A microbial biosensor for hydrogen sulfide monitoring based on potentiometry

Abstract

In this study, a microbial biosensor for hydrogen sulfide (H2S) detection based on Thiobacillus thioparus immobilized in a gelatin matrix was developed. The T. thioparus was immobilized via either surface adsorption on the gelatin matrix or entrapment in the matrix. The bacterial and gelatin concentration in the support were then varied in order to optimize the sensor response time and detection limit for both methods. The optimization was conducted by a statistical analysis of the measured biosensor response with various bacterial and polymer concentrations. According to our experiments with both immobilization methods, the optimized conditions for the entrapment method were found to be a gelatin concentration of 1% and an optical density of 82. For the surface adsorption method, 0.6% gelatin and an optical density of 88 were selected as the optimal conditions. A statistical model was developed based on the extent of the biosensor response in both methods of immobilization. The maximum change in the potential of the solution was 23.16mV for the entrapment method and 34.34mV for the surface absorption method. The response times for the entrapment and adsorption methods were 160s and 105s, respectively. The adsorption method is more advantageous for the development of a gas biosensor due to its shorter response time.