Target label-free, reagentless electrochemical DNA biosensor based on sub-optimum displacement

Toehold-mediated DNA displacement-based surface-enhanced Raman scattering DNA sensor utilizing an Au-Ag bimetallic nanodendrite substrate

A simple and sensitive surface enhanced Raman scattering (SERS)-based DNA sensor that utilizes the toehold-mediated DNA displacement reaction as a target-capturing scheme has been demonstrated. For a SERS substrate, Au-Ag bimetallic nanodendrites were electrochemically synthesized and used as a sensor platform. The incorporation of both Ag and Au was employed to simultaneously secure high sensitivity and stability of the substrate. An optimal composition of Ag and Au that satisfied these needs was determined. A double-strand composed of 'a probe DNA (pDNA)' complementary to 'a target DNA (tDNA)' and 'an indicator DNA tagged with a Raman reporter (iDNA)' was conjugated on the substrate. The conjugation made the reporter molecule close to the surface and induced generation of the Raman signal. The tDNA released the pre-hybridized iDNA from the pDNA via toehold-mediated displacement, and the displacement of the iDNA resulted in the decrease of Raman intensity. The variation of percent intensity change was sensitive and linear in the concentration range from 200fM to 20nM, and the achieved limit of detection (LOD) was 96.3fM, superior to those reported in previous studies that adopted different signal taggings based on such as fluorescence and electrochemistry.

A new method to fabricate an electrochemical aptasensor to assay adenosine deaminase concentration using an assistance DNA

A novel strategy for the fabrication of electrochemical aptasensor is proposed in this work. This strategy has been employed to develop an aptasensor for the detection of adenosine deaminase concentration. A probe which contains adenosine aptamer and modified with ferrocene is adopted in our strategy as the core element. Moreover, an assistance DNA which can hybridize with the probe was also been employed in our strategy. The enzymatic reaction of adenosine catalyzed by adenosine deaminase plays a key role as well in the regulation of the hybridized complex. The formation of these regions of rigid, duplex DNA prevents the ferrocene tag from approaching the electrode surface, suppressing amperometric currents. The electroactive probe is to reflect the concentration of the enzyme indirectly but accurately. The detection limit is 1 U L(-1), which can be acceptable for clinical applications.

Strategy to fabricate an electrochemical aptasensor: application to the assay of adenosine deaminase activity

A novel strategy for the fabrication of electrochemical aptasensor is proposed in this work, and the strategy has been employed to develop an aptasensor for the assay of adenosine deaminase activity. While a well-designed oligonucleotide containing three functional regions (an adenosine aptamer region, a G-quadruplex halves region, and a linker region) is adopted in our strategy as the core element, the enzymatic reaction of adenosine catalyzed by adenosine deaminase plays a key role as well in the regulation of the binding of the G-quadruplex halves with hemin, the electroactive probe, which is to reflect the activity of the enzyme indirectly but accurately. The detection limit of the fabrication biosensor can be lowered to 0.2 U mL(-1) of adenosine deaminase, and 1 nM of the inhibitor erythro-9-(2-hydroxy-3-nonyl) adenine hydrochloride is enough to present distinguishable electrochemical response. Moreover, since the electroactive probe is not required to be bound with the oligonucleotide, this strategy may integrate the advantages of both the labeled and label-free strategies.

Grading the commercial optical biosensor literature-Class of 2008: 'The Mighty Binders'

Optical biosensor technology continues to be the method of choice for label-free, real-time interaction analysis. But when it comes to improving the quality of the biosensor literature, education should be fundamental. Of the 1413 articles published in 2008, less than 30% would pass the requirements for high-school chemistry. To teach by example, we spotlight 10 papers that illustrate how to implement the technology properly. Then we grade every paper published in 2008 on a scale from A to F and outline what features make a biosensor article fabulous, middling or abysmal. To help improve the quality of published data, we focus on a few experimental, analysis and presentation mistakes that are alarmingly common. With the literature as a guide, we want to ensure that no user is left behind.