Derivatization, stabilization and detection of biogenic amines by cyclodextrin-modified capillary electrophoresis-laser-induced fluorescence detection.

o-Phthalaldehyde (OPA) derivatives of eight biogenic amines were stabilized at 5 degrees C by forming inclusion complexes with methyl-beta-cyclodextrin (MBCD). The derivatives were separated and detected by cyclodextrin-modified capillary electrophoresis (CE) with UV or laser-induced fluorescence (LIF) detection. Using a borate buffer, pH 9.0 consisting of ethanol and a mixture of negatively charged sulfobutylether-beta-cyclodextrin and neutral MBCD, baseline separation of the eight OPA derivatives was achieved within 25 min with high separation efficiencies. The detection limits (S/N=3) obtained by UV and LIF detection were determined to be 10 microM and 0.250 microM, respectively. Glutamic acid was added after the initial derivatization step to neutralize residual OPA which otherwise caused a significant interference, particularly when analysis was performed around the detection limit of the OPA derivatives. Important biogenic amines in fish, wine and urine were then derivatized and determined by CE-LIF. In the case of sole and rainbow trout, the results obtained were validated by an enzymatic assay using putrescine oxidase.

Monitoring motility, spreading, and mortality of adherent insect cells using an impedance sensor.

An emerging sensor technology referred to as electric cell-substrate impedance sensing (ECIS) has been extended for monitoring the behavior of insect cells including attachment, motility, and mortality. In ECIS, adherent cells were cultured on an array of eight small gold electrodes deposited on the bottom of tissue culture wells and immersed in a culture medium. Upon the attachment and spreading of cells on the gold electrode, the impedance increased because the cells acted as insulating particles to restrict the current flow. Experimental data revealed that insect cells interacted differently with various proteins used to precoat the gold electrode with concanavalin A as the best promoter to accelerate the rate of cell attachment. After the cells were fully spread, the measured impedance continued to fluctuate to reflect the constant motion and metabolic activity of the cells. As the cell behavior was sensitive to external chemicals, the applicability of ECIS for inhibition assays was demonstrated with HgCl2, trinitrotoluene, trinitrobenzene (TNB), and 2-amino-4,6-dinitrotoluene as model systems. Unlike conventional assays, the quantitative data obtained in this study are taken in real time and in a continuous fashion to depict cell motility and mortality.

Separation of resin acids using cyclodextrin-modified capillary electrophoresis.

A cyclodextrin-modified capillary electrophoretic method has been developed for the analysis of eleven common resin acids using a pH 4.5, 20 mM sodium acetate buffer containing 10% acetonitrile, 20 mM methyl-beta-cyclodextrin (MECD) and 30 mM sulfobutylether-beta-cyclodextrin (SBCD) as buffer modifiers. At pH below their pKa (< 5.7-6.4) the resin acids were virtually unionized and insoluble; however, they formed water-soluble inclusion complexes with MECD (20 mM) or SBCD (30 mM) even at pH 4.5. The analytes were separated in 25 min and, with the exception of two pairs, 12- or 14-chlorodehydroabietic/12,14-dichlorodehydroabietic acid and dehydroabietic/palustric acid, the remaining resin acids were baseline-separated. Analysis time was significantly shortened (< 12 min) at pH 9.25 using 30 mM SBCD and 20 mM MECD in 20 mM sodium borate. Resin acids were baseline-separated with the exception of two pairs, pimaric/sandaracopimaric acid and 12- or 14-chlorodehydroabietic/abietic acid. The addition of 7.5% methanol to the running buffer resolved the abietic acid peak. Both HPLC and micellar capillary electrokinetic chromatography using 20 mM deoxycholic acid, 10% acetonitrile in 20 mM sodium borate, pH 9.25, failed to resolve the resin acids. The simple capillary electrophoretic method developed would be useful for the rapid separation and characterization of several important resin acids in pulp mill effluents and other contaminated samples.

Optimization and characterization of a flow injection electrochemical system for pentachlorophenol assay.

A flow injection (FI) electrochemical detection system has been developed and optimized for the determination of pentachlorophenol (PCP) in contaminated soil. PCP was oxidized to tetrachloro-1,4-benzoquinone (1,4-TCBQ) with a high yield using bis(trifluoroacetoxy)iodobenzene in 0.1 M tartaric acid, pH 2.0, at ambient temperature. Upon rapid reaction with immobilized glucose oxidase, the detection and amplification scheme was completed as the reduced form of 1,4-TCBQ or tetrachloro-1,4-hydroquinone was reoxidized to 1,4-TCBQ at the surface of the glassy carbon electrode (+ 0.40 V vs Ag/AgCl). Rapid electron exchange between the enzyme and its glucose substrate provided a non-rate-limiting current toward the electrode. The FI electrochemical system was linear up to 1 µM oxidized PCP with a detection limit of 10 nM and exhibited a reproducibility of ±0.6% over 165 repeated analyses during 14 h of continuous operation. When applied to PCP-contaminated soil samples, the results obtained from the FI electrochemical system compared well with those of the HPLC standard method.

Developments and applications of biosensors in food analysis.

The food industry needs suitable analytical methods for process and quality control; that is, methods that are rapid, reliable, specific and cost-effective in their provision of information about physical and chemical characteristics of food. Apart from a few important analytes, such as sugars, alcohols, amino acids, flavours and sweeteners, food applications mainly focus on the determination of contaminants. However, very few biosensors play a prominent role in food processing or quality control. Considerable effort must be made to develop biosensors that are inexpensive, reliable, and robust enough to operate under realistic conditions.

On-line monitoring of glucose in mammalian cell culture using a flow injection analysis (FIA) mediated biosensor.

A flow injection analysis (FIA) biosensor system has been developed for on-line determination of glucose during mammalian cell cultivation. The culture sample was peristaltically withdrawn from the bioreactor and after cell separation by a steam sterilizable ceramic microfilter, the filtrate was continuously fed to the FIA mediated-biosensor system at 4 mLh(-1), whereas the cell-containing retentate was recirculated to the bioreactor. In the amperometric biosensor system, glucose oxidase was covalently immobilized onto a preactivated nylon membrane and attached to the sensing area of a platinum working electrode. The enzyme reaction was coupled with the mediator 1,1'-dimethylferricinium (DMFe(+))-cyclodextrin inclusion complex to recycle the reduced glucose oxidase to its original active state. 1,1'-Dimethylferrocene (DMFe) was then reoxidized to DMFe(+) at the surface of the platinum electrode poised at + 0.15 V vs silver/silver chloride. The FIA mediated-biosensor was linear up to 6 mM glucose, with a detection limit of 0.1 mM, and possessed excellent reproducibility (+/- 0.4 %, 95 % confidence interval) over 123 repeated analyses during a 62 h continuous operation. The immobilized glucose oxidase was stable for up to 7 days when applied to glucose measurement during 5-10 day fed-batch cultivation of 293S mammalian cells. The results obtained from the mediated-biosensor system compared well with the hexokinase and HPLC data.

A Combined Chemical and Electrochemical Approach Using Bis(trifluoroacetoxy)iodobenzene and Glucose Oxidase for the Detection of Chlorinated Phenols.

A novel electrocatalytic approach using a chemical reaction and an enzymatic reaction has been developed for the measurement of 18 chlorophenol congeners, including highly chlorinated pollutants such as pentachlorophenol, 2,3,5,6-tetrachlorophenol, 2,3,4,6-tetrachlorophenol, and several trichlorophenols. Chlorophenols were oxidized to chlorobenzoquinones with very high yields using bis(trifluoroacetoxy)iodobenzene in 0.1 M trichloroacetic acid, pH 1.5, at ambient temperature. UV-visible spectrophotometry, cyclic voltammetry, and HPLC have been used to characterize the reaction products and yields. Together with glucose oxidase immobilized on a working glassy carbon electrode (+0.45 V vs Ag/AgCl), chlorinated benzoquinones have been demonstrated to be efficient mediators in a glucose oxidase/glucose system. In this approach, glucose oxidase was readily reduced by excess glucose to provide a non-rate-limiting source of electron flow toward the electrode. The oxidation products of chlorophenols then recycled the reduced glucose oxidase to its active oxidative state, i.e., mediating the rate-limiting electron transfer from the enzyme to the electrode. At pH 3.5, linear behavior of the current response was observed up to 200 nM for all chlorophenol oxidation products. The detection limit of this method for both pentachlorophenol and 2,3,5,6-tetrachlorophenol was about 4 nM, which is close to the maximum allowable contamination level of pentachlorophenol in water samples (2.7 nM). The detection limit obtained for pentachlorophenol could also be considered superior to the result obtained with the PCP immunoassay technology (13.3 nM).

An improved enzymatic assay for glucose determination in blood serum using a 1,1'-dimethylferricinium dye.

1,1'-dimethylferricinium (DMFe+), a stable and pH-insensitive blue dye, was prepared via enzymatic oxidation of a 1,1'dimethyl-ferrocene (DMFe):2-hydroxypropyl-beta-cyclodextrin (HPCD) water-soluble inclusion complex, using bilirubin oxidase immobilized onto porous aminopropyl glass beads via glutaraldehyde activation. In the presence of glucose, DMFe+ was reduced to DMFe by reacting with the reduced glucose oxidase (FADH2), and the absorbance decrease was followed at 650 nm. In acetate pH 5.2 buffer, the response to glucose in blood serum was nonlinear, especially in the low concentration range, because of a competition for the reduced glucose oxidase between the DMFe+ dye and oxygen. At this pH, endogenous ceruloplasmin was also observed to oxidize residual DMFe (16%) in the dye preparation, causing an increase in absorbance at 650 nm. An assay protocol was then developed using maleate buffer, pH 6.5, to overcome these interferences as well as mutarotation of alpha-D-glucose. The results obtained for glucose in the blood serum samples agreed well with those of the reference hexokinase/glucose-6-phosphate dehydrogenase method.

Enzyme reactions in the presence of cyclodextrins: biosensors and enzyme assays.

Cyclodextrins, macrocyclic carbohydrates with apolar internal cavities, can form complexes with, and solubilize many normally water-insoluble compounds. Ferrocene and its derivatives, tetrathiafulvalene and tetramethylbenzidine, can function as redox mediators, but are insoluble in water; when they are complexed with cyclodextrins, they can be used in enzymatic assays and in the construction of mediated biosensors. In addition, the solubilization of polynuclear aromatic hydrocarbons (PAHs), including the potent carcinogen benzo[a]pyrene, by cyclodextrins has enabled the detection of these important environmental contaminants.

A substrate recycling assay for phenolic compounds using tyrosinase and NADH.

A substrate recycling assay for phenolic compounds was developed using tyrosinase, a copper-containing enzyme, in excess NADH. The reaction of various phenols with the enzyme produced an o-quinone, which was then detected by recycling between reactions with the enzyme and NADH. The recycling of quinones by excess NADH to their original reduced forms prevented the problems of subsequent quinone polymerization and product inactivation which occur in nonrecycling assays. Absorbance measurements of the NADH consumption rate enhanced the assay sensitivity for catechol 100-fold compared to nonrecycling o-quinone detection, giving a detection limit of 240 nM. Fluorescence NADH monitoring permitted a 10-fold improvement over absorbance, with a detection limit of 23 nM. The recycling reaction was selective for o-quinones, and no interference was noted for p-quinones or quinoneimines. The two-step oxidation of phenols was observed as an initial lag phase (ca. 10 min), requiring a higher enzyme concentration to achieve the same sensitivity as that for catechol. The procedure was most useful for assaying catechol, 4-chlorocatechol, phenol, p-cresol, and 4-chlorophenol and may provide selective detection of these components in mixtures. Several other derivatives of catechols, including amine derivatives, were also detected, with relative sensitivity being related to substrate activity of the enzyme.

Monitoring the activity of glucose oxidase during the cultivation of Aspergillus niger using novel amperometric sensor with 1, 1'-dimethylferricinium as a mediator.

1, 1'-dimethylferricinium (DMF+), a deep blue, and stable mediator, was prepared from a water-soluble 1, 1'-dimethylferrocene(DMF):2-hydroxypropyl- beta-cyclodextrin complex via enzymatic oxidation using immobilised bilirubin oxidase. This mediator was superior to other soluble ferrocenes, notably carboxyferrocene, in terms of both solubility (110 mM vs 0.5 mM) and oxidation potential (150 mV vs 300 mV against Ag/AgCl). Although the cyclic voltammogram of DMF+ was electrochemically equivalent to DMF, the use of the former resulted in a significantly lower background current (< 10 nA vs 30 nA). Because of its higher solubility, concentrated stock solutions of DMF+ can be prepared and supplied to the electrode. This is of particular importance when the signal is severely limited by the rate at which the working electrode can oxidase DMF to DMF+. A linear response of current versus units of glucose oxidase (GOD) was obtained up to 0.5 unit/ml. The detection limit was estimated to be 0.03 unit/ml and the response time was 2.5 min or less. The amperometric system was used successfully to follow the GOD activity during the growth of Aspergillus niger a well-known GOD producer. The results obtained correlated well with a standard absorbance-based assay using dichlorophenol-indophenol (DCPIP). The KM of GOD for the glucose in the lysate was measured as 38 mM. A reduced response and higher KM (48 mM) of the cell homogenate, compared to the lysate, illustrated the requirement for the DMF+ and glucose to diffuse across the cell membrane to interact with GOD in whole cells.

Application of a novel 1,1'-dimethylferricinium dye for the determination of uric acid in urine.

Water-soluble 2-hydroxypropyl-beta-cyclodextrin (Hp-beta-CyD), a cyclic and nonreducing oligosaccharide was used to enclose a hydrophobic guest molecule 1,1'-dimethylferrocene (DMF) to form a water-soluble yellow complex. At high concentrations (300 mM), Hp-beta-CyD enclosed up to 100 mM DMF. The yellow complex was electrochemically oxidized (platinum vs Ag/AgCl poised at +450 mV) to form a blue dye, 1,1'-dimethylferricinium (DMF+). This is a one-electron transfer process and the ferricinium cation formed exhibited an absorption peak at 650 nm. The concentrated DMF+ was stable for at least 4 mo at 4 degrees C and insensitive to a wide pH variation (pH 2-11). Application of the novel DMF+ complex as a colorimetric dye for the determination of uric acid in urine was successfully demonstrated. The reaction between the dye and uric acid is almost instantaneous and decrease in absorbance caused by the reduction of 1,1'-dimethylferricinium to 1,1'-dimethylferrocene can be followed at 650 nm. The results obtained agreed well with those of the reference reversed-phase HPLC method.

Electrochemical preparation of 1,1'-dimethylferricinium from a water-soluble 1,1'-dimethylferrocene-2-hydroxypropyl-beta-cyclodextrin complex and its applications in enzyme assay.

Water-soluble 2-hydroxypropyl-beta-cyclodextrin (hp-beta-CyD), a cyclic and nonreducing oligosaccharide, was used to enclose the hydrophobic guest molecules ferrocene (FeCp2) and 1,1'-dimethylferrocene (DMFeCp2) to form a water-soluble complex. At high concentrations (300 mM), hp-beta-CyD enclosed up to 100 mM FeCp2 or DMFeCp2. The yellow complexes were electrochemically oxidized (platinum vs Ag/AgCl poised at +450 mV) to form the blue dyes ferricinium (FeCp2+) and 1,1'-dimethylferricinium (DMFeCp2+). This is a one-electron transfer process and the ferricinium cations formed exhibited absorption peaks at 620 and 650 nm, respectively. The concentrated DMFeCp2+ was much more stable (4 months) than the FeCp2+ (2 days) and both oxidized dyes were insensitive to a wide pH variation (pH 2-11). The DMFeCp2+ was reduced easily by various reducing agents such as ascorbic acid, uric acid, and sulfite and exhibited an absorption coefficient of 325 cm-1 M-1. Application of the novel DMFeCp2+ complex as a colorimetric dye for the enzymatic oxidation of glucose, glutamate, lactate, phenylalanine, xanthine, and hypoxanthine was successfully demonstrated. When applied to real samples the results obtained agreed well with those of standard enzymatic assays. The DMFeCp2+ complex could also be utilized to monitor activity of oxidases under saturating substrate concentrations.

An improved FIA biosensor for the determination of aspartame in dietary food products.

A flow injection analysis (FIA) biosensor system was developed for the determination of the artificial sweetener aspartame (L-aspartyl-L-phenylalanine methyl ester). The system consisted of an enzyme column of pronase immobilized on activated arylamine glass beads and a L-amino acid oxidase electrode connected in series. The dipeptide bond of aspartame was cleaved by immobilized pronase to release phenylalanine, which was in turn monitored by the enzyme electrode that used L-amino acid oxidase immobilized on a preactivated nylon membrane in combination with an amperometric electrode (platinum vs silver/silver chloride, 700 mV). The response of the FIA biosensor was linear up to 1 mM aspartame with a lower detection limit of 25 microM and had good reproducibility (rsd 0.3%). The FIA biosensor was stable for at least 30 h of continuous use at Tr. Each assay takes 4 min giving a sample throughput of 15 h-1. When applied to aspartame in dietary food products the results obtained agreed well with those reported by the product manufacturers.

Improvement of the selectivity of an FIA amperometric biosensor system for glucose.

A flow injection analysis (FIA) biosensor system has been developed for the determination of glucose from urine, blood plasma and foodstuffs. Glucose oxidase was immobilized onto porous aminopropyl glass beads via glutaraldehyde activation to form an enzyme column. The hydrogen peroxide released from the conversion of glucose to gluconic acid was monitored by a platinum electrode vs. silver/silver chloride poised at +700 mV. As a novel aspect to the improvement of the selectivity of the biosensor system, an anion exchange column was placed upstream to remove uric acid, ascorbic acid or acetaminophen, three major electroactive interfering substances which usually occur in urine and blood plasma. Among several resins tested, the effective adsorption of uric and ascorbic acids could be accomplished using an acetate anion exchanger, and the selectivity coefficient was pH dependent. The binding of acetaminophen to the resin was much less efficient and, in all cases, the selectivity coefficient was independent of the operating temperature up to 37 degrees C. When applied to real samples, the data obtained by the biosensor system compared well with those of the standard hexokinase assay. The immobilized glucose oxidase could be reused for at least 2000 repeated analyses without loss of its original activity.

Determination of urinary glucose by a flow injection analysis amperometric biosensor and ion-exchange chromatography.

A practical biosensor system has been developed for the determination of urinary glucose using a flow-injection analysis (FIA) amperometric detector and ion-exchange chromatography. Glucose oxidase was immobilized onto porous aminopropyl glass beads via glutaraldehyde activation to form an immobilized enzyme column. On the basis of its negative charge at pH 5.5, endogenous urate in urine samples was effectively retained by an upstream anion-exchange resin column. The biosensor system possessed a sensitivity of 160 +/- 2.4 RU microM-1 (RU or relative unit is defined as 2.86 microV at the detection output) for glucose with a minimum detection level of 10 microM. When applied for the determination of urinary glucose, the result obtained compared very well with that of the widely accepted hexokinase assay. The immobilized glucose oxidase could be reused for more than 1000 repeated analyses without losing its original activity. The reuse of the acetate anion-exchange column before replacement would be about 25-30 analyses. Acetaminophen and ascorbic acid were also effectively adsorbed by the acetate anion exchanger. The introduction of this type of anion exchanger thus greatly improved the selectivity of the FIA biosensor system and fostered its applicability for the determination of glucose in urine samples.

A chemiluminescence fiber-optic biosensor system for the determination of glutamine in mammalian cell cultures.

A chemiluminescence fiber-optic biosensor system has been developed for determining glutamine in hybridoma cell cultures producing monoclonal antibodies against viral surface antigens. Glutaminase and glutamate oxidase (GLO) were immobilized onto aminopropyl glass beads via glutaraldehyde activation separately and packed in a column. Two separate columns containing immobilized GLO and catalase were placed upstream to eliminate endogenous glutamate. In the presence of ferricyanide, luminol reacted with hydrogen peroxide released from the enzymatic reactions to produce a chemiluminescence (CL) light signal which was detected and quantitated with a fiber-optic system. In combination with flow injection analysis it was possible to process samples virtually identically, thus avoiding difficulties in reproducing the CL signal. There was an excellent linear relationship between the CL response and standard glutamine concentration in the range 10(-6) to 10(-3) M. A complete analysis could be performed in 2 min including sampling and washing. Each immobilized enzyme column was stable for at least 300 repeated analyses without any loss of activity. When the biosensor system was used for the determination of glutamine in spent mammalian cell cultures, the values obtained compared well with those of high-performance liquid chromatography, thus validating the applicability of the CL fiber-optic system.

The potential role of biosensors in the food and drink industries.

Despite their apparent potential as analytical tools in the food and drink industries, only a few biosensors are used routinely. This article describes the development of biosensors for these sectors and discusses the technical and economic problems of applying this technology to the monitoring of food and drink products.

An FIA biosensor system for the determination of phosphate.

A flow injection analysis (FIA) biosensor system for the determination of phosphate was constructed using immobilized nucleoside phosphorylase and xanthine oxidase and an amperometric electrode (platinum vs silver/silver chloride, polarized at 0.7 V). When a phosphate-containing sample was injected into the detection cell, phosphate reacted with inosine in the carrier buffer to produce hypoxanthine and ribose-1-phosphate in the presence of nucleoside phosphorylase. Hypoxanthine was then oxidized by xanthine oxidase to uric acid and hydrogen peroxide, which were both detected by the amperometric electrode. The response of the FIA biosensor system was linear up to 100 microM phosphate, with a minimum detectable concentration of 1.25 microM phosphate. Each assay could be performed in 5-6 min and the system could be used for about 160 repeated analyses. This system was applicable for the determination of phosphate in various food products and plasma, and the results obtained agreed well with those of the enzymatic assay.

Development of a biosensor for assaying postmortem nucleotide degradation in fish tissues.

An enzyme sensor system has been developed to assess the freshness level in fish tissue. The system was designed to measure the K value, the concentration ratio of [Hx + HxR] and [Hx + HxR + IMP], where Hx, HxR, and IMP are hypoxanthine, inosine and inosine-5'-monophosphate, respectively. The [Hx + HxR] concentration in tissue extract was measured by nucleoside phosphorylase and xanthine oxidase immobilized on a preactivated nylon membrane and attached to the tip of a polarographic electrode. The electrode amperometrically detected the products of degradation, hydrogen peroxide and uric acid. For determination of [IMP + HxR + Hx], IMP was first converted to HxR by nucleotidase immobilized on the wall of a polystyrene tube. The enzyme electrode consisting of nucleoside phosphorylase and xanthine oxidase provided excellent reproducible results for at least 40 repeated assays and immobilized nucleotidase was good for at least 40 assays as well. The K value for each sample could be determined in ca. 10 min. When applied to K value measurements in several fish meats, the results obtained agreed well with those obtained by the conventional enzymatic method.