Monitoring of beef aging using a two-line flow injection analysis biosensor consisting of putrescine and xanthine electrodes

Abstract A two-line flow injection analysis (FIA) biosensor was developed which can simultaneously detect bacterial spoilage and the progress of aging. This FIA biosensor was composed of a putrescine oxidase immobilized electrode and a xanthine oxidase immobilized electrode as detectors. The putrescine electrode measures putrescine and cadaverine which are produced by bacteria, and the xanthine electrode measures hypoxanthine and xanthine which accumulate in meat with aging. The analytical conditions for this system were set as follows; flow rate, 1 ml/ min; water bath temperature, 30 °C; flow buffer, 0.1 M phosphate buffer (pH 7.0); injection volume for putrescine electrode, 200 μl; injection volume for xanthine electrode, 40 μl; and measurement cycle, 2 min. The linear relationship for standard solution was between 20 and 800 nmol/ml in the putrescine electrode and between 0.1 and 3.0 μmol/ml in the xanthine electrode. The coefficients of variation in standard solutions were 2.14% with the putrescine electrode and 2.83% with the xanthine electrode. The coefficients of variation values in the specimen solution were 3.22% and 3.76%, respectively. This two-line FIA biosensor was applied to the vacuum-packed beef stored at 0, 5 and 10 °C. The progress of aging could be monitored at all temperatures, and the bacterial spoilage could be detected before the appearance of putrid odor at 5 and 10 °C. However, at 0 °C the putrid odor did not appear during storage, and neither putrescine nor cadaverine was detected. Thus, this FIA biosensor was confirmed to be useful for the quality control of beef aging at 5 and 10 °C, but not at 0 °C.

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