An electro-wetting on dielectric (EWOD) device, includes first and second substrates defining a fluid chamber therebetween, a plurality of electro-wetting electrodes on the first substrate, and at least one first electrode and at least two second electrodes on the second substrate. The device further includes a current sensor or sensing a difference between (1) a first current flowing between the first electrode and one of the second electrodes via a first fluid package in the fluid chamber of the EWOD device and (2) a second current flowing between the first electrode and another of the second electrodes via a second fluid package in the fluid chamber of the EWOD device.
An electro-wetting on dielectric (EWOD) device, comprises first and second substrates defining a fluid chamber therebetween, a plurality of electro-wetting electrodes on the first substrate, and at least one first electrode and at least two second electrodes on the second substrate. The device further includes a current sensor for sensing a difference between (1) a first current flowing between the first electrode and one of the second electrodes via a first fluid package in the fluid chamber of the EWOD device and (2) a second current flowing between the first electrode and another of the second electrodes via a second fluid package in the fluid chamber of the EWOD device.
A microfluidic device comprises a first substrate and a second substrate, a gasket spacing the first substrate from the second substrate to define a fluid chamber between the first substrate and the second substrate, and at least one port for introducing a fluid sample into the fluid chamber. An inner edge face of the gasket defines a lateral boundary of the fluid chamber. A plurality of independently addressable array elements are provided on a surface of the first substrate facing the fluid chamber, and at least one circuit element is disposed on a surface of the second substrate facing the fluid chamber. The gasket is configured to provide a conductive path between a circuit element disposed on a surface of the second substrate facing the fluid chamber and an associated terminal.
The disclosure provides a method of manipulating droplets in an electro-wetting on dielectric (EWOD) device. Electro-wetting electrodes of the EWOD device are selectively actuated to: cause first and second droplets in a fluid medium in the fluid chamber of the EWOD device to contact each other to form a droplet interface bilayer, the first droplet containing fluid of a first composition including a first solute species and the second droplet containing fluid of a second composition different to the first composition, maintain the first and second droplets contacting each other to maintain the droplet interface bilayer and thereby allow the first solute species to pass from the first droplet to the second droplet via the DIB; and cause the first droplet to separate from the second droplet. This method aspect results in transfer of solute from the first droplet to the second droplet. This provides a convenient way of altering the concentration of a particular component or components in a fluid droplet within an EWOD device. This allows, for example, an undesired solute species to be extracted from a reaction droplet or the undesired solute species to be diluted in the reaction droplet before the droplet undergoes further reaction steps.
A method of operating an electrowetting on dielectric (EWOD) device performs electrowetting operations on fluids dispensed into the EWOD device, which provides enhanced operation for using multiple non-polar filler fluids. The method of operating includes the steps of: dispensing a polar fluid source into the EWOD device; performing an electrowetting operation to generate an aqueous barrier from the polar fluid source, wherein the aqueous barrier separates the EWOD device into a first region and a second region that are fluidly separated from each other by the aqueous barrier; inputting a non-polar first filler fluid into the first region; inputting a non-polar second filler fluid into the second region; dispensing a polar liquid droplet into the first region; transferring the polar liquid droplet from the first region to the second region by performing an electrowetting operation to reconfigure the aqueous barrier, and performing an electrowetting operation to move the polar liquid droplet from the first region to the second region through the reconfigured aqueous barrier; and performing an electrowetting operation to reconstitute the aqueous barrier to fluidly separate the first region from the second region. The method may be performed by an EWOD control system executing program code stored on a non-transitory computer readable medium.
A method of operating an EWOD device to employs a magnetic field to separate magnetically responsive particles from a polar liquid droplet. The method includes the steps of dispensing a liquid droplet onto an element array of the EWOD device, wherein the liquid droplet includes magnetically responsive particles; performing an electrowetting operation to move the liquid droplet along the element array to a location relative to a magnet element in proximity to that location of the EWOD device; operating the magnet element to apply a magnetic field to the liquid droplet, wherein at least a portion of the magnetically responsive particles aggregate within the liquid droplet in response to the magnetic field; and separating the aggregated magnetically responsive particles from the liquid droplet with the magnetic field, wherein the aggregated magnetically responsive particles move in response to the magnetic field to a location on the element array in proximity to the magnet element. Embodiments of the methods of the present application may be performed by an EWOD control system executing program code stored on a non-transitory computer readable medium.
A microfluidic device performs a method of partitioning droplets from a fluid reservoir containing particles that provides a non-Poissonian distribution of dispensed droplets containing a desired number of particles. Using an electrowetting on dielectric (EWOD) device, droplets are dispensed having a Poissonian distribution of dispensed droplets containing a desired number of particles, and the droplets are interrogated to determine whether each dispensed droplet has a desired number of particles. Droplets that contain the desired number of particles are moved by EWOD operation to a reaction area on the EWOD device, and droplets that do not contain the desired number of particles are rejected and moved by EWOD operation to a holding area on the EWOD device that is different and spaced apart from the reaction area. The result is that droplets in the reaction area have a non-Poissonian distribution of droplets containing the desired number of particles.
A microfluidic AM-EWOD device and a method of filling such a device are provided. The device comprises a chamber having one or more inlet ports. The device is configured, when the chamber contains a metered volume of a filler fluid that partially fills the chamber, preferentially maintain the metered volume of the filler fluid in a part of the chamber. The device is configured to allow displacement of some of the filler fluid from the part of the chamber when a volume of an assay fluid introduced into one of the one or more inlet ports enters the part of the chamber, thereby causing a volume of a venting fluid to vent from the chamber.
A microfluidic system and related methods of operating an electrowetting on dielectric (EWOD) device operate to concentrate particles within a liquid droplet dispensed onto an element array of the EWOD device. The method includes the steps of providing a non-polar liquid onto the element array of the EWOD device; providing a polar liquid droplet onto the element array of the EWOD device within the non-polar liquid, wherein the polar liquid droplet includes particles; and applying an actuation cycle comprising a plurality of actuation patterns, wherein at least one of the actuation patterns includes actuating one or more array element electrodes within a perimeter of the polar liquid droplet, and the particles migrate within the polar liquid droplet to become concentrated within a portion of the liquid droplet at one or more array element electrodes corresponding to one of the plurality of actuation patterns.
A method of determining the result of an assay in a microfluidic device includes the steps of: dispensing a sample droplet onto a first portion of an electrode array of the microfluidic device; dispensing a reagent droplet onto a second portion of the electrode array of the microfluidic device; controlling actuation voltages applied to the electrode array to mix the sample droplet and the reagent droplet into a product droplet; sensing a dynamic property of the product droplet; and determining an assay of the sample droplet based on the sensed dynamic property. The dynamic property is a physical property of the product droplet that influences a transport property of the product droplet on the electrode array. Example dynamic properties of the product droplet include the moveable state, split-able state, and viscosity based on droplet properties. The method may be used to perform an amoebocyte lysate (LAL) assay.
An electro-wetting on dielectric (EWOD) device, comprises first and second substrates defining a fluid chamber therebetween, a plurality of electro-wetting electrodes on the first substrate, and at least one first electrode and at least two second electrodes on the second substrate. The device further includes a current sensor for sensing a difference between (1) a first current flowing between the first electrode and one of the second electrodes via a first fluid package in the fluid chamber of the EWOD device and (2) a second current flowing between the first electrode and another of the second electrodes via a second fluid package in the fluid chamber of the EWOD device.
A microfluidic control system for controlling an EWOD device has an enhanced thermal control system for generating a temperature profile within an EWOD device that is inserted into the microfluidic control system. The microfluidic control system includes a housing that defines an aperture for receiving an EWOD device; an active heating component located within the housing at a base of the aperture; and a lid attached to the housing that is moveable between a closed position and an open position, the lid including a thermal control component. When the lid is in the closed position, the thermal control component is positioned at the aperture and aligned oppositely from the active heating component. The active heating component may include a plurality of independently controllable individual heating elements, and the thermal control component may include a respective plurality of individual thermal control elements. The microfluidic control system further may include a clamp positioned between the lid and the housing for retaining the EWOD device.
A microfluidic control system for controlling an EWOD device has an enhanced thermal control system for generating a temperature profile within an EWOD device that is inserted into the microfluidic control system. The microfluidic control system includes a housing that defines an aperture for receiving an EWOD device; an active heating component located within the housing at a base of the aperture; and a lid attached to the housing that is moveable between a closed position and an open position, the lid including a thermal control component. When the lid is in the closed position, the thermal control component is positioned at the aperture and aligned oppositely from the active heating component. The active heating component may include a plurality of independently controllable individual heating elements, and the thermal control component may include a respective plurality of individual thermal control elements. The microfluidic control system further may include a clamp positioned between the lid and the housing for retaining the EWOD device.
A microfluidic AM-EWOD device and a method of filling such a device are provided. The device comprises a chamber having one or more inlet ports. The device is configured, when the chamber contains a metered volume of a filler fluid that partially fills the chamber, preferentially maintain the metered volume of the filler fluid in a part of the chamber. The device is configured to allow displacement of some of the filler fluid from the part of the chamber when a volume of an assay fluid introduced into one of the one or more inlet ports enters the part of the chamber, thereby causing a volume of a venting fluid to vent from the chamber.
A method of determining a characteristic of a first pair of droplets in an electrowetting on dielectric microfluidic device substantially free from the influences of interference, comprises forming a droplet interface bilayer between a first pair of droplets, a droplet of the first pair of droplets contacting a first sensing electrode and another droplet of the first pair of droplets contacting a first bias electrode. A droplet interface bilayer is formed between a second pair of droplets, a droplet of the second pair of droplets contacting a second sensing electrode and another droplet of the second pair of droplets contacting a second bias electrode. A nanopore is inserted into the droplet interface bilayer of the first pair of droplets, a first signal is measured between the first bias electrode and the first sensing electrode due to transport of a target species through the nanopore of the first pair of droplets and a first signal is measured between the second bias electrode and the second sensing electrode for the second pair of droplets. A difference between the first measured signal from the first pair of droplets and the first measured signal from the second pair of droplets is measured, and the difference between the first measured signal from the first pair of droplets and the first measured signal from the second pair of droplets is reported as being the characteristic of the first pair of droplets, substantially free from interference.
A microfluidic device comprises a first substrate and a second substrate, a gasket spacing the first substrate from the second substrate to define a fluid chamber between the first substrate and the second substrate, and at least one port for introducing a fluid sample into the fluid chamber. An inner edge face of the gasket defines a lateral boundary of the fluid chamber. A plurality of independently addressable array elements are provided on a surface of the first substrate facing the fluid chamber, and at least one circuit element is disposed on a surface of the second substrate facing the fluid chamber. The gasket is configured to provide a conductive path between a circuit element disposed on a surface of the second substrate facing the fluid chamber and an associated terminal.
Droplet interfaces are formed between droplets in an electro-wetting device comprising an array of actuation electrodes. Actuation signals are applied to selected actuation electrodes to place the droplets into an energised state in which the shape of the droplets is modified compared to a shape of the droplets in a lower energy state and to bring the two droplets into proximity. The actuation signals are then changed to lower the energy of the droplets into the lower energy state so that the droplets relax into the gap and the two droplets contact each other thereby forming a droplet interface. The use of sensing electrodes in the device permit electrical current measurements across the droplet interface. The sensing electrodes can be used for either (i) applying a reference signal during droplet actuation or (ii) recording electrical current measurements.
A method of operating an electrowetting on dielectric (EWOD) device performs electrowetting operations on fluids dispensed into the EWOD device, which provides enhanced operation for using multiple non-polar filler fluids. The method of operating includes the steps of: dispensing a polar fluid source into the EWOD device; performing an electrowetting operation to generate an aqueous barrier from the polar fluid source, wherein the aqueous barrier separates the EWOD device into a first region and a second region that are fluidly separated from each other by the aqueous barrier; inputting a non-polar first filler fluid into the first region; inputting a non-polar second filler fluid into the second region; dispensing a polar liquid droplet into the first region; transferring the polar liquid droplet from the first region to the second region by performing an electrowetting operation to reconfigure the aqueous barrier, and performing an electrowetting operation to move the polar liquid droplet from the first region to the second region through the reconfigured aqueous barrier; and performing an electrowetting operation to reconstitute the aqueous barrier to fluidly separate the first region from the second region. The method may be performed by an EWOD control system executing program code stored on a non-transitory computer readable medium.
A method of operating an electrowetting on dielectric (EWOD) device performs electrowetting operations on fluids dispensed into the EWOD device, which provides enhanced operation for using multiple non-polar filler fluids. The method of operating includes the steps of: dispensing a polar fluid source into the EWOD device; performing an electrowetting operation to generate an aqueous barrier from the polar fluid source, wherein the aqueous barrier separates the EWOD device into a first region and a second region that are fluidly separated from each other by the aqueous barrier; inputting a non-polar first filler fluid into the first region; inputting a non-polar second filler fluid into the second region; dispensing a polar liquid droplet into the first region; transferring the polar liquid droplet from the first region to the second region by performing an electrowetting operation to reconfigure the aqueous barrier, and performing an electrowetting operation to move the polar liquid droplet from the first region to the second region through the reconfigured aqueous barrier; and performing an electrowetting operation to reconstitute the aqueous barrier to fluidly separate the first region from the second region. The method may be performed by an EWOD control system executing program code stored on a non-transitory computer readable medium.
The disclosure relates to a method of manipulating droplets in an electro-wetting on dielectric (EWOD) device, the EWOD device having first and second substrates defining a fluid chamber therebetween and a plurality of electro-wetting electrodes. The method comprises selectively actuating the electro-wetting electrodes to: cause first and second droplets in a fluid medium in the fluid chamber of the EWOD device to contact each other to form a droplet interface bilayer, the first droplet containing fluid of a first composition including a first solvent species and the second droplet containing fluid of a second composition, the second composition being different to the first composition and containing a solute at a higher osmolarity than the first composition and so having a higher osmotic pressure; maintain the first and second droplets contacting each other to maintain the droplet interface bilayer and thereby allow a solvent species to pass from the first droplet to the second droplet via the droplet interface bilayer; and cause the first droplet to separate from the second droplet. A method of this aspect results in transfer of solvent from the first droplet to the second droplet, whereby the fluid in the first droplet becomes more concentrated and the fluid in the second droplet becomes more diluted. This provides a convenient way of altering the concentration in a fluid droplet within an EWOD device.
The disclosure provides a method of manipulating droplets in an electro-wetting on dielectric (EWOD) device. Electro-wetting electrodes of the EWOD device are selectively actuated to: cause first and second droplets in a fluid medium in the fluid chamber of the EWOD device to contact each other to form a droplet interface bilayer, the first droplet containing fluid of a first composition including a first solute species and the second droplet containing fluid of a second composition different to the first composition, maintain the first and second droplets contacting each other to maintain the droplet interface bilayer and thereby allow the first solute species to pass from the first droplet to the second droplet via the DIB; and cause the first droplet to separate from the second droplet. This method aspect results in transfer of solute from the first droplet to the second droplet. This provides a convenient way of altering the concentration of a particular component or components in a fluid droplet within an EWOD device. This allows, for example, an undesired solute species to be extracted from a reaction droplet or the undesired solute species to be diluted in the reaction droplet before the droplet undergoes further reaction steps.
A method of operating an EWOD device to employs a magnetic field to separate magnetically responsive particles from a polar liquid droplet. The method includes the steps of dispensing a liquid droplet onto an element array of the EWOD device, wherein the liquid droplet includes magnetically responsive particles; performing an electrowetting operation to move the liquid droplet along the element array to a location relative to a magnet element in proximity to that location of the EWOD device; operating the magnet element to apply a magnetic field to the liquid droplet, wherein at least a portion of the magnetically responsive particles aggregate within the liquid droplet in response to the magnetic field; and separating the aggregated magnetically responsive particles from the liquid droplet with the magnetic field, wherein the aggregated magnetically responsive particles move in response to the magnetic field to a location on the element array in proximity to the magnet element. Embodiments of the methods of the present application may be performed by an EWOD control system executing program code stored on a non-transitory computer readable medium.
A microfluidic system includes: an electro-wetting on dielectric (EWOD) cartridge having an element array configured to receive liquid droplets, the element array including individual array elements each including array element circuity comprising sensing circuitry that is integrated into the array element circuitry; a microfluidic instrument that is configured to receive the EWOD cartridge and having an electrically conductive locator that is external to the EWOD cartridge; and a control system configured perform electrowetting operations by controlling actuation voltages applied to the element array to perform manipulation operations as to liquid droplets present on the element array. The control system further is configured to read an output from the sensing circuitry, determine a position of the locator relative to the element array based on the output, and determine a misalignment of the EWOD cartridge relative to the microfluidic instrument based on the position of the locator. The control system may adjust a droplet manipulation operation to compensate for the determined misalignment.
A microfluidic system includes: an electro-wetting on dielectric (EWOD) cartridge having an element array configured to receive liquid droplets, the element array including individual array elements each including array element circuity comprising sensing circuitry that is integrated into the array element circuitry; a microfluidic instrument that is configured to receive the EWOD cartridge and having an electrically conductive locator that is external to the EWOD cartridge; and a control system configured perform electrowetting operations by controlling actuation voltages applied to the element array to perform manipulation operations as to liquid droplets present on the element array. The control system further is configured to read an output from the sensing circuitry, determine a position of the locator relative to the element array based on the output, and determine a misalignment of the EWOD cartridge relative to the microfluidic instrument based on the position of the locator. The control system may adjust a droplet manipulation operation to compensate for the determined misalignment.
A microfluidic device comprises upper and lower spaced apart substrates defining a fluid chamber therebetween; an aperture for introducing fluid into the fluid chamber; a plurality of independently addressable array elements, each array element defining a respective region of the fluid chamber; and control means for addressing the array elements. The control means are configured to: determine that a working fluid has been introduced into a first region of the fluid chamber; and provide an output to a user to indicate that the working fluid is present in the first region.
Once the working fluid is in the first region, the fluid applicator used to dispense the fluid can be removed without any risk of accidentally withdrawing dispensed working fluid from the microfluidic device. In the case of manual loading of the working fluid the output may inform a user that it is safe to remove the applicator, or in the case of automatic or robotic loading the output signal may be provided to the system controlling the automatic or robotic loading of fluid so that the system can remove the fluid applicator.
A method of operating an electrowetting on dielectric (EWOD) device performs microfluidic diffusion separation. The method includes the steps of: inputting a sample droplet into the EWOD device, wherein the sample droplet includes a mixture of particles including first particles and second particles that are different from each other; inputting a collection droplet into the EWOD device; performing an electrowetting operation to bring the sample droplet into contact with the collection droplet; at an initial time, initiating a process of particle separation by which a portion of the sample droplet is introduced into the collection droplet, wherein the first particles move through the collection droplet at a rate different from the second particles; and after a time interval from the initial time, performing an electrowetting operation to segment a leaving droplet from the collection droplet, wherein the leaving droplet has a higher concentration of the first particles relative to the second particles as compared to a concentration of the first particles relative to the second particles in the sample droplet at the initial time. The method may be performed by an AM-EWOD control system executing program code stored on a non-transitory computer readable medium.
A method of partitioning droplets from a fluid reservoir containing particles provides a non-Poissonian distribution of dispensed droplets containing a desired number of particles. The method constitutes a method of operating an electrowetting on dielectric (EWOD) device including the steps of: inputting a fluid reservoir containing particles into the EWOD device; performing an electrowetting operation to dispense a plurality of dispensed droplets from the fluid reservoir; interrogating each droplet with a detector and determining whether each dispensed droplet has a desired number of particles; selecting dispensed droplets that contain the desired number of particles and performing an electrowetting operation to move the selected dispensed droplets to a reaction area on the EWOD device; and rejecting dispensed droplets that do not contain the desired number of particles and performing an electrowetting operation to move the rejected dispensed droplets to a holding area on the EWOD device that is different and spaced apart from the reaction area. The selected droplets may be combined, including with or without a portion of the rejected droplets and/or additional reagent, into a larger reaction droplet that may be used in subsequent reaction protocols.
A method of operating an active matrix electro-wetting on dielectric (AM-EWOD) device provides for enhanced mutual capacitance sensing using integrated impedance sensing circuitry. Array element circuitry of each array element includes actuation circuitry configured to apply actuation voltages to the array element electrode for actuating the array element, and impedance sensor circuitry integrated into the array element circuitry and configured to sense impedance at the array element electrode. The method of operating includes the steps of: perturbing a voltage applied to the array element electrode of a first array element; coupling the voltage perturbation to the array element electrode of a second array element different from the first array element; and measuring the output current from the sensor readout transistor of the second array element for sensing in response to the voltage perturbation. The method may be performed by an AM-EWOD control system executing program code stored on a non-transitory computer readable medium.
An AM-EWOD device includes a plurality of array elements arranged in an array of rows and columns, each of the array elements including array element circuitry, an element electrode, and a reference electrode. The array element circuitry includes actuation circuitry configured to apply actuation voltages to the element and/or reference electrodes for actuating the array element, and impedance sensor circuitry configured to sense impedance at the array element electrode to determine a droplet or device property at the array element, the impedance sensor circuitry comprising a sensor capacitor and a sensor readout transistor that outputs an output current for sensing. The sensor capacitor is electrically connected to a gate of the sensor readout transistor such that during a sensing phase a voltage perturbation is coupled through the sensor capacitor (and possibly other circuit elements) to the gate of the sensor readout transistor. The impedance sensor circuitry further comprises a pre-charging element that operates to turn on the sensor readout transistor during the sensing phase in combination with coupling of the voltage perturbation, thereby increasing the effect of the voltage perturbation on the output current.
G09G 3/34 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
H01L 27/12 - Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including integrated passive circuit elements with at least one potential-jump barrier or surface barrier the substrate being other than a semiconductor body, e.g. an insulating body
30.
AM-EWOD circuit configuration with sensing column detection circuit
An AM-EWOD device includes a plurality of array elements arranged in an array of rows and columns; each column including a column addressing line that applies control signals to a corresponding column of array elements, and each row including a row addressing line that applies control signals to a corresponding row of array elements; each array element including an element electrode for receiving an actuation voltage and a switch transistor, wherein the switch transistor is electrically connected between the column addressing line and the element electrode and is switched by the row addressing line; and a column detection circuit comprising an addressing circuit that applies an electrical perturbation during a sensing operation to the column addressing line of an array element being sensed, and a measuring circuit that measures an output signal from one of the column addressing lines, wherein the output signal varies based upon a capacitance present at the element electrode.
G01N 27/26 - Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variablesInvestigating or analysing materials by the use of electric, electrochemical, or magnetic means by using electrolysis or electrophoresis
G09G 3/34 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
G09G 3/00 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
G01N 27/02 - Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
A microfluidic device comprises upper and lower spaced apart substrates defining a fluid chamber therebetween; an aperture for introducing fluid into the fluid chamber; and a fluid input structure disposed over the upper substrate and having a fluid well for receiving fluid from a fluid applicator inserted into the fluid well. The fluid well communicates with a fluid exit provided in a base of the fluid input structure, the fluid exit being adjacent the aperture. The fluid well comprises first, second and third portions, with the first portion of the well forming a reservoir for a filler fluid; and the second portion of the well being configured to sealingly engage against an outer surface of a fluid applicator inserted into the fluid well. The third portion of the well communicates with the fluid exit and has a diameter at the interface between the third portion and the second portion that is greater than the diameter of the second portion at the interface between the third portion and the second portion.
An electrowetting on dielectric (EWOD) device includes an EWOD device array that applies electrowetting forces and contains a non-polar fluid. A barrier droplet configuration is formed using electrowetting forces to obstruct migration of a species from a first area of the EWOD device array to a protected area of the EWOD device array. A method of operating the EWOD device includes the steps of: dispensing a source droplet into a first area of the EWOD device array, the source droplet containing a migrating species, wherein the EWOD device array includes a second area to be protected from the migrating species; and forming a barrier droplet configuration positioned between the first area and the second area of the EWOD device array that obstructs a migration pathway of the migrating species between the first area and the second area. The barrier droplet configuration includes at least one aqueous or polar barrier droplet, and the migrating species exhibits a preference for either the polar or aqueous environment of the barrier or the non-polar environment of the oil to obstruct migration.
An EWOD device and a related method of performing a digital biological assay are described that employs two volume measurements for enhanced assay determination. The method includes partitioning a sample reservoir and measuring the volume of each partition; initiating a biological assay wherein the biological assay includes measuring a partition property and a volume of each partition in real time as part of determining a concentration of the product substance in each partition based on the measured partition property and volume; and categorizing the partitions by a number of biological entities contained in each partition from which the number of biological entities may be calculated, which in turn may be used to calculate the total number of biological entities or concentration in the sample reservoir. The method further may include an enhanced partitioning process that minimizes variation in the volume of the partitions.
An active matrix electro-wetting on dielectric (AM-EWOD) device has an optically black array element structure to enhance optical detection of constituents within a liquid droplet. The AM-EWOD device includes a thin film transistor (TFT) substrate assembly having a hydrophobic layer; thin film electronics having a plurality of array elements arranged in an array of rows and columns, each of the array elements including an array element electrode and a TFT device; and an optically black material disposed between a plane of the TFT device and the hydrophobic layer. The TFT substrate assembly further includes a planarization structure that includes a component having the optically black material. The planarization structure has a planarization component disposed between the TFT device and the array element electrode, and an ionic barrier disposed between the array element electrode and the hydrophobic coating. The planarization component or the ionic barrier includes the optically black material.
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
H01L 27/12 - Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including integrated passive circuit elements with at least one potential-jump barrier or surface barrier the substrate being other than a semiconductor body, e.g. an insulating body
35.
EWOD system and methods to increase dynamic range for digital nucleic acid amplification
A method of digital quantification of a species in an EWOD device includes inputting a sample volume and a diluent volume into the EWOD device; performing an electrowetting operation to generate a first sample droplet from the sample volume; performing an amplification process on the first sample droplet and measuring a turn-on value for the sample droplet; comparing the measured turn-on value to a target turn-on value for digital quantification; calculating a dilution factor based on the comparison of the measured and target turn-on values; performing an electrowetting operation to extract a second sample droplet from the sample volume; performing an electrowetting operation to dilute the second sample droplet with the diluent volume by the dilution factor to form a diluted second sample droplet; and performing a digital quantification on the diluted second sample droplet to quantify an initial concentration of the species in the sample volume.
A control method and related apparatus are disclosed for controlling actuation voltages applied to array elements of an element array on an electrowetting on dielectric (EWOD) device, wherein test metrics are determined and employed for optimizing subsequent droplet manipulation operations. The control method includes the steps of: receiving a liquid droplet onto the element array; applying an electrowetting actuation pattern of actuation voltages to actuate the droplet to modify a footprint of the droplet from a first state having an initial footprint to a second state having a modified footprint; sensing the modified footprint with a sensor; determining a test metric from sensing the modified footprint indicative of one or more droplet properties based on a droplet response of the liquid droplet to the electrowetting actuation pattern; and controlling actuation voltages applied to the array elements based on the test metric. The test metrics may include a transition rate and/or conformance to an actuation pattern.
An AM-EWOD device includes a plurality of array elements arranged in an array of rows and columns, each of the array elements including array element circuitry, an element electrode, and a reference electrode. The array element circuitry includes actuation circuitry that applies actuation voltages to the element and reference electrodes, and impedance sensor circuitry that senses impedance at the array element electrode to determine a droplet property at the array element. At least one component of the impedance sensor circuitry is a shared component that is shared between more than one of the array elements. The shared component may include a shared sensor readout transistor that passes a sensor current to a sensor output line, or a shared reset transistor that applies a reset voltage to a gate of the shared sensor readout transistor, with such components being shared by array elements in adjacent rows. The shared component may include a shared sensor output column line that is shared between array elements in adjacent columns.
An embodiment of the present invention provides a microfluidic device into which fluid can be more easily introduced. A microfluidic device (1) is configured such that: (i) an upper substrate (2) is bonded to a lower substrate (6) via a sealing pattern (5) in such a manner that at least a portion of an edge of the upper substrate (2) is located inward of an edge of the lower substrate (6); and (ii) the sealing pattern (5) includes at least one gap (12) that is provided at a position where the edge of the upper substrate (2) is located inward of the edge of the lower substrate (6).
Droplet interfaces are formed between droplets in an electro-wetting device comprising an array of actuation electrodes. Actuation signals are applied to selected actuation electrodes to place the droplets into an energised state in which the shape of the droplets is modified compared to a shape of the droplets in a lower energy state and to bring the two droplets into proximity. The actuation signals are then changed to lower the energy of the droplets into the lower energy state so that the droplets relax into the gap and the two droplets contact each other thereby forming a droplet interface. The use of sensing electrodes in the device permit electrical current measurements across the droplet interface. The sensing electrodes can be used for either (i) applying a reference signal during droplet actuation or (ii) recording electrical current measurements.
An impedance cytometry device is described along with methods of accurately measuring particle size of particles contained in a fluid that is passed through the impedance cytometry device. The impedance cytometry device includes a substrate, and an electrode arrangement deposited on the substrate in a co-planar fashion. The electrode arrangement includes a drive electrode and a plurality of measurement electrodes located in a same plane as the drive electrode. The plurality of measurement electrodes includes at least two pairs of measurement sub-electrodes, each pair of measurement sub-electrodes including a first measurement sub-electrode positioned adjacent to the drive electrode, and a second measurement sub-electrode separated from the drive electrode by a respective first measurement sub-electrode. The impedance cytometry device may be incorporated into a substrate assembly of an electrowetting on dielectric (EWOD) device, such as in a substrate assembly containing electrowetting drive electrodes or a common reference electrode, or into a microfluidic blood counter device.
G01N 15/12 - Investigating individual particles by measuring electrical or magnetic effects by observing changes in resistance or impedance across apertures when traversed by individual particles, e.g. by using the Coulter principle
G01N 33/483 - Physical analysis of biological material
An active matrix electro-wetting on dielectric (AM-EWOD) device includes a plurality of array elements arranged in an array, each array element including array element circuitry, an element electrode, and a reference electrode. The array element circuitry includes an actuation circuit configured to apply actuation voltages to the electrodes, and an impedance sensor circuit configured to sense impedance at the array element electrode to determine a droplet property. The actuation circuitry includes a memory capacitor for storing voltage data corresponding to either an actuated state or an unactuated state of the array element, and an input applied to the memory capacitor operates to effect an operation of the impedance sensor circuit. Such input may isolate the array element from the actuation voltage during operation of the impedance sensor circuit, and the memory capacitor may operate as part of the impedance sensor circuit as a reference capacitor for determining the droplet property.
A microfluidic AM-EWOD device and a method of filling such a device are provided. The device comprises a chamber having one or more inlet ports. The device is configured, when the chamber contains a metered volume of a filler fluid that partially fills the chamber, preferentially maintain the metered volume of the filler fluid in a part of the chamber. The device is configured to allow displacement of some of the filler fluid from the part of the chamber when a volume of an assay fluid introduced into one of the one or more inlet ports enters the part of the chamber, thereby causing a volume of a venting fluid to vent from the chamber.
An EWOD device includes opposing substrates defining a gap and each including an insulating surface facing the gap. Array elements include electrode elements to which actuation voltages are applied. A pre-charging structure defines a channel in fluid communication with the gap wherein the channel receives an input of a fluid reservoir for generation of the liquid droplet, and the pre-charging structure includes an electrical element electrically exposed to the channel. The electrical element pre-charges the fluid reservoir within the channel, and a portion of the gap containing the liquid droplet spaced apart from the channel is electrically isolated from the electrical element such that the liquid droplet is at a floating electrical potential when located within said portion of the gap. The electrical element may be an electrode portion that is exposed to the channel, or an externally connected pre-charging element inserted into the channel.
An EWOD device includes a first substrate assembly and a second substrate assembly; wherein one of said substrate assemblies includes electrowetting electrodes, and the first substrate assembly and the second substrate assembly are spaced apart to define a channel between the substrate assemblies; and a housing for receiving the first substrate assembly and the second substrate assembly, the housing comprising an alignment feature for locating at least one of the first and second substrate assemblies within the housing. The device further includes a fixing feature for fixing the first and second substrate assemblies within the housing. The second substrate assembly is located within the housing such that the second substrate assembly is an outer component of the EWOD device. The device further may include a spacer that spaces apart the first substrate assembly from the second substrate assembly to define the channel between the first and second substrate assemblies.
An EWOD device includes a first and second substrate assemblies, and a spacer that spaces apart the first substrate assembly from the second substrate assembly to define a channel between them. The spacer defines fluid input ports that are in fluid communication with the channel, and the spacer is configured for directing fluid from the fluid input ports into the channel. The spacer has a combed spacer configuration to define the fluid input ports, including alternating teeth that extend into the channel from a base region, and the teeth isolate adjacent fluid input ports from each other. The spacer may contact only a portion of the first and second substrate assemblies to form a spacerless region within the EWOD device, and the spacer includes regions that are in contact with both the first and second substrate assemblies and extend into the channel to define a cell-gap of the channel.
An EWOD device includes a first and second substrate assemblies, and a spacer that spaces apart the first substrate assembly from the second substrate assembly to define a channel between them. The spacer defines fluid input ports that are in fluid communication with the channel, and the spacer is configured for directing fluid from the fluid input ports into the channel. The spacer has a combed spacer configuration to define the fluid input ports, including alternating teeth that extend into the channel from a base region, and the teeth isolate adjacent fluid input ports from each other. The spacer may contact only a portion of the first and second substrate assemblies to form a spacerless region within the EWOD device, and the spacer includes regions that are in contact with both the first and second substrate assemblies and extend into the channel to define a cell-gap of the channel.
An EWOD device includes a first substrate assembly and a second substrate assembly; wherein one of said substrate assemblies includes electrowetting electrodes, and the first substrate assembly and the second substrate assembly are spaced apart to define a channel between the substrate assemblies; and a housing for receiving the first substrate assembly and the second substrate assembly, the housing comprising an alignment feature for locating at least one of the first and second substrate assemblies within the housing. The device further includes a fixing feature for fixing the first and second substrate assemblies within the housing. The second substrate assembly is located within the housing such that the second substrate assembly is an outer component of the EWOD device. The device further may include a spacer that spaces apart the first substrate assembly from the second substrate assembly to define the channel between the first and second substrate assemblies.
A pixel circuit acts as a sensing element in a sensing device. The pixel circuit includes a sensing electrode, a first gate electrically connected to the sensing electrode, a second gate in electrical communication with the first gate, and a readout device that is electrically connected to the second gate. An input voltage applied to the sensing electrode is amplified between the first gate and the second gate, the amplification being measured as an output signal from the readout device to perform a sensing operation. For example, the output signal may be relatable to pH, analyte measurements, or other properties of sample liquids analyzed by the sensing device. A sensing device may include multiple pixels disposed on a substrate, each pixel including said pixel circuit. Driver circuits controlled by control electronics are configured to generate signals that selectively address the pixels and to read out voltages at the sensing electrodes.
G01N 27/414 - Ion-sensitive or chemical field-effect transistors, i.e. ISFETS or CHEMFETS
G01N 27/00 - Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
G01N 31/00 - Investigating or analysing non-biological materials by the use of the chemical methods specified in the subgroupsApparatus specially adapted for such methods
49.
EWOD device with holdback feature for fluid loading
An electrowetting on dielectric (EWOD) device includes a first substrate assembly and a second substrate assembly spaced apart to define a channel between them; an input port in fluid communication with the channel, the input port defining an input well for receiving a fluid for inputting into the channel; and a control port in fluid communication with the channel, the control port defining a control well for receiving a fluid and having a seal that seals the control port in a sealed state in which fluid is restricted from entering the control well from the channel. When the seal is pierced, the control port is placed in an unsealed state permitting fluid to enter the control well from the channel. The electrowetting force may be manipulated to remove the dispensed droplets via an exit port. Multiple cycles of fluid input/droplet manipulation/fluid extraction may be repeated to perform complex reaction protocols.
A microfluidic system is configured for enhanced temperature control by combining spatial and temporal temperature control. The microfluidic system includes an electro-wetting on dielectric (EWOD) device comprising an element array configured to receive one or more liquid droplets, the element array comprising a plurality of individual array elements; a control system configured to control actuation voltages applied to the element array to perform manipulation operations of the liquid droplets; and a plurality of thermal control elements located at different spatial locations along the EWOD device, at least one of the thermal control elements being variable in temperature with respect to time. The control system includes a thermal control unit configured to control temperatures of the thermal control elements to generate a plurality of thermal zones located at different spatial locations along the EWOD device, at least one of the thermal zones being variable in temperature with respect to time.
A microfluidic system includes an electro-wetting on dielectric (EWOD) device and a control system that controls actuation voltages applied to the element array of the EWOD device to perform manipulation operations as to fluid droplets. The control system applies a sequence of actuation voltages to a portion of the array elements associated with a droplet to maintain the droplet in a desired droplet state corresponding to a predetermined droplet property. The sequence of actuation voltages includes an actuation-on period in which the portion of the array elements associated with the droplet is actuated and an actuation-off period in which the portion of the array elements associated with the droplet is not actuated, and the actuation-off period is non-zero. The control system may apply a sequence of actuation voltages comprising a predetermined duty cycle, and/or the actuation voltages may be applied in accordance with a sensor based intervention.
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
H01L 27/12 - Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including integrated passive circuit elements with at least one potential-jump barrier or surface barrier the substrate being other than a semiconductor body, e.g. an insulating body
52.
Droplet actuation method for a microfluidic device
A microfluidic system includes an electrowetting on dielectric (EWOD) device comprising an array of elements that are actuatable for manipulation of a liquid droplet within the EWOD device. The system has a pattern generator that generates an actuation pattern for actuating a portion of the elements in the array of elements, and a signal generator that generates voltage signals for actuating elements in the array of elements in accordance with the actuation pattern. The pattern generator generates an actuation pattern in which voltage signals applied to elements in at least part of a region at or adjacent to a contact line of the droplet are different from voltage signals applied to elements that are not in the part of the region at or adjacent to the contact line. The system further may include a sensor for sensing the droplet contact line constituting a boundary of the liquid droplet.
An EWOD device for processing multiple droplets through multiple temperature zones. The device is configured to achieve a high spatial density of temperature zones with a wide temperature difference between hot and cold zones. A first set of temperature control elements is arranged above (or below) a fluid gap in an EWOD device and a second set of temperature control elements is arranged below (or above) the fluid gap. A temperature control element of one set is offset from temperature control elements of the other set in the plane of the fluid gap. The temperature control element of one set may be located at a different separation from the fluid gap to the temperature control element of the other set. The device has an optional temperature control element and/or arrangement which offsets the low temperature point from the inlet temperature. The two sets of temperature control elements are substantially interacting, in the sense that they cannot be considered to be thermally isolated from one another. This invention also describes methods to process multiple droplets within the multiple temperature zones.
A heating system for an EWOD device using a single, spatially-structured temperature control element, used to create a zone with a specific temperature profile. The heating system uses multiple contact regions between the temperature control element and the device. One or more contact regions are separated from the temperature control element by one or more thermally resistive layers that restrict heat flow from the temperature control element to the device, and further restrict lateral flow of heat between adjacent contact regions. The heating system can use materials with different thermal resistance to alter the heat flow to different regions. The spatial location of the contact regions is also used to determine the temperature profile within the device. The device has an optional temperature control element which offsets the low temperature point from the inlet temperature. This invention includes methods to process multiple droplets within the multiple temperature zones.
A method of extracting assay fluid from an EWOD device, the EWOD device comprising two opposing substrates defining a fluid space there between and an aperture for extraction of fluid from the fluid space. The method comprises providing, in the fluid space of the EWOD device, a droplet of assay fluid adjacent to the aperture such that the droplet blocks extraction, via the aperture, of filler fluid contained in the fluid space of the EWOD device, and extracting, via the aperture, at least some of the assay fluid of the droplet from the fluid space. The method comprises, during the extracting, controlling the assay fluid droplet by electrowetting to maintain the blocking of extraction of filler fluid. By controlling the position of the unextracted portion of the assay fluid droplet relative to the aperture during the extraction process, the unextracted portion of the assay fluid droplet continues to block extraction of filler fluid. This makes it much less likely for unwanted extraction of filler fluid to occur.
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
H01L 27/12 - Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including integrated passive circuit elements with at least one potential-jump barrier or surface barrier the substrate being other than a semiconductor body, e.g. an insulating body
F16K 99/00 - Subject matter not provided for in other groups of this subclass
A fluid loader is provided for loading fluid into a microfluidic device, the microfluidic device having upper and lower spaced apart substrates defining a fluid chamber therebetween and an aperture for receiving fluid into the fluid chamber. The fluid loader includes a fluid well communicating with a fluid exit provided in a base of the fluid loader. The base of the fluid loader is shaped, in use, to locate the fluid loader relative to the aperture, and to direct fluid leaving the fluid loader via the fluid exit preferentially in a first direction in the fluid chamber of the microfluidic device. In one embodiment the base of the fluid loader includes a protruding portion having at least first and second legs, the first leg being shorter than the second leg. In use, the fluid loader is positioned such that the first leg of the fluid loader is between a fluid loading area associated with the aperture and an operating area of the device.
Provided is a microfluidic device that, as compared with a conventional microfluidic device, (i) is smoother in surface of a water-repellent layer provided above a segment electrode and (ii) makes it easier for microfluid provided in the surface of the water-repellent layer to slide. A microfluidic device (1) includes: an array substrate (10) including a plurality of electrodes (14); and a counter substrate (40) including at least one electrode (42), the array substrate (10) and the counter substrate (40) having therebetween an internal space (50) in which to cause an electroconductive droplet (51) to move across the plurality of electrodes (14), and the plurality of electrodes (14) being provided on a first flattening resin layer (13) and each being a light-blocking metal electrode.
0 or (b) re-writing the set of data N−1 times (where N≥2). The reference electrode is then set to a second reference voltage different from the first reference voltage, and features (i) to (iii) are repeated. When the data are first written, there is a delay between the time when the voltage on the reference electrode is transitioned and the time when a given array element is next written with data. Feature (iii) allows the time for which the correct data values are held to be increased relative to the time for which incorrect data values may possibly be held, so that the time for which an element may be in an incorrect state can be made insignificant in terms of its effect on unwantedly perturbing droplet operations.
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
F04B 19/00 - Machines or pumps having pertinent characteristics not provided for in, or of interest apart from, groups
G09G 3/34 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source
C25B 9/06 - Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof
A pixel circuit acts as a sensing element in a sensing device. The pixel circuit includes a sensing electrode, a first gate electrically connected to the sensing electrode, a second gate in electrical communication with the first gate, and a readout device that is electrically connected to the second gate. An input voltage applied to the sensing electrode is amplified between the first gate and the second gate, the amplification being measured as an output signal from the readout device to perform a sensing operation. For example, the output signal may be relatable to pH, analyte measurements, or other properties of sample liquids analyzed by the sensing device. A sensing device may include multiple pixels disposed on a substrate, each pixel including said pixel circuit. Driver circuits controlled by control electronics are configured to generate signals that selectively address the pixels and to read out voltages at the sensing electrodes.
G01N 27/00 - Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
G01N 31/00 - Investigating or analysing non-biological materials by the use of the chemical methods specified in the subgroupsApparatus specially adapted for such methods
G01N 27/414 - Ion-sensitive or chemical field-effect transistors, i.e. ISFETS or CHEMFETS
61.
Method of driving an element of an active matrix EWOD device, a circuit, and an active matrix EWOD device
A method of driving an element of an active matrix electro-wetting on dielectric (AM-EWOD) device comprise applying a first alternating voltage to a reference electrode of the AM-EWOD device; and either (i) applying to the element electrode a second alternating voltage that has the same frequency as the first alternating voltage and that is out of phase with the first alternating voltage or (ii) holding the element electrode in a high impedance state. The effect of applying the second alternating voltage to the element electrode is to put the element in an actuated state in which the element is configured to actuate any liquid droplet present in the element, while the effect of holding the element electrode in the high impedance state is to put the element in a non-actuated state.
B01J 19/00 - Chemical, physical or physico-chemical processes in generalTheir relevant apparatus
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
G09G 3/34 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source
F04B 19/00 - Machines or pumps having pertinent characteristics not provided for in, or of interest apart from, groups
H01L 21/67 - Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereofApparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
62.
Active matrix EWOD device and method of driving thereof
An AM-EWOD device comprises: first and second substrates (72,36); first and second array element electrodes (38A, 38B) disposed on the first substrate (72) and defining first and second array elements in the AM-EWOD device; a reference electrode (28) disposed on the first substrate (72); a sensor; and a reference electrode drive circuit (50). The reference electrode drive circuit (50) is configured to drive the reference electrode with a first voltage waveform for actuating an array element or with a second voltage waveform different from the first voltage waveform when performing a sensing operation.
Provided is a microfluidic device that makes it possible to more easily inject a fluid. A microfluidic device (1) wherein an upper substrate (2) is bonded to a lower substrate (6) via a seal pattern (5) such that at least one portion of an end part of the upper substrate (2) is positioned further to the inside than an end part of the lower substrate (6) and wherein at least one break (12) is formed in the seal pattern (5) where the end part of the upper substrate (2) is positioned further to the inside than the end part of the lower substrate (6).
An electrowetting device (1) is provided with a lower substrate (10) that has an electrode (13) and an upper substrate (20) that has an electrode (22). The upper substrate (20) has through-holes (25), and the electrode (13) is provided in an area including the area directly below the through-holes (25). A hydrophobic layer (23) is provided on the upper surface of the upper substrate (20), a hydrophobic layer (15) is provided on the upper surface of the lower substrate (10), and a hydrophilic layer (24) is provided inside the through-holes (25).
B01J 19/00 - Chemical, physical or physico-chemical processes in generalTheir relevant apparatus
G01N 37/00 - Details not covered by any other group of this subclass
G09F 9/37 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements in which the desired character or characters are formed by combining individual elements being movable elements
An active matrix electro-wetting on dielectric (AM-EWOD) device includes a plurality of array elements arranged in an array, each of the array elements including array element circuitry, an element electrode, and a reference electrode. The array element circuitry includes an actuation circuit configured to apply actuation voltages to the electrodes, and an impedance sensor circuit configured to sense impedance at the array element electrode to determine a droplet property at the array element. The impedance sensor circuit is operated by perturbing a potential applied to the reference electrode. The AM-EWOD device includes a common row addressing line. The impedance sensor circuit further is operated by supplying voltage signals over the common addressing line to effect both a reset operation and an operation for selecting a row in the array to be sensed. The circuitry isolates the array element from the actuation voltage during operating the impedance sensor circuit.
G01N 27/02 - Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
B01J 19/00 - Chemical, physical or physico-chemical processes in generalTheir relevant apparatus
G01N 1/00 - SamplingPreparing specimens for investigation
G01N 35/08 - Automatic analysis not limited to methods or materials provided for in any single one of groups Handling materials therefor using a stream of discrete samples flowing along a tube system, e.g. flow injection analysis
66.
MICROFLUIDIC DEVICE AND A METHOD OF LOADING FLUID THEREIN
A microfluidic AM-EWOD device and a method of filling such a device are provided. The device comprises a chamber having one or more inlet ports. The device is configured, when the chamber contains a metered volume of a filler fluid that partially fills the chamber, preferentially maintain the metered volume of the filler fluid in a part of the chamber. The device is configured to allow displacement of some of the filler fluid from the part of the chamber when a volume of an assay fluid introduced into one of the one or more inlet ports enters the part of the chamber, thereby causing a volume of a venting fluid to vent from the chamber.
G01N 35/08 - Automatic analysis not limited to methods or materials provided for in any single one of groups Handling materials therefor using a stream of discrete samples flowing along a tube system, e.g. flow injection analysis
B01J 19/00 - Chemical, physical or physico-chemical processes in generalTheir relevant apparatus
G01N 37/00 - Details not covered by any other group of this subclass
An active matrix electro-wetting on dielectric (AM-EWOD) device includes a plurality of array elements arranged in an array, each of the array elements including array element circuitry, an element electrode, and a reference electrode. The array element circuitry includes an actuation circuit configured to apply actuation voltages to the electrodes, and an impedance sensor circuit configured to sense impedance at the array element electrode to determine a droplet property at the array element. The impedance sensor circuit is operated by perturbing a potential applied to the reference electrode. The AM-EWOD device includes a common row addressing line. The impedance sensor circuit further is operated by supplying voltage signals over the common addressing line to effect both a reset operation and an operation for selecting a row in the array to be sensed. The circuitry isolates the array element from the actuation voltage during operating the impedance sensor circuit.
G09G 3/34 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
An active matrix electro-wetting on dielectric (AM-EWOD) device includes a plurality of array elements arranged in an array, each array element including array element circuitry, an element electrode, and a reference electrode. The array element circuitry includes an actuation circuit configured to apply actuation voltages to the electrodes, and an impedance sensor circuit configured to sense impedance at the array element electrode to determine a droplet property. The actuation circuitry includes a memory capacitor for storing voltage data corresponding to either an actuated state or an unactuated state of the array element, and an input applied to the memory capacitor operates to effect an operation of the impedance sensor circuit. Such input may isolate the array element from the actuation voltage during operation of the impedance sensor circuit, and the memory capacitor may operate as part of the impedance sensor circuit as a reference capacitor for determining the droplet property.
A method of determining the result of an assay in a microfluidic device includes the steps of: dispensing a sample droplet onto a first portion of an electrode array of the microfluidic device; dispensing a reagent droplet onto a second portion of the electrode array of the microfluidic device; controlling actuation voltages applied to the electrode array to mix the sample droplet and the reagent droplet into a product droplet; sensing a dynamic property of the product droplet; and determining an assay of the sample droplet based on the sensed dynamic property. The dynamic property is a physical property of the product droplet that influences a transport property of the product droplet on the electrode array. Example dynamic properties of the product droplet include the moveable state, split-able state, and viscosity based on droplet properties. The method may be used to perform an amoebocyte lysate (LAL) assay.
G01N 35/08 - Automatic analysis not limited to methods or materials provided for in any single one of groups Handling materials therefor using a stream of discrete samples flowing along a tube system, e.g. flow injection analysis
G01N 1/00 - SamplingPreparing specimens for investigation
G01N 33/86 - Chemical analysis of biological material, e.g. blood, urineTesting involving biospecific ligand binding methodsImmunological testing involving blood coagulating time
G01N 37/00 - Details not covered by any other group of this subclass
70.
DROPLET MICROFLUIDIC DEVICE AND METHODS OF SENSING THE RESULT OF AN ASSAY THEREIN
A method of determining the result of an assay in a microfluidic device includes the steps of: dispensing a sample droplet onto a first portion of an electrode array of the microfluidic device; dispensing a reagent droplet onto a second portion of the electrode array of the microfluidic device; controlling actuation voltages applied to the electrode array to mix the sample droplet and the reagent droplet into a product droplet; sensing a dynamic property of the product droplet; and determining an assay of the sample droplet based on the sensed dynamic property. The dynamic property is a physical property of the product droplet that influences a transport property of the product droplet on the electrode array. Example dynamic properties of the product droplet include the moveable state, split-able state, and viscosity based on droplet properties. The method may be used to perform an amoebocyte lysate (LAL) assay.
A method of determining the result of an assay in a microfluidic device includes the steps of: dispensing a sample droplet onto a first portion of an electrode array of the microfluidic device; dispensing a reagent droplet onto a second portion of the electrode array of the microfluidic device; controlling actuation voltages applied to the electrode array to mix the sample droplet and the reagent droplet into a product droplet; sensing a dynamic property of the product droplet; and determining an assay of the sample droplet based on the sensed dynamic property. The dynamic property is a physical property of the product droplet that influences a transport property of the product droplet on the electrode array. Example dynamic properties of the product droplet include the moveable state, split-able state, and viscosity based on droplet properties. The method may be used to perform an amoebocyte lysate (LAL) assay.
In a method of performing dilution of a droplet in an EWOD device, a parent droplet is provided on an electrode array of the EWOD device, wherein the parent droplet has a first concentration of a species. A diluent droplet also is provided on the electrode array of the EWOD device. The method includes controlling actuation voltages applied to the electrode array of the EWOD device to join the parent droplet and the diluent droplet into a product droplet having a diluted second concentration of the species different from the first concentration in the parent droplet. The actuation voltages then are controlled to split the product droplet into one or more daughter droplets having the second concentration of the species. A dilution ratio may be calibrated based on the volumes of the droplets. Serial dilution steps may be performed to generate daughter droplets of different species concentrations at each step.
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
G01N 27/02 - Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
G01N 27/22 - Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating capacitance
An EWOD (or AM-EWOD) device includes a reference electrode and a plurality of array elements, each array element including an array element electrode, and control electronics. In a first mode optimized for EWOD actuation, the control electronics is configured to control a supply of time varying voltages to the array element electrodes and the reference electrode, thereby generating an actuation voltage as a potential difference between voltages at the array element electrodes and the reference electrode. The reference electrode includes a first electrical connection and a second electrical connection. In a second mode, the control electronics further is configured to supply an electrical current flow between the first electrical connection and the second electrical connection to generate resistance heat for controlling temperature of the EWOD device. Control may include sensing a temperature of the EWOD device, and switching between operating in the first or second mode based on the sensed temperature.
An EWOD (or AM-EWOD) device includes a reference electrode (28) and a plurality of array elements (38), each array element including an array element electrode (38A, 38B), and control electronics (43). In a first mode optimized for EWOD actuation, the control electronics (43) is configured to control a supply of time varying voltages to the array element electrodes (38A, 38B) and the reference electrode (28), thereby generating an actuation voltage as a potential difference between voltages at the array element electrodes and the reference electrode. The reference electrode (28) includes a first electrical connection (A) and a second electrical connection (B). In a second mode, the control electronics (43) further is configured to supply an electrical current flow between the first electrical connection (A) and the second electrical connection (B) to generate resistance heat for controlling temperature of the EWOD device. Control may include sensing a temperature of the EWOD device, and switching between operating in the first or second mode based on the sensed temperature.
B01J 19/00 - Chemical, physical or physico-chemical processes in generalTheir relevant apparatus
G01N 1/00 - SamplingPreparing specimens for investigation
G01N 35/08 - Automatic analysis not limited to methods or materials provided for in any single one of groups Handling materials therefor using a stream of discrete samples flowing along a tube system, e.g. flow injection analysis
A method for managing prefixes of a mobile node (MN) includes receiving a servable prefix and a cost associated with the servable prefix from a first router serving the MN, wherein the servable prefix is one of a plurality of prefixes assigned to the MN that is servable by the first router, deciding whether to release the servable prefix through the first router in accordance with the cost associated with the servable prefix, and releasing the servable prefix when the MN has decided to release the servable prefix.
An active matrix electrowetting on dielectric (AM-EWOD) device includes a plurality of array elements configured to manipulate one or more droplets of fluid on an array, each of the array elements including a corresponding array element circuit. Each array element circuit includes a top substrate electrode and a drive electrode between which the one or more droplets may be positioned, with an insulator layer being interposed between the one or more droplets and the drive electrode; and write circuitry configured to write data to the array element. At least some of the array element circuits include measure circuitry configured to detect a pinhole defect in the insulator layer.
An integrated fluidic device comprising includes an input chamber that provides an input of a sample fluid, and a first overspill chamber in fluid communication with the input chamber. A metering conduit is in fluid communication with the fluid input chamber and the first overspill chamber. The metering conduit meters a first metered volume of fluid from the sample fluid, and the first overspill chamber receives fluid in excess of the first metered volume of fluid. A second overspill chamber is in fluid communication with the metering conduit. The metering conduit meters a second metered volume of fluid from the first metered volume of fluid, and the second overspill chamber receives fluid from the first metered volume of fluid in excess of the second metered volume of fluid. The second overspill chamber has a fluid actuated closable valve for controlling the metering of the second metered volume of fluid.
An integrated microfluidic device for carrying out a series of fluidic operations includes a housing including a plurality of n microfluidic conduits, wherein n is at least three, and a rotating valve having an internal channel with an entrance port and an exit port that are angularly separated. The rotating valve is positionable in a first position to connect two of the n fluidic conduits via the internal channel, and upon rotating the valve to a second position, two other of the n fluidic conduits are connected by the internal channel. The device further may include one or more fluidic chambers in fluid communication with respective fluidic conduits. Fluid contained in one fluidic chamber is transferrable by application of positive or negative gas pressure through associated fluidic conduits into another fluidic chamber via the internal channel. The device may be utilized to perform a variety of fluidic operations.
G01N 33/00 - Investigating or analysing materials by specific methods not covered by groups
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
F16K 99/00 - Subject matter not provided for in other groups of this subclass
G01N 33/49 - Physical analysis of biological material of liquid biological material blood
G01N 33/569 - ImmunoassayBiospecific binding assayMaterials therefor for microorganisms, e.g. protozoa, bacteria, viruses
G01N 15/14 - Optical investigation techniques, e.g. flow cytometry
C07C 231/02 - Preparation of carboxylic acid amides from carboxylic acids or from esters, anhydrides, or halides thereof by reaction with ammonia or amines
79.
AM-EWOD device and method of driving with variable voltage AC driving
An active matrix electrowetting on dielectric (AM-EWOD) device includes a substrate electrode and a plurality of array elements, each array element including an array element electrode. The AM-EWOD device further includes thin film electronics disposed on a substrate. The thin film electronics includes first circuitry configured to supply a first time varying signal V1 to the array element electrodes, and second circuitry configured to supply a second time varying signal V2 to the substrate electrode. An actuation voltage is defined by a potential difference between V2 and V1, and the first circuitry further is configured to adjust the amplitude of V1 to adjust the actuation voltage. V1 may be adjusted to adjust the actuation voltage while V2 remains unchanged. The actuation voltage may be controlled to operate the AM-EWOD device between high and low voltage modes of operation in accordance with different droplet manipulation operations to be performed.
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
G09G 3/34 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source
80.
Efficient dilution method, including washing method for immunoassay
A method of droplet manipulation utilizing a droplet manipulation device includes activating elements of the device to bring a first droplet into proximity of a second droplet, controlling the elements of the device to alter the shape of at least one of the first and second droplets, and further controlling the elements of the device to move at least one of the first or second droplets until the droplets are in contact about an aggregate area. The elements are controlled in a manner so as to control the area of contact and the degree of mixing of the fluid between the first and second droplets. The method may be employed to move particles of a particulate suspension from the first droplet to the second droplet. The droplet manipulation device may be an electrowetting on dielectric (EWOD) device, which includes shaping electrodes activated to shape droplets, and a bridging electrode activated to join the droplets to transfer fluid between the shaped droplets.
An active matrix electrowetting on dielectric (AM-EWOD) device includes a plurality of array elements configured to manipulate one or more droplets of fluid on an array, each of the array elements including a corresponding array element circuit. Each array element circuit includes write circuitry configured to write data to the corresponding array element for controlling the manipulation of the droplets of fluid, and sensor circuitry configured to sense an impedance present at the corresponding array element. The sensor circuitry is configured to operate in one of a normal mode of sensitivity for detection of a droplet, or a high mode of sensitivity to detect an electric property of an array element hydrophobic surface. The sensor circuitry includes an active element, such as an active capacitor or active transistor, and a capacitance across the active element is different in the normal sensitivity mode as compared to the high sensitivity mode.
G01R 27/28 - Measuring attenuation, gain, phase shift, or derived characteristics of electric four-pole networks, i.e. two-port networksMeasuring transient response
B01D 59/46 - Separation by mass spectrography using only electrostatic fields
G06F 3/038 - Control and interface arrangements therefor, e.g. drivers or device-embedded control circuitry
C25B 9/04 - Devices for current supply; Electrode connections; Electric inter-cell connections
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
G02B 26/00 - Optical devices or arrangements for the control of light using movable or deformable optical elements
82.
Active matrix device and method of driving the same
An active matrix electrowetting on dielectric (AM-EWOD) device includes a plurality of array elements configured to manipulate one or more droplets of fluid on an array, each of the array elements including a corresponding array element circuit. Each array element circuit includes a top substrate electrode and a drive electrode between which the one or more droplets may be positioned, with an insulator layer being interposed between the one or more droplets and the drive electrode; and write circuitry configured to write data to the array element. At least some of the array element circuits include measure circuitry configured to detect a pinhole defect in the insulator layer.
An electrowetting on dielectric (EWOD) device which includes a plurality of array elements configured to manipulate one or more droplets of fluid on an array, each of the array elements including a corresponding array element driver circuit, wherein each array element driver circuit includes: a top substrate electrode and a first drive electrode between which the one or more droplets may be positioned, the top substrate electrode being formed on a top substrate, and the first drive electrode being formed on a lower substrate; and circuitry configured to selectively provide drive voltages to the first drive electrode to move the one or more droplets among the plurality of array elements, and wherein at least one of the plurality of array elements includes: a heater element also formed on the lower substrate and configured to heat the one or more droplets when positioned between the top substrate electrode and the first drive electrode of the at least one array element; and circuitry configured to control the heater element.
G02B 1/06 - Optical elements characterised by the material of which they are madeOptical coatings for optical elements made of fluids in transparent cells
An active matrix device is provided which includes N array elements arranged spatially in a sequence of first through Nth array elements (where N is an integer ≧2); the N array elements each including a write input for receiving a corresponding write input signal which controls operation of the array element, and a sense circuit for sensing a property of the array element and providing a sensor output based on the sensed property; and further including a manipulation circuit including logic circuitry connecting the sensor output from an nth array element in the sequence directly to the write input of an (n+1)th array element and configured to provide the write input signal to the write input of the (n+1)th array element based on the sensor output from the nth array element.
G09G 5/00 - Control arrangements or circuits for visual indicators common to cathode-ray tube indicators and other visual indicators
G02F 1/00 - Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulatingNon-linear optics
B01L 3/00 - Containers or dishes for laboratory use, e.g. laboratory glasswareDroppers
G09G 3/36 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source using liquid crystals
G06F 3/044 - Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means by capacitive means
G09G 3/34 - Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix by control of light from an independent source
85.
Active matrix device and method of driving the same
A static random-access memory (SRAM) cell which includes: a sampling switch and a feedback switch; and a first inverter and a second inverter connected in series whereby an output of the first inverter is connected to an input of the second inverter. An input of the first inverter is connected to a data input of the SRAM cell via the sampling switch, and to a data output of the SRAM cell independent of the feedback switch, an output of the second inverter is connected to the input of the first inverter via the feedback switch, and first and second clock inputs of the SRAM cell are configured to control the sampling switch and the feedback switch, respectively.
An active-matrix device is provided which includes a plurality of array element circuits arranged in rows and columns; a plurality of source addressing lines each shared between the array element circuits in corresponding same columns; a plurality of gate addressing lines each shared between the array element circuits in corresponding same rows; a plurality of sensor row select lines each shared between the array element circuits in corresponding same rows, wherein each of the plurality of array element circuits includes: an array element which is controlled by application of a drive voltage by a drive element; writing circuitry for writing the drive voltage to the drive element, the writing circuitry being coupled to a corresponding source addressing line and gate addressing line among the plurality of source addressing lines and gate addressing lines; and sense circuitry for sensing an impedance presented at the drive element, the sense circuitry being coupled to a corresponding sensor row select line; and a row driver and a column driver.
G01R 27/28 - Measuring attenuation, gain, phase shift, or derived characteristics of electric four-pole networks, i.e. two-port networksMeasuring transient response
An array element circuit with an integrated impedance sensor is provided. The array element circuit includes an array element which is controlled by application of a drive voltage by a drive element; writing circuitry for writing the drive voltage to the drive element; and sense circuitry for sensing an impedance presented at the drive element.
B01D 57/02 - Separation, other than separation of solids, not fully covered by a single other group or subclass, e.g. by electrophoresis
89.
Array element for temperature sensor array circuit, temperature sensor array circuit utilizing such array element, and AM-EWOD device including such a temperature sensor array circuit
An array element for a temperature sensor array circuit. The array element includes a switch transistor; and a temperature sensor element having an impedance which varies as a function of temperature, the temperature sensor element being connected in parallel with a source and drain of the switch transistor.
