Ancient Martian Floods in a Plausible Variable Climatic Environment as Revealed from the Sequential Growth of Allan Hills 84001 Carbonate Globules

No abstract available

Ancient Martian Floods in a Plausible Variable Climatic Environment as Revealed from the Sequential Growth of Allan Hills 84001 Carbonate Globules

No abstract available

Modeling and optimization of the E-beam treatment of chicken steaks and hamburgers, considering food safety, shelf-life, and sensory quality

[EN] The present work was carried out to model the effect of E-beam treatment on the safety,shelf-life and sensory attributes of two poultry products, steaks and hamburgers, and tooptimize the radiation treatment. The inactivation of Salmonella spp. by means of differ-ent irradiation doses was modeled using a first order kinetics. The shelf-life was studiedby periodically counting the bacterial number in samples. For the modeling of experimen-tal data, only the exponential phase of growth was taken into account. The effect of theirradiation dose on the sensory attributes (appearance, odor and flavor) and instrumen-tal color (L*, a* and b* parameters) was modeled using the Gompertz function and theActivation Inactivation or linear models. The optimization of the irradiation dose was car-ried out by maximizing the sensory scores of samples and minimizing the instrumentalcolor changes. The safety and the shelf-life of samples were ensured by introducing con-straints into the optimization problem. In the case of hamburgers, the optimum calculateddose was 2.04 kGy, which guarantees the safety of the product and provides the best combi-nation of sensory and instrumental attributes. As regards the steaks, the optimum assesseddose was 1.11 kGy, significantly lower than for hamburgersThe authors acknowledge the financial support from the Project CSD2007-00016 (CONSOLIDER-INGENIO 2010) and AGL 2010-19158, both funded by the Spanish Ministry of Economy and Competitiveness.Cárcel Carrión, JA.; Benedito Fort, JJ.; Cambero, M.; M. C. CABEZA; Ordóñez, J. (2015). Modeling and optimization of the E-beam treatment of chicken steaks and hamburgers, considering food safety, shelf-life, and sensory quality. Food and Bioproducts Processing. 96:133-144. https://doi.org/10.1016/j.fbp.2015.07.006S1331449

Modeling and optimization of sensory changes and shelf-life in vacuum-packaged cooked ham treated by E-beam irradiation

[EN] The E-beam irradiation of vacuum-packaged RTE cooked ham was carried out to establish the dose required to achieve the food safety objective (FSO) and to minimize changes in selected sensory attributes. Cooked ham was irradiated with doses ranging 1-4 kGy. After the treatment, the microbial inactivation of Listeria monocytogenes, the shelf-life of the product and some sensory attributes (appearance, odor, and flavor) were determined. The inactivation of L monocytogenes was satisfactorily described by a first-order kinetics equation (R2=0.99). The influence of the irradiation dose on appearance, odor, and flavor was modeled through Gompertz (R2=0.99, for appearance) and Activation/Inactivation (R2=0.99, for odor and flavor) equations. A model was also developed to determine the shelf-life of irradiated cooked ham depending on the irradiation dose (R2 > 0.91). The dose that maximized the scores of the sensory attributes was 0.96 kGy resulting in an acceptable sensory quality for 80 days. It is possible to apply up to 2 kGy to ensure microbial safety, while provoking no significant changes in the above mentioned sensory attributes. (C) 2010 Elsevier Ltd. All rights reserved.The authors acknowledge the financial support from the Project CSD2007-00016 (CONSOLIDER-INGENIO 2010) funded by the Spanish Ministry of Science and Innovation.Benedito Fort, JJ.; Cambero, MI.; Ortuño Cases, C.; Cabeza, MC.; Ordoñez, JA.; De La Hoz, L. (2011). Modeling and optimization of sensory changes and shelf-life in vacuum-packaged cooked ham treated by E-beam irradiation. Radiation Physics and Chemistry. 80(3):505-513. https://doi.org/10.1016/j.radphyschem.2010.11.001S50551380