An apparatus and method for detecting one or more target molecules includes a hydrophobic substrate, and a sensor. The sensor includes two or more electrodes disposed on the hydrophobic substrate and separated from one another by a gap, a plurality of nanostructures formed on or within an upper surface of each electrode, a plurality of binding molecules attached to the plurality of nanostructures, wherein the plurality of binding molecules are configured to bind with the one or more target molecules, and wherein the upper surface of each electrode and the plurality of nanostructures are hydrophilic, and may further detect two or more analytes with two or more sensors that detect two or more different modalities, such as, electrical, optical fluorescence, optical resonance, magnetic detection, or acoustic waves.

Selective amplification of DNA in PCR exponentially increases the signal in molecular diagnostics for nucleic acids, but analogous techniques exist for signal enhancement in clinical tests for proteins or cells. Instead, the signal from affinity-based measurements of these biomolecules depends linearly on probe concentration. Substituting antibody-based probes tagged for fluorescent quantification with lasing detection probes would create a new platform for biomarker quantification based on optical rather than enzymatic amplification. Here, a viral laser is constructed which bridges synthetic biology and laser physics, and demonstrates viral-lasing probes for biosensing. At the transition to lasing, photon flux from the probes increases by five orders of magnitude and narrows spectral linewidth to below 5.0 nm. Viral-lasing probes display an unprecedented >1,000,000% increase in signal from only a 50% increase in probe concentration, using fluorimeter-compatible optics, and can detect biomolecules at clinically-relevant concentrations.

An apparatus and method for detecting one or more target molecules includes a hydrophobic substrate, and a sensor. The sensor includes two or more electrodes disposed on the hydrophobic substrate and separated from one another by a gap, a plurality of nanostructures formed on or within an upper surface of each electrode, a plurality of binding molecules attached to the plurality of nanostructures, wherein the plurality of binding molecules are configured to bind with the one or more target molecules, and wherein the upper surface of each electrode and the plurality of nanostructures are hydrophilic, and may further detect two or more analytes with two or more sensors that detect two or more different modalities, such as, electrical, optical fluorescence, optical resonance, magnetic detection, or acoustic waves.

An apparatus and method for detecting one or more target molecules includes a hydrophobic substrate, and a sensor. The sensor includes two or more electrodes disposed on the hydrophobic substrate and separated from one another by a gap, a plurality of nanostructures formed on or within an upper surface of each electrode, a plurality of binding molecules attached to the plurality of nanostructures, wherein the plurality of binding molecules are configured to bind with the one or more target molecules, and wherein the upper surface of each electrode and the plurality of nanostructures are hydrophilic, and may further detect two or more analytes with two or more sensors that detect two or more different modalities, such as, electrical, optical fluorescence, optical resonance, magnetic detection, or acoustic waves.

An apparatus and method for detecting one or more target molecules includes a hydrophobic substrate, and a sensor. The sensor includes two or more electrodes disposed on the hydrophobic substrate and separated from one another by a gap, a plurality of nanostructures formed on or within an upper surface of each electrode, a plurality of binding molecules attached to the plurality of nanostructures, wherein the plurality of binding molecules are configured to bind with the one or more target molecules, and wherein the upper surface of each electrode and the plurality of nanostructures are hydrophilic, and may further detect two or more analytes with two or more sensors that detect two or more different modalities, such as, electrical, optical fluorescence, optical resonance, magnetic detection, or acoustic waves.

An apparatus and method for detecting one or more target molecules includes a hydrophobic substrate, and a sensor. The sensor includes two or more electrodes disposed on the hydrophobic substrate and separated from one another by a gap, a plurality of nanostructures formed on or within an upper surface of each electrode, a plurality of binding molecules attached to the plurality of nanostructures, wherein the plurality of binding molecules are configured to bind with the one or more target molecules, and wherein the upper surface of each electrode and the plurality of nanostructures are hydrophilic, and may further detect two or more analytes with two or more sensors that detect two or more different modalities, such as, electrical, optical fluorescence, optical resonance, magnetic detection, or acoustic waves.