We report on the use of PDMS multichannels for affinity studies of DNA aptamer–human Immunoglobulin E (IgE) interactions by
surface plasmon resonance imaging (SPRi). The sensing surface was prepared with thiol-terminated aptamers through a self-assembling
process in the PDMS channels defined on a gold substrate. Cysteamine was codeposited with the thiol aptamers to promote proper
spatial arrangement of the aptamers and thus maintain their optimal binding efficiencies. Four aptamers with different nucleic
acid sequences were studied to test their interaction affinity toward IgE, and the results confirmed that aptamer I (5′-SH-GGG
GCA CGT TTA TCC GTC CCT CCT AGT GGC GTG CCC C-3′) has the strongest binding affinity. Control experiments were conducted with
a PEG-functionalized surface and IgG was used to replace IgE in order to verify the selective binding of aptamer I to the
IgE molecules. A linear concentration-dependent relationship between IgE and aptamer I was obtained, and a 2-nM detection
limit was achieved. SPRi data were further analyzed by global fitting, and the dissociation constant of aptamer I–IgE complex
was found to be 2.7 × 10−7 M, which agrees relatively well with the values reported in the literature. Aptamer affinity screening by SPR imaging demonstrates
marked advantages over competing methods because it does not require labeling, can be used in real-time, and is potentially
high-throughput. The ability to provide both qualitative and quantitative results on a multichannel chip further establishes
SPRi as a powerful tool for the study of biological interactions in a multiplexed format.
Figure The SPRi sensograms and thier global fits for aptamer I and IgE interactions. Insert in the difference image obtained with
the PDMS microchannel flow cell for aptamer IV, III, and I (from left to right 相似文献
A method for the immobilization of proteins at the surface of surface plasmon resonance imaging (SPRi) chips is presented. The technology, based on the electro‐deposition of a 4‐carboxymethyl aryl diazonium (CMA) monolayer is compared to a classical thioctic acid self‐assembled monolayer. SPRi live recording experiments followed by the quantification of the diazonium surface coverage demonstrate the presence of a monolayer of electro‐deposited molecules (11*1012 molecules mm?²). This monolayer, when activated through a classical carbodiimide route, generates a surface suitable for the protein immobilization. In the present study, protein A and BSA are immobilized as specific and control spots (150 μm id), respectively. The AFM characterization of the spots deposited onto CMA or thioctic acid modified chips prove the presence of 4.7 nm protein monolayers. Finally, the SPRi detection capabilities of the two surface chemistries are compared according to specific signal, non‐specific interaction and regeneration possibilities. Advantages are given to the CMA surface modification since no measurable non‐specific signal is obtained while reaching a higher specific signal.相似文献
Only few papers deal with Surface Plasmon Resonance imaging (SPRi) direct detection on complex matrices, limiting the biosensor application to real analytical problems. In this work a SPRi biosensor for anti-bovine IgG detection in untreated human bodily fluids, i.e. diluted human serum and milk, was developed. Enhanced levels of cow's milk antibodies in children's serum are suspected for their possible correlation with Type 1 diabetes during childhood and their detection in real samples was up to now performed by classical immunoassays based on indirect detection. The biosensor was optimised in standard samples and then in untreated human milk for anti-bovine IgG direct detection. The key novelty of the work is the evaluation of matrix effect by applying to real samples an experimental and ex ante method previously developed for SPRi signal sampling in standard solutions, called "Data Analyzer"; it punctually visualises and analyses the behaviour of receptor spots of the array, to select only spot areas with the best specific vs. unspecific signal values. In this way, benefits provide by SPRi image analysis are exploited here to quantify and minimise drawbacks due to the matrix effect, allowing to by-pass every matrix pre-treatment except dilution. 相似文献
Surface plasmon resonance imaging (SPRi) by enabling label‐free, real time assessment of biomolecular interactions in multiplexed manner is one of the methods of choice for high throughput characterization of large pools of DNA aptamer candidates following in vitro selection. Moreover, with major advances in in situ amplification methods SPRi became also a viable detection platform for aptamer microarrays. In case of aptamer microarrays, commonly prepared by microspotting, the direct assessment of the surface density of aptamer probes, which is essential for both kinetic and sensing measurements is not possible. Therefore, here we introduce a methodology for simple, one‐step determination of surface densities of thiol labelled aptamer monolayers microspotted on gold SPRi chips. Based on this methodology we investigated in detail the effect of the surface density of aptamers on target binding through two aptamer‐target systems, i. e. human immunoglobulin E (hIgE) and six histidine tag 6xHis‐tag. We found that the surface density of the aptamers is indeed critical and shows a sharp maximum in terms of target binding efficiency, which is largely determined by the size of the target. The optimal aptamer surface densities determined, the immobilization chemistry (shared by many detection platforms, e. g., electrochemical, surface acoustic) and the trends identified may be used for rapid rational optimization of aptamer‐target assays. 相似文献
The use of nanoparticles (NPs) can substantially improve the analytical performance of surface plasmon resonance imaging (SPRi) in general, and in DNA sensing in particular. In this work, we report on the modification of the gold surface of commercial biochips with gold nanospheres, silica-coated gold nanoshells, and silver nanoprisms, respectively. The NPs were tethered onto the surface of the chip and functionalized with a DNA probe. The effects of tethering conditions and varying nanostructures on the SPRi signals were evaluated via hybridization assays. The results showed that coupling between planar surface plasmons and electric fields, generated by localized surface plasmons of the NPs, is mandatory for signal enhancement. Silver nanoprisms gave the best results in improving the signal change at a target DNA concentration of <50 nM by +50 % (compared to a conventional SPRi chip). The limit of detection for the target DNA was 0.5 nM which is 5 times less than in conventional SPRi.
We demonstrate the characterization of mu-contact printed protein patterns and analysis of protein-protein interactions by two-dimensional (2-D) surface plasmon resonance imaging (SPRi). Advancements in SPRi image quality from employing a light emitting diode (LED) as the light source are described. We show that a LED offers an ideal point source that can eliminate interference artifacts and speckles found when using a laser source. The attainable thickness resolution in fixed-angle imaging is comparable to that of a monochromatic source, providing a solid foundation for quantitative analysis with the system. The SPR imaging technique reported here affords sub-nanometer thickness sensitivity and micrometer lateral resolution, allowing for convenient studies of biomolecular interactions and surface morphologies of ultrathin films. Spatially well-defined protein patterns of bacterial toxins were obtained by microcontact printing using a polydimethylsiloxane (PDMS) stamp on a functionalized self-assembled monolayer on Au. The influence of protein concentration in the inking solution on transfer efficiency was investigated, and a nonlinear correlation was observed between the solution concentration and the amount of protein immobilized on the surface. Quantitative analysis of protein interaction was performed with toxin-specific antibody, showing a concentration-dependent relationship that verifies the retention of biological activity of the protein after printing. The study demonstrates the feasibility and effectiveness of using LEDs as light sources in SPR imaging, opening doors for developing compact SPR instruments for direct, sensitive, and label-free detection of biohazardous molecules. 相似文献
The on-line coupling of comprehensive two-dimensional liquid chromatography (liquid chromatography x size-exclusion chromatography, LC x SEC) and infrared (IR) spectroscopy has been realized by means of an IR flow cell. The system has been assessed by the functional-group analysis of a series of styrene-methylacrylate (SMA) copolymers with varying styrene content. Ultraviolet (UV) detection was used as a detection technique to verify the detection with IR. The LC x SEC-IR functional-group contour plots (comprehensive chromatograms) obtained for styrene were in agreement with the contour plots constructed from the UV signal. In addition, contour plots can be obtained from non-UV-active groups. One such plot, for the carbonyl-stretching vibration of methylacrylate (MA), is shown. Selective detection of MA proved possible using flow cell IR detection. The combination of the contour plots for styrene and MA allowed a full characterization of the copolymer and it was revealed that the present series of SMA copolymers exhibited homogeneous chemical-composition distributions (CCDs). In addition, commercially available fast-SEC columns have been assessed in this study with respect to their potential to serve as second-dimension separation columns. 相似文献
A general method has been developed to determine the ionization constants of polymer thin films based on the stimuli-responsiveness of the polymer. Robust polymer films were fabricated on silicon wafers and gold slides using perfluorophenyl azide (PFPA) as the coupling agent. The ionization constants were measured by a number of techniques including ellipsometry, dynamic contact angle goniometry, and surface plasmon resonance imaging (SPRi). Using poly(4-vinylpyridine) (P4VP) as the model system, P4VP thin films were fabricated and the ionization constants of the films were measured taking advantage of the pH responsive property of the polymer. The pK(a) determined by ellipsometry, ~4.0, reflects the swelling of the polymer film in response to pH. The pK(a) value calculated from the dynamic contact angle measurements, ~5.0, relies on the change in hydrophilicity/hydrophobicity of the films as the polymer undergoes protonation/deprotonation. The pK(a) value measured by SPRi, ~4.9, monitors in situ the change of refractive index of the polymer thin film as it swells upon protonation. This was the first example where SPRi was used to measure the ionization constants of polymers. 相似文献
An electrochemical sensor(carboxylatopillar[5]arene-coated nitrogen-doped carbon dots, namely CCDs)based on carboxylatopillar[5]arene(CP[5]) functionalized nitrogen-doped carbon dots(N-CDs) has been developed in a facile and economic manner. To improve the performance of this electrochemical sensor in pesticide detection, the optimal solution p H(p H 7) and loading amount of CCDs on the electrode(0.50 mg/m L) have been determined. By virtue of the good conductivity of N-CDs and the molecular rec... 相似文献
We describe a microfluidic device that can be used to detect interactions between red blood cells (RBCs) and endothelial cells using a gold pillar array (created by electrodeposition) and an integrated detection electrode. Endothelial cells can release nitric oxide (NO) via stimulation by RBC‐derived ATP. These studies incorporate on‐chip endothelial cell immobilization, direct RBC contact, and detection of NO in a single microfluidic device. In order to study the RBC‐EC interactions, this work used a microfluidic device made of a PDMS chip with two adjacent channels and a polystyrene base with embedded electrodes for creating a membrane (via gold pillars) and detecting NO (at a glassy carbon electrode coated with platinum‐black and Nafion). RBCs were pharmacologically treated with treprostinil in the absence and presence of glybenclamide, and ATP release was determined as was the resultant NO release from endothelial cells. Treprostinil treatment of RBCs resulted in ATP release that stimulated endothelial cells to release on average 1.8±0.2 nM NO per endothelial cell (average±SEM, n=8). Pretreatment of RBCs with glybenclamide inhibited treprostinil‐induced ATP release and, therefore, less NO was produced by the endothelial cells (0.92±0.1 nM NO per endothelial cell, n=7). In the future, this device can be used to study interactions between many other cell types (both adherent and non‐adherent cell lines) and incorporate other detection schemes. 相似文献
Base excision repair (BER) is the major mechanism for the correction of damaged nucleobases resulting from the alkylation and oxidation of DNA. The first step in the BER pathway consists of excision of the abnormal base by several specific DNA N-glycosylases. A decrease in BER activity was found to be related to an increased risk of carcinogenesis and aging. To investigate BER activities we set up a new device for DNA repair analysis based on surface plasmon resonance imaging (SPRi). Oligonucleotides bearing an abnormal nucleoside, namely 8-oxo-7,8-dihydro-2'-deoxyguanosine and (5'S)-5',8-cyclopurine-2'-deoxynucleoside, were grafted by a pyrrole electro-copolymerization process on a glass prism coated with a gold layer. The latter label-free DNA sensor chip permits the detection of N-glycosylase/AP-lyase activity as well as the binding of repair proteins to DNA damage without cleavage activity. Thus, the Fapy DNA N-glycosylase (Fpg) protein is shown as expected to bind and then cleave its natural substrate, namely 8-oxo-7,8-dihydro-guanine, together with the resulting abasic site. Using the current SPR imaging-based DNA array we observed an original binding activity of Fpg towards the (5'S)-5',8-cyclodAdenosine residue. These results altogether show that SPR imaging may be used to simultaneously and specifically detect recognition and excision of several damaged DNA nucleobases, and constitutes an interesting technique to screen inhibitors of DNA repair proteins. 相似文献
In this paper, we describe a simple charge-coupled device (CCD) based lensless fluorometer with sensitivity in the range of current ELISA plate readers. In our lensfree fluorometer, a multi-wavelength LED light source was used for fluorophore excitation. To collimate the light, we developed a simple optical S?ller collimator based on a "stack of pinholes" (a stack of black PMMA with array of pinholes machined with laser) enabling the light to be collimated from the LED through the filters and the assay's microfluidics directly onto the CCD without a lens. The elimination of the lens that is used in almost all other current CCD based detection systems has four major advantages: (1) It simplifies the device design and fabrication while reducing cost. (2) It reduces the distance between the sample and the measuring device (without a lens the distance needed to focus the image on the CCD is reduced and the fluorometer can be more compact). (3) It couples the CCD and the detected surface by using an optical S?ller Collimator which allows the use of filters for fluorescence detection. (4) It also uncouples the CCD and the microfluidics to enable the use of interchangeable fluidics while protecting the delicate CCD. The lensless CCD-based fluorometer is capable of detecting 16 samples simultaneously, and was used for in vitro detection of botulinum neurotoxin serotype A (BoNT-A) activity with a FRET assay that measures cleavage of a fluorophore-tagged peptide substrate specific for BoNT-A (SNAP-25) by the toxin light chain (LcA). The limit of detection (LOD) of our lensless fluorometer is 1.25 nM, which is similar to the LOD of a modern ELISA plate reader. Combined with microfluidics, this simple low cost point-of-care (POC) medical diagnostic system may be useful for the performance of many other complex medical diagnostic assays without a laboratory and thus potentially enhancing the accessibility and the quality of health care delivery in underserved populations. 相似文献
Protein biomarker discovery and validation are crucial for diagnosis, prognosis, and theranostics of human pathologies; "omics" approaches bring new insights in this field. In particular, the combination of immuno-sensors in array format with mass spectrometry efficiently extends the classical immunoassay format and includes molecular characterization. Here, we coupled surface plasmon resonance imaging (SPRi) with MALDI-TOF mass spectrometry in a hyphenated technique which enables multiplexed quantification of binding by SPRi and molecular characterization of interacting partners by subsequent MS analysis. This adds specificity, because MS enables differentiation of molecules that are difficult to distinguish by use of antibodies, for example truncation variants or protein isoforms. Proof of concept was established for detection, identification, and characterization of a potential breast cancer marker, the LAG3 protein, at ~1?μg?mL(-1), added to human plasma. The analytical performance of this new method, dubbed "SUPRA-MS", was established, particularly its specificity (S/N > 10) and reliability (100?% LAG3 identification with high significant mascot score >87.9). The adjusted format for rapid, collective, and automated on-chip MALDI-MS analysis is robust at the femtomole level and has numerous potential applications in proteomics. 相似文献
We are describing immunochromatographic test strips with smart phone-based fluorescence readout. They are intended for use in the detection of the foodborne bacterial pathogens Salmonella spp. and Escherichia coli O157. Silica nanoparticles (SiNPs) were doped with FITC and Ru(bpy), conjugated to the respective antibodies, and then used in a conventional lateral flow immunoassay (LFIA). Fluorescence was recorded by inserting the nitrocellulose strip into a smart phone-based fluorimeter consisting of a light weight (40 g) optical module containing an LED light source, a fluorescence filter set and a lens attached to the integrated camera of the cell phone in order to acquire high-resolution fluorescence images. The images were analysed by exploiting the quick image processing application of the cell phone and enable the detection of pathogens within few minutes. This LFIA is capable of detecting pathogens in concentrations as low as 105 cfu mL−1 directly from test samples without pre-enrichment. The detection is one order of magnitude better compared to gold nanoparticle-based LFIAs under similar condition. The successful combination of fluorescent nanoparticle-based pathogen detection by LFIAs with a smart phone-based detection platform has resulted in a portable device with improved diagnosis features and having potential application in diagnostics and environmental monitoring.
The successful combination of fluorescent nanoparticle-based pathogen detection by lateral flow immunoassay with a smart phone-based detection platform has resulted in a portable device that enables rapid and reliable bacterial detection holding large potential in diagnostics and environmental monitoring
A one‐step method to fabricate a biomimetic dual‐scale hierarchical structure for a transparent anti‐reflective, self‐cleaning layer for organic solar cells is reported. Template‐mediated UV replica molding is used to directly create a multi‐functional surface with an acrylate‐functionalized perfluoropolyether without complicated processing steps. The surface exhibits superhydrophobic properties and self‐cleaning characteristics. In addition, the surface leads to an enhancement of photovoltaic power conversion efficiency by ≈10% as a result of reflection suppression and transmittance enhancement. The method can easily be applied to large area substrates (22 cm × 24 cm) in a cost‐effective manner. Furthermore, the solar cell can withstand harsh outdoor conditions for a long time, without a notable change in the device performance, owing to robust surface layer and non‐fouling properties.
An integrated microfluidic biosensor is presented that combines sample pre-concentration and liposome-based signal amplification
for the detection of enteric viruses present in environmental water samples. This microfluidic approach overcomes the challenges
of long assay times of cell culture-based methods and the need to extensively process water samples to eliminate inhibitors
for PCR-based methods. Here, viruses are detected using an immunoassay sandwich approach with the reporting antibodies tagged
to liposomes. Described is the development of the integrated device for the detection of environmentally relevant viruses
using feline calicivirus (FCV) as a model organism for human norovirus. In situ fabricated nanoporous membranes in glass microchannels
were used in conjunction with electric fields to achieve pre-concentration of virus–liposome complexes and therefore enhance
the antibody–virus binding efficiency. The concentrated complexes were eluted to a detection region downstream where captured
liposomes were lysed to release fluorescent dye molecules that were then quantified using image processing. This system was
compared to an optimized electrochemical liposome-based microfluidic biosensor without pre-concentration. The limit of detection
of FCV of the integrated device was at 1.6 × 105 PFU/mL, an order of magnitude lower than that obtained using the microfluidic biosensor without pre-concentration. This significant
improvement is a key step toward the goal of using this integrated device as an early screening system for viruses in environmental
water samples. 相似文献
