Sergio Marín

Direct electrochemical stripping detection of cystic-fibrosis-related DNA linked through cadmium sulfide quantum dots.

Electrochemical detection of a cadmium sulfide quantum dots (CdS QDs)-DNA complex connected to paramagnetic microbeads (MB) was performed without the need for chemical dissolving. The method is based on dropping 20 microl of CdS QD-DNA-MB suspension on the surface of a screen-printed electrode. It is followed by magnetic collection on the surface of the working electrode and electrochemical detection using square-wave voltammetry (SWV), giving a well-shaped and sensitive analytical signal. A cystic-fibrosis-related DNA sequence was sandwiched between the two DNA probes. One DNA probe is linked via biotin-streptavidin bonding with MB and the other one via thiol groups with the CdS QD used as tags. Nonspecific signals of DNA were minimized using a blocking agent and the results obtained were successfully employed in a model DNA sensor with an interest in future applications in the clinical field. The developed nanoparticle biosensing system may offer numerous opportunities in other fields where fast, low cost and efficient detection of small volume samples is required.

Detection of cadmium sulphide nanoparticles by using screen-printed electrodes and a handheld device

A simple method based on screen-printed electrodes and a handheld potentiostatic device is reported for the detection of water soluble CdS quantum dots modified with glutathione. The detection method is based on the stripping of electrochemically reduced cadmium at pH 7.0 by using square wave voltammetry. Various parameters that affect the sensitivity of the method are optimized. QD suspension volumes of 20 microl and a number of around 2 x 10(11) CdS quantum dots have been able to be detected. The proposed method should be of special interest for bioanalytical assays, where CdS quantum dots can be used as electrochemical tracers.

Crystal and electrochemical properties of water dispersed CdS nanocrystals obtained via reverse micelles and arrested precipitation

Different methods of synthesis for the production of electroactive nanocrystals (NCs) for use as labels in DNA sensing systems are presented. They are based on two general ways of controlling the formation and growth of the nanoparticles: (a) physical restriction of the volume available for the growth of the individual nanoparticles by using templates such as reverse micelles; (b) arrested precipitation that depends on exhaustion of one of the reactants. The water dispersed nanocrystals thus obtained are then characterized by optical or electrochemical techniques so as to evaluate the quality of the prepared NCs. A novel direct electrochemical stripping detection protocol that involves the use of a bismuth modified graphite epoxy composite electrode is developed and applied so as to quantify the CdS NCs. The electrochemical study revealed a linear dependency of the stripping current upon the concentration of CdS NCs with a detection limit of around 10(15) CdS NCs cm(-3). The obtained NCs are of great interest for future applications in electrochemical genosensors.

Electrochemical investigation of cellular uptake of quantum dots decorated with a proline-rich cell penetrating peptide.

The use of square wave voltammetry to monitor the cellular uptake, in HeLa cells, of quantum dots (QD) decorated with sweet arrow peptide (SAP) is reported. A SAP derivative containing an additional N-terminal cysteine residue (C-SAP) was synthesized using the solid-phase method and conjugated to QDs. The obtained results show that QDs-SAP either interact with the extracellular cell membrane matrix or translocate the bilayer. The first situation, membrane adsorption, is probably a transient state before cellular uptake. Both confocal microscopy and SWV results support the detection of this cellular internalization process. The developed electrochemical investigation technique can provide valuable insights into the study of peptide-mediated delivery, as well as the design and development of nanoparticle probes for intracellular imaging, diagnostic, and therapeutic applications. In addition, the described electrochemical interrogation is low cost, is easy to use, and offers future interest for diagnostics including cell analysis.

Nanomaterial based electrochemical transducing platforms for biomedical applications

Recent advances of our research in the development of novel nanomaterial based electrochemical transducing platforms for biomedical applications are outlined. The objective has been to design platforms with interest for future applications in low cost, user-friendly and efficient electrochemical based sensors and biosensors that can be used even by non professional people for fast diagnostic at home or doctor’s office as well as other applications where either an emergency exists or an alternative method toward the sophisticated and expensive laboratory instrumentation is being required.