Abstract: A pipette-fillable fluid reservoir body. The fluid reservoir body includes two or more discrete fluid chambers therein. At least one of the fluid chambers contains a pressure compensation device and at least another one of the fluid chambers is devoid of a pressure compensation device. Each of the fluid chambers is in fluid flow communication with a fluid supply via, and each of the fluid chambers have sidewalls and a bottom wall attached to the side walls, wherein the bottom wall slopes toward the fluid supply via. The fluid reservoir body also includes an ejection head support face in fluid flow communication with the fluid chambers for attachment of a fluid ejection device to the ejection head support face for ejecting fluid from the fluid chambers.

Abstract: A system and method for ejecting one or more fluids from a digital dispense device. The method includes a) inputting to a memory a volume per unit area for each of the one or more fluids to be ejected from the digital dispense device; b) matching the volume per unit area to a device resolution for the digital dispense device; c) formatting fluid ejectors for the digital dispense device for the device resolution; and d) ejecting fluid from the digital dispense device to provide the volume per area for each of the one or more fluids.

Abstract: A system and method for ejecting one or more fluids from a digital dispense device. The method includes a) inputting to a memory a volume per unit area for each of the one or more fluids to be ejected from the digital dispense device; b) matching the volume per unit area to a device resolution for the digital dispense device; c) formatting fluid ejectors for the digital dispense device for the device resolution; and d) ejecting fluid from the digital dispense device to provide the volume per area for each of the one or more fluids.

Abstract: A digital dispense system and method of using a digital dispense system. The digital dispense system includes a pipette-fillable fluid cartridge having one or more fluid chambers therein and having an ejection head attached thereto. The ejection head contains a plurality of fluid ejectors thereon. The fluid ejectors are in fluid flow communication with the one or more fluid chambers of the pipette-fillable fluid cartridge. A fluid detection circuit is disposed on the ejection head and associated with at least one of the plurality of fluid ejectors for signaling the presence or absence of fluid in the one or more fluid chambers.

Abstract: A pipette-fillable fluid reservoir body. The fluid reservoir body includes two or more discrete fluid chambers therein. At least one of the fluid chambers contains a pressure compensation device and at least another one of the fluid chambers is devoid of a pressure compensation device. Each of the fluid chambers is in fluid flow communication with a fluid supply via, and each of the fluid chambers have sidewalls and a bottom wall attached to the side walls, wherein the bottom wall slopes toward the fluid supply via. The fluid reservoir body also includes an ejection head support face in fluid flow communication with the fluid chambers for attachment of a fluid ejection device to the ejection head support face for ejecting fluid from the fluid chambers.

Abstract: A digital dispense system for preparing and analyzing a plurality of samples. The system includes two or more fluid droplet ejection devices. Each fluid droplet ejection device contains a fluid droplet ejection cartridge containing at least one fluid to be dispensed. The fluid droplet ejection cartridge is attached to a translation mechanism for moving the fluid droplet ejection cartridge back and forth over a sample holder in an x direction. A sample tray translation mechanism is provided for moving a sample tray along a production path in a y direction orthogonal to the x direction through the two or more fluid droplet ejection devices.

Abstract: A digital dispense system and method for analyzing samples. The system includes a fluid droplet ejection system housed in a compact housing unit. The fluid droplet ejection system contains a fluid droplet ejection head and fluid cartridge containing one or more fluids to be dispensed, a cartridge translation mechanism for moving the fluid droplet ejection head and fluid cartridge back and forth over a sample holder in an x direction; and a sample holder translation mechanism for moving a sample back and forth beneath the fluid droplet ejection head and fluid cartridge in a y direction orthogonal to the x direction. A digital display device is attached to the fluid droplet ejection system for displaying fluid volume information to a user. The fluid volume information is selected from relative fluid volume, absolute fluid volume, and a combination of relative and absolute fluid volumes.

Abstract: A digital dispense device and method for ejecting one or more fluids into a target area of a substrate. The digital dispense device includes (A) a fluid ejection head for the digital dispense device having one or more arrays of fluid ejectors thereon; (B) a fluid ejection head translation device for moving the ejection head over the target area of the substrate in a first direction, wherein the one or more arrays of fluid ejectors on the fluid ejection head are oriented parallel to the first direction; and (C) a control device for activating one or more fluid ejectors in the one or more arrays of fluid ejectors as the one or more fluid ejectors intersect the target area of the substrate.

Abstract: A removable maintenance fluid holder for a digital dispense system, a digital dispense system containing the removable maintenance fluid holder, and a method of maintaining a fluid droplet dispense cartridge. The removable maintenance fluid holder includes a housing having a handle end and a fluid receptacle end distal from the handle end. The fluid receptable end includes a fluid receptacle for holding fluid dispensed from a fluid droplet ejection head of a fluid droplet cartridge in the digital dispense system. The removable maintenance fluid holder is configured to be inserted and removed from the digital dispense system on a periodic basis.

Abstract: A system and method for ejecting one or more fluids from a digital dispense device. The method includes a) inputting to a memory a volume per unit area for each of the one or more fluids to be ejected from the digital dispense device; b) matching the volume per unit area to a device resolution for the digital dispense device; c) formatting fluid ejectors for the digital dispense device for the device resolution; and d) ejecting fluid from the digital dispense device to provide the volume per area for each of the one or more fluids.

Abstract: A digital dispense system for preparing and analyzing a plurality of samples. The system includes two or more fluid droplet ejection devices. Each fluid droplet ejection device contains a fluid droplet ejection cartridge containing at least one fluid to be dispensed. The fluid droplet ejection cartridge is attached to a translation mechanism for moving the fluid droplet ejection cartridge back and forth over a sample holder in an x direction. A sample tray translation mechanism is provided for moving a sample tray along a production path in a y direction orthogonal to the x direction through the two or more fluid droplet ejection devices.

Abstract: A digital dispense system and method for preparing samples for analysis. The system includes a fluid droplet ejection system housed in a compact housing unit. The fluid droplet ejection system contains a fluid droplet ejection head and fluid cartridge containing one or more fluids to be dispensed, a cartridge translation mechanism for moving the fluid droplet ejection head and fluid cartridge back and forth over a sample holder in an x direction; and a sample holder translation mechanism for moving a sample back and forth beneath the fluid droplet ejection head and fluid cartridge in a y direction orthogonal to the x direction. A digital display device is attached to the fluid droplet ejection system for displaying fluid volume information to a user. The fluid volume information is selected from relative fluid volume, absolute fluid volume, and a combination of relative and absolute fluid volumes.

Abstract: A system tracks the fluid information in fluid cartridges used in digital dispense devices connected to a network. Each device stores a history of cartridges that have been used in the device. Each cartridge stores a fluid information value and/or an indicator that indicates whether the cartridge has been used before in any device. When a device receives a previously-used cartridge, the device broadcasts a request for information about that cartridge from the other devices. Each device having the matching cartridge identification value in its history reports over the network the latest fluid information value associated with the matching cartridge identification value. The requesting device chooses the most up-to-date response based on the latest value of fluid information. The requesting device then updates its memory using the latest value and begins incrementing the information from that latest information for subsequent fluid dispense jobs performed using the installed cartridge.

Abstract: A controller for controlling a microfluidic device. A first computing device receives commands from a user interface in a relatively high level protocol using a standardized command language, converts the commands from the standardized command language into a relatively mid-level protocol, sends the commands in the relatively mid-level protocol, receiving data, converts the data into the standardized command language, and sends the data to the user interface according to the standardized command language. A second computing device receives the commands from the first computing device in the relatively mid-level protocol, converts the commands from the relatively mid-level protocol to at least one relatively lower level protocol that is understood by a microfluidic device that is connected to the controller, receives data from the microfluidic device, and sends the data to the first computing device.

Abstract: A location-based address adapter for use in a system to facilitate communication between a host computer and one peripheral device of a plurality of peripheral devices includes a body and an electrical circuit. The body is removably attached to one peripheral device at a time. The electrical circuit includes a communications interface circuit and an adapter memory circuit. The communications interface circuit has a respective pass-through wired connection between each of a plurality of input connectors and a plurality of output connectors to facilitate bi-directional communications between the host computer and the peripheral device. The adapter memory circuit stores a unique physical location address for association with a physical location associated with the peripheral device to which the body is attached. The unique physical location address is a non-network based address.

Abstract: A location-based address adapter for use in a system to facilitate communication between a host computer and one peripheral device of a plurality of peripheral devices includes a body and an electrical circuit. The body is removably attached to one peripheral device at a time. The electrical circuit includes a communications interface circuit and an adapter memory circuit. The communications interface circuit has a respective pass-through wired connection between each of a plurality of input connectors and a plurality of output connectors to facilitate bi-directional communications between the host computer and the peripheral device. The adapter memory circuit stores a unique physical location address for association with a physical location associated with the peripheral device to which the body is attached. The unique physical location address is a non-network based address.

Abstract: A system tracks the exact amount of ink remaining in printhead cartridges used in printers connected to a network. Each printer stores a history of cartridges that have been used in the printer. Each cartridge stores a status indicator that indicates whether the cartridge has been used before in any printer. When a printer receives a previously-used cartridge, the printer broadcasts a request for information about that cartridge from the other printers. Each printer having the matching printhead identification number in its history reports over the network the last recorded ink dot count associated with the matching printhead identification number. The requesting printer chooses the most up-to-date response based on the highest dot count or the latest time-stamp. The requesting printer then updates its memory using the dot count from the most up-to-date response and begins counting dots from that updated count for subsequent print jobs performed using the installed cartridge.

Abstract: A system tracks the exact amount of ink remaining in printhead cartridges used in printers connected to a network. Each printer stores a history of cartridges that have been used in the printer. Each cartridge stores a status indicator that indicates whether the cartridge has been used before in any printer. When a printer receives a previously-used cartridge, the printer broadcasts a request for information about that cartridge from the other printers. Each printer having the matching printhead identification number in its history reports over the network the last recorded ink dot count associated with the matching printhead identification number. The requesting printer chooses the most up-to-date response based on the highest dot count or the latest time-stamp. The requesting printer then updates its memory using the dot count from the most up-to-date response and begins counting dots from that updated count for subsequent print jobs performed using the installed cartridge.

Abstract: A system tracks the exact amount of ink remaining in printhead cartridges used in printers connected to a network. Each printer stores a history of cartridges that have been used in the printer. Each cartridge stores a status indicator that indicates whether the cartridge has been used before in any printer. When a printer receives a previously-used cartridge, the printer broadcasts a request for information about that cartridge from the other printers. Each printer having the matching printhead identification number in its history reports over the network the last recorded ink dot count associated with the matching printhead identification number. The requesting printer chooses the most up-to-date response based on the highest dot count or the latest time-stamp. The requesting printer then updates its memory using the dot count from the most up-to-date response and begins counting dots from that updated count for subsequent print jobs performed using the installed cartridge.

Abstract: A controller for controlling a microfluidic device. A first computing device receives commands from a user interface in a relatively high level protocol using a standardized command language, converts the commands from the standardized command language into a relatively mid-level protocol, sends the commands in the relatively mid-level protocol, receiving data, converts the data into the standardized command language, and sends the data to the user interface according to the standardized command language. A second computing device receives the commands from the first computing device in the relatively mid-level protocol, converts the commands from the relatively mid-level protocol to at least one relatively lower level protocol that is understood by a microfluidic device that is connected to the controller, receives data from the microfluidic device, and sends the data to the first computing device.