Rosa J. Jagus

Combined Effect of Nisin and Pulsed Electric Fields on the Inactivation of Escherichia coli

The Doehlert design was applied in order to investigate the combined effect of nisin and high voltage pulsed electric fields (PEF) on the inactivation of Escherichia coli in simulated milk ultrafiltrate media. Nisin alone was totally inactivated by PEF, but in the presence of bacterial cells a protective effect was observed. However, the effectiveness of nisin was still decreased when bacterial cells were subjected to the combined treatment. In spite of this phenomenon, an almost additive response emerged as a consequence of the combined treatment. A 4-log cycle reduction may be accomplished with around 1,000 IU/ml (7.15 microM) of nisin and three pulses of 11.25 kV/cm or 500 IU/ml for five pulses of the same intensity. The observed efficacy arising from the combination of both treatments suggests the possibility of using PEF for improving the action spectrum of natural antimicrobials.

Physical and Antimicrobial Properties of Tapioca Starch-HPMC Edible Films Incorporated with Nisin and/or Potassium Sorbate

The antimicrobial effectiveness of nisin and potassium sorbate, incorporated individual and combined, in films made with tapioca starch and its mixtures with hydroxypropyl methylcellulose were studied. The combination of antimicrobials was more effective against Listeria innocua and Zygosaccharomyces bailii than their individual incorporation, with the added advantage of providing greater inhibitory spectrum. The effect of the formulation on some physical properties was also evaluated. The blended biopolymers-based films showed an increase of stress (σr) and elastic modulus (E) but a decrease of the strain at break (εr). In turn, the water vapour permeability and solubility in water were enhanced. In addition, these films were clearer than those made only with starch. It must be remark that, despite the antimicrobial agents modified films physical properties, producing a lower σr and E, a higher εr, solubility and darker films, they maintained a suitable behaviour as a packaging material.

Inactivation of Escherichia coli by a combination of nisin, pulsed electric fields, and water activity reduction by sodium chloride.

The effect of nisin combined with pulsed electric fields (PEF) and water activity reduction by sodium chloride (NaCl) on the inactivation of E. coli in simulated milk ultrafiltrate media was studied with a Doehlert design and a response surface method. The reduction of water activity from 0.99 to 0.95 by the addition of NaCl (without any other hurdle) did not affect E. coli viability of approximately 10(8) CFU/ml. A reduction in PEF effectiveness occurred when the NaCl concentration was increased because of an increase in conductance, which reduced the pulse decay time. In cells submitted to PEF nisin activity was decreased, probably as a consequence of the nonspecific binding of nisin to cellular debris or the emergence of new binding sites in or from cells. However, the lethal effect due to nisin was reestablished and further improved when water activity was reduced to 0.95. A synergistic effect was evidenced when low-intensity PEF were applied. Decreasing water activity to 0.95 and applying PEF at 5 kV/cm (a nonlethal intensity when no other hurdle is used) with the further addition of nisin (1,200 IU/ml) resulted in a 5-log cycle reduction of the bacterial population.

Effect of natamycin, nisin and glycerol on the physicochemical properties, roughness and hydrophobicity of tapioca starch edible films

In this paper, films based on tapioca starch and containing nisin, natamycin and glycerol were characterized in relation to their physicochemical properties, roughness and hydrophobicity. The content of glycerol affected the mechanical properties of the films studied and the roughness and it was observed an increase in WVP with the increase in glycerol content. The addition of antimicrobials affected the mechanical properties, being nisin the one that produced the greater decrease in the Young modulus. The color was highly affected by the joint presence of natamycin and nisin, which increased the yellow index. The contact angle increased with antimicrobial addition indicating a decrease in hydrophilicity. Nisin also affected the roughness of the films. Water vapor permeability was slightly reduced by the presence of natamycin. It was observed that water vapor permeability and contact angle were correlated with the roughness of the films.

Combined effect of water activity and pH on the inhibition of Escherichia coli by nisin.

The Doehlert design and surface response methodology were used to study the influence of pH and water activity (aw) on Escherichia coli inhibition by nisin. Combining stress factors at levels where they are not inhibitory by themselves, a reduction of E. coli survival fraction can be achieved with lower nisin doses than in a single nisin treatment. For all the pH values assayed, a synergistic effect of aw and nisin concentration was detected, and the isoresponse lines showed the existence of an area of maximum inhibition. Factors that reduced viable cell counts by 4 to 5 log cycles were 1,000 to 1,400 IU of nisin per ml at pH 5.5 to 6.5 and a water activity of 0.97 and 0.98. The addition of different ionic and nonionic solutes to control aw suggested that the effect of aw in the inhibitory action of nisin on E. coli cells was not solute-specific. The use of the Doehlert experimental design was effective to determine the optimal combination of stress factors, as well as to point out the most important variables that affected E. coli inhibition.

Chapter 49 – Combinational Approaches for Antimicrobial Packaging: Natamycin and Nisin

Abstract Food safety is a global priority and one of the major objectives of the current food legislation. The right combination of strategies for food industrialization, including the packaging step, ensures the achievement of that objective. New food products and new industrialization processes impose the need for the development of new packaging materials that ensure food protection and that address the changing demands of the food industry and consumers. The general perception of the importance of minimizing environmental damage has catalyzed the exploration of new biobased packaging materials, such as biodegradable and edible films, because they are environmentally friendly. In addition, consumer demand for more natural foods has promoted research about natural antimicrobials like natamycin and nisin. This chapter reviews the available information on antimicrobial packaging containing the natural antimicrobials natamycin and nisin simultaneously and, in particular, their antimicrobial effectiveness. According to published and new results evaluated, packaging containing natamycin and nisin is a very efficient strategy to control food contamination. In addition, the use of biodegradable materials to produce the packaging contributes to environment protection.