A layered nanocomposite of laccase, chitosan, and Fe3O4 nanoparticles-reduced graphene oxide for the nanomolar electrochemical detection of bisphenol A.

A hybrid conjugate of reduced graphene oxide/ferrous-ferric oxide nanoparticles (rGO-Fe3O4 NPs) is characterized and assembled with chitosan and laccase to form a layered functional superstructure. After its characterization by field-effect scanning electron microscopy, energy-dispersive X-ray analysis, X-ray photoelectron spectroscopy, attenuated total reflectance Fourier transform infrared, cyclic voltammetry (CV), and electrochemical impedance spectroscopy (EIS), the nanocomposite has been deposited on glassy carbon for the enzyme-mediated electrochemical determination of the endocrine disruptor bisphenol A (BPA). Proof-of-concept assays conducted by using CV, EIS, and square wave voltammetry reveal that the enzymatic biosensor provides linear response in a wide range of BPA concentrations (6-228 ppb), very high sensitivities, and excellent durability (over 1-month storage). Using amperometric detection, remarkable sensitivities (2080 µA µM-1 cm-2) and detection limits (18 nM) are attained. Applications to real samples of bottled water proved feasible with recoveries in the range 107-124%. Graphical abstract Reduced graphene oxide conjugated with magnetite nanoparticles (rGO-Fe3O4) was assembled with laccase (wine-colored dots) and chitosan for the electrochemical determination of bisphenol A. The enzymatic biosensor exhibited excellent linearity (6-228 ppb) and stability. Best sensitivity (2080 µA µM-1 cm-2, detection limit 18 nM) was obtained by amperometry.

Edible Chitosan Films and Their Nanosized Counterparts Exhibit Antimicrobial Activity and Enhanced Mechanical and Barrier Properties.

Chitosan and chitosan-nanoparticles were combined to prepare biobased and unplasticized film blends displaying antimicrobial activity. Nanosized chitosans obtained by sonication for 5, 15, or 30 min were combined with chitosan at 3:7, 1:1, and 7:3 ratios, in order to adjust blend film mechanical properties and permeability. The incorporation of nanosized chitosans led to improvements in the interfacial interaction with chitosan microfibers, positively affecting film mechanical strength and stiffness, evidenced by scanning electron microscopy. Nanosized or blend chitosan film sensitivity to moisture was significantly decreased with the drop in biocomposite molecular masses, evidenced by increased water solubility and decreased water vapor permeability. Nanosized and chitosan interactions gave rise to light biobased films presenting discrete opacity and color changes, since red-green and yellow-blue colorations were affected. All chitosan blend films exhibited antimicrobial activity against both Gram-positive and Gram-negative bacteria. The performance of green unplasticized chitosan blend films displaying diverse morphologies has, thus, been proven as a potential step towards the design of nontoxic food packaging biobased films, protecting against spoilage microorganisms, while also minimizing environmental impacts.

Reduced graphene oxide-nickel nanoparticles/biopolymer composite films for the sub-millimolar detection of glucose.

Hybrid conjugates of graphene with metallic/semiconducting nanostructures can improve the sensitivity of electrochemical sensors due to their combination of well-balanced electrical/electrocatalytic properties and superior surface-to-volume ratio. In this study, the synthesis and physical characterization of a hybrid conjugate of reduced graphene oxide and nickel nanoparticles (rGO-Ni NPs) is presented. The conjugate was further deposited onto a glassy carbon electrode as a nanocomposite film of chitosan and glucose oxidase. The electrochemical response and morphology of the films were investigated using SEM, CV, and EIS, and their applications as a glucose biosensor explored for the first time in proof-of-concept tests. The low operating potential along with the good linearity and sensitivity (up to 129 µA cm(-2) mM(-1)) found in the sub-millimolar range suggest potential applications in the self-management of hypoglycemia from blood samples or in the development of non-invasive assays for body fluids such as saliva, tears or breath.

Probing the contribution of different intermolecular forces to the adsorption of spheroproteins onto hydrophilic surfaces.

Protein adsorption is a delicate process, which results from the balance between the properties of proteins and their solid supports. Although the relevance of some of these parameters has been already unveiled, the precise involvement of electrostatics and other weaker intermolecular forces requires further comprehension. Aiming to contribute to this task, this work explores the attachment, rearrangement, and surface aggregation of a model spheroprotein, such as bovine ß-lactoglobulin (ß-LG), onto hydrophilic substrates prefunctionalized with different alkylthiol films. Thereby, a variety of electrostatic scenarios for the adsorption of ß-LG could be recreated through the variation of the pH and the functional chemistry of the surfaces. The changes in surface mass density (plus associated water) and film flexibility were followed in situ with quartz crystal microbalance with dissipation monitoring. Film packing and aggregation were assessed by faradaic electrochemical measurements and ex situ atomic force microscopy and field effect scanning electron microscopy. In contrast to previous hypotheses arguing that electrostatic interactions between charged substrates and proteins would be the only driving force, a complex interplay between Coulombic and non-Coulombic intermolecular forces (which would depend upon the experimental conditions) has been suggested to explain the results.

Chitosan biopolymer-F(ab')2 immunoconjugate films for enhanced antigen recognition.

The limited stability and random orientation of antibodies passively adsorbed onto solid supports are some of the main factors limiting the analytical performance of immune-based assay systems. Although the use of specific antibody-binding proteins led to significant enhancements in sensitivity, several uncertainties related to the orientation of these layers and the stability of the complexes formed with the antibodies need to be addressed for further progress. This paper introduces an alternative strategy based on the use of a charged polysaccharide layer for the stabilized and oriented assembly of antibody fragments. About one monolayer of F(ab')2 fragments of anti-human immunoglobulin G was passively adsorbed onto mercaptopropionic acid (MPA) and MPA/chitosan modified Au surfaces showing very good conformational stability. However, interrogation tests in the presence of human immunoglobulin G showed a piezoelectrical antibody binding signal about two times higher when the fragments were adsorbed onto chitosan. Given the similar coverage and conformational stability found in both cases and considering the different electrostatic scenarios, it is strongly suggested that the enhanced recognition of antigens may arise from the assembly of F(ab')2 mostly oriented in a hinge down end-on phase. Supporting this view, a limit of detection of about 3 µg mL-1 was obtained from electrochemical methods. Although high, this is one of the best results reported (to the best of our knowledge) in proof-of-concept experiments using 2D electrically insulating immobilization layers with such a limited antibody loading capacity.

A solid-state CdSe quantum dot sensitized solar cell based on a quaterthiophene as a hole transporting material.

A hybrid quantum dot sensitized solar cell (QDSC) composed of CdSe quantum dots (QDs) as light harvesters and TiO(2) and 3,3'''-didodecyl-quaterthiophene (QT12) as electron and hole conductors, respectively, has been fully processed in air. The sensitizer has been introduced into the TiO(2) nanoporous layer either by the successive ionic layer adsorption and reaction method or by attaching colloidal QDs either directly or through molecular cables (linkers). As previously observed for QDSCs based on liquid electrolytes, the efficiency depends on the way of QD attachment, the direct adsorption of QDs being the procedure yielding the best results. Thermal annealing was applied in order to enhance the device response under illumination. Remarkable open circuit potentials are attained (close to 1 V), leading to an efficiency of 0.34% (AM 1.5G) in initial tests. Although low, it ranks as one of the highest values reported for solid state QDSCs based on titanium dioxide and colloidal quantum dots.

Uncovering the role of the ZnS treatment in the performance of quantum dot sensitized solar cells.

Among the third-generation photovoltaic devices, much attention is being paid to the so-called Quantum Dot sensitized Solar Cells (QDSCs). The currently poor performance of QDSCs seems to be efficiently patched by the ZnS treatment, increasing the output parameters of the devices, albeit its function remains rather unclear. Here new insights into the role of the ZnS layer on the QDSC performance are provided, revealing simultaneously the most active recombination pathways. Optical and AFM characterization confirms that the ZnS deposit covers, at least partially, both the TiO(2) nanoparticles and the QDs (CdSe). Photoanodes submitted to the ZnS treatment before and/or after the introduction of colloidal CdSe QDs were studied by electrochemical impedance spectroscopy, cyclic voltammetry and photocurrent experiments. The corresponding results prove that the passivation of the CdSe QDs rather than the blockage of the TiO(2) surface is the main factor leading to the efficiency improvement. In addition, a study of the ultrafast carrier dynamics by means of the Lens-Free Heterodyne Detection Transient Grating technique indicates that the ZnS shell also increases the rate of electron transfer. The dual role of the ZnS layer should be kept in mind in the quest for new modifiers for enhancing the performance of QDSCs.

Solid-state electropolymerization and doping of triphenylamine as a route for electroactive thin films.

Solid-state electropolymerization could be a way to produce organic semiconductors with potential application as Hole Transporting Materials (HTMs) in hybrid organic-inorganic devices. Thereby, thin solid films of triphenylamine (TPA) deposited by spin coating on conducting glass substrates have been electrochemically treated by performing multiple voltammetric cycles between -0.4 V and 1.0 V vs. Ag/AgCl in a 0.5 M sodium perchlorate aqueous electrolyte. Subsequent characterization by means of in situ UV-Vis spectroscopy, in situ Electrochemical Quartz Crystal Microbalance, Atomic Force Microscopy, Contact Angle analysis, and Open Circuit Potential measurements reveals cross-linking of the monomeric units in the thin film. Such polymerized films are characterized by a high electroactivity linked to doping/undoping, a reversible electrochromic behavior under potentiodynamic conditions and fast changes of the open circuit potential upon illumination, indicating efficient charge transport throughout the film. While extensive polymerization has been demonstrated for TPA, this process is negligible in the case of tri-p-tolylamine, which is linked to the para substitution of the phenyl rings. In more general vein, the feasibility of solid-state electropolymerization is illustrated as well as the potential advantages of this methodology for the preparation of hybrid inorganic/organic materials based on nanoporous oxide matrices.