Immobilization and detection of Listeria monocytogenes

A procedure was developed for immobilization of Listeria monocytogenes cells on metal hydroxides coupled with detection and enumeration using an automated optical system. The results of the immobilization procedure (<1 h) and detection during overnight incubation agreed with calculated plate counts, and this technique is simple and rapid and provides samples that are ready for confirmation of the presence of the pathogen by rapid methods.     

QCM-based DNA biosensor for detection of genetically modified organisms (GMOs)

Development of a mass sensitive quartz crystal microbalance (QCM)-based DNA biosensor for the detection of the hybridization of CaMV 35S promoter sequence (P35S) was investigated for the screening of genetically modified organisms (GMOs). Attention was focused on the choice of the coating chemistry that could be used for the immobilization of probe sequences on the gold surface of the quartz crystal. Two immobilization procedures were tested and compared considering the amount of the immobilized P35S probe and the extent of the hybridization reaction with the target oligonucleotide. In wet chemistry procedure, the interaction between the thiol and gold for the immobilization of a thiolated probe was employed. Direct surface functionalization of piezoelectric quartz crystals were achieved in 13.56 MHz plasma polymerization reactor utilising ethylenediamine (EDA) precursors for the immobilization of amined probes. Results indicated that immobilization of a thiolated probe provides better immobilization characteristics and higher sensitivity for the detection of the hybridization reaction. The thiolated probe was used for the detection of P35S sequence in PCR-amplified DNAs and in real samples of pflp (ferrodoxin like protein)-gene inserted tobacco plants. Fragmentation of the genomic DNAs were achieved by digestion with restriction endonucleases and ultrasonication. The results obtained from the fragmented genomic DNAs demonstrated that it is possible to detect the target sequence directly in non-amplified genomic DNAs by using the developed QCM-based DNA biosensor system. The developed QCM-based DNA biosensor represented promising results for a real-time, label-free, direct detection of DNA samples for the screening of GMOs.     

Impedance-based detection of DNA sequences using a silicon transducer with PNA as the probe layer

Electrochemical impedance measurements were used for the detection of single-strand DNA sequences using a peptide nucleic acid (PNA) probe layer immobilized onto Si/SiO2 chips. An epoxysilane layer is first immobilized onto the Si/SiO2 surface. The immobilization procedure consists of an epoxide/amine coupling reaction between the amino group of the PNA linker and the epoxide group of the silane. A 20-nucleotide sequence of PNA was used. Impedance measurements allow for the detection of the changes in charge distribution at the oxide/solution interface following modifications to the oxide surface. Due to these modifications, there are significant shifts in the semiconductor's flat-band potential after immobilization and hybridization. The results obtained using this direct and rapid approach are supported by fluorescence measurements according to classical methods for the detection of nucleic acid sequences.     

DNA probe attachment on plastic surfaces and microfluidic hybridization array channel devices with sample oscillation

DNA probe immobilization on plastic surfaces and device assembly are both critical to the fabrication of microfluidic hybridization array channel (MHAC) devices. Three oligonucleotide (oligo) probe immobilization procedures were investigated for attaching oligo probes on four different types of plastic surfaces (polystyrene, polycarbonate, poly(methylmethacrylate), and polypropylene). These procedures are the Surmodics procedure, the cetyltrimethylammonium bromide (CTAB) procedure, and the Reacti-Bind procedure. To determine the optimal plastic substrate and attachment chemistry for array fabrication, we investigated plastic hydrophobicity, intrinsic fluorescence, and oligo attachment efficiency. The Reacti-Bind procedure is least effective for attaching oligo probes in the microarray format. The CTAB procedure performs well enough to use in array fabrication, and the concentration of CTAB has a significant effect on oligo immobilization efficiency. We also found that use of amine-modified oligo probes resulted in better immobilization efficiency than use of unmodified oligos with the CTAB procedure. The oligo probe immobilization on plastic surfaces by the Surmodics procedure is the most effective with regard to probe spot quality and hybridization sensitivity. A DNA hybridization assay on such a device results in a limit of detection of 12pM. Utilizing a CO(2) IR laser machining and adhesive layer approach, we have developed an improved procedure for realizing a DNA microarray inside a microfluidic channel. This device fabrication procedure allows for more feasible spot placement in the channel and reduced sample adsorption by adhesive tapes used in the fabrication procedure. We also demonstrated improved hybridization kinetics and increased detection sensitivity in MHAC devices by implementing sample oscillation inside the channel. A limit of detection of 5pM has been achieved in MHAC devices with sample oscillation.     

Accelerated Immunofluorescence Procedure for the Detection of Salmonella in Foods and Animal By-Products

An accelerated, direct immunofluorescent-antibody procedure was developed for the detection of Salmonella in food products. This method includes pre-enrichment and selective enrichment but eliminates many of the washing and smear treatments present in existing methods. Commercially available fluorescein-conjugated somatic antiserum was used in comparing this method with conventional culture, biochemical, and serological procedures. The 894 samples tested represented 39 different products. The fluorescent-antibody procedure detected Salmonella in 216 test samples as compared to 205 positives recovered by using the standard culture procedures. In no instance did the fluorescent-antibody procedure fail to detect a Salmonella positive which had been detected by the standard procedure. With a three-tube, most-probable-number procedure, the fluorescent-antibody method was able to detect Salmonella at a level of 0.036 organism per g. In addition to being a more rapid method for the detection of Salmonella, it has proven to be comparable to conventional culture procedures.     

A Quantitative Real-time PCR Assay for Quantification of Viable Listeria Monocytogenes Cells After Bacteriocin Injury in Food-First Insights

Quantitative real-time PCR may be a rapid and automated procedure for detection of bacterial pathogens from food samples. Nevertheless, when testing the effects of antimicrobials on the viability of bacterial pathogens in foods, we found that DNA from dead cells interfered greatly in the detection of viable Listeria monocytogenes after treatment with the broad-spectrum bacteriocin enterocin AS-48. To overcome this problem, a quantitative real-time PCR (qRT-PCR) assay based on bacterial mRNA was adapted to quantify viable L. monocytogenes in food after bacteriocin treatments. The procedure allowed a better and faster estimation of viable cells compared to PALCAM viable cell counts when the threshold level was 2 log units/g of food, while PALCAM viable count allowed detection of one log unit/g. This procedure may be useful to verify the efficacy of bacteriocins against L. monocytogenes in foods.     

Gene Specific Impedimetric Bacterial DNA Sensor for Rheumatic Heart Disease

An impedimetric mga gene specific DNA sensor was developed by immobilization of single stranded DNA probe onto the screen printed modified gold-dendrimer nanohybrid composite electrode for early and rapid detection of S. pyogenes in human throat swab samples causing rheumatic heart disease. Electrochemical impedance response was measured after hybridization with bacterial single stranded genomic DNA (ssG-DNA) with probe. The sensor was found highly specific to S. pyogenes and can detect as low as 0.01 ng ssDNA in 6 µL sample only in 30 min. The nanohybrid sensor was also tested with non-specific pathogens and characterized by FTIR. An early detection of the pathogen S. pyogenes in human can save damage of mitral and aortic heart valves (rheumatic heart disease) by proper medical care.     

Microfluidic On-chip Capture-cycloaddition Reaction to Reversibly Immobilize Small Molecules or Multi-component Structures for Biosensor Applications

Methods for rapid surface immobilization of bioactive small molecules with control over orientation and immobilization density are highly desirable for biosensor and microarray applications. In this Study, we use a highly efficient covalent bioorthogonal [4+2] cycloaddition reaction between trans-cyclooctene (TCO) and 1,2,4,5-tetrazine (Tz) to enable the microfluidic immobilization of TCO/Tz-derivatized molecules. We monitor the process in real-time under continuous flow conditions using surface plasmon resonance (SPR). To enable reversible immobilization and extend the experimental range of the sensor surface, we combine a non-covalent antigen-antibody capture component with the cycloaddition reaction. By alternately presenting TCO or Tz moieties to the sensor surface, multiple capture-cycloaddition processes are now possible on one sensor surface for on-chip assembly and interaction studies of a variety of multi-component structures. We illustrate this method with two different immobilization experiments on a biosensor chip; a small molecule, AP1497 that binds FK506-binding protein 12 (FKBP12); and the same small molecule as part of an immobilized and in situ-functionalized nanoparticle.     

A rapid in situ immobilization of d-amino acid oxidase based on immobilized metal affinity chromatography

A rapid in situ immobilization process was developed based on conventional separation technique of immobilized metal affinity chromatography (IMAC) and was studied in the case of d-amino acid oxidase (DAAO) with binding–enhancing Heli-tag (His-Arg-Asn-Tyr-Gly-Gly-Cys-Cys-Gly). A recombinant Escherichia coli strain JM105 (Δase)/pGEMK-R-DAAO-Heli was successfully constructed to synthesize chimeric protein DAAO-Heli. Without additional purification procedure, the tagged enzyme DAAO-Heli could be directly immobilized to EP-IDA-Ni²⁺ support with purity of 90 % and DAAO activity of over 70 U/g support. Experimental results showed that the immobilized DAAO-Heli was 73 times more thermally stable than free enzyme. Besides, it remained 67 % of initial activity after 100 cycles of batch catalysis and its operational stability was improved 36 times than that of the previously IMAC-immobilized DAAO-His. Furthermore, the epoxy (EP) support could be easily recovered and repeatedly used with simple steps, which could reduce the immobilization costs significantly.     

Recent advances in the development of biosensor for phenol: a review

Phenol and its derivatives are widespread contaminants whose sources are both natural and industrial. Phenol is massively produced and used as a starting material for synthetic polymers and fibers. Although phenolic compounds play important biochemical and physiological roles in living systems, their accumulation in the environment as a result of intensive human activity may result in drastic ecological problem. Various analytical techniques are available for the detection of phenol in environmental samples. But they need complex sample pre-treatment so as are time consuming, costly and use heavy devices. On the other hand a biosensor is a device that gives rapid detection, cost effective and easy. A review study was carried out to accumulate the possible biosensors for the detection of phenolic compounds in environmental samples. A number of biological components including microorganisms, enzymes, antibodies, antigens, nucleic acids etc. can be used for the construction of biosensors that was found to detect phenolic compounds. Of all type of biological components microorganisms and enzymes are mostly used. The microorganisms are Pseudomonas, Moraxella, Arthrobacter, Rhodococcus, and Trichosporon. The most used enzymes are tyrosinase, peroxidase, laccase, glucose dehydrogenase, cellobiose dehydrogenase etc. Antibody sensors can detect a very trace level. The biorecognition of DNA biosensors occur by hybridization of DNA. Biosensors are found to work well when the biological sensing element is immobilized. A variety of immobilization techniques were found to use as adsorption, covalent binding, entrapment, cross-linking etc. For immobilization the matrices used was polyvinyl alcohol, Osmium complex, nafion/sol?Cgel silicate, chitosan, silica gel etc.     

Use of Tethered Enzymes as a Platform Technology for Rapid Analyte Detection

Background

Rapid diagnosis for time-sensitive illnesses such as stroke, cardiac arrest, and septic shock is essential for successful treatment. Much attention has therefore focused on new strategies for rapid and objective diagnosis, such as Point-of-Care Tests (PoCT) for blood biomarkers. Here we use a biomimicry-based approach to demonstrate a new diagnostic platform, based on enzymes tethered to nanoparticles (NPs). As proof of principle, we use oriented immobilization of pyruvate kinase (PK) and luciferase (Luc) on silica NPs to achieve rapid and sensitive detection of neuron-specific enolase (NSE), a clinically relevant biomarker for multiple diseases ranging from acute brain injuries to lung cancer. We hypothesize that an approach capitalizing on the speed and catalytic nature of enzymatic reactions would enable fast and sensitive biomarker detection, suitable for PoCT devices.

Methods and findings

We performed in-vitro, animal model, and human subject studies. First, the efficiency of coupled enzyme activities when tethered to NPs versus when in solution was tested, demonstrating a highly sensitive and rapid detection of physiological and pathological concentrations of NSE. Next, in rat stroke models the enzyme-based assay was able in minutes to show a statistically significant increase in NSE levels in samples taken 1 hour before and 0, 1, 3 and 6 hours after occlusion of the distal middle cerebral artery. Finally, using the tethered enzyme assay for detection of NSE in samples from 20 geriatric human patients, we show that our data match well (r = 0.815) with the current gold standard for biomarker detection, ELISA—with a major difference being that we achieve detection in 10 minutes as opposed to the several hours required for traditional ELISA.

Conclusions

Oriented enzyme immobilization conferred more efficient coupled activity, and thus higher assay sensitivity, than non-tethered enzymes. Together, our findings provide proof of concept for using oriented immobilization of active enzymes on NPs as the basis for a highly rapid and sensitive biomarker detection platform. This addresses a key challenge in developing a PoCT platform for time sensitive and difficult to diagnose pathologies.     

Rapid Plate Method for the Isolation of Lysogenic Bacteriophages

We have devised a rapid plate method for the detection and isolation of lysogenic phages and have used the procedure to screen 15 strains of Staphylococcus aureus. This method should prove applicable to a wide variety of bacterial species and should be especially valuable for those pathogens for which no phage-typing system is available.     

Improvement of the stability and selectivity of Rhizomucor miehei lipase immobilized on silica nanoparticles: Selective hydrolysis of fish oil using immobilized preparations

We report the effect of random and oriented immobilization of Rhizomucor miehei lipase (RML) on its functional properties. For this purpose, silica nanoparticles (MCM-41 and SBA-15) were prepared, characterized and functionalized by glycidyloxypropyl trimethoxysilane. Direct immobilization of RML on these supports was performed via the variety of amino acid residues on the surface of RML which promotes random immobilization. To perform oriented immobilization, partial modification of epoxy functionalized supports was carried out by introducing iminodiacetic acid groups followed by addition of Cu²⁺. In this way, immobilization is mainly directed via the most accessible histidine group, followed by intramolecular reaction of the other nucleophilic residues of the enzyme and the remaining epoxy groups on the support. The results showed higher thermal stability for immobilized derivatives compared to the soluble enzyme. Co-solvent stability of the derivatives was also studied in presence of six polar organic solvents (DMSO, THF, acetonitrile, 1-propanol, 2-propanol and dioxane). Influence of the immobilization procedure on activity and selectivity of the immobilized preparations was studied in selective hydrolysis of fish oil. All the derivatives discriminate between cis-5,8,11,14,17-eicosapentaenoic acid (EPA) and cis-4,7,10,13,16,19-docosahexaenoic acid (DHA) in favor of EPA. Remarkable improvement in selectivity was obtained using oriented immobilization of RML.     

Rapid visualization of protein bands in preparative SDS-polyacrylamide gels.

A rapid sensitive method has been developed for the detection of protein bands in sodiumdodecyl sulfate (SDS)-polyacrylamide gels that is suitable for the recovery of individual polypeptides on a preparative scale. The process is reversible and allows for the complete recovery of unmodified protein from preparative gels. The visualization is rapid, requiring between 30 and 40 min, and sensitive, detecting as little protein as 0.1 μg/mm³. The procedure employs high concentrations of sodium acetate.     

Highly sensitive and rapid gene mapping using miniaturized blot hybridization: application to prenatal diagnosis

We have developed a protocol for the preparation and analysis of amniocyte DNA which permits more sensitive and more rapid antenatal detection of sickle-cell anemia (SCA) than previously has been possible. After rapid extraction of DNA from amniotic cells, only 50 ng of MstII-digested DNA need be analyzed by mini-gel electrophoresis and hybridization detection to determine reliably the fetal genotype. Under these conditions, the entire gene-mapping procedure can be performed within 5 days. When larger amounts of DNA ($\text{> 500}\text{ng}$) are analyzed, the minimal diagnosis time is reduced to 2 days. The resolution of restriction fragments on mini-gels is comparable to that obtained with larger gels. The 1.15-kb β^A and 1.35-kb β^SMstII fragments are well separated. The technique is useful whenever rapid and sensitive analysis of genomic DNA is desired.     

Multisubstrate-compatible ELISA procedures for rapid and high-sensitivity immunoassays

This protocol describes an improved and optimized approach to develop rapid and high-sensitivity ELISAs by covalently immobilizing antibody on chemically modified polymeric surfaces. The method involves initial surface activation with KOH and an O(2) plasma, and then amine functionalization with 3-aminopropyltriethoxysilane. The second step requires covalent antibody immobilization on the aminated surface, followed by ELISA. The ELISA procedure developed is 16-fold more sensitive than established methods. This protocol could be used generally as a quantitative analytical approach to perform high-sensitivity and rapid assays in clinical situations, and would provide a faster approach to screen phage-displayed libraries in antibody development facilities. The antibody immobilization procedure is of ～3 h duration and facilitates rapid ELISAs. This method can be used to perform assays on a wide range of commercially relevant solid support matrices (including those that are chemically inert) with various biosensor formats.     

Development of multiplex PCR for fast detection of Paenibacillus Larvae in putrid masses and in isolated bacterial colonies

The present study was performed to develop a fast and sensitive multiplex polymerase chain reaction protocol for routine diagnostics of American foulbrood. A new approach for detection of Paenibacillus larvae in putrid masses was described. Forty five samples of putrid masses obtained from bee combs suspicious for American foulbrood, a reference strain Paenibacillus larvae (NBIMCC 8478), clinical isolates and 4 strains of closely related bacterial species were included in experiments. Bacterial colonies?? DNA was isolated by heat and centrifugation method (standard procedure) and with prepGem commercial kit. DNA from putrid masses was isolated by standard and modified procedure. Three pairs of primers specific for 16S rRNA and one pair specific for 35 kDa metalloproteinase genes of Paenibacillus larvae were tested as single pair and in different combinations as multiplex PCR. The sensitivity of the multiplex PCR protocol for putrid masses, developed in study was 100%, versus 45.2% for the standard protocol. The developed multiplex PCR protocol could be successfully used for rapid and specific detection of Paenibacillus larvae in both putrid masses and isolated bacterial colonies.     

Purity Control of the Production of Baker''s Yeast Employing a Fluorescent Antiserum

A simple staining procedure for the rapid detection of wild yeasts contaminating baker's yeast during the course of industrial production is described. Fluorescein-labeled, specific antiserum against Saccharomyces cerevisiae is applied to smears of baker's yeast which are then examined by ultraviolet microscopy. Optimal results are obtained with the combined phase contrast and fluorescence which makes the S. cerevisiae appear green, whereas cells of wild yeasts are visible in bright red counterstain. With this method, wild yeasts could be identified in baker's yeast at a dilution of 1:10,000.     

Site-specific immobilization of a (His)6-tagged acetylcholinesterase on nickel nanoparticles for highly sensitive toxicity biosensors

This paper reports site-specific affinity immobilization of (His)6-tagged acetylcholinesterase (AChE) onto Ni/NiO nanoparticles for the development of an electrochemical screen-printed biosensor for the detection of organophosphate pesticides. The method is based on the specific affinity binding of the His-tagged enzyme to oxidized nickel nanoparticle surfaces in the absence of metal chelators. This approach allows stable and oriented attachment of the enzyme onto the oxidized nickel through the external His residue in one-step procedure, allowing for fast and sensitive detection of paraoxon in the concentration range from 10⁻⁸ to 10⁻¹³ M. A detection limit of 10⁻¹² M for paraoxon was obtained after 20 min incubation. This method can be used as a generic approach for the immobilization of other His-tagged enzymes for the development of biosensors.     

Urea denaturation of the immobilized proteases of Streptomyces griseus (pronase)

The protease preparation (pronase, EC 3.4. group) from Streptomyces griseus has been covalently immobilized on porous succinamidopropyl glass using a carbodiimide carboxyl activation procedure. The separate activities of the individual proteases in this preparation were assayed using specific synthetic substrates. Stabilities of both soluble and immobilized preparations were determined and compared by assaying for each activity in urea solutions of various concentration. The loss of activity by the immobilized enzymes was shown to be reversible under most conditions. Analysis of the data in terms of a two-state transition showed that the urea concentration resulting in 50% loss of activity was increased for each enzyme as a result of immobilization. Also the m-value in the relation ΔG_D = ΔG^H₂O_D - m[urea] decreased for each enzyme upon immobilization. Thus, all of the enzymes were stabilized by immobilization and the apparent broadening of the transitions, as measured by the decreased m-value, was interpreted as the formation of a population of molecules with different stabilities. The degree of apparent stabilization upon immobilization varied with the magnitude decreasing as: aminopeptidases > carboxypeptidase ? trypsin > proteases A and B. Furthermore, it is suggested that stabilization may result from multipoint attachment since the magnitude was correlated with the number of potential enzyme reaction sites as reflected by their lysine contents.