Abstract: A fluidic testing system and method for use are presented. The fluidic testing system includes a microfluidic channel, a first chamber and second chamber. The microfluidic channel has only one port for the introduction and/or extraction of fluid through the microfluidic channel. The first chamber is disposed at a terminal end of the microfluidic channel. The second chamber is coupled to the fluidic channel and is aligned such that each opening to the second chamber is configured to be aligned substantially parallel to a gravity vector during operation.

Abstract: A fluidic testing system and method for use are presented. The fluidic testing system includes a microfluidic channel, a first chamber and second chamber. The microfluidic channel has only one port for the introduction and/or extraction of fluid through the microfluidic channel. The first chamber is disposed at a terminal end of the microfluidic channel. The second chamber is coupled to the fluidic channel and is aligned such that each opening to the second chamber is configured to be aligned substantially parallel to a gravity vector during operation.

Abstract: A microfluidic system is presented that includes a cartridge, a container, and a lid for the container. The cartridge includes a plurality of microfluidic channels coupled to one or more chambers. The container holds dry chemicals and includes a housing with a first opening and a second opening smaller than the first opening. The container is designed to be inserted into an opening of the cartridge, such that the container is independently secured within the opening. The insertion of the container allows for the container to be fluidically coupled with a microfluidic channel of the plurality of microfluidic channels via the second opening. The lid includes a column that extends from the lid into the container.

Abstract: A fluidic testing system is presented that includes a plurality of test chambers, a plurality of inlet channels, and a fluidic network that connects the inlet channels to one or more other chambers. The plurality of test chambers are each characterized by a length and a hydraulic diameter. The length of each test chamber is aligned substantially parallel to a gravity vector. Each of the test chambers has only one opening disposed along the length of the corresponding test chamber. Additionally, each of the test chambers is coupled via its respective opening to only one of the plurality of inlet channels.

Abstract: A fluidic testing system is presented that includes a plurality of test chambers, a plurality of inlet channels, and a fluidic network that connects the inlet channels to one or more other chambers. The plurality of test chambers are each characterized by a length and a hydraulic diameter. The length of each test chamber is aligned substantially parallel to a gravity vector. Each of the test chambers has only one opening disposed along the length of the corresponding test chamber. Additionally, each of the test chambers is coupled via its respective opening to only one of the plurality of inlet channels.

Abstract: A fluidic testing method is presented that includes flowing an initial amount of liquid down a first inlet channel of a single-port fluidic testing system, and splitting the initial amount of liquid from the first inlet channel into a plurality of second inlet channels. Each second inlet channel is coupled to a given test chamber of a plurality of test chambers, wherein each of the plurality of test chambers has a wall that defines a longest side of a given test chamber, and wherein each of the plurality of test chambers has only one opening through the wall of a corresponding test chamber. The method also includes filling each of the plurality of test chambers with a final amount of liquid, the final amount being substantially equal in each of the test chambers and summing from each test chamber to equal the initial amount of liquid.

Abstract: A system and method for eluting a sample from a swab are presented. The system includes a chamber dimensioned to receive at least a portion of the length of at least one swab, a fluidic channel connected to the chamber, and an actuator. The chamber has at least one wall being a flexible film. The fluidic channel is configured to at least one of introduce and expel liquids from the chamber. The actuator is configured to contact an outer surface of the flexible film such that movement of the actuator against the outer surface of the flexible film causes a respective movement of the at least one swab when the at least one swab is disposed next to an inner surface of the flexible film. The respective movement of the at least one swab elutes the sample from the at least one swab into the chamber.

Abstract: A fluidic testing system is presented that includes a plurality of test chambers, a plurality of inlet channels, and a fluidic network that connects the inlet channels to one or more other chambers. The plurality of test chambers are each characterized by a length and a hydraulic diameter. The length of each test chamber is aligned substantially parallel to a gravity vector. Each of the test chambers has only one opening disposed along the length of the corresponding test chamber. Additionally, each of the test chambers is coupled via its respective opening to only one of the plurality of inlet channels.

Abstract: A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

Abstract: A fluidic testing system is presented that includes a plurality of test chambers, a plurality of inlet channels, and a fluidic network that connects the inlet channels to one or more other chambers. The plurality of test chambers are each characterized by a length and a hydraulic diameter. The length of each test chamber is aligned substantially parallel to a gravity vector. Each of the test chambers has only one opening disposed along the length of the corresponding test chamber. Additionally, each of the test chambers is coupled via its respective opening to only one of the plurality of inlet channels.

Abstract: A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

Abstract: A fluidic testing system and method for use are presented. The fluidic testing system includes a microfluidic channel, a first chamber and second chamber. The microfluidic channel has only one port for the introduction and/or extraction of fluid through the microfluidic channel. The first chamber is disposed at a terminal end of the microfluidic channel. The second chamber is coupled to the fluidic channel and is aligned such that each opening to the second chamber is configured to be aligned substantially parallel to a gravity vector during operation.

Abstract: A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

Abstract: A system for at least one of homogenization and lysis of a sample includes one or more walls forming an enclosed chamber, a permanent magnet within the enclosed chamber, a magnet guide, and one or more magnets located outside the chamber. The enclosed chamber has an inlet and one or more fluidic connections configured to introduce at least the sample into the chamber. The permanent magnet has a positive pole and a negative pole. The magnet guide is configured to laterally guide the permanent magnet between a first position and a second position and maintain a substantially constant orientation of the permanent magnet during the movement. Movement of the magnets outside the chamber changes a magnetic field between the one or more magnets and the permanent magnet. The permanent magnet moves between the first and second positions in response to the changing magnetic field.

Abstract: A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

Abstract: A system for at least one of homogenization and lysis of a sample includes one or more walls forming an enclosed chamber having an inlet and a plurality of fluidic connections. A first fluidic network is coupled to at least one of the plurality of fluidic connections and a second fluidic network is coupled to at least one of the plurality of fluidic connections. The system further includes a rotary element within the chamber, and an actuator configured to rotate the rotary element. The first fluidic network is configured to introduce at least a sample into the chamber from at least one first reservoir. The second fluidic network is configured to expel at least the sample from the chamber to at least one second reservoir. The rotary element is rotated by the actuator about an axis extending along a length of the rotary element.

Abstract: A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

Abstract: A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

Abstract: A fluidic testing method is presented that includes flowing an initial amount of liquid down a first inlet channel of a single-port fluidic testing system, and splitting the initial amount of liquid from the first inlet channel into a plurality of second inlet channels. Each second inlet channel is coupled to a given test chamber of a plurality of test chambers, wherein each of the plurality of test chambers has a wall that defines a longest side of a given test chamber, and wherein each of the plurality of test chambers has only one opening through the wall of a corresponding test chamber. The method also includes filling each of the plurality of test chambers with a final amount of liquid, the final amount being substantially equal in each of the test chambers and summing from each test chamber to equal the initial amount of liquid.

Abstract: A fluidic testing system is presented that includes a plurality of test chambers, a plurality of inlet channels, and a fluidic network that connects the inlet channels to one or more other chambers. The plurality of test chambers are each characterized by a length and a hydraulic diameter. The length of each test chamber is aligned substantially parallel to a gravity vector. Each of the test chambers has only one opening disposed along the length of the corresponding test chamber. Additionally, each of the test chambers is coupled via its respective opening to only one of the plurality of inlet channels.