Modeling the Combined Effects of Temperature, pH, and Sodium Chloride and Sodium Lactate Concentrations on the Growth Rate of<i> Lactobacillus plantarum </i>ATCC 8014

Dalcanton, Francieli; Carrasco, Elena; Pérez‐Rodríguez, Fernando; Posada-Izquierdo, Guiomar Denisse; Aragão, Gláucia Maria Falcão de; Garcı́a-Gimeno, Rosa Marı́a

doi:10.1155/2018/1726761

Cited by 19 publications

(11 citation statements)

References 42 publications

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“…Besides medium composition, Lactobacillus spp. growth can be influenced by a set of various conditions such as temperature, pH, oxygen concentration, or water activity [13,14]. The optimum temperature and pH conditions for lactobacilli growth are 30-40 • C and 5.5-6.2, respectively; however, the Lactobacillus genus is diversified and belonging bacteria can grow in temperature ranging from 2 to 53 • C and pH varying between 4.5 and 6.5, some strains can grow in even lower pH [15].…”

Section: Introductionmentioning

confidence: 99%

Growth Kinetics of Probiotic Lactobacillus Strains in the Alternative, Cost-Efficient Semi-Solid Fermentation Medium

Śliżewska

Chlebicz-Wójcik

2020

Biology

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The growing need for Lactobacillus bacteria usage in industry and the expending probiotic market led to a search for new cost-efficient fermentation media from which a high yield of these bacteria could be obtained. The following study aimed to elaborate cultivation medium, for Lactobacillus spp. growth, which main components would be wheat, maize, barley, and rye flours. The optimal temperature for Lactobacillus growth in new semi-solid fermentation (SSF) medium, water content, and pH of the medium were analyzed by the plate count method. It was established, that the highest bacteria counts were obtained from cultures conducted in the SSF medium with flours to water ratio of 1:1.5 with a natural pH of 6.0 at 37 °C. Subsequently, the growth kinetics of analyzed strains, in both MRS and the SSF media, were studied. The newly designed media contributed to the increased duration of selected Lactobacillus strains lag phase, which varied from 1.98 to 5.64; nevertheless, the maximum growth rate of the strains was two times higher in the SSF medium rather than in MRS, which also resulted in shorter generation time. The developed medium has the potential to become a new cost-efficient fermentation medium for Lactobacillus spp.

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Section: Introductionmentioning

confidence: 99%

Growth Kinetics of Probiotic Lactobacillus Strains in the Alternative, Cost-Efficient Semi-Solid Fermentation Medium

Śliżewska

Chlebicz-Wójcik

2020

Biology

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“…Vázquez and Murado [21] proposed a model based on the re-parametrized logistic equation to describe fermentation kinetics of lactic acid production by Lactococcus lactis and Pediococcus acidilactici in a batch system. Da Silva et al [22] studied the growth of L. plantarum, W. viridescens, and L. sakei under different isothermal culture conditions at temperatures of 4, 8, 12, 16, 20, and 30 • C. They determined that LAB growth was strongly influenced by the culture temperature and created new models that allowed them to predict growth at temperatures ranging from 4 to 30 • C. Dalcanton et al [23] built a response model of the growth rate of L. plantarum as a function of temperature, pH, and concentrations of NaCl and sodium lactate (NaC 3 H 5 O 3 ).…”

Section: Introductionmentioning

confidence: 99%

Primary Model for Biomass Growth Prediction in Batch Fermentation

et al. 2021

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Predictive models may be considered a tool to ensure food quality as they provide insights that support decision making on the design of processes, such as fermentation. Objective: To formulate a mathematical model that describes the growth of lactic acid bacteria (LAB) in batch fermentation. Methodology: Based on real-life experimental data from eight LAB strains, we formulated a primary model in the form of a third-degree polynomial function that successfully describes the four phases observed in LAB growth, i.e., lag, exponential, stationary, and death. Our cubic mathematical model allows us to understand the fundamental nonlinear dynamics of LAB as well as its time-variant dependencies. Parameters of the model are written in terms of initial biomass, maximum biomass, maximum growth rate, and lag phase duration. Further, a statistical analysis was performed to compare our cubic primary model with the ones proposed by Gompertz, Baranyi, and Vázquez-Murado by computing the coefficient of determination R2, the residual sum of squares RSS, and the Akaike Information Criterion AIC. Results: The average statistical results from the cubic model are as follows: R2=0.820 providing a better fit than the other three models, RSS=0.658 and AIC=−6.499, where both values are lower than the other models considered in this study. Conclusion: The cubic primary model formulated in this work describes the behavior of biomass as it accurately represents the four phases of biomass growth in batch fermentation process.

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“…For example, temperature and higher activity of water (a w ) helps in rapid LAB growth reducing the pH. The smoke contributes to several aroma and antimicrobial substances like carbonyls, organic acids (formic, acetic, isobutyric, butyric, and propionic acids) and phenols (antioxidants) thereby coagulating superficial proteins and inhibiting microbes ( 79 ).…”

Section: Biochemical Modifications In Fermented Food Products Made Of...mentioning

confidence: 99%

Engineered Biofilm: Innovative Nextgen Strategy for Quality Enhancement of Fermented Foods

et al. 2022

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Microbial communities within fermented food (beers, wines, distillates, meats, fishes, cheeses, breads) products remain within biofilm and are embedded in a complex extracellular polymeric matrix that provides favorable growth conditions to the indwelling species. Biofilm acts as the best ecological niche for the residing microbes by providing food ingredients that interact with the fermenting microorganisms' metabolites to boost their growth. This leads to the alterations in the biochemical and nutritional quality of the fermented food ingredients compared to the initial ingredients in terms of antioxidants, peptides, organoleptic and probiotic properties, and antimicrobial activity. Microbes within the biofilm have altered genetic expression that may lead to novel biochemical pathways influencing their chemical and organoleptic properties related to consumer acceptability. Although microbial biofilms have always been linked to pathogenicity owing to its enhanced antimicrobial resistance, biofilm could be favorable for the production of amino acids like l-proline and L-threonine by engineered bacteria. The unique characteristics of many traditional fermented foods are attributed by the biofilm formed by lactic acid bacteria and yeast and often, multispecies biofilm can be successfully used for repeated-batch fermentation. The present review will shed light on current research related to the role of biofilm in the fermentation process with special reference to the recent applications of NGS/WGS/omics for the improved biofilm forming ability of the genetically engineered and biotechnologically modified microorganisms to bring about the amelioration of the quality of fermented food.

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Modeling the Combined Effects of Temperature, pH, and Sodium Chloride and Sodium Lactate Concentrations on the Growth Rate of Lactobacillus plantarum ATCC 8014

Cited by 19 publications

References 42 publications

Growth Kinetics of Probiotic Lactobacillus Strains in the Alternative, Cost-Efficient Semi-Solid Fermentation Medium

Growth Kinetics of Probiotic Lactobacillus Strains in the Alternative, Cost-Efficient Semi-Solid Fermentation Medium

Primary Model for Biomass Growth Prediction in Batch Fermentation

Engineered Biofilm: Innovative Nextgen Strategy for Quality Enhancement of Fermented Foods

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