A structured substrate includes a substrate body having an active side. The substrate body includes reaction cavities that open along the active side and interstitial regions that separate the reaction cavities. The structured substrate includes an ensemble amplifier positioned within each of the reaction cavities. The ensemble amplifier includes a plurality of nanostructures configured to at least one of amplify electromagnetic energy that propagates into the corresponding reaction cavity or amplify electromagnetic energy that is generated within the corresponding reaction cavity.

A structured substrate includes a substrate body having an active side. The substrate body includes reaction cavities that open along the active side and interstitial regions that separate the reaction cavities. The structured substrate includes an ensemble amplifier positioned within each of the reaction cavities. The ensemble amplifier includes a plurality of nanostructures configured to at least one of amplify electromagnetic energy that propagates into the corresponding reaction cavity or amplify electromagnetic energy that is generated within the corresponding reaction cavity.

An analyte [25] in a matrix is sensed using a sensing device having a detection probe [21] conjugated to a mediator-receptor [22] that is not a binder for the analyte. The sensor device is provided with mediators [23] conjugated to analyte-receptors [24], where the mediators are selected to bind to the mediator-receptors, and where the analyte-receptors are selected to bind to the analyte. In some embodiments, the mediators are bound to the detection probe by a tether molecule, or tether molecule fragment, or tether domain. In other embodiments, the mediators are not bound to the detection probe. The presence of the analyte is detected by optically or electrically detecting changes of distance between the mediators and the mediator-receptor, indicative of association and/or dissociation events between mediators and mediator-receptor, the characteristics of which are affected by whether the analyte is bound to the analyte-receptor.

An analyte [25] in a matrix is sensed using a sensing device having a detection probe [21] conjugated to a mediator-receptor [22] that is not a binder for the analyte. The sensor device is provided with mediators [23] conjugated to analyte-receptors [24], where the mediators are selected to bind to the mediator-receptors, and where the analyte-receptors are selected to bind to the analyte. In some embodiments, the mediators are bound to the detection probe by a tether molecule, or tether molecule fragment, or tether domain. In other embodiments, the mediators are not bound to the detection probe. The presence of the analyte is detected by optically or electrically detecting changes of distance between the mediators and the mediator-receptor, indicative of association and/or dissociation events between mediators and mediator-receptor, the characteristics of which are affected by whether the analyte is bound to the analyte-receptor.

The present invention provides novel microfluidic substrates and methods that are useful for performing biological, chemical and diagnostic assays. The substrates can include a plurality of electrically addressable, channel bearing fluidic modules integrally arranged such that a continuous channel is provided for flow of immiscible fluids.

Biosensors and methods for localized surface plasmon resonance biosensing are disclosed. The biosensor can include a substrate having a substrate surface to which a plurality of localized surface plasmon resonance (LSPR) antennae are affixed. The LSPR antennae can be affixed via an affixation surface of the LSPR antenna. The LSPR antennae can have a functional surface opposite the affixation surface. Each functional surface can be functionalized by a plurality of single-stranded DNA.

Biosensors and methods for localized surface plasmon resonance biosensing are disclosed. The biosensor can include a substrate having a substrate surface to which a plurality of localized surface plasmon resonance (LSPR) antennae are affixed. The LSPR antennae can be affixed via an affixation surface of the LSPR antenna. The LSPR antennae can have a functional surface opposite the affixation surface. Each functional surface can be functionalized by a plurality of single-stranded DNA.

A target analyte in a matrix is sensed using a sensor device having protrusions [500] such as e.g. nanorods, containing free charge carriers. Conformational molecules [504, 506] are bound at a first end to the protrusions, and bound at a second end to a label [502] e.g. a nanoparticle, that is free to move relative to the protrusions. The conformational molecule changes its conformation when bound to the analyte, thereby changing the distance and/or the relative orientation of the label to the protrusion. Energy [510] is used to excite free electrons in the protrusion near a plasmon resonance and resulting optical radiation [514] at wavelengths near the plasmon resonance wavelength is detected [516] and analyzed [518] to determined the presence/concentration of the analyte.

A target analyte in a matrix is sensed using a sensor device having protrusions [500] such as e.g. nanorods, containing free charge carriers. Conformational molecules [504, 506] are bound at a first end to the protrusions, and bound at a second end to a label [502] e.g. a nanoparticle, that is free to move relative to the protrusions. The conformational molecule changes its conformation when bound to the analyte, thereby changing the distance and/or the relative orientation of the label to the protrusion. Energy [510] is used to excite free electrons in the protrusion near a plasmon resonance and resulting optical radiation [514] at wavelengths near the plasmon resonance wavelength is detected [516] and analyzed [518] to determined the presence/concentration of the analyte.

A microstructured chip (3; 33; 43; 53; 63) for surface plasmon resonance (SPR) analysis, taking the form of a solid formed by: a base (5; 77); an upper surface (4; 44), at least part of which is covered with a metal layer (2; 22; 42; 52; 62); and at least one side surface (55; 66). The chip is characterized in that the aforementioned upper surface is provided with micrometric zones intended to receive species to be analyzed and selected from among n protrusions and m cavities, and in that when n+m≧2 the zones are separated from one another by planar surfaces, with n varying between 1 and j, m varying between 0 and i, and j and i being integers.