A heating device heats the transparent window in response to a control system.

Abstract: Various embodiments of a sequencing system capable of rapidly imaging samples at multiple wavelengths are provided herein. In one embodiment, the system includes a fast-indexing filter wheel having a plurality of excitation and emission filters capable of being rapidly rotated into and out of communication with an excitation source (e.g., an arc lamp, a laser. For example, the filter wheel can be configured to index in an amount of time falling within a range of about 40 ms to about 60 ms, preferably 50 ms. The system can also be configured to account for vibrations resulting from the quick starts and stops of the fast-indexing filter wheel as well as vibrations resulting from other sources. Various methods of rapidly imaging a sample at multiple wavelengths are also provided herein.

Abstract: An apparatus for sealing a microplate, wherein the apparatus comprises a microplate having a first surface and an opposing second surface. A plurality of wells is formed in the first surface of the microplate, wherein each of the plurality of wells is sized to receive an assay therein. A sealing cover is disposed over the microplate adjacent the plurality of wells and is compliant to accommodate variations between the sealing cover and the microplate and/or distribute loads evenly therebetween.

Abstract: A heating apparatus comprising a support base and a microplate having a first surface and an opposing second surface. The microplate is positioned adjacent the support base and comprises a plurality of wells formed in the first surface thereof. Each of the plurality of wells is sized to receive an assay therein. A sapphire crystalline transparent window is positioned adjacent the microplate opposing the support base. A heating device heats the transparent window in response to a control system.

Abstract: A filling apparatus for filling a microplate. The microplate having a plurality of wells each sized to receive an assay. The filling apparatus can comprise an assay input layer having a first surface and an opposing second surface. The assay input layer can comprise an assay input port extending from the first surface to the second surface and at least one pressure nodule extending from the second surface. An output layer can comprise a plurality of staging capillaries each having an inlet and an outlet. A intermediate layer can be disposed between the assay input layer and the output layer. The intermediate layer can be flexible and comprise a plurality of microfluidic channels and a flow aperture being in fluid communication with the assay input port and the plurality of microfluidic channels.

Abstract: A method of testing compatibility of a detection probe comprising an oligonucleotide and a fluorophore to a composition of a sealing cover, can comprise (a) depositing a quantity of the fluorophore into a plurality of containers; (b) providing a plurality of sealing covers; (c) sealing the plurality of containers with each of the plurality of the sealing covers; (d) exciting the fluorophore; (e) measuring an emission intensity from the fluorophore; and (f) evaluating the emission intensity from the fluorophore to determine the relative compatibility of each of the plurality of sealing covers with the fluorophore.

Abstract: A sealing cover roll for use in sealing a microplate comprising an elongated carrier liner having a first surface and a second surface. A plurality of sealing covers are releasably carried on the first surface of the elongated carrier liner. Each of the plurality of sealing covers comprises a base stock and an adhesive. The adhesive is operable to retain the base stock to the elongated carrier liner and permit release of the base stock and the adhesive from the elongated carrier liner. A roll core supports a rolled configuration of the elongated carrier liner such that the first surface of the elongated carrier liner faces toward the roll core when rolled.

Abstract: An automated seal applicator for applying a sealing cover to a microplate. The microplate can comprise a plurality of wells for receiving an assay. The automated seal applicator can comprise a housing and a removable sealing cover cassette containing a sealing cover roll. The sealing cover roll can comprise an elongated carrier liner and a plurality of individual sealing covers releasably carried on the elongated carrier liner. The sealing cover cassette can be selectively engagable with the housing. A sealing cover drive system can engage the sealing cover roll and maintain a predetermined alignment of each of the plurality of individual sealing covers relative to the microplate.

Abstract: A filling apparatus for filling a microplate. The microplate having a plurality of wells each sized to receive an assay. The filling apparatus can comprise an output layer having a depression and a plurality of staging capillaries. Each of the plurality of staging capillaries can comprises an inlet disposed in the depression and an outlet, and can further be sized to receive the assay. A floating insert comprising a first surface and an opposing second surface, and an aperture for receiving the assay extending therethrough, can be moveably disposed in the depression. The floating insert and the depression can together define a main capillary gap therebetween in fluid communication between the aperture and each of the plurality of staging capillaries. The size of the main capillary gap can vary depending upon the relative position of the floating insert and the output layer.

Abstract: An automated seal applicator for applying a sealing cover to a microplate. The microplate can comprise a plurality of wells for receiving an assay. The automated seal applicator can comprise a housing and a sealing cover cartridge containing a sealing cover releasably carried on a carrier liner. The sealing cover can be at least partially contained within the sealing cover cartridge. A sealing cover drive system can engage the sealing cover and/or the carrier liner and maintain a predetermined alignment of the sealing cover relative to the microplate.

Abstract: A filling apparatus for filling a microplate. The microplate can comprise a plurality of wells each sized to receive an assay. A substrate can comprise a first surface and an opposing second surface, a first assay input port for receiving the assay disposed on the first surface, a plurality of staging capillaries extending through the substrate, and a first plurality of microfluidic channels fluidly coupling the first assay input port with at least one of the plurality of staging capillaries. Each of the plurality of staging capillaries can comprise an inlet and an outlet and be sized to receive the assay.

Abstract: A filling apparatus for filling a microplate. The microplate having a plurality of wells each sized to receive an assay. The filling apparatus can comprise an assay input layer having a first surface and an opposing second surface. The assay input layer can comprise an assay input port extending from the first surface to the second surface, a venting manifold formed in the second surface, and a vent hole in fluid communication with the venting manifold and atmosphere. An output layer can comprise a plurality of staging capillaries each having an inlet and an outlet. A venting layer can be disposed between the assay input layer and the output layer. The venting layer can comprise a plurality of microfluidic channels, a flow aperture being in fluid communication with the assay input port and the plurality of microfluidic channels, and a plurality of vent apertures each in fluid communication with at least one of the plurality of staging capillaries.

Abstract: An seal applicator for applying a sealing cover to a microplate. The microplate can comprise a plurality of wells for receiving an assay. The seal applicator can comprise a housing containing a sealing cover roll. The sealing cover roll can comprise an elongated carrier liner and a plurality of individual sealing covers releasably carried on the elongated carrier liner. The seal applicator can further comprise a plane assembly supporting the elongated carrier liner and a drive roller assembly engaging the elongated carrier liner. The drive roller assembly can selectively drive the carrier liner.

Abstract: A filling apparatus for filling a microplate. The microplate having a plurality of wells each sized to receive an assay. The filling apparatus can comprise an output layer having a plurality of capillaries. Each of the plurality of capillaries can comprise an inlet and an outlet. A funnel member can comprise a first assay chamber and a first outlet in fluid communication with the first assay chamber. The first outlet can deliver a first fluid bead of the assay along a top surface of the output layer and in fluid communication with at least some of the plurality of capillaries such that a portion of the fluid bead is drawn within at least some of the plurality of capillaries in response to capillary force. The funnel member and the output layer can be moveable relative to each other between a first position and a second position to draw the first fluid bead across the top surface.