Color-encoded microcarriers based on nano-silicon dioxide film for multiplexed immunoassays

Multiplexed analysis allows researchers to obtain high-density information with minimal assay time, sample volume and cost. Currently, microcarrier or particle-based approaches for multiplexed analysis involve complicated or expensive encoding and decoding processes. In this paper, a novel optical encoding technique based on nano-silicon dioxide film is presented. Microcarriers composed of thermally grown silicon dioxide (SiO(2)) film and monocrystalline silicon (Si) substrate were fabricated. The nano-silicon dioxide film exhibited unique surface color by low-coherence interference. Hence the colors can be used for encoding at least 100 microcarriers loaded with films of different thickness. We demonstrated that color-encoded microcarriers loaded with antigens could be used for multiplexed immunoassays to detect goat anti-human IgG, goat anti-mouse IgG and goat anti-rabbit IgG, with fluorescent detection as the interrogating approach. This microcarrier-based method also exhibited improved analytical performance compared with a microarray technique. This approach will provide new opportunities for multiplexed target assay development.     

Microfluidic device for immunoassays based on surface plasmon resonance imaging

We have designed and fabricated a polydimethylsiloxane (PDMS) microfluidic device containing an array of gold spots onto which antigens or antibodies of interest can be attached. We use surface plasmon resonance (SPR) imaging to monitor the antibody-antigen recognition and binding events. This combination offers two significant advantages: (1) the microfluidic device dramatically reduces reaction time and sample consumption; and (2) the SPR imaging yields real-time detection of the immunocomplex formation. Thus, an immunoreaction may be detected and quantitatively characterized in about 10 min. The sensitivity of this method is at the subnanomolar level. When gold nanoparticles are selectively coupled to the immunocomplex to cause signal amplification, the sensitivity reaches the ten to one hundred picomolar level but the time required increases to about 60 min.     

Versatile self-complexing compounds based on covalently linked donor-acceptor cyclophanes

A range of covalently linked donor-acceptor compounds which contain 1) a hydroquinone (HQ) unit, 2) a 1,5-dioxynaphthalene (DNP) ring system, or 3) a tetrathiafulvalene (TTF) unit as the pi-donor, and 4) cyclobis(paraquat-p-phenylene) (CBPQT(4+)) as the pi-accepting tetracationic cyclophane were prepared and shown to operate as simple molecular machines. The pi-donating arms can be included inside the cyclophane in an intramolecular fashion by virtue of stabilizing noncovalent bonding interactions. What amounts to self-complexing/decomplexing equilibria were shown to be highly temperature dependent when the pi-donating arm contains either an HQ or DNP moiety. The thermodynamic parameters associated with the equilibria have been unraveled by using variable-temperature (1)H NMR spectroscopy. The negative DeltaH degrees and DeltaS degrees values account for the fact that the "uncomplexed" conformation becomes the dominant species, since the entropy gain associated with the decomplexation process overcomes the enthalpy loss resulting from the breaking of the donor-acceptor interactions. The arm's in-and-out movements with respect to the linked cyclophanes can be arrested by installing a bulky substituent at the end of the arm. In the case of compounds carrying a DNP ring system in their side arm, two diastereoisomeric, self-complexing conformations are observed below 272 K in hexadeuterioacetone. By contrast, control over the TTF-containing arm's movement is more or less ineffective through the thermally sensitive equilibrium although it can be realized by chemical and electrochemical ways as a result of TTF's excellent redox properties. Such self-complexing compounds could find applications as thermo- and electroswitches. In addition, the thermochromism associated with the arm's movement could lead to some of the compounds finding uses as imaging and sensing materials.     

Versatile logic devices based on programmable DNA-regulated silver-nanocluster signal transducers

A DNA-encoding strategy is reported for the programmable regulation of the fluorescence properties of silver nanoclusters (AgNCs). By taking advantage of the DNA-encoding strategy, aqueous AgNCs were used as signal transducers to convert DNA inputs into fluorescence outputs for the construction of various DNA-based logic gates (AND, OR, INHIBIT, XOR, NOR, XNOR, NAND, and a sequential logic gate). Moreover, a biomolecular keypad that was capable of constructing crossword puzzles was also fabricated. These AgNC-based logic systems showed several advantages, including a simple transducer-introduction strategy, universal design, and biocompatible operation. In addition, this proof of concept opens the door to a new generation of signal transducer materials and provides a general route to versatile biomolecular logic devices for practical applications.     

Sensitivity of microarray based immunoassays using surface-attached hydrogels

A promising pathway to improve on the sensitivity of protein microarrays is to immobilize the capture antibodies in a three dimensional hydrogel matrix. We describe a simple method based on printing of an aqueous protein solution containing a photosensitive polymer and the capture antibody onto a plastic chip surface. During short UV-exposure photocrosslinking occurs, which leads to formation of a hydrogel, which is simultaneously bound to the substrate surface. In the same reaction the antibody becomes covalently attached to the forming hydrogel. As the capture antibodies are immobilized in the three-dimensional hydrogel microstructures, high fluorescence intensities can be obtained. The chip system is designed such, that non-specific protein adsorption is strongly prevented. Thus, the background fluorescence is strongly reduced and very high signal-to-background ratios are obtained (SBR > 6 for c_BSA = 1 pM; SBR > 100 for c_BSA > 100 pM). The kinetics of antigen binding to the arrayed antibodies can be used to determine the concentration of a specific protein (for example the tumor marker β₂-microglobulin) in solution for a broad range of analyte concentrations. By varying size and composition of the protein-filled hydrogel microstructures as well as adjusting the extent of labeling it is possible to easily adapt the surface concentration of the probe molecules such that the fluorescence signal intensity is tuned to the prevalence of the protein in the analyte. As a consequence, the signal tuning allows to analyze solutions, which contain both proteins with high (here: upper mg mL⁻¹ range) and with very low concentrations (here: lower μg mL⁻¹ range). This way quantitative analysis with an exceptionally large dynamic range can be performed.     

Multiple homogeneous immunoassays based on a quantum dots-gold nanorods FRET nanoplatform

Multi-sized quantum dots (QDs) donors and tailor-made gold nanorods (GNRs) are employed to form a FRET nanoplatform for homogeneous immunoassays developed for analysis of multiple virus antigens. The single GNRs/multiple QDs nanocomposite based nanosensor offers a simple and sensitive approach for multiple analytes detection in a homogeneous format.     

Multiplex immunoassays of equine virus based on fluorescent encoded magnetic composite nanoparticles

A new detection format for multiplexed analysis based on fluorescent encoded magnetic composite nanoparticles is presented. Two kinds of virus were analyzed by this new method: equine influenza virus (EIV) and equine infectious anemia virus (EIAV). Firstly, EIV antigen and EIAV antigen were conjugated to two kinds of fluorescent encoded magnetic composite nanoparticles, while the green-emitting CdTe quantum dots (QDs) were attached to the antibody of EIV and EIAV. Then both green-emitting CdTe QD-labeled antibodies and antigens labeled with fluorescent encoded magnetic composite nanoparticles were used to form an immunoassay system for the detection of EIV and EIAV antigens. The method is time-saving and has higher sensitivity (1.3 ng mL⁻¹ for EIV antigens and 1.2 ng mL⁻¹ for EIAV antigens) than the conventional methods. A competitive immunoassay method based on this analysis system was used to detect EIV and EIAV antigens in spiked serum samples with satisfactory results.     

Versatile assembly of 5-aminothiazoles based on the Ugi four-component coupling

A flexible route to novel 5-aminothiazoles has been developed based on cyclisation of diamide adducts, prepared using the Ugi reaction, in the presence of Lawesson’s reagent. The Walborsky reagent (1,1,3,3-tetramethylbutyl isocyanide) was used as the isonitrile component, facilitating subsequent deprotection of the N-alkyl group to yield free 5-aminothiazoles, which were prepared with a variety of substituents at the 2- and 4-positions.     

Versatile chiral auxiliaries for NMR spectroscopy based on carbamoyl derivatives of dihydroquinine

Carbamoylation at the C(9) site of dihydroquinine affords new and efficient chiral solvating agents for the NMR enantiodiscrimination of simple derivatives of chiral alcohols, amines, carboxyl acids and amino acids.     

Homogeneous immunoassays

Applied Biochemistry and Biotechnology -     

Electrochemical immunoassays

Immunoassays (IA) use the specific antigen antibody complexation for analytical purposes. Radioimmunoassays (RIA), fluorescence immunoassays (FIA) and enzyme immunoassays (EIA) are well established in clinical diagnostics. For the development of hand-held devices which can be used for point of care measurements, electrochemical immunoassays are promising alternatives to existing immunochemical tests. Moreover, for opaque or optically dense matrices electrochemical methods are superior. Potentiometric, capacitive and amperometric transducers have been applied for direct and indirect electrochemical immunoassays. However, due to their fast detection, broad linear range and low detection limit, amperometric transducers are preferred. Competitive and non-competitive amperometric immunoassays have been developed with redox compounds or enzymes as labels. This review will give an overview of the most frequently applied principles in electrochemical immunoassays. The potential of an indirect competitive amperometric immunoassay for the determination of creatinine within nanomolar range and the circumvention of the most serious problem in electrochemical immunoassays, namely regeneration, will be discussed.     

Chemiluminescence immunoassays

Over the last 25 years, radioimmunoassays have developed into highly sophisticated analytical systems capable of offering exquisite sensitivity and specificity. The expansion of the scope of their application from human health care to other areas such as food and water analysis is in part due to the move away from the use of radioactive tracers. Chemiluminescent molecules perhaps provide the most logical non-radioactive alternative.     

Amperometmc immunoassays

When an electrode is placed in an electrolyte solution an electrical double layer is formed at the surface which functions electrically as a capacitor. An applied oscillating potential causes a certain current flow depending on the capacitance of this double layer. Carbon electrodes were prepared with immobilized antibodies (or antigens). When a specific antigen (or antibody) is added to the solutions, an antigen/antibody complex is formed at the electrode surface, which perturbs the electrical double layer and results in a current change. Dose-response curves can be obtained by measuring these current changes. Under the proper conditions this dose response is specific in the presence of non-specific proteins (e.g. serum). The method has been demonstrated, and dose-response curves obtained, for IgG, anti-IgG, anti-ferritin and S. Aureus cells. No labelled tag is required with this method.     

Development of fluorescence based flow immunoassays utilising restricted access columns

Summary The development of high-speed flow immunoassay techniques is described. The principles are based on heterogeneous flow immunoassay interactions. High sample throughput can be used for screening small analytes in a number of biological matrices originating from samples of water from environmentally polluted areas, or biological fluids such as urine and plasma. The immunochemical detection principle is based on chromatographic separation of the immunocomplex formed (AbAg or AbAg^*) and the free antigen (Ag) by a restricted access (RA) column, utilising size-exclusion and reversed phase mechanisms. A fluorescein-labelled analyte (Ag^*) was used in the competitive assay format with fluorescence detection. Sample throughput was 80 h⁻¹ and detection limits 1.4 nM (300pgml⁻¹) for atrazine and 2.3 nM (500 pg ml⁻¹) for the sum of triazines. Analyses could be performed at a sample throughput of 400 6 h⁻¹ shift. Basic immunoaffinity interactions of a number of immunoreagents, using fluorescence polarisation were studied and outlined both for triazines and for 2,4-D. Structural variations in tracer synthesis confirmed that this is an important part in the design and optimisation of flow immuno methodologies.     

Electrochemical immunoassays

Immunoassays (IA) use the specific antigen antibody complexation for analytical purposes. Radioimmunoassays (RIA), fluorescence immunoassays (FIA) and enzyme immunoassays (EIA) are well established in clinical diagnostics. For the development of hand-held devices which can be used for point of care measurements, electrochemical immunoassays are promising alternatives to existing immunochemical tests. Moreover, for opaque or optically dense matrices electrochemical methods are superior. Potentiometric, capacitive and amperometric transducers have been applied for direct and indirect electrochemical immunoassays. However, due to their fast detection, broad linear range and low detection limit, amperometric transducers are preferred. Competitive and noncompetitive amperometric immunoassays have been developed with redox compounds or enzymes as labels. This review will give an overview of the most frequently applied principles in electrochemical immunoassays. The potential of an indirect competitive amperometric immunoassay for the determination of creatinine within nanomolar range and the circumvention of the most serious problem in electrochemical immunoassays, namely regeneration, will be discussed.     

Versatile chemical transformations of benzoxazole based ligands on complexation with 3d-metal ions

Two benzoxazoles derivative ligands were synthesized from the condensation of 3,5-di-tert-butyl-o-benzoquinone (DTBBQ) with ethanolamine or 1,3-diamino-2-hydroxypropane in methanol. Condensation of DTBBQ with ethanolamine gives the expected 5,7-di-tert-butyl-2-methylenhydroxylbenzoxazole (HL1) while with 1,3-diamino-2-hydroxypropane it gives (2-hydroxyethyl-2-{2,4-bis(1,1-dimethylethyl)-1-phenol-6 amino}-2{5,7-di-tert-butyl-benzoxazole}) (H(2)L2) with only one benzoxazole ring instead of the symmetric bis-benzoxazole derivative. The structure of HL1 and H(2)L2 were confirmed by NMR-spectroscopy and X-ray diffraction on a single crystal for HL1. The reaction of HL1 with CuCl(2) gives a mononuclear [Cu(II)(HL1)(2)Cl(2)] (1) complex for which the crystal structure shows that HL1 is preserved. In contrast, upon reaction with nickel(II), cobalt(II), and manganese(II) H(2)L2 is further oxidized and transformed in new ligands HL3 in mononuclear complexes [M(II)(L3)(2)] (M = Ni(II) (2); M = Co(II) (3)) and H(2)L4 in tetranuclear complex [Mn(II)(4)(HL4)(4)Cl(4)] (4) as found from the crystal structures of complexes 2-4. Electrochemical studies for complexes 2 and 3 evidence complicated redox properties. [Mn(II)(4)(HL4)(4)Cl(4)] (4) has a cubane-like structure with a "4 + 2" fashion The magnetic susceptibility of 4 is well fitted considering one Mn---Mn interaction J(a)(Mn(II)-Mn(II)) = -0.50(1) cm(-1) with g = 2.00(7).     

Versatile Neuromorphic Modulation and Biosensing based on N-type Small-molecule Organic Mixed Ionic-Electronic Conductors

The ion/chemical-based modulation feature of organic mixed ionic-electronic conductors (OMIECs) are critical to advancing next generation bio-integrated neuromorphic hardware. Despite achievements with polymeric OMIECs in organic electrochemical neuronal synapse (OENS). However, small molecule OMIECs based OENS has not yet been realized. Here, for the first time, we demonstrate an effective materials design concept of combining n-type fused all-acceptor small molecule OMIECs with subtle side chain optimization that enables robustly and flexibly modulating versatile synaptic behavior and sensing neurotransmitter in solid or aqueous electrolyte, operating in accumulation modes. By judicious tuning the ending side chains, the linear oligoether and butyl chain derivative gNR-Bu exhibits higher recognition accuracy for a model artificial neural network (ANN) simulation, higher steady conductance states and more outstanding ambient stability, which is superior to the state-of-art n-type OMIECs based OENS. These superior artificial synapse characteristics of gNR-Bu can be attributed to its higher crystallinity with stronger ion bonding capacities. More impressively, we unprecedentedly realized n-type small-molecule OMIECs based OENS as a neuromorphic biosensor enabling to respond synaptic communication signals of dopamine even at sub-μM level in aqueous electrolyte. This work may open a new path of small-molecule ion-electron conductors for next-generation ANN and bioelectronics.     

Prostate-specific antigen immunoassays on the BioCD

The BioCD is a spinning-disc interferometric biosensor on which antibodies are immobilized to capture target antigens from biological samples. In this work, BioCDs measured the interferometric response to prostate-specific antigen (PSA). The ideal detection limit for PSA was determined using a BioCD with 12,500 printed target antibody spots with a corresponding number of reference protein spots. Statistical analysis projects the detection limit of PSA as a function of the number of spots included in the average. When approximately 10,000 spot pairs were averaged, the 3σ detection limit was 60 pg/ml in a 2 mg/ml simple protein background. A standard format for BioCD immunoassays uses 96 wells with 32 target spots paired with reference spots. In serum, the detection limit for this format was 1 ng/ml in 3:1 diluted female human serum using a sandwich assay with a nonfluorescent mass tag.