Aptamer-based electrochemical biosensor for <Emphasis Type="Italic">Botulinum</Emphasis> neurotoxin

We have developed an aptamer-based electrochemical sensor for detection of Botulinum neurotoxin, where steric hindrance is applied to achieve specific signal amplification via conformational change of the aptamer. The incubation time and potassium concentration of the reaction buffer were found to be key parameters affecting the sensitivity of detection of the recognition of Botulinum neurotoxin by the aptamer. Under optimized experimental conditions, a high signal-to-noise ratio was obtained within 24 h with a limit of detection (LOD) of 40 pg/ml by two standard deviation cutoffs above the noise level.     

Paper‐Based Electrochemiluminescent 3D Immunodevice for Lab‐on‐Paper,Specific, and Sensitive Point‐of‐Care Testing

Recent research on microfluidic paper‐based analytical devices (μPADs) has shown that paper has great potential for the fabrication of low‐cost diagnostic devices for healthcare and environmental monitoring applications. Herein, electrochemiluminescence (ECL) was introduced for the first time into μPADs that were based on screen‐printed paper‐electrodes. To further perform high‐specificity, high‐performance, and high‐sensitivity ECL on μPADs for point‐of‐care testing (POCT), ECL immunoassay capabilities were introduced into a wax‐patterned 3D paper‐based ECL device, which was characterized by SEM, contact‐angle measurement, and electrochemical impedance spectroscopy. With the aid of a home‐made device‐holder, the ECL reaction was triggered at room temperature. By using a typical tris(bipyridine)ruthenium–tri‐n‐propylamine ECL system, this paper‐based ECL 3D immunodevice was applied to the diagnosis of carcinoembryonic antigens in real clinical serum samples. This contribution further expands the number of sensitive and specific detection modes of μPADs.     

Current chemical biology tools for studying protein phosphorylation and dephosphorylation

Amongst different posttranslational events involved in cellular-signaling pathways, phosphorylation and dephosphorylation of proteins are the most prevalent. Aberrant regulations in the cellular phosphoproteome network are implicated in most major human diseases. Consequently, kinases and phosphatases are two of the most important groups of drug targets in medicinal research today. A major challenge in the understanding of protein phosphorylation and dephosphorylation is the sheer complexity of the phosphoproteome network and the lack of tools capable of studying protein phosphorylation and dephosphorylation as they occur in cells. We highlight herein various chemical biology tools that have emerged in the last decade for such studies. First, we discuss the use of small-molecule mimics of phosphoamino acids and their use in elucidating the function of protein phosphorylation and dephosphorylation. We also introduce recent advances in the field of activity-based protein profiling (ABPP) for proteome-wide detection of protein phosphorylation and dephosphorylation. We next discuss the key concepts in the design of peptide- and protein-based biosensors capable of real-time reporting of phosphorylation/dephosphorylation events. Finally, we highlight the application of peptide and small-molecule microarrays (SMMs), and their applications in high-throughput screening and discovery of new compounds related to phosphorylation/dephosphorylation.     

Sensitive Detection of Small Molecule–Protein Interactions on a Metal–Insulator–Metal Label‐Free Biosensing Platform

The need to develop label‐free biosensing devices that enable rapid analyses of interactions between small molecules/peptides and proteins for post‐genomic studies has increased significantly. We report a simple metal–insulator–metal (MIM) geometry for fabricating a highly sensitive detection platform for biosensing. MIM substrates consisting of an Au–PMMA–Ag nanolayer were extensively studied using both theoretical and experimental approaches. By monitoring reflectivity changes at the normal incidence angle, we observed molecular interactions as the thickness of the biolayer increased on the substrate surface. These interactions included the adsorption of various proteins (Mw=6–150 kD) and interactions between small molecules (Mw≤2 kD) and the immobilized proteins. The interaction of designed monosaccharide‐modified designed peptides with various lectins was also clearly detected. These interactions could not be detected by the conventional Au‐only substrate. Thus, the MIM approach affords a powerful label‐free biosensing device that will aid our understanding of protein interactions and recognition.     

Tuning the Electrical and Optical Properties of Diketopyrrolopyrrole Complexes for Panchromatic Dye‐Sensitized Solar Cells

A series of metal‐free organic dyes that were bridged by a diketopyrrolopyrrole moiety and were composed of indoline and triphenylamine as donor groups and furan and benzene as conjugated spacer groups were designed and synthesized for use in dye‐sensitized solar cells (DSCs). The photophysical properties, electrochemical properties, and performance of the DSCs were related to the structure of their corresponding dyes. Their absorption spectra broadened upon the introduction of the indoline and heterocyclic furan moieties through fine‐tuning of their molecular configuration. The overall conversion efficiencies of DSCs that were based on these dyes ranged from 5.14–6.53 %. Among the four dyes that were tested, indoline‐based ID01 and ID02 showed higher efficiencies (6.35 % and 6.53 %) as a result of their improved light‐harvesting efficiency and larger electron driving force. The ID01 dye, which contained an indoline moiety as an electron donor and a furan group as a π‐conjugated linker, showed an excellent monochromatic incident‐photon‐to‐current‐conversion efficiency (IPCE) spectrum (350–650 nm) with a maximum value of 78 % in the high plateau region and an onset value close to 800 nm. Intensity‐modulated photovoltage spectroscopy (IMVS) and impedance spectroscopy (IS) revealed that dyes that contained benzene conjugation spacers suppressed the charge‐recombination rate more efficiently than dyes that contained furan spacers, thereby resulting in improved photovoltage.     

Fabrication of a Retinal‐protein Photoreceptor Array

A pixel‐architecture film of retinal proteins was prepared by an approach combining chemical, physical and biological technologies. Oriented multilayers of purple membrane composed of bacteriorhodopsin (BR) and lipids were patterned on an array of gold electrode pixels. In order to improve stability and resolution, the gene engineering technique was employed to make a mutant of the protein BR by replacing the 36^th amino acid residue from aspartic acid to cysteine with a thiol end group ready to react with gold; electric sedimentation was used to guarantee the high probability of formation of the Au‐S bond and meanwhile to orient BR; further chemical crosslinking was introduced among layers of purple membranes to significantly enhance photoelectrical signals while keeping high stability. The non‐bound BR region was eventually washed out by detergent, and the remaining BR pixels were thus detergent resistant due to chemical crosslinking among BR layers and covalent binding between the multilayer and the substrate. The protein array was confirmed to keep photoelectrical activity.     

A self-powered "sense-act-treat" system that is based on a biofuel cell and controlled by boolean logic

Bio-logic-al: an autonomous, integrated "sense-act-treat" system that is based on an enzymatic biofuel cell has been developed. The system couples a biocomputing logic-detection method with a drug-release system to provide a logic-activated therapeutic intervention in response to a simulated abnormal physiological state, without the need for an external power source, control electronics, or microelectromechanical actuators.     

Aptamer-based origami paper analytical device for electrochemical detection of adenosine

Paper biosensors: an origami sensor is printed on a single piece of paper, folded into a three-dimensional fluidic device, and encapsulated by thermal lamination. Aptamer is trapped in the fluidic channel, where it binds to the target and releases an enzyme to generate a signal. The device is read out using a digital multimeter.     

Hydrogen Peroxide Induced Activation of Gene Expression in Mammalian Cells using Boronate Estrone Derivatives

Keeping the boron out of the ER: A genetic switch was engineered that activates gene expression in the presence of H(2) O(2) . The use of a boronate group on an estrone molecule allows for activation of gene expression through binding of the estrogen receptor only when the boron group is oxidized by H(2) O(2) . This sensor is highly sensitive and specific for H(2) O(2) .