Synthesis of hydrophobic nanoparticles for real‐time lysozyme detection using surface plasmon resonance sensor

Diagnostic biomarkers such as proteins and enzymes are generally hard to detect because of the low abundance in biological fluids. To solve this problem, the advantages of surface plasmon resonance (SPR) and nanomaterial technologies have been combined. The SPR sensors are easy to prepare, no requirement of labelling and can be detected in real time. In addition, they have high specificity and sensitivity with low cost. The nanomaterials have also crucial functions such as efficiency improvement, selectivity, and sensitivity of the detection systems. In this report, an SPR‐based sensor is developed to detect lysozyme with hydrophobic poly (N‐methacryloyl‐(L)‐phenylalanine) (PMAPA) nanoparticles. The SPR sensor was first characterized by attenuated total reflection‐Fourier transform infrared, atomic force microscope, and water contact angle measurements and performed with aqueous lysozyme solutions. Various concentrations of lysozyme solution were used to calculate kinetic and affinity coefficients. The equilibrium and adsorption isotherm models of interactions between lysozyme solutions and SPR sensor were determined and the maximum reflection, association, and dissociation constants were calculated by Langmuir model as 4.87, 0.019 nM⁻¹, and 54 nM, respectively. The selectivity studies of SPR sensor were investigated with competitive agents, hemoglobin, and myoglobin. Also, the SPR sensor was used four times in adsorption/desorption/recovery cycles and results showed that, the combination of optical SPR sensor with hydrophobic ionizable PMAPA nanoparticles in one mode enabled the detection of lysozyme molecule with high accuracy, good sensivity, real‐time, label‐free, and a low‐detection limit of 0.66 nM from lysozyme solutions. Lysozyme detection in a real sample was performed by using chicken egg white to evaluate interfering molecules present in the medium.     

A real‐time PCR assay for detection and quantification of Lactococcus garvieae

Aims: To develop a rapid, sensitive, specific tool for the detection and quantification of Lactococcus garvieae in food and environmental samples. Methods and Results: A real‐time quantitative PCR (qPCR) assay with primers for CAU12F and CAU12R based on the 16S rRNA gene of L. garvieae was successfully established. The limit of detection for L. garvieae genomic DNA was 1 ng DNA in conventional PCR and 32 fg with a mean C_T value of 36·75 in qPCR. Quantification of L. garvieae vegetative cells was linear (R² = 0·99) over a 7‐log‐unit dynamic range down to ten L. garvieae cells. Conclusions: This method is highly specific, sensitive and reproducible for the detection of L. garvieae compared to gel‐based conventional PCR assays, thus providing precise quantification of L. garvieae in food and natural environments. Significance and Impact of the Study: This work provides efficient diagnostic and monitoring tools for the rapid identification of L. garvieae, an emerging pathogen in aquaculture and an occasional human pathogen from other members of the genus Lactobacillus.     

Bare fiber Bragg grating immunosensor for real‐time detection of Escherichia coli bacteria

Escherichia coli (E. coli) bacteria have been identified to be the cause of variety of health outbreaks resulting from contamination of food and water. Timely and rapid detection of the bacteria is thus crucial to maintain desired quality of food products and water resources. A novel methodology proposed in this paper demonstrates for the first time, the feasibility of employing a bare fiber Bragg grating (bFBG) sensor for detection of E. coli bacteria. The sensor was fabricated in a photo‐sensitive optical fiber (4.2 µm/80 µm). Anti‐E. coli antibody was immobilized on the sensor surface to enable the capture of target cells/bacteria present in the sample solution. Strain induced on the sensor surface as a result of antibody immobilization and subsequent binding of E. coli bacteria resulted in unique wavelength shifts in the respective recording of the reflected Bragg wavelength, which can be exploited for the application of biosensing. Functionalization and antibody binding on to the fiber surface was cross validated by the color development resulting from the reaction of an appropriate substrate solution with the enzyme label conjugated to the anti‐E. coli antibody. Scanning electron microscope image of the fiber, further verified the E. coli cells bound to the antibody immobilized sensor surface.

     

A molecularly imprinted nanofilm‐based quartz crystal microbalance sensor for the real‐time detection of pirimicarb

This study aimed to prepare a novel quartz crystal microbalance (QCM) sensor for the detection of pirimicarb. Pirimicarb‐imprinted poly (ethylene glycol dimethacrylate‐N‐metacryloyl‐(l )‐tryptophan methyl ester) [p (EGDMA‐MATrp)] nanofilm (MIP) on the gold surface of a QCM chip was synthesized using the molecular imprinting technique. A nonimprinted p (EGDMA‐MATrp) nanofilm (NIP) was also synthesized using the same experimental technique. The MIP and NIP nanofilms were characterized via Fourier transform infrared spectroscopy attenuated total reflectance spectroscopy, contact angle, atomic force microscopy, and an ellipsometer. A competitive adsorption experiment on the sensor was performed to display the selectivity of the nanofilm. An analysis of the QCM sensor showed that the MIP nanofilm exhibited high sensitivity and selectivity for pirimicarb determination. A liquid chromatography‐tandem mass spectrometry method was prepared and validated to determine the accuracy and precision of the QCM sensor. The accuracy and precision of both methods were determined by a comparison of six replicates at three different concentrations to tomato samples extracted by using a Quick, Easy, Cheap, Effective, Rugged and Safe (QuEChERS) method. The limit of detection of the QCM sensor was found to be 0.028 nM. In conclusion, the QCM sensor showed good accuracy, with recovery percentages between 91 and 94%. Also, the pirimicarb‐imprinted QCM sensor exhibited a fast response time, reusability, high selectivity and sensitivity, and a low limit of detection. Therefore, it offers a serious alternative to the traditional analytical methods for pesticide detection in both natural sources and aqueous solutions.     

An amperometric enzyme biosensor for real‐time measurements of cellobiohydrolase activity on insoluble cellulose

An amperometric enzyme biosensor for continuous detection of cellobiose has been implemented as an enzyme assay for cellulases. We show that the initial kinetics for cellobiohydrolase I, Cel7A from Trichoderma reesei, acting on different types of cellulose substrates, semi‐crystalline and amorphous, can be monitored directly and in real‐time by an enzyme‐modified electrode based on cellobiose dehydrogenase (CDH) from Phanerochaete chrysosporium (Pc). PcCDH was cross‐linked and immobilized on the surface of a carbon paste electrode which contained a mediator, benzoquinone. An oxidation current of the reduced mediator, hydroquinone, produced by the CDH‐catalyzed reaction with cellobiose, was recorded under constant‐potential amperometry at +0.5 V (vs. Ag/AgCl). The CDH‐biosensors showed high sensitivity (87.7 µA mM^?1 cm^?2), low detection limit (25 nM), and fast response time (t_95% ～ 3 s) and this provided experimental access to the transient kinetics of cellobiohydrolases acting on insoluble cellulose. The response from the CDH‐biosensor during enzymatic hydrolysis was corrected for the specificity of PcCDH for the β‐anomer of cello‐oligosaccharides and the approach were validated against HPLC. It is suggested that quantitative, real‐time data on pure insoluble cellulose substrates will be useful in attempts to probe the molecular mechanism underlying enzymatic hydrolysis of cellulose. Biotechnol. Bioeng. 2012; 109: 3199–3204. © 2012 Wiley Periodicals, Inc.     

Electrochemical detection of extracellular hydrogen peroxide in Arabidopsis thaliana: a real‐time marker of oxidative stress

An electrochemical approach to directly measure the dynamic process of H₂O₂ release from cultures of Arabidopsis thaliana cells is reported. This approach is based on H₂O₂ oxidation on a Pt electrode in conjunction with continuous measurement of sample pH. For [H₂O₂] <1 mm , calibration plots were linear and the amperometric response of the electrode was maximum at pH 6. At higher concentrations ([H₂O₂] >1 mm ), the amperometric response can be described by Michaelian‐type kinetics and a mathematical expression relating current intensity and pH was obtained to quantitatively determine H₂O₂ concentration. At pH 5.5, the detection limit of the sensor was 3.1 µm (S/N = 3), with a response sensitivity of 0.16 Am ^?1 cm^?2 and reproducibility was within 6.1% in the range 1–5 × 10^?3 m (n = 5). Cell suspensions under normal physiological conditions had a pH between 5.5–5.7 and H₂O₂ concentrations in the range 7.0–20.5 µm (n = 5). The addition of exogenous H₂O₂, as well as other potential stress stimuli, was made to the cells and the change in H₂O₂ concentration was monitored. This real‐time quantitative H₂O₂ analysis is a potential marker for the evaluation of oxidative stress in plant cell cultures.     

Optimization of the HyPer sensor for robust real‐time detection of hydrogen peroxide in the rice blast fungus

Reactive oxygen species (ROS) production and breakdown have been studied in detail in plant‐pathogenic fungi, including the rice blast fungus, Magnaporthe oryzae; however, the examination of the dynamic process of ROS production in real time has proven to be challenging. We resynthesized an existing ROS sensor, called HyPer, to exhibit optimized codon bias for fungi, specifically Neurospora crassa, and used a combination of microscopy and plate reader assays to determine whether this construct could detect changes in fungal ROS during the plant infection process. Using confocal microscopy, we were able to visualize fluctuating ROS levels during the formation of an appressorium on an artificial hydrophobic surface, as well as during infection on host leaves. Using the plate reader, we were able to ascertain measurements of hydrogen peroxide (H₂O₂) levels in conidia as detected by the MoHyPer sensor. Overall, by the optimization of codon usage for N. crassa and related fungal genomes, the MoHyPer sensor can be used as a robust, dynamic and powerful tool to both monitor and quantify H₂O₂ dynamics in real time during important stages of the plant infection process.     

Multiplex real‐time PCR assays for detection of four seedborne spinach pathogens

Aims

To develop multiplex TaqMan real‐time PCR assays for detection of spinach seedborne pathogens that cause economically important diseases on spinach.

Methods and Results

Primers and probes were designed from conserved sequences of the internal transcribed spacer (for Peronospora farinosa f. sp. spinaciae and Stemphylium botryosum), the intergenic spacer (for Verticillium dahliae) and the elongation factor 1 alpha (for Cladosporium variabile) regions of DNA. The TaqMan assays were tested on DNA extracted from numerous isolates of the four target pathogens, as well as a wide range of nontarget, related fungi or oomycetes and numerous saprophytes commonly found on spinach seed. Multiplex real‐time PCR assays were evaluated by detecting two or three target pathogens simultaneously. Singular and multiplex real‐time PCR assays were also applied to DNA extracted from bulked seed and single spinach seed.

Conclusions

The real‐time PCR assays were species‐specific and sensitive. Singular or multiplex real‐time PCR assays could detect target pathogens from both bulked seed samples as well as single spinach seed.

Significance and Impact of the Study

The freeze‐blotter assay that is currently routinely used in the spinach seed industry to detect and quantify three fungal seedborne pathogens of spinach (C. variabile, S. botryosum and V. dahliae) is quite laborious and takes several weeks to process. The real‐time PCR assays developed in this study are more sensitive and can be completed in a single day. As the assays can be applied easily for routine seed inspections, these tools could be very useful to the spinach seed industry.     

Development and comparison of SYBR Green quantitative real‐time PCR assays for detection and enumeration of sulfate‐reducing bacteria in stored swine manure

Aims: To develop and evaluate primer sets targeted to the dissimilatory sulfite reductase gene (dsrA) for use in quantitative real‐time PCR detection of sulfate‐reducing bacteria (SRB) in stored swine manure. Methods and Results: Degenerate primer sets were developed to detect SRB in stored swine manure. These were compared with a previously reported primer set, DSR1F+ and DSR‐R, for their coverage and ability to detect SRB communities in stored swine manure. Sequenced clones were most similar to Desulfovibrio sp. and Desulfobulbus sp., and these SRB populations differed within different manure ecosystems. Sulfur content of swine diets was shown to affect the population of Desulfobulbus‐like Group 1 SRB in manure. Conclusions: The newly developed assays were able to enumerate and discern different groups of SRB, and suggest a richly diverse and as yet undescribed population of SRB in swine manure. Significance and Impact of the Study: The PCR assays described here provide improved and efficient molecular tools for quantitative detection of SRB populations. This is the first study to show population shifts of SRB in swine manure, which are a result of either the effects of swine diets or the maturity of the manure ecosystem.     

A real‐time PCR assay for improved rapid,specific detection of Cryphonectria parasitica

Cryphonectria parasitica, an ascomycete fungus, is the causal agent of chestnut blight. This highly destructive disease of chestnut trees causes significant losses, and is therefore a regulated pathogen in Europe. Existing methods for the detection of C. parasitica include morphological identification following culturing, or PCR; however, these are time‐consuming resulting in delays to diagnosis. To allow improved detection, a new specific real‐time PCR assay was designed to detect C. parasitica directly from plant material and fungal cultures, and was validated according to the European Plant Protection Organisation (EPPO) standard PM 7/98. The analytical specificity of the assay was tested extensively using a panel of species taxonomically closely related to Cryphonectria, fungal species associated with the hosts and healthy plant material. The assay was found to be specific to C. parasitica, whilst the analytical sensitivity of the assay was established as 2 pg µL^?1 of DNA. Comparative testing of 63 samples of naturally infected plant material by the newly developed assay and traditional morphological diagnosis demonstrated an increased diagnostic sensitivity when using the real‐time PCR assay. Furthermore the assay is able to detect both virulent and hypovirulent strains of C. parasitica. Therefore the new real‐time PCR assay can be used to provide reliable, rapid, specific detection of C. parasitica to prevent the accidental movement of the disease and to monitor its spread.     

Non‐invasive optical method for real‐time assessment of intracorneal riboflavin concentration and efficacy of corneal cross‐linking

Keratoconus is the primary cause of corneal transplantation in young adults worldwide. Riboflavin/UV‐A corneal cross‐linking may effectively halt the progression of keratoconus if an adequate amount of riboflavin enriches the corneal stroma and is photo‐oxidated by UV‐A light for generating additional cross‐linking bonds between stromal proteins and strengthening the biomechanics of the weakened cornea. Here we reported an UV‐A theranostic prototype device for performing corneal cross‐linking with the ability to assess corneal intrastromal concentration of riboflavin and to estimate treatment efficacy in real time. Seventeen human donor corneas were treated according to the conventional riboflavin/UV‐A corneal cross‐linking protocol. Ten of these tissues were probed with atomic force microscopy in order to correlate the intrastromal riboflavin concentration recorded during treatment with the increase in elastic modulus of the anterior corneal stroma. The intrastromal riboflavin concentration and its consumption during UV‐A irradiation of the cornea were highly significantly correlated (R = 0.79; P = .03) with the treatment‐induced stromal stiffening effect. The present study showed an ophthalmic device that provided an innovative, non‐invasive, real‐time monitoring solution for estimating corneal cross‐linking treatment efficacy on a personalized basis.      

Fluorescence optical detection in situ for real‐time monitoring of cytochrome P450 enzymatic activity of liver cells in multiple microfluidic devices

We describe an in situ fluorescence optical detection system to demonstrate real‐time and non‐invasive detection of reaction products in a microfluidic device while under perfusion within a standard incubator. The detection system is designed to be compact and robust for operation inside a mammalian cell culture incubator for quantitative detection of fluorescent signal from microfluidic devices. When compared to a standard plate reader, both systems showed similar biphasic response curves with two linear regions. Such a detection system allows real‐time measurements in microfluidic devices with cells without perturbing the culture environment. In a proof‐of‐concept experiment, the cytochrome P450 1A1/1A2 activity of a hepatoma cell line (HepG2/C3A) was monitored by measuring the enzymatic conversion of ethoxyresorufin to resorufin. The hepatoma cell line was embedded in Matrigel^TM construct and cultured in a microfluidic device with medium perfusion. The response of the cells, in terms of P450 1A1/1A2 activity, was significantly different in a plate well system and the microfluidic device. Uninduced cells showed almost no activity in the plate assay, while uninduced cells in Matrigel^TM with perfusion in a microfluidic device showed high activity. Cells in the plate assay showed a significant response to induction with 3‐Methylcholanthrene while cells in the microfluidic device did not respond to the inducer. These results demonstrate that the system is a potentially useful method to measure cell response in a microfluidic system. Biotechnol. Bioeng. 2009; 104: 516–525 © 2009 Wiley Periodicals, Inc.     

A quantitative real‐time PCR assay for the detection of Ramularia collo‐cygni from barley (Hordeum vulgare)

Aims: The aim of this study was to develop a real‐time quantitative PCR test to recognize and quantify the DNA levels of the increasingly important barley pathogen Ramularia collo‐cygni. Methods and Results: The method described uses specifically designed primers and a molecular beacon probe based on an internal transcribed spacer (ITS) sequence. Pathogen extracted from barley leaves could be quantified to the picogram level in both leaves showing symptoms of infection and symptomless barley leaves. Conclusions: A relationship between R. collo‐cygni DNA levels and disease symptoms was established in spring barley under natural infection conditions. Significance and Impact of the Study: To our knowledge, this is the first report of a test of this type and makes an important contribution to studies into the life cycle of this pathogen.     

Real‐time and multiplex real‐time polymerase chain reactions for the detection of Bartonella henselae within cat flea,Ctenocephalides felis,samples

Bartonella henselae (Rhizobiales: Bartonellacae), the agent of cat‐scratch disease, is an emerging bacterial pathogen which can be transmitted via infective faecal material of Ctenocephalides felis Bouché (Siphonaptera: Pulicidae). Worldwide, B. henselae has been identified in 1–53% of felines and 2.9–17.4% of fleas. Although culture is the routine method for detection, the procedure is time‐consuming and is rarely used for isolation directly from flea vectors. The current study reports the development of a quantitative real‐time polymerase chain reaction (qPCR) to detect and quantify B. henselae organisms from vector samples. The qPCR is specific and detects as few as 2.5 genome copies. To enable direct quantification of Bartonella organisms in different vector samples, we developed a qPCR to detect C. felis DNA that also acts as an extraction control. Combining both PCRs into a multiplex format validates B. henselae results when sampling flea populations, although there is a reduction in sensitivity. This reduction might be counteracted by a different combination of probe fluorophores.     

Development of a real‐time TaqMan PCR assay for the detection of porcine and bovine Torque teno virus

Aims: The goal of this study was to develop and to optimize molecular tools to detect the presence of Torque teno virus (TTV) in swine and cattle. A novel real‐time polymerase chain reaction (PCR) using a TaqMan probe was developed to detect both genogroups of TTV strains. Methods and Results: Oligonucleotide primers and hybridization probes were designed based on sequence analysis of the noncoding region, a highly conserved part of the genome. The real‐time PCR assay specifically detected bovine and porcine TTV DNA without cross‐amplification of other common pathogens. The assay was compared with conventional PCR and nested‐PCR assays for the detection of porcine genogroups 1 and 2 and bovine TTV on plasma and faecal samples, and the assay was found faster, more reliable and reduced the risk of false positive results. Conclusions: The real‐time PCR assay provided better detection results for the two TTV genogroups in both swine and cattle compared to the conventional PCR assays. Significance and Impact of the Study: This new TaqMan PCR assay will be a useful tool for the detection of animal TTV strains, to evaluate the viral load from animal host and finally to identify the presence of these viruses in the agri‐food continuum.