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1 Centro de Energia Nuclear na Agricultura, Universidade de SaËo Paulo, PO Box 96, 13400-970, Piracicaba â SP, Brazil 2Departamento de Quı´mica, Universidade Federal de SaËo Carlos, SaËo Carlos â SP, Brazil 3Departamento de CieËncias Naturais, Universidade Federal de SaËo JoaËo Del Rei, SaËo JoaËo Del Rei â MG, Brazil and 4REQUIMTE, Departamento de Quı´mica-Fı´sica, Faculdade de Farma´cia, Universidade do Porto, Porto, Portugal Among the existing procedures for glucose determination, those based on enzymatic reaction are widely employed [3,4]. Generally, the procedures are based on the hydrogen peroxide produced during glucose oxidation by glucose oxidase (GOD) [5,6], with detection employing chemiluminescence [7], ultraviolet light (UV)-Vis spectrophotometry [8] or electrochemistry [9]. The chemiluminescent technique presents attractive features such as high sensibility and a wide dynamic range, which can be attained using inexpensive instruments [10,11]. These features have been exploited with ï¬ow analysis procedures, resulting in a useful combination considering the versatility due to the ï¬ow analysis techniques [12,13], and especially those based on sequential injection [14,15] and multicommutation [16,17]. The present paper intends to develop a multicommutated ï¬ow analysis procedure for glucose determination in animal blood serum based on enzymatic reaction and detection by chemiluminescence. The method selected is based on the reaction of luminol with hydrogen peroxide produced by the reaction of GOD with glucose [18]. Exploiting the advantages provided by the multicommutation process [19] regarding solution handling, it is intended to design a ï¬ow system to save reagents without sacriï¬cing data quality and system robustness. An automatic ï¬ow procedure based on multicommutation dedicated for the determination of glucose in animal blood serum using glucose oxidase with chemiluminescence detection is described. The ï¬ow manifold consisted of a set of three-way solenoid valves assembled to implement multicommutation. A microcomputer furnished with an electronic interface and software written in Quick BASIC 4.5 controlled the manifold and performed data acquisition. Glucose oxidase was immobilized on porous silica beads (glass aminopropyl) and packed in a minicolumn (15 à 5 mm). The procedure was based on the enzymatic degradation of glucose, producing hydrogen peroxide, which oxidized luminol in the presence of hexacyanoferrate(III), causing the chemiluminescence. The system was tested by analysing a set of serum animal samples without previous treatment. Results were in agreement with those obtained with the conventional method (LABTEST Kit) at the 95% conï¬dence level. The detection limit and variation coeï¬cient were estimated as 12.0 mg lÃ1 (99.7% conï¬dence level) and 3.5% (n ¼ 20), respectively. The sampling rate was about 60 determinations hÃ1 with sample concentrations ranging from 50 to 600 mg lÃ1 glucose. The consumptions of serum sample, hexacyanoferrate(III) and luminol were 46 ml, 10.0 mg and 0.2 mg/determination, respectively. Experimental Apparatus The equipment set-up consisted of a 700 plus Femto spectrophotometer furnished with a home-made ï¬at ï¬ow cell (80 mm2 surface, 1.0 mm optical path length) machined in acrylic [17]; a 586 microcomputer equipped with a PCL-711S electronic interface card (Advantech Corp.); an IPC4 Ismatec peristaltic pump equipped with Tygon pumping tubes; a 12 V regulated power supply to drive the solenoid valves; a home-made electronic interface to match the voltage and current intensity required to drive the solenoid valves [19]; a minicolumn (10 mm length, 3 mm i.d.) to pack the glass beads with immobilized enzyme; joint devices machined in acrylic; and mixing coils and ï¬ow lines of polyethylene tubing (0.8 mm i.d.). A standard UV-Vis spectrophotometer was used as a chemiluminescence detector, and for this, the light source was turned oï¬. The spectrophotometer was set to work in the transmittance mode. The chemiluminescence ï¬ow Introduction Glucose in animal blood serum is an important parameter in studies involving physiological processes and nutrition [1]. The glucose level in animal blood is dependent on the amount of glucose originating from dietary sources and those generated by animal metabolic processes such as glycogenolysis and gluconeogenesis [1,2], etc. Therefore, according to these authors, the glucose level can be used as a diagnostic parameter for animal health. * To whom correspondence should be addressed. e-mail: reis@cena.usp.br Journal of Automated Methods & Management in Chemistry ISSN 1463â9246 print/ISSN 1464â5068 online # 200? Taylor & Francis Ltd http://www.tandf.co.uk/journals cell was installed in the spectrophotometer about 2 mm from the photodetector inlet slit. Reagent solutions All solutions were prepared with analytical-grade chemicals. Freshly puriï¬ed water presenting a conductivity of less than 0.1 mS cmÃ1 was used throughout. The solutions, including samples and standards, were stored in polyethylene bottles. A 2000 mg lÃ1 glucose stock solution was prepared by dissolving sugar (Sigma Chemical Co.) in water. Reference solutions of 0.0, 50.0, 100.0, 200.0, 400.0 and 600.0 mg lÃ1 glucose were prepared in water by appropriate dilution from the stock solution. These solutions were stored in a refrigerator at 5 C, and equilibrated to laboratory temperature (25 C) before use. A 2.5 mmol 5-amino-2,3-dihydro-1,4-phthalazinedione (luminol) solution was prepared by dissolving 0.0443 g salt (Sigma) in 100 ml 0.2 mol lÃ1 K2CO3 solution with the pH adjusted to 10.5 with an HCl solution. A 0.1 mol lÃ1 K3Fe(CN)6 solution was prepared daily by dissolving 3.29 g salt (Merck) in 100 ml water. Phosphate buï¬er solutions 0.1 mol lÃ1, pH 6.0 and 7.5, were prepared by dissolving 13.6 g KH2PO4 (Merck) in water. pHs were adjusted with a 0.1 mol lÃ1 NaOH solution and volumes were made up to 1000 ml with water. The chromogenic solution was prepared by dissolving 17 mg phenol salt in 25 ml tris(hydroxymethyl)-aminomethan solution buï¬er (pH 6.5) and 4 mg 4-aminoantipyrine in 50 ml of the same buï¬er solution. Before use, they were mixed. The 150 mmol lÃ1 tris(hydroxymethyl)aminomethan buï¬er solution was prepared by dissolving 4.54 g salt in water and adjusting the pH to 6.5 using a 0.2 mol lÃ1 HCl solution completing the volume to 250 ml with water. A 200 U peroxidase enzyme solution was prepared by dissolving 1 mg peroxidase in 5 ml phosphate buï¬er solution (pH 7.5). A colorimetric glucose enzymatic assay, purchased from LABTEST Diagnostic (Belo Horizonte, MG, Brazil) was used to compare results. Enzyme immobilization GOD was immobilized on aminopropyl (Sigma) porous Ë silica beads of 200â400 mesh and a pore size of 170 A according to Matsumoto et al. [9]. About 0.2 g aminopropyl beads were washed ï¬rst with distilled water and then with the 0.2 mol lÃ1 carbonate buï¬er solution (pH 10.0). Afterwards, the beads were added to 20 ml 0.2 mol lÃ1 carbonate solution (pH 10.0) plus 2.5 ml 5% (v/v) glutaraldehyde and stirred for 2 h while the temperature was maintained at 25 C. Afterwards, the solution was ï¬ltered and washed sequentially with both water and a 0.1 mol lÃ1 phosphate buï¬er solution (pH 6.0). Glucose oxidase enzyme (4.2 mg, 150 U) from Aspergillus niger (G-7016, Sigma) was placed in a beaker and dissolved with 20 ml 0.1 mol lÃ1 phosphate buï¬er. The aminopropyl beads were added to this solution, which was maintained for 60 min in an ice bath at 5 C with slow stirring. Afterwards, it was ï¬ltered and conditioned in 10 ml 0.2 mg cyanoborohydride solution for 2 h, maintaining the temperature at 5 C, followed by ï¬ltration and washing with water and phosphate buï¬er solution. The beads were conditioned in a 0.2 mol lÃ1 glycine solution medium (20 ml) for 2 h at 25 C. After this step, they were ï¬ltered and washed with phosphate buï¬er and inserted into the minicolumn using a syringe without a needle. When not in use, the column was maintained in a 0.1 mol lÃ1 phosphate buï¬er solution (pH 7.5) refrigerated at 5 C. The assay described above was repeated using intervals of 120 and 180 min. Aiming to verify the eï¬ciency of the immobilizing procedure, batch experiments were carried out using enzymatic solutions before and after the immobilization step. This was done by mixing 200 ml GOD solution, 200 ml peroxidase enzyme solution, 1400 ml chromogenic reagent solution and 1400 ml 300 mg lÃ1 glucose solution. After a delay of 5 min, the absorbance of the product was measured at 505 nm. Blood sampling and conditioning Blood samples were collected and processed to obtain the serum as established in the literature [20,21]. This was done by puncturing the tail or jugular vein of the animals with a syringe needle of calibre 18 to prevent haemolysis. The blood was transferred to a glass tube (10 ml) previously sterilized under vacuum and centrifuged at 2500 rpm for 12 min. After this step, it was maintained at rest for 24 h at room temperature (25 C) to permit the blood clotting and serum separation. A 4-ml aliquot of serum (supernatant) was transferred to another tube that was centrifuged for 10 min to improve separation. The samples were maintained in a freezer at Ã4 C and before analysis they were equilibrated to room temperature. Flow system and procedure The ï¬ow network was designed to implement the multicommutation approach. The manifold is shown in ï¬gure 1. All valves are switched oï¬ and the carrier stream (C) ï¬ows through the enzymatic column and the reaction coil (B) towards the detector (D), while the sample (S) and reagent solutions (R1, R2) are pumped towards the storage vessels. Because the spectrophotometer was set to work in the transmittance mode with the light source switched oï¬, it was adjusted to 100% using a 600 mg lÃ1 glucose solution at pH 7.5 and switching on V1, V2, V3 and V4 for a time of 3 min that was enough to obtain a stable measurement. The analytical process started when the microcomputer running the software sent a sequence of electric pulses through the digital output of the PCL711S interface card to switch valves V1, V2, V3 and V4 on/oï¬ as indicated in the valvesâ timing course (ï¬gure 1). In the ï¬rst step, the carrier solution was directed to its storage vessel and sample serum was pumped through the enzymatic V2 V4 R2 V1 B GOD y z DET V3 R1 Figure 1. Flow diagram of the system. V1, V2, V3 and V4, three-way solenoid valves; S, sample; C, carrier stream, phosphate solution at pH 7.5, ï¬ow rate at 35 ml sÃ1; R1, luminol solution, 2.5 mmol lÃ1 ï¬ow rate at 20 ml sÃ1 pH 10.5; R2, hexacyanoferrate (III) solution, 0.1 mol lÃ1 ï¬ow rate at 20 ml sÃ1; x, y, z, joint devices; GOD, column with the immobilized enzyme; B, coiled reactor, length 75 cm, 0.8 mm i.d.; DET, chemiluminescence detector; W, waste; solid and dashed lines into the valvesâ symbol indicate the ï¬ow pathways when the valve is on or oï¬, respectively. Arrows indicate the ï¬ow direction. T1, T2, T3 and T4, timing course of valves V1, V2, V3 and V4, respectively; the shadow surface beneath the valvesâ timing courses lines indicates that the corresponding valve was switched on. column (GOD) where glucose oxidation occurred. When valves V1 and V2 were switched oï¬, the carrier solution ï¬owed again through the column and reaction coil towards the detector. As indicated in the valvesâ timing course, in the next steps valves V3 and V4 were switched on to add to the sample zone the luminol and the catalyzing solutions (R1, R2), to allow reaction development. In these conditions, light emission due to chemiluminescence occurred within the ï¬ow cell. The carrier ï¬uid (C), luminol (R1) and hexacyanoferrate (R2) solutions and serum sample (S) were pumped at ï¬ow rates of 35, 20, 20 and 23 ml sÃ1, respectively. A set of experiments to deï¬ne the volumes of the aliquots of sample and of reagents solutions were carried out by varying the time intervals to switch on/oï¬ V1 and V2 from 1 to 4 s for the sample introduction and from 6 to 22 s for reagents R1 and R2. A set of glucose standard solutions ranging from 50 to 600 mg lÃ1 was used throughout. Since pH and temperature could aï¬ect the enzymatic reaction, the experiments described before were carried out using as the carrier stream a phosphate buï¬er solution at pH 7.5, and the temperature of the laboratory was maintained at 25 C. On the other hand, the luminol solution was prepared in buï¬ered medium with pH adjusted to 10.5, which is the recommended value for the chemiluminescence reaction [17]. After these steps, experiments varying the pH from 6.0 to 8.5 and the temperature from 18 to 50 C were performed. The described assays were done using luminol and hexacyanoferrate solutions with concentrations of 2.5 mmol lÃ1 and 0.1 mol lÃ1, respectively. Thus, to ï¬nd the best condition, experiments were also carried out using concentrations ranging from 0.05 to 0.5 mol lÃ1 hexacyanoferrate solutions and 0.5â4.5 mmol lÃ1 luminol solutions. Intending to demonstrate the feasibility of the proposed system, a set of serum samples was analysed without any prior treatment. The main parameters considered were precision, accuracy, reagent consumption and sampling throughput. To allow comparison, the serum samples were also analysed employing a conventional method [22]. Results and discussion Enzyme immobilization To ï¬nd the best time to end the immobilization procedure, the absorbance of the enzymatic solutions was measured before and during the immobilization step. The initial absorbance was 0.41, and it decreased to 0.08 after 60 min. Since increasing the immobilization time up to 180 min gave no signiï¬cant variation, a time of 60 min was chosen for the subsequent assays. Eï¬ects of temperature and pH The enzymatic reaction can be aï¬ected by temperature and the pH of the medium. Therefore, to establish the best operational conditions, experiments were carried out varying these parameters. The results are shown in table 2. From these data, one can deduce that in the assayed temperature range, the signal increased about 20%. On the other hand, the pH of the carrier solution presented a remarkable eï¬ect showing a maximum at pH 7.5. This value was maintained for the additional experiments. Considering that the signal increasing was not signiï¬cant when 30 C was employed, the experiments were carried out maintaining the temperature of the laboratory at 25 C, thus avoiding the use of a water bath with controlled temperature thus allowing a signiï¬cant simpliï¬cation of the equipment. Eï¬ect of reagent concentration Since the volumes of the aliquots of the reagent solutions were settled, additional experiments were performed to optimize their concentrations. The luminol concentration was changed from 0.5 to 4.5 mmol lÃ1 and the generated signal increased to 2.5 mmol lÃ1, thus maintaining a constant at higher values. Similar experiments were performed to verify the catalyzing eï¬ect of the hexacyanoferrate(III) concentration, yielding the results shown in ï¬gure 2. The signal ampliï¬cation was remarkable up to a 0.3 mol lÃ1 hexacyanoferrate(III) concentration. The decrease observed when the reagent concentration was higher than this value was in accordance with results presented elsewhere [18]. The 0.1 mol lÃ1 solution was chosen considering that the sensibility presented with this concentration was suï¬cient to analyse the blood serum samples. Sample analysis Considering the results discussed above, the best operational conditions (summarized in table 3) were supplied to a microcomputer when the control software was run. mV Eï¬ects of sample and reagent volumes The ï¬ow rates of serum sample (S), luminol (R1) and hexacyanoferrate(III) (R2) solutions were ï¬xed at 23, 20 and 20 ml sÃ1, respectively (ï¬gure 1). The eï¬ects of sample and reagent volumes on the analytical signal were investigated by varying the time intervals to switch on valves V1, V2, V3 and V4. The volumes are summarized in table 1. Under these conditions, the sample volume that ï¬owed through the enzymatic column during the insertion step varied from 23 to 92 ml. The maximum signal was recorded when the volumes of the inserted aliquots were 46, 360 and 320 ml for sample, luminol and hexacyanoferrate solutions, respectively. Therefore, these values were selected for further experiments. Therefore, the time intervals settled to switch on valves V1, V2, V3 and V4 were 2.0, 2.0, 18.0 and 16.0 s, respectively. Table 1. Sample volume (ml) 23 46 70 93 46 46 46 46 46 46 46 46 Eï¬ect of the sample and reagent volumes on the signal. Reagent R1 volume (ml) 240 240 240 240 120 240 360 440 360 360 360 360 Reagent R2 volume (ml) 120 120 120 120 120 120 120 120 120 200 320 440 Signal (mV) 10.6 16.8 18.2 18.0 12.6 16.8 21.2 17.0 21.2 24.2 30.6 28.4 Sample ¼ 400 mg lÃ1 glucose standard solution. R1 ¼ 2.5 mmol lÃ1 luminol solution; R2 ¼ 0.1 mol lÃ1 hexacyanoferrate(III). Table 2. Eï¬ect of temperature and pH. pH 7.0 7.0 7.0 7.0 7.0 6.0 6.5 7.0 7.5 8.0 8.5 Signal (mV) 25.0 à 0.2 28.2 à 0.1 31.0 à 0.3 30.4 à 0.3 30.2 à 0.2 20.2 à 0.1 22.6 à 0.2 28.2 à 0.1 44.8 à 0.3 40.6 à 0.1 40.2 à 0.2 Temperature ( C) 18 25 30 40 50 25 25 25 25 25 25 0 0,0 0,1 0,2 0,3 0,4 0,5 0,6 -1 Hexacyanoferrate(III) (mol L ) Results are the mean of three consecutive measurements. 112 Figure 2. Eï¬ect of hexacyanoferrate(III) concentration on the signal. System parameters were the same as those for ï¬gure 1. Table 3. Step Operational condition of the system. Parameters Flow rates (ml sÃ1): carrier ¼ 35, sample ¼ 20 luminol ¼ 20 hexacyanoferrate(III) ¼ 23 Sample solution volume (40 ml) Luminol volume (360 ml) Hexacyanoferrate(III) solution volume (320 ml) Carrier solution volume (525 ml) Valve switched on time (s) V1, V2, V3, V4 (180) Spectrophotometer calibration* Sample inserting Reagent inserting Reagent inserting Washing * Transmittance adjusting. V1 and V2 (2.0) V3 (18) V4 (16) all valves oï¬ (15) Figure 3. Signal records of the reference solutions containing (a) br, (b) 50, (c) 100, (d) 200, (e) 300, (f) 400, (g) 500 and (h) 600 mg lÃ1 glucose. After establishing the operational conditions, a set of animal blood serum was analysed yielding the records showed in ï¬gure 3. To validate the developed procedure, glucose was also determined using a manual procedure [22]. The results obtained using both procedures are summarized in table 4. When comparing these results by applying a paired t-test, no signiï¬cant diï¬erence at the 95% conï¬dence level was observed. From ï¬gure 3, it can be deduced that a sampling rate of 60 determinations hÃ1 was achieved. Table 4. Sample 1 2 3 4 5 Comparison of results. Proposed system (mg lÃ1) 202.6 à 7 189.9 à 3 134.8 à 4 131.6 à 1 131.7 à 25 LABTEST Kit (mg lÃ1) 198.9 à 17 186.1 à 15 138.4 à 8 135.3 à 0 117 à 21 Results are the mean of three consecutive measurements (mg lÃ1). Analytical ï¬gures of merit In the best operational conditions (summarized in table 3) when processing a set of standard solutions presenting up to 600 mg lÃ1 glucose, a linear response described by the equation: signal (mV) ¼ (2.4852 à 0.6888) þ (0.1473 à 0.0025) mg lÃ1 glucose was obtained. The blank value was 2.3957 à 0.5987 (n ¼ 10) and the limit of detection of 12 mg lÃ1 glucose was estimated as three times the standard deviation of blank signal measurements divided by the slop of the calibration line. Other proï¬table characteristics such as a relative standard deviation of 3.5% (n ¼ 20) using a typical sample presenting 190.3 mg lÃ1 glucose, a low reagent consumption of 10.0 mg hexacyanoferrate(III) and 0.2 mg luminol/determination were also observed. Furthermore, maintaining the established operational conditions, the immobilized enzyme could be used for 60 days permitting that 1200 determinations were performed.
Journal of Automated Methods and Management in Chemistry – Hindawi Publishing Corporation
Published: Sep 14, 2014
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