A Fano resonator device can be used to sequence DNA or other macromolecules. The device includes customized molecular components, informed by computation analysis. Techniques for preparing and using the device also are disclosed. The device can be incorporated in a system that further includes a sample processing component and a flow chamber.

A Fano resonator device can be used to sequence DNA or other macromolecules. The device includes customized molecular components, informed by computation analysis. Techniques for preparing and using the device also are disclosed. The device can be incorporated in a system that further includes a sample processing component and a flow chamber.

An analyzing apparatus for molecules is provided. A pore device includes a cation selective nanopore, and a first chamber and a second chamber which are separated by the cation selective nanopore. In an initial state, the first chamber includes molecules to be analyzed, and the second chamber has higher salt concentration than the first chamber. A current sensor measures an ionic current flowing through a first electrode and a second electrode provided in the first chamber and the second chamber.

The present disclosure features an apparatus for identifying molecules, the apparatus including chambers configured to receive a conducting media; a membrane including a pore separating the chambers, a first set of electrodes in the chambers, a first current detector measuring an electrical signal between the first set of electrodes, a second set of electrodes electrically contacting the membrane, a second current detector configured measuring an electrical signal between the second set of electrodes, a plasmonic feature adjacent to the pore of the membrane, a light source configured to emit light onto the plasmonic feature, a light collector to collect the light scattered from the plasmonic feature, and a computing device configured to identify at least one attribute of a molecule that passes through the pore of the membrane.

The present disclosure features an apparatus for identifying molecules, the apparatus including chambers configured to receive a conducting media; a membrane including a pore separating the chambers, a first set of electrodes in the chambers, a first current detector measuring an electrical signal between the first set of electrodes, a second set of electrodes electrically contacting the membrane, a second current detector configured measuring an electrical signal between the second set of electrodes, a plasmonic feature adjacent to the pore of the membrane, a light source configured to emit light onto the plasmonic feature, a light collector to collect the light scattered from the plasmonic feature, and a computing device configured to identify at least one attribute of a molecule that passes through the pore of the membrane.

A method and system to decode information stored on a polymer sequence, such as a DNA strand, is described herein. The method and system use molecular probes to label sections of the polymer sequence. Each molecular probe includes a fluorophore and a quencher. The fluorophore produces light with a color and wavelength corresponding to the information stored on the section of the polymer sequence the molecular probe labels. The quencher inhibits the production of light by an adjacent fluorophore. When adjacent sections of the polymer sequence are labeled with molecular probes, the fluorophore of the leading molecular probe produces light while the trailing molecular probe's light is quenched. The method and system then sequentially unbind the molecular probes from the sections of the polymer sequence within a waveguide, producing a sequence of observable fluorescence signals. The sequence can be used to determine the information stored on a polymer sequence.

A method and system to decode information stored on a polymer sequence, such as a DNA strand, is described herein. The method and system use molecular probes to label sections of the polymer sequence. Each molecular probe includes a fluorophore and a quencher. The fluorophore produces light with a color and wavelength corresponding to the information stored on the section of the polymer sequence the molecular probe labels. The quencher inhibits the production of light by an adjacent fluorophore. When adjacent sections of the polymer sequence are labeled with molecular probes, the fluorophore of the leading molecular probe produces light while the trailing molecular probe's light is quenched. The method and system then sequentially unbind the molecular probes from the sections of the polymer sequence within a waveguide, producing a sequence of observable fluorescence signals. The sequence can be used to determine the information stored on a polymer sequence.

A rotor assembly includes a rotor plate to rotate around a first axis, a bucket attached to the rotor plate and to rotate around a second axis, and a stop plate to rotate around the first axis between an open position and a closed position. When in the closed position, the stop plate engages the bucket to fix an angular position of the bucket relative to a plane of rotation of the rotor assembly. The rotor assembly further includes a housing for a sensor array component, the housing disposed in the bucket and including a solution inlet, a solution outlet, a transfer basin, a solution retainer disposed between the solution outlet and the transfer basin, and a collection reservoir in fluid communication with the transfer basin. The solution inlet and the solution outlet to engage ports of a flow cell of a sensor array.

A rotor assembly includes a rotor plate to rotate around a first axis, a bucket attached to the rotor plate and to rotate around a second axis, and a stop plate to rotate around the first axis between an open position and a closed position. When in the closed position, the stop plate engages the bucket to fix an angular position of the bucket relative to a plane of rotation of the rotor assembly. The rotor assembly further includes a housing for a sensor array component, the housing disposed in the bucket and including a solution inlet, a solution outlet, a transfer basin, a solution retainer disposed between the solution outlet and the transfer basin, and a collection reservoir in fluid communication with the transfer basin. The solution inlet and the solution outlet to engage ports of a flow cell of a sensor array.

An example method includes introducing a first fluid to a flow channel of a flow cell including a working electrode having a surface that is at least partially exposed to the flow channel, the surface being unmodified or modified with a first member of a transition metal complex binding pair, whereby a linking moiety of a complex present in the first fluid chemically attaches the complex to the surface to form a temporarily modified surface of the working electrode; performing a sensing operation involving the complex of the temporarily modified surface; and applying a desorption voltage of the linking moiety to the working electrode, thereby detaching the linking moiety and regenerating the surface.