基于适配体亲和毛细管电泳-激光诱导荧光检测的凝血酶分析

以一种高亲和力适配体作为亲和荧光探针,以自建的毛细管电泳-激光诱导荧光(CE-LIF)检测装置为基础,建立了一种高灵敏、快速测定人凝血酶的方法。荧光标记的凝血酶适配体特异性地与凝血酶结合并形成稳定的凝血酶-适配体复合物,采用CE-LIF对复合物进行分离检测,从而测定凝血酶浓度。探讨了盐离子种类及浓度对适配体与凝血酶结合的影响,并在选定的电泳条件下对凝血酶检测的线性范围、检出限和重现性进行了测定。结果表明,盐离子存在的条件下适配体与凝血酶的亲和力降低,不利于两者的结合;人血清溶液中,凝血酶浓度在0.25～10 nmol/L范围内与复合物峰面积具有良好的线性相关性(r20.991),检出限(S/N3)为55.6 pmol/L;精密度和回收率测定结果均能满足分析的要求。     

High-sensitive determination of human alpha-thrombin by its 29-mer aptamer in affinity probe capillary electrophoresis

ACE technique provides an effective tool for the separation and identification of disease-related biomarkers in clinical analysis. In recent years, a couple of synthetic DNA or RNA oligonucleotides, known as aptamers, rival the specificity and affinity for targets to antibodies and are employed as one kind of powerful affinity probe in ACE. In this work, based on high affinity between antithrombin aptamer and thrombin (their dissociation constant is 0.5 nM), a carboxyfluorescein-labeled 29-nucleotide (nt) aptamer (F29-mer) was used and an aptamer-based affinity probe CE (aptamer-based APCE) method was successfully established for high-sensitive detection and quantitative analysis of thrombin. Experimental conditions including incubation temperature and time, buffer composition, and concentration of cations were investigated and optimized. Under the optimized condition, the linear range was from 0 to 400 nM and the LOD was 2 nM (74 ng/mL, S/N = 3), i.e., 40 amol, both in running buffer and in 5% v/v human serum. This LOD is the lowest one than those achieved by the previous APCE methods but based on a 15-mer aptamer. This approach offers a promising method for the rapid, selective, and sensitive detection of thrombin in practical utility. Further binding experiments using one carboxyfluorescein-labeled aptamer and the other nonlabeled aptamer or vice versa were carried out to deduce the formation of ternary complex when these two aptamers coexisted in the free solution with thrombin.     

Highly sensitive determination of recombinant human erythropoietin-α in aptamer-based affinity probe capillary electrophoresis with laser-induced fluorescence detection

Recombinant human erythropoietin-α (rHuEPO-α) has been widely used in clinic for anemia treatment. The detection and quantification of rHuEPO-α is essential for monitoring this widespread recombinant glycoprotein pharmaceutical. In this paper, we developed a new affinity probe capillary electrophoresis/laser-induced fluorescence (APCE/LIF) method for the detection of rHuEPO-α by using a specific single-stranded DNA aptamer probe for the first time. In this method, the complex of aptamer-rHuEPO-α and the free aptamer can be well separated and identified by their migration and fluorescence intensity after systematic optimization. The existence of sodium cation in the sample buffer and running buffer played a critical role for stabilizing complex and enhancing the separation efficiency, additionally, suitable high voltage and sample buffer additives were also important for improving the peak height of the complex. Under the optimized conditions, the method was successfully applied for the quantification of rHuEPO-α in physiological buffer, artificial urine and human serum. The linear range for rHuEPO-α was from 0.2 to 100 nM and the limit of detection was 0.2 nM (i.e. 7.4 ng/mL). Further binding experiments using fluorescein isothiocyanate-labeled rHuEPO-α (F-rHuEPO-α) and N-deglycosylated F-rHuEPO-α demonstrated that the oligosaccharides moiety was of importance in the specific interaction between rHuEPO-α and its aptamer.     

A label-free and high sensitive aptamer biosensor based on hyperbranched polyester microspheres for thrombin detection

In this paper, we have synthesized hyperbranched polyester microspheres with carboxylic acid functional groups (HBPE-CA) and developed a label-free electrochemical aptamer biosensor using thrombin-binding aptamer (TBA) as receptor for the measurement of thrombin in whole blood. The indium tin oxide (ITO) electrode surface modified with HBPE-CA microspheres was grafted with TBA, which has excellent binding affinity and selectivity for thrombin. Binding of the thrombin at the modified ITO electrode surface greatly restrained access of electrons for a redox probe of [Fe(CN)₆]^3−/4−. Moreover, the aptamer biosensor could be used for detection of thrombin in whole blood, a wide detection range (10 fM–100 nM) and a detection limit on the order of 0.90 fM were demonstrated. Control experiments were also carried out by using bull serum albumin (BSA) and lysozyme in the absence of thrombin. The good stability and repeatability of this aptamer biosensor were also proved. We expect that this demonstration will lead to the development of highly sensitive label-free sensors based on aptamer with lower cost than current technology. The integration of the technologies, which include anticoagulant, sensor and nanoscience, will bring significant input to high-performance biosensors relevant to diagnostics and therapy of interest for human health.     

Rapid determination of total hardness in water using fluorescent molecular aptamer beacon

A double-labelled synthetic oligonucleotide is used as a fluorescent molecular aptamer beacon for the reagentless determination of total hardness in tap and bottled waters. Modified thrombin binding aptamer (5′-NH-C3-GGTTGGTGTGGTTGG-C3-SH-3′) carrying 6-carboxyfluorescein (FAM) and 7-amino-4-methyl-coumarin labels at 5′ and 3′, respectively, was used for the simultaneous combined measurement of Mg²⁺ and Ca²⁺ cations. Interference from the K⁺ cation is eliminated via selective tuning of the assay conditions, increasing the temperature beyond the melting point of the potassium-stabilised quadruplex facilitating its liberation from the quadruplex, whilst maintaining the integrity of the magnesium/calcium-stabilised structure. No interference from other cations found in tap or bottled water was observed. The detection limit of the aptamer beacon is 0.04 mmol L⁻¹, with a dynamic linear range of 0-0.5 μM and is very reproducible, with an R.S.D. = 8%, n = 3. The fluorescent molecular beacon is applied to the determination of total hardness in tap and bottled waters and its’ performance compared to that of the standard method of complexiometric titration and atomic absorption spectroscopy, with an excellent correlation observed. Further work is focused on the immobilization of the aptamer for the development of a re-usable fluorescent/electrochemical aptasensor, for the determination of water hardness.     

Fluorescence polarization detection for affinity capillary electrophoresis

Affinity capillary electrophoresis (ACE) with laser-induced fluorescence polarization (LIFP) detection is described, with examples of affinity interaction studies. Because fluorescence polarization is sensitive to changes in the rotational motion arising from molecular association or dissociation, ACE-LIFP is capable of providing information on the formation of affinity complexes prior to or during CE separation. Unbound, small fluorescent probes generally have little fluorescence polarization because of rapid rotation of the molecule in solution. When the small fluorescent probe is bound to a larger affinity agent, such as an antibody, the fluorescence polarization (and anisotropy) increases due to slower motion of the much larger complex molecule in the solution. Fluorescence polarization results are obtained by simultaneously measuring fluorescence intensities of vertical and horizontal polarization planes. Applications of CE-LIFP to both strong and weak binding systems are discussed with antibody-antigen and DNA-protein binding as examples. For strong affinity binding, such as between cyclosporine and its antibody, complexes are formed prior to CE-LIFP analysis. For weaker binding, such as between single-stranded DNA and its binding protein, the single-stranded DNA binding protein is added to the CE separation buffer to enhance dynamic formation of affinity complexes. Both fluorescence polarization (and anisotropy) and mobility shift results are complementary and are useful for immunoassays and binding studies.     

A sensitive fluorescence anisotropy method for detection of lead (II) ion by a G-quadruplex-inducible DNA aptamer

Sensitive and selective detection of Pb²⁺ is of great importance to both human health and environmental protection. Here we propose a novel fluorescence anisotropy (FA) approach for sensing Pb²⁺ in homogeneous solution by a G-rich thrombin binding aptamer (TBA). The TBA labeled with 6-carboxytetramethylrhodamine (TMR) at the seventh thymine nucleotide was used as a fluorescent probe for signaling Pb²⁺. It was found that the aptamer probe had a high FA in the absence of Pb²⁺. This is because the rotation of TMR is restricted by intramolecular interaction with the adjacent guanine bases, which results in photoinduced electron transfer (PET). When the aptamer probe binds to Pb²⁺ to form G-quadruplex, the intramolecular interaction should be eliminated, resulting in faster rotation of the fluorophore TMR in solution. Therefore, FA of aptamer probe is expected to decrease significantly upon binding to Pb²⁺. Indeed, we observed a decrease in FA of aptamer probe upon Pb²⁺ binding. Circular dichroism, fluorescence spectra, and fluorescence lifetime measurement were used to verify the reliability and reasonability of the sensing mechanism. By monitoring the FA change of the aptamer probe, we were able to real-time detect binding between the TBA probe and Pb²⁺. Moreover, the aptamer probe was exploited as a recognition element for quantification of Pb²⁺ in homogeneous solution. The change in FA showed a linear response to Pb²⁺ from 10 nM to 2.0 μM, with 1.0 nM limit of detection. In addition, this sensing system exhibited good selectivity for Pb²⁺ over other metal ions. The method is simple, quick and inherits the advantages of aptamer and FA.     

Label-free aptamer-based chemiluminescence detection of adenosine

We have developed a novel sensitive chemiluminescence (CL) aptasensor for the target assay as exemplified by using adenosine as a model target. In this work, we have demonstrated the signaling mechanism to make detection based on magnetic separation and 3,4,5-trimethoxyl-phenylglyoxal (TMPG), a special CL reagent as the signaling molecule, which reacts instantaneously with guanine nucleobases (G) of adenosine-binding aptamer strands. Briefly, amino-functioned capture DNA sequences are immobilized on the surface of carboxyl-modified magnetic beads, and then hybridized with label-free G-rich (including 15 guanine nucleobases) adenosine-binding aptamer strands to form our CL aptasensor. Upon the introduction of adenosine, the aptamer on the surface of magnetic beads is triggered to make structure switching to the formation of the adenosine/aptamer complex. Consequently, G-rich aptamer strands are forced to dissociate from magnetic beads sensing interface, resulting in a decrease of CL signal. The decrement of peak signal is proportional to the amount of adenosine. The effects of the amounts of capture DNA, aptamer, magnetic beads are investigated and optimized. It was found that the CL intensity had a linear dependency on the concentration of adenosine in the range of 4 × 10⁻⁷ to 1 × 10⁻⁵ M. With a low detection limit of 8 × 10⁻⁸ M and simplicity in CL detection, this novel technique will offer a great promise for future target/aptamer analysis.     

Enzymatic cleavage and mass amplification strategy for small molecule detection using aptamer-based fluorescence polarization biosensor

Fluorescence polarization (FP) assays incorporated with fluorophore-labeled aptamers have attracted great interest in recent years. However, detecting small molecules through the use of FP assays still remains a challenge because small-molecule binding only results in negligible changes in the molecular weight of the fluorophore-labeled aptamer. To address this issue, we herein report a fluorescence polarization (FP) aptamer assay that incorporates a novel signal amplification strategy for highly sensitive detection of small molecules. In the absence of adenosine, our model target, free FAM-labeled aptamer can be digested by nuclease, resulting in the release of FAM-labeled nucleotide segments from the dT-biotin/streptavidin complex with weak background signal. However, in the presence of target, the FAM-labeled aptamer–target complex protects the FAM-labeled aptamer from nuclease cleavage, allowing streptavidin to act as a molar mass amplifier. The resulting increase in molecular mass and FP intensity of the aptamer–target complex provides improved sensitivity for concentration measurement. The probe could detect adenosine from 0.5 μM to 1000 μM, with a detection limit of 500 nM, showing that the sensitivity of the probe is superior to aptamer-based FP approaches previously reported for adenosine. Importantly, FP could resist environmental interferences, making it useful for complex biological samples without any tedious sample pretreatments. Our results demonstrate that this dual-amplified, aptamer-based strategy can be used to design fluorescence polarization probes for rapid, sensitive, and selective measurement of small molecules in complicated biological environment.     

Electrochemiluminescence biosensor for the assay of small molecule and protein based on bifunctional aptamer and chemiluminescent functionalized gold nanoparticles

An electrochemiluminescence (ECL) biosensor for simultaneous detection of adenosine and thrombin in one sample based on bifunctional aptamer and N-(aminobutyl)-N-(ethylisoluminol) functionalized gold nanoparticles (ABEI-AuNPs) was developed. A streptavidin coated gold nanoparticles modified electrode was utilized to immobilize biotinylated bifunctional aptamer (ATA), which consisted of adenosine and thrombin aptamer. The ATA performed as recognition element of capture probe. For adenosine detection, ABEI-AuNPs labeled hybridization probe with a partial complementary sequence of ATA reacted with ATA, leading to a strong ECL response of N-(aminobutyl)-N-(ethylisoluminol) enriched on ABEI-AuNPs. After recognition of adenosine, the hybridization probe was displaced by adenosine and ECL signal declined. The decrease of ECL signal was in proportion to the concentration of adenosine over the range of 5.0 × 10⁻¹²–5.0 × 10⁻⁹ M with a detection limit of 2.2 × 10⁻¹² M. For thrombin detection, thrombin was assembled on ATA modified electrode via aptamer–target recognition, another aptamer of thrombin tagged with ABEI-AuNPs was bounded to another reactive site of thrombin, producing ECL signals. The ECL intensity was linearly with the concentration of thrombin from 5 × 10⁻¹⁴ M to 5 × 10⁻¹⁰ M with a detection limit of 1.2 × 10⁻¹⁴ M. In the ECL biosensor, adenosine and thrombin can be detected when they coexisted in one sample and a multi-analytes assay was established. The sensitivity of the present biosensor is superior to most available aptasensors for adenosine and thrombin. The biosensor also showed good selectivity towards the targets. Being challenged in real plasma sample, the biosensor was confirmed to be a good prospect for multi-analytes assay of small molecules and proteins in biological samples.     

Novel application of fluorescence coupled capillary electrophoresis to resolve the interaction between the G‐quadruplex aptamer and thrombin

The dynamic binding status between the thrombin and its G‐quadruplex aptamers and the stability of its interaction partners were probed using our previously established fluorescence‐coupled capillary electrophoresis method. A 29‐nucleic acid thrombin binding aptamer was chosen as a model to study its binding affinity with the thrombin ligand. First, the effects of the cations on the formation of G‐quadruplex from unstructured 29‐nucleic acid thrombin binding aptamer were examined. Second, the rapid binding kinetics between the thrombin and 6‐carboxyfluorescein labeled G‐quadruplex aptamer was measured. Third, the stability of G‐quadruplex aptamer–thrombin complex was also examined in the presence of the interfering species. Remarkably, it was found that the complementary strand of 29‐nucleic acid thrombin binding aptamer could compete with G‐quadruplex aptamer and thus disassociated the G‐quadruplex structure into an unstructured aptamer. These data suggest that our in‐house established fluorescence‐coupled capillary electrophoresis assay could be applied to binding studies of the G‐quadruplex aptamers, thrombin, and their ligands, while overcoming the complicated and costly approaches currently available.     

A highly sensitive fluorescence resonance energy transfer aptasensor for staphylococcal enterotoxin B detection based on exonuclease-catalyzed target recycling strategy

An ultrasensitive fluorescence resonance energy transfer (FRET) bioassay was developed to detect staphylococcal enterotoxin B (SEB), a low molecular exotoxin, using an aptamer-affinity method coupled with upconversion nanoparticles (UCNPs)-sensing, and the fluorescence intensity was prominently enhanced using an exonuclease-catalyzed target recycling strategy. To construct this aptasensor, both fluorescence donor probes (complementary DNA₁–UCNPs) and fluorescence quencher probes (complementary DNA₂–Black Hole Quencher₃ (BHQ₃)) were hybridized to an SEB aptamer, and double-strand oligonucleotides were fabricated, which quenched the fluorescence of the UCNPs via FRET. The formation of an aptamer–SEB complex in the presence of the SEB analyte resulted in not only the dissociation of aptamer from the double-strand DNA but also both the disruption of the FRET system and the restoration of the UCNPs fluorescence. In addition, the SEB was liberated from the aptamer–SEB complex using exonuclease I, an exonuclease specific to single-stranded DNA, for analyte recycling by selectively digesting a particular DNA (SEB aptamer). Based on this exonuclease-catalyzed target recycling strategy, an amplified fluorescence intensity could be produced using different SEB concentrations. Using optimized experimental conditions produced an ultrasensitive aptasensor for the detection of SEB, with a wide linear range of 0.001–1 ng mL⁻¹ and a lower detection limit (LOD) of 0.3 pg mL⁻¹ SEB (at 3σ). The fabricated aptasensor was used to measure SEB in a real milk samples and validated using the ELISA method. Furthermore, a novel aptasensor FRET assay was established for the first time using 30 mol% Mn²⁺ ions doped NaYF₄:Yb/Er (20/2 mol%) UCNPs as the donor probes, which suggests that UCNPs are superior fluorescence labeling materials for food safety analysis.     

Aptamer-functionalized solid phase microextraction–liquid chromatography/tandem mass spectrometry for selective enrichment and determination of thrombin

In this publication, a novel solid phase microextraction (SPME) coating functionalized with a DNA aptamer for selective enrichment of a low abundance protein from diluted human plasma is described. This approach is based on the covalent immobilization of an aptamer ligand on electrospun microfibers made with the hydrophilic polymer poly(acrylonitrile-co-maleic acid) (PANCMA) on stainless steel rods. A plasma protein, human α-thrombin, was employed as a model protein for selective extraction by the developed Apt-SPME probe, and the detection was carried out with liquid chromatography/tandem mass spectrometry (LC–MS/MS). The SPME probe exhibited highly selective capture, good binding capacity, high stability and good repeatability for the extraction of thrombin. The protein selective probe was employed for direct extraction of thrombin from 20-fold diluted human plasma samples without any other purification. The Apt-SPME method coupled with LC–MS/MS provided a good linear dynamic range of 0.5–50 nM in diluted human plasma with a good correlation coefficient (R² = 0.9923), and the detection limit of the proposed method was found to be 0.30 nM. Finally, the Apt-SPME coupled with LC–MS/MS method was successfully utilized for the determination of thrombin in clinical human plasma samples. One shortcoming of the method is its reduced efficiency in undiluted human plasma compared to the standard solution. Nevertheless, this new aptamer affinity-based SPME probe opens up the possibility of selective enrichment of a given targeted protein from complex sample either in vivo or ex vivo.     

Simultaneously fluorescence detecting thrombin and lysozyme based on magnetic nanoparticle condensation

In this protocol, a fluorescent aptasensor based on magnetic separation for simultaneous detection thrombin and lysozyme was proposed. Firstly, one of the anti-thrombin aptamer and the anti-lysozyme aptamer were individually immobilized onto magnetic nanoparticles, acting as the protein captor. The other anti-thrombin aptamer was labeled with rhodamine B and the anti-lysozyme aptamer was labeled with fluorescein, employing as the protein report. By applying the sandwich detection strategy, the fluorescence response at 515 nm and 578 nm were respectively corresponding to lysozyme and thrombin with high selectivity and sensitivities. The fluorescence intensity was individually linear with the concentration of thrombin and lysozyme in the range of 0.13-4 nM and 0.56-12.3 nM, and the detection limits were 0.06 nM of thrombin and 0.2 nM of lysozyme, respectively. The preliminary study on simultaneous detection of thrombin and lysozyme in real plasma samples was also performed. It shows that the proposed approach has the good character for simultaneous multiple protein detection.     

Detection of thrombin using an excimer aptamer switch labeled with dual pyrene molecules

We constructed an excimer aptamer probe containing one pyrene molecule at each end of a DNA aptamer to achieve the detection of thrombin, which binds to the heparin-binding site of thrombin with high binding affinity. The specific binding of thrombin to the excimer aptamer probe brought the two pyrene molecules at the termini of the duplex of the aptamer into close proximity, generating an excimer. The excimer emitted a distinct fluorescence peak, and fluorometric measurement of excimer allowed the sensitive detection of thrombin. The effects of experimental conditions like pH, ionic strength, and cations were investigated and optimized. The detection limit for thrombin was about 42 pM. This aptamer switch has potential in the study of molecular interactions and protein sensing with other switch-based detection strategy.

Aptamer-quantum dots conjugates-based ultrasensitive competitive electrochemical cytosensor for the detection of tumor cell

A novel competitive electrochemical cytosensor was reported by using aptamer (Apt)-quantum dots (Qdots) conjugates as a platform for tumor cell recognition and detection. The complementary DNA (cDNA), aptamer and Qdots could be assembled to the gold electrode surface. When the target cells existed, they could compete with cDNA to bind with Apt-Qdots conjugates based on the specific recognition of aptamer to MUC1 protein overexpressed on the cell surface, which resulted in the denaturation of double-stranded DNA structure and the release of the Apt-Qdots conjugates from the electrode. Electrochemical stripping measurement was then employed to determine the Cd²⁺ concentration in Qdots left at the electrode. The peak current was inversely proportional to the logarithmic value of cell concentration ranging from 1.0 × 10² to 1.0 × 10⁶ cells mL⁻¹ with a detection limit of 100 cells mL⁻¹. Meanwhile, the recognition of aptamer to the target cells could be clearly observed through the strong fluorescence from Qdots. This is an example of the combination of aptamer and nanoparticles for the application of cell analysis, which is essential to cancer diagnosis and therapy.     

Feasibility of gymnodimine and 13-desmethyl C spirolide detection by fluorescence polarization using a receptor-based assay in shellfish matrixes

The detection of toxins in shellfish through reliable methods is essential for human health preservation and prevention of economic losses in the aquaculture industry. Although no human intoxication has been unequivocally linked to gymnodimines or spirolides, these phycotoxins are highly toxic by intraperitoneal injection causing false positives in lipophilic toxin detection by the mouse bioassay. Based on the detection of molecular interactions by fluorescence polarization an inhibition assay was developed using fluorescent α-bungarotoxin and nicotinic acetylcholine receptor-enriched membranes of Torpedo marmorata to detect gymnodimine and 13-desmethyl C spirolide. Both toxins, classified into the cyclic imine group, inhibit the interaction of α-bungarotoxin with Torpedo nicotinic acetylcholine receptors in the nM range. In this study we analyze the matrix effect of four shellfish species on the fluorescence polarization assay. Mussels, clams, cockles and scallops were extracted with acetone and sequentially partitioned with n-hexane and chloroform. The interference of these shellfish extracts with the α-bungarotoxin fluorescence or its binding to the nicotinic acetylcholine receptor was lower than 11%. The average recovery rates of gymnodimine and 13-desmethyl C spirolide using these solvents were 90.6 ± 7.8% and 89.6 ± 3.2%, respectively with variations among species. The quantification range of this fluorescence polarization assay for gymnodimine and 13-desmethyl C spirolide in all tested species was 80-2000 μg kg⁻¹ and 85-700 μg kg⁻¹ of shellfish meat, respectively. This assay format can be used to detect gymnodimine and 13-desmethyl C spirolide in shellfish as a screening assay.     

A novel optical thrombin aptasensor based on magnetic nanoparticles and split DNAzyme

In this paper, we report a novel and sensitive optical sensing protocol for thrombin detection based on magnetic nanoparticles (MNPs) and thrombin aptamer, employing split HRP-mimicking DNAzyme halves as its sensing element, which can catalyze the H₂O₂-mediated oxidation of the colorless ABTS into a blue-green product. A single nucleotide containing the recognition element and sensing element is utilized in our protocol. The specific recognition of thrombin and its aptamer leads to the structure deformation of the DNA strands and causes the split of the DNAzyme halves. Therefore, the decrease of absorption spectra can be recorded by the UV–visible Spectrophotometer. DNA-coated MNPs are utilized to separate the interferential materials from the analyst, thus making this assay can be applied in the detection of thrombin in complex samples, such as human plasma. This original, sensitive and cost-effective assay showed favorable recognition for thrombin. The absorbance signals with the concentration of thrombin over a range from 0.5 to 20 nM and the detection limit of thrombin was 0.5 nM. The controlled experiments showed that thrombin signal was not interfered in the presence of other co-existence proteins.     

Terphenyl based ‘Turn On’ fluorescent sensor for mercury

New terphenyl-based derivative 4 with pyrene as a fluorophore has been synthesized and examined for its cation recognition abilities toward various cations by NMR and fluorescence spectroscopy. The results show that it has very high binding affinity (log β = 5.12) and selectivity for mercury. A fluorescence enhancement of 375% was observed for the 4-Hg²⁺ system in THF. A Hg²⁺ selective electrode (ISE) was also formed which showed excellent selectivity over all the other cations tested. The lower limit of detection is 2.1 × 10⁻⁶ M.     

Piezoelectric affinity sensors for cocaine and cholinesterase inhibitors

We report here the development of piezoelectric affinity sensors for cocaine and cholinesterase inhibitors based on the formation of affinity complexes between an immobilized cocaine derivative and an anti-cocaine antibody or cholinesterase. For both binding reactions benzoylecgonine-1,8-diamino-3,4-dioxaoctane (BZE-DADOO) was immobilized on the surface of the sensor. For immobilization, pre-conjugated BZE-DADOO with 11-mercaptomonoundecanoic acid (MUA) via 2-(5-norbornen-2,3-dicarboximide)-1,1,3,3-tetramethyluronium-tetrafluoroborate (TNTU) allowed the formation of a chemisorbed monolayer on the piezosensor surface.The detection of cocaine was based on a competitive assay. The change of frequency measured after 300 s of the binding reaction was used as the signal. The maximum binding of the antibody resulted in a frequency decrease of 35 Hz (with an imprecision 3%, n = 3) while the presence of 100 pmol l⁻¹ cocaine decreased the binding by 11%. The limit of detection was consequently below 100 pmol l⁻¹ for cocaine. The total time of one analysis was 15 min.This BZE-DADOO-modified sensor was adapted for the detection of organophosphates. BZE-DADOO - a competitive inhibitor - served as binding element for cholinesterase in a competitive assay.