Irreversible enzyme-shuttle immunoassay

The concept of a competitive enzyme immunoassay that utilizes simultaneously the bound and the free analyte-enzyme conjugate (heterobifunctional conjugate) for signal generation in response to varying analyte concentrations in samples has been investigated. Two antigenic sites of the heterobifunctional conjugate are used in the assay for binding to immunoglobulins: the analyte derivative binds to an immobilized antibody, Ab(1), and the enzyme component binds to a spatially separated immobilized antibody, Ab(2). The analytical system is set up such that in the absence of analyte, the conjugate is predominantly bound in the compartment that contains Ab(1). With increasing concentration of native analyte in samples, an increasing concentration of native analyte in samples, an increasing amount of conjugate migrates to the second compartment that contains Ab(2). The enzyme bound in each compartment is used for signal generation. Mathematical models have been developed to determine the optimal conditions and to predict the performance of such dual-antibody systems. The theoretical predictions are supported by experimental results. The dual-antibody system has been compared with a conventional competitive enzyme immunoassay using the same reagents.     

Modeling of immunosensors under nonequilibrium conditions. I. Mathematic modeling of performance characteristics.

Immunosensors for the detection of small analytes that use analyte-enzyme conjugates as signal generators require special attention if operated under nonequilibrium conditions. If the size of the analyte and the analyte-enzyme conjugate differ substantially, the two antigens do not diffuse at the same rate. This can cause time-dependent shifts in the sensitivity of competitive immunoassays. Therefore, immunosensors operating at short incubation times require precise timing that meets closely the specifications for which the sensors were calibrated. As an example, we have analyzed kinetic binding curves for the quantitative determination of progesterone with an immobilized monoclonal antibody and a conjugate between horseradish peroxidase and progesterone as signal generator. Mathematical paradigms have been developed to simulate the diffusion, antigen-antibody complex formation, and competitive binding processes in this analytical system. Dose-response curves obtained under nonequilibrium conditions can vary substantially from those obtained at equilibrium of antigen-antibody interaction. The degree of this variation depends on the performance characteristics of the major components of the immunosensor. The developed mathematical solutions reflect experimental results and can be used to model optimal conditions for immunosensors operating under nonequilibrium conditions. In this paper (Part I), we report on the mathematical modeling of the interaction between analyte, analyte-enzyme conjugate, and an immobilized antibody. In Part II (W. Schramm and S.-H. Paek (1991) Anal. Biochem. 196), we present experimental results and compare them with the theoretical models.     

A flow immunoassay for studies of human exposure and toxicity in biological samples

This paper describes a heterogeneous competitive flow immunoassay with a high sample throughput which can be used for the screening of smaller analytes in various samples. The method is based on off-line incubation of the analyte (Ag), a fluorescent labelled tracer (Ag*) and the corresponding antibody (Ab). The separation of bound (Ab-Ag*) and free tracer (Ag*) is based on a size exclusion and reversed phase mechanism utilizing a restricted access (RA) column. The column traps the free unbound tracer (Ag*) in its hydrophobic (C18) inner cavity but excludes the large Ab-Ag* complex, which is passed on and measured by the fluorescence detector. The flow immunoassay was developed using the triazine herbicide atrazine as a model compound owing to its human toxicity and widespread use. A sample throughput of 80 samples per hour and a detection limit of 300 pg ml-1 in water were obtained. Urine samples were successfully applied for direct injections into the flow system, while for human plasma samples an additional clean-up step using solid phase extraction was efficiently included where pure extract is obtained with the highly stable and biocompatible extracting column material. The resulting detection limits for atrazine in plasma and water samples using this clean-up and trace enrichment procedure were found to be 2 ng ml-1 and 20 pg ml-1 respectively.     

Modeling of immunosensors under nonequilibrium conditions. II. Experimental determination of performance characteristics.

In an attempt to optimize immunosensors operating with an immobilized antibody as binding protein and an analyte-enzyme conjugate as signal generator that is significantly larger in molecular size than the analyte, in a previous communication (Part I) (S.-H. Paek and W. Schramm (1991) Anal. Biochem. 196) we developed mathematical models for the prediction of performance characteristics. These models are compared in this contribution with experimentally obtained results. As an example, a monoclonal antibody to the steroid hormone progesterone has been used as binding protein, an 125I-progesterone derivative, and a progesterone-horseradish peroxidase derivative as tracers for signal generation. A minimum of parameters needs to be experimentally determined to calculate the performance: the amount of immobilized antibody, the diffusion coefficient of antigens, the thickness of the penetration layer, and the on- and off-rates for binding of the antigen to the antibody. We have described simple methods to obtain these data for the labeled antigen and for the unlabeled analyte that does not provide a signal per se. Kinetic binding curves for antigen-antibody complex formation obtained with the mathematical models correlated well with experimentally obtained results for antigens of different sizes. Although equilibrium of the antigen-antibody complex for the enzyme-labeled analyte conjugate requires about 4 h in the absence of free analyte, dose-response curves can be obtained after 5 min and the relative position of these curves does not change significantly after 30 min. Using a total volume of 200 microliters for the analytical procedure in microtiter wells, agitation as a means to accelerate convective diffusion during an incubation period of 30 min is not necessary with the analyte-enzyme conjugate. However, immunosensors using large analyte-enzyme conjugates as signal generators for the detection of small analytes require strict control of the incubation time if operated within short periods of time (less than 30 min).     

Performance characteristics of a reversible immunosensor with a heterobifunctional enzyme conjugate as signal generator

Factors that control the performance of a reversible immunosensor with an analyte (progesterone)-enzyme (horseradish peroxidase) conjugate as signal generator have been investigated. The conjugate is used in conjunction with two antibodies, which are specific to progesterone and to horseradish peroxidase, immobilized on two spatially separated polypropylene mesh discs. The conjugate and two antibodies are confined to an internal compartment of a microdialyzer by a semipermeable membrane. The small analyte from an external medium permeates across the membrane into the internal compartment where the analyte concentration determines the relative amounts of the bound conjugate on the two solid surfaces. By measuring two signals from the conjugate bound at two separate sites, we experimentally obtained time-response curves to a concentration pulse of the external analyte. A mathematical (kinetic) model describing the sensor system was developed and used for the determination of rate-limiting factors. In semicontinuous monitoring of the analyte concentrations, operation of the immunosensor with the enzyme conjugate as signal generator required special attention to (a) enzyme stability, (b) analyte permeation (dependence on medium components), and (c) kinetics related to the different accessibility to the same antibody of the small analyte (to be measured) vs. the larger counterpart on the enzyme conjugate (for signal generation). (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 56: 221-231, 1997.     

Development of immunosensor based on OWLS technique for determining Aflatoxin B1 and Ochratoxin A

Mycotoxins are toxic secondary metabolites produced by a number of different fungi, and can be present in a wide range of food and feed commodities including cereal grains, oil seeds, dried fruits, apple juice, wine and meat products from animals fed contaminated meal. Many mycotoxins are highly resistant, and survive food processing, and therefore enter the food chain and provide a threat to human health. The optical waveguide lightmode spectroscopy (OWLS) technique has been applied to the detection of Aflatoxin and Ochratoxin in both competitive and in direct immunoassays. After immobilizing the antibody or antigen conjugate for the direct or indirect measurement, respectively, the sensor chip was used in flow-injection analyser (FIA) system. When using non-competitive method, sensor responses were obtained first only at analyte concentrations of 5-10 ng ml(-1). In both cases, the responses were very unstable. For competitive sensor investigation with the sensitized chip first the optimal dilution rate of monoclonal antibodies was determined, for the measurement of Ochratoxin A and Aflatoxin B1 the monoclonal antibody stock solution was diluted to 1 microg ml(-1) and to a 1:400 dilution, respectively. During the competitive measurement standard solutions were mixed with monoclonal antibodies at the appropriate concentration, the mixture was incubated for 1 min and injected into the OWLS system. The sensitive detection range of the competitive detection method was between 0.5 and 10 ng ml(-1) in both cases. After the establishment of the indirect method, barley and wheat flour samples were measured, and the results were in good correlation by those measured by enzyme linked immuno-sorbent assay (ELISA). Regression coefficient between the two methods for Ochratoxin and Aflatoxin was determined as 0.96 and 0.89, respectively.     

A new approach to the construction of potentiometric immunosensors.

An electrochemical immunosensor based on a new detection principle was developed. Laccase, which is able to catalyse the electroreduction of oxygen via the direct (mediatorless) mechanism was used as an enzyme label. The new detection method does not require the presence of an electrochemically active mediator, and the reaction substrates are atmospheric oxygen and electrons, the latter being taken by the active site of the enzyme label directly from the electrode. The formation of the complex between laccase-labelled antibody and antigen on the electrode surface resulted in a considerable (more than 300 mV) shift of the electrode potential. The rate of the increase of the electrode potential was inversely proportional to the concentration of the free antigen in the sample. The non-specific adsorption of conjugate and other proteins on the electrode could be eliminated by using a polyethylenimine-based polymer on the electrode surface. Insulin was used as a model analyte. The sensitivity limit for this antigen was approximately 3 micrograms ml-1.     

Use of a biomimetic peptide in the design of a competitive binding assay for biotin and biotin analogues

A competitive binding assay for biotin, biocytin, and desthiobiotin utilizing a genetically engineered enzyme-ligand conjugate is described herein. This assay is unique in that the enzyme-ligand conjugate consists of the streptavidin binding peptide Strep-tag II, which mimics the binding of biotin to streptavidin, rather than biotin itself. This allows for the construction of a well-defined, oligosubstituted enzyme-ligand conjugate for which the site of attachment of the ligand on the enzyme is known precisely. The assay has detection limits of 5 x 10(-8) M for biotin, 1 x 10(-7) M for biocytin, and 2 x 10(-6) M for desthiobiotin, and it serves as a model system in that it demonstrates the feasibility of using enzyme-ligand conjugates in which a peptide mimic of the analyte ligand is genetically fused to the enzyme. This avoids the problems associated with covalent attachment of the ligand to the enzyme, such as multiple substitution of the ligand and variability of the site of attachment. To our knowledge, this is the first example of using an enzyme-peptide mimic conjugate to detect a nonpeptide analyte.     

A highly sensitive flow-through amperometric immunosensor based on the Peroxidase chip and enzyme-channeling principle

A concept based on the Peroxidase-chip (P-chip), antibody co-immobilization, competitive and enzyme-channeling principle was exploited to develop an integrated flow-through amperometric biosensor for detection of environmental pollutants such as s-triazine herbicides. In this concept, recombinant peroxidase is immobilized on the gold electrode (P-chip) in such a way that direct electron transfer is achieved. The recognition and quantitation the target analyte is realized through the competition between the simazine-glucose oxidase (GOD) conjugate and free simazine for the binding sites of the monoclonal antibody co-immobilized with peroxidase on the gold electrode. The arrangement allows to generate a specific signal in the presence of glucose through the channeling of H2O2 produced by GOD conjugate bound to the antibody. The immunosensor exhibited 50% signal decrease (IC50 value) at approximately 0.02 microg l(-1). A concentration of 0.1 ng l(-1) gave a signal clearly distinguishable from the blank whereas the ELISA using the same antibody had a typical detection limit of about 1 microg l(-1), which is four orders of magnitude higher compared to the presented biosensor system. The results demonstrated that gene engineering biomolecules, in this case recombinant peroxidase, might be attractive reagents for the development of electrochemical immunosensors.     

Determination of testosterone metabolites in human hepatocytes. I. Development of an on-line sample preparation liquid chromatography technique and mass spectroscopic detection of 6beta-hydroxytestosterone

A rapid and sensitive RP-HPLC assay for determination of 6beta-hydroxytestosterone in human hepatocytes with corticosterone as the internal standard is described. The procedure employs on-line sample enrichment using a BioTrap 500 MS (20x4 mm I.D.) extraction pre-column and subsequent gradient separation on a Prontosil 60-5 C(18)-H (250x2 mm I.D., 5 micrometer particle size) analytical column in the back-flush mode using a ternary eluent system composed of methanol, tetrahydrofuran and water. Signal monitoring was done by measurement of the responses from liquid chromatography coupled to mass spectroscopy (LC-MS/MS) using an atmospheric pressure chemical ionization (APCI) source conducted in the selected reaction monitoring (SRM) mode. Mean recoveries of 6beta-hydroxytestosterone from an estimate of the biological matrix, i.e., Dulbecco's modified Eagle medium "High Glucose", ranged from 101.8-104.4% for samples containing the target analyte at the 250, 500 and 1000 ng/ml level. The limit of quantitation (LOQ) was 20 ng/ml at an injection volume of 100 microliter determined in the same matrix. Linearity of signal responses versus concentration for all three analytes was accomplished in the range of 100-4000 ng/ml. Mean values of the coefficients of variation (C.V.) for the target analyte obtained for the concentrations 250, 500 and 1000 ng/ml at 5 different days in quintuplicate ranged from 1.5-7.7% (within-day) and 4.8-7.3% (between-day). The corresponding values for the accuracy ranged from 87.7-106.1% for the within-day and from 98.8-102.5% for the between-day measurements. The target analyte was sufficiently stable at both storage and sample preparation conditions because no substantial deviations between analyte concentrations measured before and after subsequently performed freeze and thaw cycles were observed.     

The immunochemistry of solid-phase sandwich enzyme-linked immunosorbent assays

Multivalent antigens (Ags) such as membrane proteins can be quantitated by using sandwich enzyme-linked immunosorbent assays (ELISAs), which typically show sensitivity from 0.1 to 50 ng/ml. The percentage of antigen that binds in the log-log linear region reflects the affinity of the capture antibody (CAb), and the range of linearity for assays conducted with a particular CAb is proportional to the antibody (Ab) concentration. The sandwich ELISA titration plot reflects the actual amount of Ag bound when asymmetrical configurations are used; steric hindrance that occurs with certain symmetrical configurations, especially when enzyme-Ab conjugates of greater than or equal to 10(6) daltons are used, can alter this relationship. Monoclonal CAbs bind less Ag than polyclonal CAbs. Immobilization of monoclonal CAbs by using a modified avidin-biotin system can result in greater antigen capture capacity (AgCC) than when the Abs are directly adsorbed on plastic. Adsorption of proteins on polystyrene is noncovalent and proportional to the amount added for up to 150 ng/200 microliter in a microtiter well. Adsorption can result in substantial loss of antigenic or antibody activity. Desorption is continuous at a low level and can negatively influence the results of an immunoassay. Data from microtiter sandwich ELISAs can be readily acquired and analyzed by using a computer-based analysis system (ELISANALYSIS) written for the IBM PC. This analytical system considers the immunochemical principles of sandwich ELISAs predicted theoretically and demonstrated empirically.     

黄曲霉毒素B1抗独特型抗体的制备和应用研究I抗独特型抗体的制备和性质研究

以黄曲霉毒素B1(AFB1)与牛血清蛋白（BSA)的连接物AFB1-BSA注射免疫兔子获得抗AFB1抗血清,经(NH4)2SO4沉淀、酶切处理与亲和层析分离纯化后,得到抗AFB1独特型抗体Ab1及其酶切片段Fab1,然后再将Fab1注射免疫BALB／c小鼠,得到抗(抗AFB1)独特型抗体Ab2及其酶切Fab2。研究了Ab2和Fab2的性质,结果表明,Ab2和其Fab2部仅与Ab1及其Fab1反应,而不和抗桔霉素等其他抗体反应,有较好的特异性。以AFB1与卵清蛋白(OV)的连接物AFB1-OV为包被抗原,Fab1为反应抗体,Ab2和Fab2为竞争抗原,达到50％的竞争抑制率时,Ab2和Fab2的浓度分别为3．98ug／ml和1．12ug／ml;而以Ab2和Fab2为包被抗原,Fab1为反应抗体,AFB1为竞争抗原,达到50％的竞争抑制率时,AFB1的浓度分别为44．67ug/L和6.31ug／L,这表明无论是Ab2还是Fab2都和AFB1有很好的内影像关系,可以作为AFB1的替代品用于AFB1的免疫学检测。但是相对而言,由于Fab2的分子量小,反应时的空间位阻小,所以Fab2更适合于用作AFB1的替代品。     

Multi-analyte analysis of biological fluids with a recycling immunoaffinity column array.

A system for isolating and measuring up to 30 analytes in a single biological sample is described. The system is based on recycling a pre-labeled sample through an array of capillary immunoaffinity columns, each packed with glass beads, coated with a different antibody, thus enabling each column to isolate and extract a single analyte. Detection of the bound analytes is achieved by laser-induced fluorescence (LIF), using a laboratory-built scanning detector coupled to a fiber-optic spectrometer. The array can be regenerated up to 200 times, provided a suitable temperature is maintained. The individual immunoaffinity columns are able to bind between 2.9 and 3.6 ng of analyte, depending upon the individual column, with lower limits of detection (LOD) in the order of 1.6-2.8 pg/ml. The inter- and intra-assay coefficients of variation (CV) for all 30 columns in the array were less than 6.03+/-0.33 at analyte concentrations of 100 pg/ml. Comparison to standard enzyme-immunoassays demonstrated r(2) values in the range of 0.9151-0.9855 when analyzed by least-squares linear regression.     

Disposable amperometric immunosensor system for rabbit IgG using a conducting polymer modified screen-printed electrode

A disposable and mediatorless immunosensor based on a conducting polymer (5,2':5'2"-terthiophene-3'-carboxylic acid) coated screen-printed carbon electrode has been developed using a separation-free homogeneous technique for the detection of rabbit IgG as a model analyte. Horseradish peroxidase (HRP) and streptavidin were covalently bonded with the polymer on the electrode and biotinylated antibody was immobilized on the electrode surface using avidin-biotin coupling. This sensor was based on the competitive assay between free and labeled antigen for the available binding sites of antibody. Glucose oxidase was used as a label and in the presence of glucose, H(2)O(2) formed by the analyte-enzyme conjugate was reduced by the enzyme channeling via HRP bonded on the electrode. The catalytic current was monitored amperometrically at -0.35 V vs. Ag/AgCl and this method showed a linear range of RIgG concentrations from 0.5 to 2 microg/ml with standard deviation +/-0.0145 (n=4). Detection limit was determined to be 0.33 microg/ml.     

Ultrasensitive electrochemical immunosensor for ochratoxin A using gold colloid-mediated hapten immobilization

A convenient, specific, and highly sensitive electrochemical immunosensor based on an indirect competitive assay format was developed for the determination of ochratoxin A (OTA), a common toxic contaminant in various kinds of agricultural products. The sensing substrate was prepared using a gold electrode modified with a self-assembled monolayer of 1,6-hexanedithiol that mediated the assembly of a gold colloid layer, which could enhance the surface loading of OTA-ovalbumin conjugate and improve the sensitivity in electrochemical readouts. After competition of the limited anti-OTA mouse monoclonal antibody between immobilized hapten and OTA analyte in sample solution, alkaline phosphatase (ALP)-labeled horse anti-mouse immunoglobulin G (IgG) antibody was selectively bound onto the surface of the electrode, affording an indicator for OTA concentration in the sample. Electrochemical response arising from the oxidation of enzymatic product of 1-naphthyl phosphate was observed to be inversely proportional to OTA concentration in the range from 10 pg/ml to 100 ng/ml with a detection limit as low as 8.2 pg/ml. Furthermore, a negligible matrix effect and good recoveries were obtained in the determination of corn samples, evidencing the feasibility of the proposed method for accurate determination of OTA in corn samples.     

A competitive enzyme hybridization assay for plasma determination of phosphodiester and phosphorothioate antisense oligonucleotides.

An enzyme competitive hybridization assay was developed and validated for determination of mouse plasma concentrations of a 15mer antisense phosphodiester oligodeoxyribonucleotide and of two phosphorothioate analogs. Assays were performed in 96-well microtiter plates. The phosphodiester sense sequence was covalently bound to the microwells. The 5'-biotinylated antisense sequence was used as tracer. The principle of the assay involves competitive hybridization of tracer and antisense nucleotide to the solid phase-immobilized sense oligonucleotide. Solid phase- bound tracer oligonucleotide was assayed after reaction with a streptavidin-acetylcholinesterase conjugate, using the colorimetric method of Ellman. As in competitive enzyme immunoassays, coloration was inversely related to the amount of analyte initially present in the sample. The limit of quantification was 900 pM for phosphodiester antisense oligonucleotide using a 100 microl volume of plasma without extraction. Cross-reactivity was negligible after a four base deletion in either the 3'or 5'position. The assay was simple and sensitive, suitable for in vitro screening of oligonucleotide hybridization potency in biological fluids and for measuring the plasma pharmacokinetics of phosphorothioate and phosphodiester sequences.     

Photometric and electrochemical enzyme-multiplied assay techniques using beta-galactosidase as reporter enzyme

Beta-galactosidase (beta-gal) is shown to be a versatile new reporter enzyme in both photometric and electrochemical enzyme-multiplied assay techniques (EMATs). The well-known beta-gal substrate analog, o-nitrophenyl beta-d-galactopyranoside, yields the visibly colored, o-nitrophenol product upon hydrolysis, whereas the substrate, p-aminophenyl beta-D-galactopyranoside, gives rise to an electrooxidizable product, p-aminophenol. These beta-gal substrates made possible the demonstration of both photometric and electrochemical signal transduction schemes for beta-gal-based EMAT detection of estradiol (as the estradiol-bovine serum albumin (E-BSA) conjugate). The EMAT system is composed of the reporter enzyme, beta-gal, with covalently attached estradiol, and estrogen antibody, which inhibits enzyme activity of the beta-gal-estradiol conjugate up to approximately 75%. Reporter enzyme inhibition is relieved significantly by addition of < or =2 ng/mL of estradiol (as E-BSA), which competes for binding with the antibody. Thus, the presence of analyte (E-BSA) is reported by the enzyme (beta-gal), which amplifies the ligand-protein dissociation event by turning over its substrate repeatedly. The electrochemical version of EMAT, based on amperometric detection of p-aminophenol, is responsive to added estradiol within minutes. These results show that beta-gal may serve as a useful alternative to glucose-6-phosphate dehydrogenase, which currently is used as reporter enzyme in commercially available EMAT systems.     

Development of an electrochemical immunosensor for alanine aminotransferase

Alanine aminotransferase (ALT) has been regarded as one of the most sensitive indicators of hepatocellular damage. While ALT is widely used in the practice of medicine, few attempts have been made to develop biosensors applicable to the on-site diagnosis of liver diseases. In the hope of developing an immunosensor for measurement of ALT activity, we have generated monoclonal antibodies to human recombinant ALT and fabricated them for use in a sensor. The ALT immunosensor was composed of the followings: (1) anti-ALT antibody-immobilized outer membrane; (2) pyruvate oxidase-absorbed inner membrane; (3) a self assembled monolayer mediator-coated gold working electrode and an Ag/AgCl reference electrode. The chronoamperometric measurement of the immunosensor was performed with 40 microl of PBS containing substrates and ALT without a washing step in less than 5 min. The dynamic range of ALT immunosensor was presented as five orders of magnitude, ranging between 10 pg/ml and 1 microg/ml. The detection limit and the sensitivity were 10 pg/ml and 26.3 nA/(ng/ml), respectively. In the meantime, the enzyme sensor fabricated without anti-ALT antibody showed much poorer analytical values. The dynamic range, the detection limit, and the sensitivity were 10 ng/ml-100 microg/ml, 10 ng/ml and 11.4 nA/(ng/ml), respectively. The presented results indicated that the immunosensor system provided much better technical performance in all of the aspects evaluated than did the enzyme sensor without the immobilized-antibody.     

New approach to heterogeneous enzyme immunoassays using tagged enzyme-ligand conjugates

A new approach to heterogeneous enzyme immunoassays has been developed that uses a tag molecule linked to an enzyme-ligand conjugate. The insoluble phase is an insolubilized receptor to that tag. The antibody to the ligand, in addition to complexing either the free ligand or the one covalently linked to the tagged enzyme, also serves to mask the tag on the tagged enzyme-ligand conjugate so that it can no longer bind to the insolubilized receptor. Accordingly, the proportion of enzyme conjugate associated with the insoluble fraction is proportional to the amount of analyte ligand being assayed. This heterogeneous EIA based on the “antibody masking the tag” is called AMETIA. In the model system we use DNP-lysine as the ligand, β-galactosidase as the enzyme, biotin as the tag, and avidin immobilized to Sepharose as the insoluble receptor.     

Development of a highly sensitive and selective microplate chemiluminescence enzyme immunoassay for the determination of free thyroxine in human serum

A microplate chemiluminescence enzyme immunoassay (CLEIA) with high sensitivity, selectivity and reproducibility was developed for the determination of free thyroxine (FT4) in human serum. A competitive assay has been utilized with horseradish peroxidase (HRP) labeled thyroxine analog in the chemiluminescence (CL) detection. The CL signal produced by the emission of photons from luminol was directly proportional to the amount of analyte. The linear range was 0.45-7.5 ng dL(-1 )and the detection limit was 0.09 ng dL(-1). Experimental conditions, such as temperature, pH, incubation time, titration level and other relevant variables upon the CL signal have been examined and optimized. A coefficient of variance of less than 16% was obtained for intra- and inter-assay precision. The present method has been successfully applied to the analysis of FT4 in human serum. The positive and negative coincidence ratios are satisfactory. Good correlations were obtained between the results by the proposed method and radioimmunoassay (RIA), as well as a Bayer ACS-180SE detection system.