Abstract: An apparatus includes a fluidic coupler including an opening. A first port is in fluid communication with the opening and is to interface with an inlet of a flow cell of a sensor device. A second port is to interface with an outlet of the flow cell of the sensor device. A third port is in fluidic communication with the second port. The apparatus further includes a mechanical assembly moveable between a first position and a second position. The fluidic coupler is secured to the flow cell of the sensor device in the first position. The fluidic coupler is disengaged from the flow cell of the sensor device in the second position.

Abstract: A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Abstract: An apparatus includes a fluidic coupler including an opening. A first port is in fluid communication with the opening and is to interface with an inlet of a flow cell of a sensor device. A second port is to interface with an outlet of the flow cell of the sensor device. A third port is in fluidic communication with the second port. The apparatus further includes a mechanical assembly moveable between a first position and a second position. The fluidic coupler is secured to the flow cell of the sensor device in the first position. The fluidic coupler is disengaged from the flow cell of the sensor device in the second position.

Abstract: A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Abstract: A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Abstract: Various embodiments of a low-volume sequencing system are provided herein. The system can include a low-volume flowcell having at least one reaction chamber of a defined volume (e.g., less than about 100 ?l). The system can also include an automated reagent delivery mechanism configured to reversibly couple with the inlet port corresponding to a target reaction chamber thereby placing allowing for reagent to be accurately moved from a storage container to the reaction chamber with minimal reagent waste. The flowcells can include a plurality of reaction chambers (e.g., 6) thereby allowing for parallel analysis of multiple samples. Various methods of analyzing a biomolecule are also provided herein.

Abstract: A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Abstract: A clamp device includes a frame; a carriage slidably engaged with the frame and including a receptacle to receive a cartridge including fluidics ports and electronic contacts, the carriage slidable between an open position and a closed position; a fluidics interface to engage the fluidics ports of the cartridge when the carriage is in a closed position; an electronic interface to engage the electronic contacts of the cartridge when the carriage is in the closed position; a driver to draw the fluidics interface and the electronic interface together, the cartridge secured between the electronic interface and the fluidics interface; and a sensor system to detect the presence of the cartridge in the receptacle and configured to prevent the driver from drawing the fluidics interface and electronic interface together when the cartridge is absent.

Abstract: A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Abstract: A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Abstract: A clamp device includes a frame; a carriage slidably engaged with the frame and including a receptacle to receive a cartridge including fluidics ports and electronic contacts, the carriage slidable between an open position and a closed position; a fluidics interface to engage the fluidics ports of the cartridge when the carriage is in a closed position; an electronic interface to engage the electronic contacts of the cartridge when the carriage is in the closed position; a driver to draw the fluidics interface and the electronic interface together, the cartridge secured between the electronic interface and the fluidics interface; and a sensor system to detect the presence of the cartridge in the receptacle and configured to prevent the driver from drawing the fluidics interface and electronic interface together when the cartridge is absent.

Abstract: A method of preparing reagents includes inserting a cartridge into an instrument. The cartridge includes a plurality of reagent enclosures disposed in a cavity of the cartridge and exposing a port to an exterior of the cartridge. Each reagent enclosure includes a reagent container including a reagent and an internal cavity defining a compressible volume, an opening defined through the reagent container to the internal cavity. The method further includes connecting a plurality of fluid ports to the openings of the plurality of reagent enclosures; applying a solution through the fluid ports to at least partially fill the plurality of reagent enclosures; and cycling a pressure of the cavity, whereby for each of the reagent enclosures, during increasing pressure, the solution enters the internal cavity of the reagent container, combines with the reagent, and compresses the compressible volume, and during decreasing pressure, the compressible volume decreases and the reagent is ejected through the opening.

Abstract: A method of sensing nucleotide reactions includes flowing at least one nucleotide solution from a container of at least two containers of a sensor system. The sensor system includes a sensor sensitive to a byproduct of nucleotide incorporation. Each container of the at least two containers includes a different nucleotide solution. The sensor system enters an idle mode after flowing. The method further includes cycling the at least two containers through at least two cycles. Each cycle includes depressurizing the at least two containers for a first period and pressurizing the at least two containers for a second period. The method also includes pressurizing the at least two containers when the sensor system enters an active mode.

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 method of sensing nucleotide reactions includes flowing at least one nucleotide solution from a container of at least two containers of a sensor system. The sensor system includes a sensor sensitive to a byproduct of nucleotide incorporation. Each container of the at least two containers includes a different nucleotide solution. The sensor system enters an idle mode after flowing. The method further includes cycling the at least two containers through at least two cycles. Each cycle includes depressurizing the at least two containers for a first period and pressurizing the at least two containers for a second period. The method also includes pressurizing the at least two containers when the sensor system enters an active mode.

Abstract: Various embodiments of a low-volume sequencing system are provided herein. The system can include a low-volume flowcell having at least one reaction chamber of a defined volume (e.g., less than about 100 ?l). The system can also include an automated reagent delivery mechanism configured to reversibly couple with the inlet port corresponding to a target reaction chamber thereby placing allowing for reagent to be accurately moved from a storage container to the reaction chamber with minimal reagent waste. The flowcells can include a plurality of reaction chambers (e.g., 6) thereby allowing for parallel analysis of multiple samples. Various methods of analyzing a biomolecule are also provided herein.

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 method of sensing nucleotide reactions includes flowing at least one nucleotide solution from a container of at least two containers of a sensor system. The sensor system includes a sensor sensitive to a byproduct of nucleotide incorporation. Each container of the at least two containers includes a different nucleotide solution. The sensor system enters an idle mode after flowing. The method further includes cycling the at least two containers through at least two cycles. Each cycle includes depressurizing the at least two containers for a first period and pressurizing the at least two containers for a second period. The method also includes pressurizing the at least two containers when the sensor system enters an active mode.

Abstract: Assemblies for and methods of coupling a microtiter plate and receptacle for centrifugation of liquid from the microtiter plate to the receptacle are provided. In some embodiments, a coupling frame can be used. In other embodiments, the microtiter plate couples directly to the receptacle. In some embodiments, relative motion between the receptacle and the microtiter plate is limited in the x-y plane. In some embodiments, relative motion between the receptacle and the microtiter plate is limited in the x-z plane. In some embodiments, relative motion between the receptacle and the microtiter plate is limited in the y-z plane.