Table 1.

Comparison of five types of nanosensors based on different detection method for studying sequence specific DNA-binding interactions.

Detection method	Nanoparticle applied	Advantages	Limitations
Colorimetric	Noble metal nanoparticles	•Easy readout (possible for visual detection) •Equipment free & onsite detection with mobile devices •Cost-effective	oNanoparticles may be unstable in high salt condition oNon-specific adsorption or fouling of nanoparticle surfaces oVisual detection is usually qualitative
Dynamic light scattering (DLS)	Metal nanoparticle	•High sensitivity •Requires less nanoparticles to get scattering signal •Label-free •Fast •High-throughput	oRequires a sophisticated equipment oOnly for detection in solution
Surface enhanced Raman spectroscopy (SERS)	Metal nanostructures	•High sensitivity •Molecular fingerprint specificity •Fast •High-throughput	oUsually requires a sophisticated equipment oRequires a well-engineered SERS substrate for enhanced signal
Fluorescence	Quantum dots; Carbon dots; Metal nanoclusters; Conjugated polymers; AIE dyes	•High sensitivity •Multiplexing using different fluorescent materials with tunable emission colors	oPhotobleaching of fluorescent nanomaterials oUsually requires a fluorimeter
Electrochemical	Metal nanoparticles; Carbon nanomaterials; Conducting polymers	•High sensitivity •Real-time monitoring •Onsite detection with a portable potentiostat	oRequires the use of electroactive indicators oInterference from oxidation at high voltages oNon-specific adsorption of biomolecules to electrode surfaces