Predictive modeling of <i>Pseudomonas fluorescens</i> growth under different temperature and pH values

Gonçalves, Letícia Dias dos Anjos; Piccoli, Roberta Hilsdorf; Peres, Alexandre de Paula; Saúde, André Vital

doi:10.1016/j.bjm.2016.12.006

Abstract

Meat is one of the most perishable foods owing to its nutrient availability, high water activity, and pH around 5.6. These properties are highly conducive for microbial growth. Fresh meat, when exposed to oxygen, is subjected to the action of aerobic psychrotrophic, proteolytic, and lipolytic spoilage microorganisms, such as Pseudomonas spp. The spoilage results in the appearance of slime and off-flavor in food. In order to predict the growth of Pseudomonas fluorescens in fresh meat at different pH values, stored under refrigeration, and temperature abuse, microbial mathematical modeling was applied. The primary Baranyi and Roberts and the modified Gompertz models were fitted to the experimental data to obtain the growth parameters. The Ratkowsky extended model was used to determine the effect of pH and temperature on the growth parameter µ_max. The program DMFit 3.0 was used for model adjustment and fitting. The experimental data showed good fit for both the models tested, and the primary and secondary models based on the Baranyi and Roberts models showed better validation. Thus, these models can be applied to predict the growth of P. fluorescens under the conditions tested.

Keywords:
Meat; Deterioration; Modeling

Introduction

Fresh meat is a highly perishable product owing to its high nutritious content. Many interrelated factors influence the shelf life and freshness of meat such as storage temperature, atmospheric oxygen (O₂), endogenous enzymes, moisture, light and most importantly, micro-organisms.¹1 Zhou GH, Xu XL, Liu Y. Preservation technologies for fresh meat – a review. Meat Sci. 2010;86:119-128. Therefore, meat is a complex niche with particular physicochemical characteristics that allow colonization and development of a wide variety of organisms,²2 Ercolini D, Russo F, Torrieri E, Mais P, Villani F. Changes in the spoilage related microbiota of beef during refrigerated storage under different packaging conditions. Appl Environ Microbiol. 2006;72:4663-4671. making it highly susceptible to be contaminated by spoilage bacteria.³3 Mayr D, Margesin R, Klingsbichel E, Hartungen E, Jenewein D, Schinner F, et al. Rapid detection of meat spoilage by measuring volatile organic compounds by using proton transfer reaction mass spectrometry. Appl Environ Microbiol. 2003;69:4697-4705. Microbial spoilage can lead to food disposal and consequent economic losses to the industry and a decrease in consumer trust.⁴4 Nychas GJE, Marshall DL, Sofos J. Meat, poultry, seafood. In: Doyle MP, Beuchat LR, Montville TJ, eds. Food Microbiology: Fundamentals and Frontiers. Washington: ASM; 2007:105–140.

Various conservation methods are available to increase the shelf life of fresh meat including refrigeration.⁵5 Ercolini D, Russo F, Nasi A, Ferranti P, Villani F. Mesophilic and psychrotrophic bacteria from meat and their spoilage potential in vitro and in beef. Appl Environ Microbiol. 2009;75:1990-2001. The use of cold temperatures, such as refrigeration and freezing, is considered the most effective method of retarding or inhibiting microbial growth in meat products during transportation or storage for maintaining product quality and extending shelf life.⁶6 Al-Jasser MS. Effect of cooling and freezing temperatures on microbial and chemical properties of chicken meat during storage. J Food Agric Environ. 2012;10:113-116. The use of refrigeration to preserve food is based on the reduced rate of metabolism in microorganisms at low temperatures.⁷7 Lebert I, Begot C, Lebert A. Growth of Pseudomonas fluorescens and Pseudomonas fragi in a meat medium as affected by pH (5.8–7.0), water activity (0.97–1.00) and temperature (7–25 °C). Int J Food Microbiol. 1998;39:53-56. The rate of enzyme-catalyzed reactions is temperature dependent, and considerably slows down at low temperatures. Therefore, it is extremely important to control and maintain the refrigeration temperature within the acceptable limits to ensure the security and integrity, and to extend the shelf life of meat products.⁸8 Zhou K, Fu P, Li P, Cheng W, Liang Z. Predictive modeling and validation of growth at different temperatures of Brochothrix thermosphacta. J Food Saf. 2009;29:460-473.

However, even in cold stored meat, the organoleptic spoilage by microbial consumption of meat nutrients, such as sugars and free amino acids, and the release of undesired volatile metabolites cannot be eliminated completely. These activities may be performed at low temperatures by psychrotrophic bacteria compromising preserving effect of low temperature.⁵5 Ercolini D, Russo F, Nasi A, Ferranti P, Villani F. Mesophilic and psychrotrophic bacteria from meat and their spoilage potential in vitro and in beef. Appl Environ Microbiol. 2009;75:1990-2001. These microorganism can thrive well at low temperatures via modifying their cytoplasmic membrane and increasing the unsaturated fatty acids levels, which keep the membrane in semifluid state, thereby facilitating the transport of nutrients and enzymes.⁹9 Madigan MT, Martinko JM, Dunlap PV, Clark DP. Microbiologia de brock. Artmed: Porto Alegre; 2010. Their ability to grow at low temperatures is one of the challenges to the meat industry while considering the meat quality and public health.¹⁰10 Barancelli GV, Contreras CCJ. Microbial deterioration of vacuum-packaged chilled beef cuts and techniques for microbiota detection and characterization: a review. Braz J Microbiol. 2011;42:1-11.

Pseudomonas spp. stand out among the psychotropic microorganisms, particularly, those involved in the spoilage of meat stored at low temperatures.¹¹11 Ercolini D, Casaburi A, Nasi A, Ferrocino I, Di Monaco R, Ferranti P, et al. Different molecular types of Pseudomonas fragi have the overall behavior as meat spoilers. Int J Food Microbiol. 2010;142:120-131. They are Gram-negative, aerobic, proteolytic and lipolytic microorganisms mostly associated with the deterioration of fresh meat. The most commonly found pseudomonas in meat is Pseudomonas fluorescens, which is characterized by producing a soluble pigment called pyoverdine.

Predictive microbiology can be used to assess the quality of food susceptible to deterioration by these spoiling microorganisms considering the fact that the behavior of the microbial population and its effect on environment can be predicted, as its status is known at any given time.¹²12 Ferrer J, Prats C, López D, Vives-Regot J. Mathematical modelling methodologies in predictive food microbiology: a SWOT analysis. Int J Food Microbiol. 2009;134:2-8. Thus, predictive models can be used to predict product quality and microbiological safety considering the product characteristics and processing and storage conditions.¹³13 Psomas AN, Nychas GJ, Haroutounian SA, Skandams PN. Development and validation of a tertiary simulation model for predicting the growth of the food microorganisms under dynamic and static temperature conditions. Comput Electron Agric. 2011;76:119-129.

This study aimed to construct and validate the mathematical models for predicting P. fluorescens growth at different temperatures and pH conditions.

Material and methods

Inoculum standardization and maintenance

Freeze-dried P. fluorescens strain ATCC 13525 was stored at -18 °C in a freezing medium containing 15 mL glycerol, 0.5 g bacteriological peptone, 0.3 g yeast extract, 0.5 g NaCl, and 100 mL distilled water. Prior to use, the strain was activated in brain heart infusion (BHI) broth (HiMedia, Mumbai, India) and incubated at 28 °C for 24 h to obtain the number of cells necessary for standardization.

Effect of storage temperature and pH of the medium on the growth of P. fluorescens in meat broth

Aliquots of the standardized inoculum were transferred to 100 mL meat broth (10 g meat extract, 10 g meat peptone, 5 g tryptone, and 5 g glucose in 1 L water) at a final concentration of 10⁴ CFU mL^-1, and incubated at 4 °C, 7 °C, and 12 °C.

The pH of the medium was adjusted to 5.5, 6.0, and 6.3 with 2 M NaOH or 2 M HCl using a digital pH meter (Digimed DM20, Campo Grande, Brazil).

The growth of P. fluorescens at each pH and temperature condition (4 °C and pH 5.5; 4 °C and pH 6.0; 4 °C and pH 6.3; 7 °C and pH 5.5; 7 °C and pH 6.0; 7 °C and pH 6.3; 12 °C and pH 5.0; 12 °C and pH 6.0; and 12 °C and pH 6.3) was monitored at 3, 6, 9, 12, 24, 30, 36, 48, 54, 60, 72, 84, 96, 108, and 120 h of incubation. At each interval, an aliquot of 1 mL was transferred to a tube containing 9 mL of 0.1% (w/v) peptone water, and was serially diluted. Subsequently, a 0.01-mL aliquot from appropriate dilutions was taken and plated on Trypticase Soy Agar (TSA) plates (HiMedia, Mumbai, India) by microdrop technique. The plates were incubated at 28 °C for 24 h, and the colonies were counted.

Analysis of growth data for obtaining models

The model for P. fluorescens growth in meat broth was developed using the two-stage methodology. In the first stage, the maximum specific growth rate (µ_max), and the lag phase (λ) were calculated for each experimental combination. The growth parameters were obtained by the modified Gompertz and Baranyi and Roberts equation to the experimental data by using DMFit 3.0 program. In the second stage, the estimates obtained for µ_max were adjusted for the extended Ratkowsky model to determine the effect of temperature and pH on the maximum specific growth rate of P. fluorescens, according to the following equation:

(1)

µ_{\max} = a (pH - {pH}_{mim}) {(T - T_{mim})}^{2}

where a is the regression constant, and pH_mim, T_mim are the minimum pH and minimum temperature, respectively, estimated theoretically for the microbial growth.

Validation of the results by statistical analysis of models

The following statistical parameters were calculated for the validation of the models: correlation coefficient (R²), mean square error (RMSE), bias factor, and accuracy factor.¹⁴14 Samapundo S, Devlieghere F, Meulenaer B, Geeraerd AH, Van Impe JF, Debevre JM. Predictive modelling of the individual and combined effect of water activity and temperature on the radial growth of Fusarium verticilliodes and F. proliferatum on corn. Int J Food Microbiol. 2005;105:35-52. The correlation coefficient (R²) describes the model fit throughout the length of the curve; the closer the value of R² is to one, the better the model fit is.

The mean square error (RMSE) is given by Eq. (2), and presents the model error relative to the data, that is, how close are the predicted values to the observed values; where the closer to zero indicates a better fit.

(2)

RMSE = \frac{SQR}{n} = Σ {(valueobs - valuepred)}^{2}

where valueobs is the experimental value, valuepred is the value predicted by the model, SQR is the sum of square residuals, and n is the number of degrees of freedom (number of data points - number of model parameters).

The bias factor shown in Eq. (3) gives the same weight to the average values that over- or underestimates the average, that is, an average relative deviation.

(3)

Bias factor = 10^{Σ \log [(valueobs - valuepred) / n]}

where valueobs is the experimental value, valuepred is the value predicted by the model, and n is the number of data points minus the number of model parameters.

The accuracy factor is the most reliable and accurate statistical measurement, as it uses both, the predicted and observed values, and determines the percentage prediction error. This factor takes into account only the absolute values. The closer the value is to 1, the lower the percentage error is. The calculation factor is corrected by Eq. (4).

(4)

Accuracy factor = 10^{Σ | \log (valueobs - valuepred) |} / n

where valueobs is the experimental value; valuepred is the value predicted by the model, and n is the number of data points minus the number of model parameters.

Results and discussion

Primary growth model of P. fluorescens in meat broth

Table 1 shows the growth parameters for P. fluorescens at three different temperatures and pH values.

The modeled growth parameters in Table 1 show that, in general, different pH values did not affect the growth of P. fluorescens at a given temperature. This is evident, for example, considering the concentration of 5 log CFU mL^-1, when the deterioration process starts. This concentration of population is reached in about 50 h at all temperatures, regardless of the pH value (Fig. 1).

Thumbnail

Table 1
Growth parameters of P. fluorescens in meat broth at 4 ºC, 7 ºC, and 12 ºC, and pH 5.5, 6.0, and 6.3.

Fig. 1
Primary growth modeling of P. fluorescens at 4 °C and pH 5.5 (A), pH 6.0 (B), and pH 6.3 (C).

The final meat pH can vary from 5.5 to 7.0, and is highly dependent on the amount of glycogen present in the tissue at the time of slaughter, since it turns into lactic acid after slaughter.¹⁵15 Baranyi J, Métris A, Le MY, Elfwing A, Ballagi A. Modelling the variability of lag times and the first generation times of single cells of E. coli. Int J Food Microbiol. 2005;100:13-19. The final pH value directly affects microbial growth,¹⁶16 Cardenas FC, Giannuzzi L, Zaritzky NE. Mathematical modelling of microbial growth in ground beef from Argentina: effect of lactic acid addition, temperature and packaging film. Meat Sci. 2008;79:509-520. as at low pH, weak acids in the undissociated form can pass through the plasma membrane of the microorganism. Then, the acid dissociates by consuming ATP, releasing protons, and stabilizing pH; this results in cell death.¹⁷17 Axe DD, Bailey JE. Transport of lactate and acetate through the energized cytoplasmic membrane of Escherichia coli. Biotechnol Bioeng. 1995;47:8-19. On the other hand, when food is stored under aerobic conditions, the pH tends to increase, leading the total cell counts greater than 10⁷ CFU mL^-2. These changes are caused possibly due to the formation of basic substances synthesized mainly during the pseudomonas growth.¹⁸18 Mano SB, Ordenez JA, Fernando GDG. Growth/survival of natural flora and Aeromonas hydrophila on refrigerated uncooked pork and turkey packaged in modified atmospheres. Int J Food Microbiol. 2000;17:657-669. However, this relationship between the increased microbial growth rate and higher pH values was observed only at 12 °C. An earlier study investigated the microbiological deterioration of ground beef at a pH range from 5.34 to 6.13, and found a significant effect of meat pH on the growth kinetic parameters of pseudomonas.¹⁹19 Koutsoumanis K, Stamatiou A, Skandamis P, Nychas GJE. Development of a microbial model for the combined effect of temperature and pH on spoilage of ground meat, and validation of the model under dynamic temperature conditions. Appl Environ Microbiol. 2006;72:124-134. In contrast, some other studies¹⁶16 Cardenas FC, Giannuzzi L, Zaritzky NE. Mathematical modelling of microbial growth in ground beef from Argentina: effect of lactic acid addition, temperature and packaging film. Meat Sci. 2008;79:509-520.^,²⁰20 Zuliani V, Lebert I, Augustin JC, Garry P, Vendeuvre JL, Lebert A. Modelling the behaviour of Listeria monocytogenes in ground pork as a function of pH, water activity, nature and concentration of organic acid salts. J Appl Microbiol. 2007;103:536-550. reported that, depending on the conditions, pH might not have effect on microbial growth in a range close to that employed in this work.

Moreover, it was observed that the increase in storage temperature from 4 °C to 12 °C led to a decrease in the lag phase and an increase in the exponential phase. This behavior led to a population concentration of about 6 log CFU mL^-1 after 70, 40, and 24 h, at 4 °C, 7 °C, and 12 °C, respectively, independent of the pH value (Figs. 1^–3).

Fig. 2
Primary growth model of P. fluorescens at 7 °C and pH 5.5 (A), pH 6.0 (B), and pH 6.3 (C).

Fig. 3
Primary growth model of P. fluorescens at 12 °C and pH 5.5 (A), pH 6.0 (B), and pH 6.3 (C).

A study investigated the prediction of shelf life of pork, and found that the total viable count reached 6 log CFU mL^-1 after 25 h, 60 h, and 100 h at 15 °C, 7 °C, and 4 °C, respectively.²¹21 Tang X, Suna X, Wu VCH, Xie J, Pana Y, Zhao Y, et al. Predicting shelf-life of chilled pork sold in China. Food Control. 2013;32:334-340.

As shown in Table 1, a higher lag phase was observed at 7 °C and pH 5.5 by the adjustment of the two primary models to the experimental data. Moreover, the lag phase (λ) was lower at the highest pH (6.3) tested, probably because most bacteria grow best in an environment having pH near to neutral (7.0). However, despite the growing conditions at 7 °C, a higher lag phase was observed at more acidic pH (5.5), and the same was also observed for µ_max. This behavior is opposite of that observed by other authors, as Gospavic et al.²²22 Gospavic R, Kreyenschmidt J, Bruckner S, Popov V, Haque N. Mathematical modeling for predicting the growth of Pseudomonas spp. in poultry under variable temperature conditions. Int J Food Microbiol. 2008;127:290-297. and Koutsomanis et al.²³23 Koutsoumanis K, Giannakourou MC, Taoukis PS, Nychas GJ. Application of shelf life decision system (SLDS) to marine cultured fish quality. Int J Food Microbiol. 2002;73:375-382. found that at a higher lag phase, the maximum growth rate was lower. It is important to mention that these authors used a higher temperature range of 0–15 °C and 0–20 °C, compared to the one used in this work. It is noteworthy that the findings of Gospavic et al.²²22 Gospavic R, Kreyenschmidt J, Bruckner S, Popov V, Haque N. Mathematical modeling for predicting the growth of Pseudomonas spp. in poultry under variable temperature conditions. Int J Food Microbiol. 2008;127:290-297. have shown that the growth of Pseudomonas spp. adjusted to the modified Gompertz model presented a higher lag phase at 2 °C and 4 °C, corroborating the increase in µ_max. The decrease in λ and the increase in µ_max become clear when the values at 2 °C and 4 °C are compared with those obtained at 15 °C and 20 °C. The maximum tested value in this work was 12 °C.

At 12 °C, the estimated λ values adjusted by the Baranyi and Roberts model to the experimental data were very low. In contrast, these values were not estimated by the modified Gompertz model, evidencing no lag phase at 12 °C.

With respect to the temperature increase from 7 °C to 12 °C, although a decrease in lag phase was observed, no significant changes were observed for the maximum specific growth rate, as can be seen in Table 1. At a greater range of growing conditions such as 4 °C and 12 °C, the λ values significantly decreased, while µ_max increased considerably.

The modified Gompertz model could not estimate the λ value either for the growing condition at 4 °C and pH 5.5 or at 12 °C. As the P. fluorescens culture was activated before being inoculated in meat broth, the lag phase might have been suppressed. In addition, the Gompertz model does not consider the adaptation phase (lag phase), but only the increase in the number of cells within the exponential growth.¹⁵15 Baranyi J, Métris A, Le MY, Elfwing A, Ballagi A. Modelling the variability of lag times and the first generation times of single cells of E. coli. Int J Food Microbiol. 2005;100:13-19. Therefore, in some growth conditions, this phase could not be estimated by this model.

In the combined effect of the pH and incubation temperature on P. fluorescens growth, in general, higher temperature and higher pH result in the higher specific growth rate but lower lag phase. Thus, meat with initial pH closer to neutral and stored under temperature abuse may have short shelf life.

Table 2 shows the coefficient of determination (R²) and the root mean square error (RMSE) for the primary models.

Thumbnail

Table 2
R² and RMSE of primary growth model for P. fluorescens.

For all growing conditions shown in Table 2, the primary models showed good fit to the experimental data, with R ² values very close to 1; and low RMSE values demonstrated that the predicted values are close to the observed values, which ensure the validation of data. Gospavic et al.²²22 Gospavic R, Kreyenschmidt J, Bruckner S, Popov V, Haque N. Mathematical modeling for predicting the growth of Pseudomonas spp. in poultry under variable temperature conditions. Int J Food Microbiol. 2008;127:290-297. modeled the growth of Pseudomonas spp. in poultry at different temperature conditions, and also found good fit to the data by the Baranyi and Roberts and the modified Gompertz models.

Table 3 shows the Baranyi and Roberts and the modified Gompertz models for P. fluorescens at 4 °C, 7 °C, and 12 °C, and pH 5.5, 6.0, and 6.3.

Thumbnail

Table 3
The Baranyi and Roberts and the modified Gompertz growth models for P. fluorescens at 4 ºC, 7 ºC and 12 ºC, and pH 5.5, 6.0, and 6.3.

Once validated, the equations (Table 3) can be used for prediction of P. fluorescens growth in meat broth under the conditions tested.

Therefore, for the growing conditions employed in this study, it is possible to assess the cell concentration rate over time using the equations generated in the Baranyi and Roberts models. In addition, it is also possible to assess the cell concentration at any time by the equations generated by the modified Gompertz model.

Many studies have used combination of the sensory evaluation and the predictive microbiology to estimate the shelf life of a particular food. Kreyenschmidt et al.²⁴24 Kreyenschmidt J, Hübner A, Beierle E, Chonsch L, Scherer A, Petersen B. Determination of the shelf life of sliced cooked ham based on the growth of lactic acid bacteria in different steps of the chain. J Appl Microbiol. 2010;108:510-520. and Nychas et al.²⁵25 Nychas GJE, Skandamis PN, Tassou CC, Koutsoumanis KP. Meat spoilage during distribution. Meat Sci. 2008;78:77-89. estimated, by sensory parameters, the shelf life of poultry infected by Pseudomonas spp. when microbial population reached 7 log CFU g^-1 using the prediction curves obtained by the primary models. Then, the authors calculated the time to achieve a growth rate of 7 log CFU g^-1 under the environmental conditions tested, which was considered the end of shelf life for the meat. Therefore, the predictive models can also be used for the estimation of shelf life of food products.

Secondary growth model for P. fluorescens in meat broth

Table 4 shows the secondary models generated for the effect of temperature and pH on the maximum specific growth rate.

Thumbnail

Table 4
Secondary models for P. fluorescens.

The statistical parameters for the validation of the secondary model for the growth data are shown in Table 5.

Thumbnail

Table 5
Statistical parameters, R ², RMSE, bias factor, and accuracy factor for validation secondary modeling of P. fluorescens.

Considering the data in Table 3, a secondary Ratkowsky model was used to evaluate the effect of pH and incubation temperature on P. fluorescens growth, which was best validated from primary data (µ_max) generated by the Baranyi and Roberts model, since it has smaller RMSE, and R², and the bias factor and accuracy factor are close to 1.

Conclusion

The primary models generated showed a good fit to the experimental data and can be used to predict the growth of P. fluorescens under the conditions employed in this study. The primary modeling showed that the increase or decrease in pH had a little effect on the microbial growth parameters, when compared with the temperature conditions. With respect to the combined effect of temperature and pH, in general, the increase in temperature concomitant with higher pH led to an increase in µ_max and a decrease in λ value, resulting in a shorter shelf life, especially considering the temperature abuse tested.

The secondary modeling using the Ratkowsky model obtained from the data of the Baranyi model was validated better than that obtained by the Gompertz model, especially because the latter showed a low goodness of fit indices.

Thus, the equation in the secondary model obtained from the Baranyi model can be used to predict the effect of pH and temperature on P. fluorescens growth.

Acknowledgements

The authors thank CAPES for granting master's scholarship, and Federal University of Lavras and Mitah Technologies for the encouragement and facilitation of executing the study.

References

¹
Zhou GH, Xu XL, Liu Y. Preservation technologies for fresh meat – a review. Meat Sci 2010;86:119-128.
²
Ercolini D, Russo F, Torrieri E, Mais P, Villani F. Changes in the spoilage related microbiota of beef during refrigerated storage under different packaging conditions. Appl Environ Microbiol 2006;72:4663-4671.
³
Mayr D, Margesin R, Klingsbichel E, Hartungen E, Jenewein D, Schinner F, et al. Rapid detection of meat spoilage by measuring volatile organic compounds by using proton transfer reaction mass spectrometry. Appl Environ Microbiol 2003;69:4697-4705.
⁴
Nychas GJE, Marshall DL, Sofos J. Meat, poultry, seafood. In: Doyle MP, Beuchat LR, Montville TJ, eds. Food Microbiology: Fundamentals and Frontiers. Washington: ASM; 2007:105–140.
⁵
Ercolini D, Russo F, Nasi A, Ferranti P, Villani F. Mesophilic and psychrotrophic bacteria from meat and their spoilage potential in vitro and in beef. Appl Environ Microbiol 2009;75:1990-2001.
⁶
Al-Jasser MS. Effect of cooling and freezing temperatures on microbial and chemical properties of chicken meat during storage. J Food Agric Environ. 2012;10:113-116.
⁷
Lebert I, Begot C, Lebert A. Growth of Pseudomonas fluorescens and Pseudomonas fragi in a meat medium as affected by pH (5.8–7.0), water activity (0.97–1.00) and temperature (7–25 °C). Int J Food Microbiol 1998;39:53-56.
⁸
Zhou K, Fu P, Li P, Cheng W, Liang Z. Predictive modeling and validation of growth at different temperatures of Brochothrix thermosphacta. J Food Saf 2009;29:460-473.
⁹
Madigan MT, Martinko JM, Dunlap PV, Clark DP. Microbiologia de brock Artmed: Porto Alegre; 2010.
¹⁰
Barancelli GV, Contreras CCJ. Microbial deterioration of vacuum-packaged chilled beef cuts and techniques for microbiota detection and characterization: a review. Braz J Microbiol. 2011;42:1-11.
¹¹
Ercolini D, Casaburi A, Nasi A, Ferrocino I, Di Monaco R, Ferranti P, et al. Different molecular types of Pseudomonas fragi have the overall behavior as meat spoilers. Int J Food Microbiol 2010;142:120-131.
¹²
Ferrer J, Prats C, López D, Vives-Regot J. Mathematical modelling methodologies in predictive food microbiology: a SWOT analysis. Int J Food Microbiol. 2009;134:2-8.
¹³
Psomas AN, Nychas GJ, Haroutounian SA, Skandams PN. Development and validation of a tertiary simulation model for predicting the growth of the food microorganisms under dynamic and static temperature conditions. Comput Electron Agric. 2011;76:119-129.
¹⁴
Samapundo S, Devlieghere F, Meulenaer B, Geeraerd AH, Van Impe JF, Debevre JM. Predictive modelling of the individual and combined effect of water activity and temperature on the radial growth of Fusarium verticilliodes and F. proliferatum on corn. Int J Food Microbiol. 2005;105:35-52.
¹⁵
Baranyi J, Métris A, Le MY, Elfwing A, Ballagi A. Modelling the variability of lag times and the first generation times of single cells of E. coli. Int J Food Microbiol 2005;100:13-19.
¹⁶
Cardenas FC, Giannuzzi L, Zaritzky NE. Mathematical modelling of microbial growth in ground beef from Argentina: effect of lactic acid addition, temperature and packaging film. Meat Sci 2008;79:509-520.
¹⁷
Axe DD, Bailey JE. Transport of lactate and acetate through the energized cytoplasmic membrane of Escherichia coli. Biotechnol Bioeng 1995;47:8-19.
¹⁸
Mano SB, Ordenez JA, Fernando GDG. Growth/survival of natural flora and Aeromonas hydrophila on refrigerated uncooked pork and turkey packaged in modified atmospheres. Int J Food Microbiol 2000;17:657-669.
¹⁹
Koutsoumanis K, Stamatiou A, Skandamis P, Nychas GJE. Development of a microbial model for the combined effect of temperature and pH on spoilage of ground meat, and validation of the model under dynamic temperature conditions. Appl Environ Microbiol. 2006;72:124-134.
²⁰
Zuliani V, Lebert I, Augustin JC, Garry P, Vendeuvre JL, Lebert A. Modelling the behaviour of Listeria monocytogenes in ground pork as a function of pH, water activity, nature and concentration of organic acid salts. J Appl Microbiol 2007;103:536-550.
²¹
Tang X, Suna X, Wu VCH, Xie J, Pana Y, Zhao Y, et al. Predicting shelf-life of chilled pork sold in China. Food Control. 2013;32:334-340.
²²
Gospavic R, Kreyenschmidt J, Bruckner S, Popov V, Haque N. Mathematical modeling for predicting the growth of Pseudomonas spp. in poultry under variable temperature conditions. Int J Food Microbiol 2008;127:290-297.
²³
Koutsoumanis K, Giannakourou MC, Taoukis PS, Nychas GJ. Application of shelf life decision system (SLDS) to marine cultured fish quality. Int J Food Microbiol. 2002;73:375-382.
²⁴
Kreyenschmidt J, Hübner A, Beierle E, Chonsch L, Scherer A, Petersen B. Determination of the shelf life of sliced cooked ham based on the growth of lactic acid bacteria in different steps of the chain. J Appl Microbiol. 2010;108:510-520.
²⁵
Nychas GJE, Skandamis PN, Tassou CC, Koutsoumanis KP. Meat spoilage during distribution. Meat Sci. 2008;78:77-89.

Publication Dates

Publication in this collection
Apr-Jun 2017

History

Received
7 May 2015
Accepted
13 Oct 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ¹
Zhou GH, Xu XL, Liu Y. Preservation technologies for fresh meat – a review. Meat Sci 2010;86:119-128.

[2] ²
Ercolini D, Russo F, Torrieri E, Mais P, Villani F. Changes in the spoilage related microbiota of beef during refrigerated storage under different packaging conditions. Appl Environ Microbiol 2006;72:4663-4671.

[3] ³
Mayr D, Margesin R, Klingsbichel E, Hartungen E, Jenewein D, Schinner F, et al. Rapid detection of meat spoilage by measuring volatile organic compounds by using proton transfer reaction mass spectrometry. Appl Environ Microbiol 2003;69:4697-4705.

[4] ⁴
Nychas GJE, Marshall DL, Sofos J. Meat, poultry, seafood. In: Doyle MP, Beuchat LR, Montville TJ, eds. Food Microbiology: Fundamentals and Frontiers. Washington: ASM; 2007:105–140.

[5] ⁵
Ercolini D, Russo F, Nasi A, Ferranti P, Villani F. Mesophilic and psychrotrophic bacteria from meat and their spoilage potential in vitro and in beef. Appl Environ Microbiol 2009;75:1990-2001.

[6] ⁶
Al-Jasser MS. Effect of cooling and freezing temperatures on microbial and chemical properties of chicken meat during storage. J Food Agric Environ. 2012;10:113-116.

[7] ⁷
Lebert I, Begot C, Lebert A. Growth of Pseudomonas fluorescens and Pseudomonas fragi in a meat medium as affected by pH (5.8–7.0), water activity (0.97–1.00) and temperature (7–25 °C). Int J Food Microbiol 1998;39:53-56.

[8] ⁸
Zhou K, Fu P, Li P, Cheng W, Liang Z. Predictive modeling and validation of growth at different temperatures of Brochothrix thermosphacta. J Food Saf 2009;29:460-473.

[9] ⁹
Madigan MT, Martinko JM, Dunlap PV, Clark DP. Microbiologia de brock Artmed: Porto Alegre; 2010.

[10] ¹⁰
Barancelli GV, Contreras CCJ. Microbial deterioration of vacuum-packaged chilled beef cuts and techniques for microbiota detection and characterization: a review. Braz J Microbiol. 2011;42:1-11.

[11] ¹¹
Ercolini D, Casaburi A, Nasi A, Ferrocino I, Di Monaco R, Ferranti P, et al. Different molecular types of Pseudomonas fragi have the overall behavior as meat spoilers. Int J Food Microbiol 2010;142:120-131.

[12] ¹²
Ferrer J, Prats C, López D, Vives-Regot J. Mathematical modelling methodologies in predictive food microbiology: a SWOT analysis. Int J Food Microbiol. 2009;134:2-8.

[13] ¹³
Psomas AN, Nychas GJ, Haroutounian SA, Skandams PN. Development and validation of a tertiary simulation model for predicting the growth of the food microorganisms under dynamic and static temperature conditions. Comput Electron Agric. 2011;76:119-129.

[14] ¹⁴
Samapundo S, Devlieghere F, Meulenaer B, Geeraerd AH, Van Impe JF, Debevre JM. Predictive modelling of the individual and combined effect of water activity and temperature on the radial growth of Fusarium verticilliodes and F. proliferatum on corn. Int J Food Microbiol. 2005;105:35-52.

[15] ¹⁵
Baranyi J, Métris A, Le MY, Elfwing A, Ballagi A. Modelling the variability of lag times and the first generation times of single cells of E. coli. Int J Food Microbiol 2005;100:13-19.

[16] ¹⁶
Cardenas FC, Giannuzzi L, Zaritzky NE. Mathematical modelling of microbial growth in ground beef from Argentina: effect of lactic acid addition, temperature and packaging film. Meat Sci 2008;79:509-520.

[17] ¹⁷
Axe DD, Bailey JE. Transport of lactate and acetate through the energized cytoplasmic membrane of Escherichia coli. Biotechnol Bioeng 1995;47:8-19.

[18] ¹⁸
Mano SB, Ordenez JA, Fernando GDG. Growth/survival of natural flora and Aeromonas hydrophila on refrigerated uncooked pork and turkey packaged in modified atmospheres. Int J Food Microbiol 2000;17:657-669.

[19] ¹⁹
Koutsoumanis K, Stamatiou A, Skandamis P, Nychas GJE. Development of a microbial model for the combined effect of temperature and pH on spoilage of ground meat, and validation of the model under dynamic temperature conditions. Appl Environ Microbiol. 2006;72:124-134.

[20] ²⁰
Zuliani V, Lebert I, Augustin JC, Garry P, Vendeuvre JL, Lebert A. Modelling the behaviour of Listeria monocytogenes in ground pork as a function of pH, water activity, nature and concentration of organic acid salts. J Appl Microbiol 2007;103:536-550.

[21] ²¹
Tang X, Suna X, Wu VCH, Xie J, Pana Y, Zhao Y, et al. Predicting shelf-life of chilled pork sold in China. Food Control. 2013;32:334-340.

[22] ²²
Gospavic R, Kreyenschmidt J, Bruckner S, Popov V, Haque N. Mathematical modeling for predicting the growth of Pseudomonas spp. in poultry under variable temperature conditions. Int J Food Microbiol 2008;127:290-297.

[23] ²³
Koutsoumanis K, Giannakourou MC, Taoukis PS, Nychas GJ. Application of shelf life decision system (SLDS) to marine cultured fish quality. Int J Food Microbiol. 2002;73:375-382.

[24] ²⁴
Kreyenschmidt J, Hübner A, Beierle E, Chonsch L, Scherer A, Petersen B. Determination of the shelf life of sliced cooked ham based on the growth of lactic acid bacteria in different steps of the chain. J Appl Microbiol. 2010;108:510-520.

[25] ²⁵
Nychas GJE, Skandamis PN, Tassou CC, Koutsoumanis KP. Meat spoilage during distribution. Meat Sci. 2008;78:77-89.

Growing conditions	Baranyi and Roberts		Gompertz
	λ (h)	µ_max (h^-1)	λ (h)	µ_max (h^-1)
4 ºC and pH 5.5	19.99	0.040149	-	0.030961
4 ºC and pH 6.0	18.64	0.043955	18.63	0.042155
4 ºC and pH 6.3	19.65	0.043430	20.59	0.042679
7 ºC and pH 5.5	20.86	0.082562	19.75	0.075270
7 ºC and pH 6.0	18.74	0.081530	16.43	0.070892
7 ºC and pH 6.3	14.89	0.071963	14.42	0.067418
12 ºC and pH 5.5	8.27 × 10^-8	0.087592	-	0.070049
12 ºC and pH 6.0	7.91 × 10^-8	0.092016	-	0.074098
12 ºC and pH 6.3	1.43 × 10^-7	0.100424	-	0.086309

Growing conditions	Baranyi and Roberts		Gompertz
	R ²	RMSE	R ²	RMSE
4 ºC pH 5.5	0.98	0.1701	0.97	0.2105
4 ºC pH 6.0	0.99	0.1026	0.99	0.0959
4 ºC pH 6.3	0.99	0.8333	0.99	0.0854
7 ºC pH 5.5	0.989	0.1703	0.996	0.1077
7 ºC pH 6.0	0.990	0.1469	0.993	0.1284
7 ºC pH 6.3	0.992	0.1400	0.994	0.1154
12 ºC pH 5.5	0.987	0.1815	0.972	0.2612
12 ºC pH 6.0	0.991	0.1614	0.979	0.2505
12 ºC pH 6.3	0.984	0.2126	0.968	0.2967

Model	Growing conditions	Equation
Baranyi and Roberts	4 ºC pH 5.5	dN/dt = -2.23159 * 0.040149 * [1 - N(t)/7.412011] * N(t)
	4 ºC pH 6.0	dN/dt = -2.2691713 * 0.043955 * [1 - N(t)/7.225329] * N(t)
	4 ºC pH 6.3	dN/dt = -2.3479932 * 0.04343 * [1 - N(t)/7.281148] * N(t)
Gompertz	4 ºC pH 5.5	Log N(t) = 3.797973 + 3.62246489exp{-exp [-0.023233(t-43.04189)]}
	4 ºC pH 6.0	Log N(t) = 3.952039 + 3.19371571exp{-exp [-0.03588(t-46.49816)]}
	4 ºC pH 6.3	Log N(t) = 3.952664 + 3.24166902exp{-exp [-0.035789 (t-48.53329)]}
Baranyi and Roberts	7 ºC pH 5.5	dN/dt = 5.5991153 * 0.082562 * [1 - N(t)/8.264927] * N(t)
	7 ºC pH 6.0	dN/dt = -4.6091953 * 0.08153 * [1 - N(t)/8.163269] * N(t)
	7 ºC pH 6.3	dN/dt = 2.9202683 * 0.071963 * [1 - N(t)/8.157786] * N(t)
Gompertz	7 ºC pH 5.5	Log N(t) = 4.344648 + 3.8213554exp{-exp[-0.053543 (t-38.4268)]}
	7 ºC pH 6.0	Log N(t) = 4.523484 + 3.56886414exp{-exp[-0.053996 (t-34.94508)]}
	7 ºC pH 6.3	Log N(t) = 4.361284 + 3.66777251exp{-exp[-0.49965 (t-34.4322)]}
Baranyi and Roberts	12 ºC pH 5.5	dN/dt = -1 * 0.087592 * [1 - N(t)/7.25E-09] * N(t)
	12 ºC pH 6.0	dN/dt = -1 * 0.092016 * [1 - N(t)/7.28E-09] * N(t)
	12 ºC pH 6.3	dN/dt = -1 * 0.0100424 * [1 - N(t)/1.44E-08] * N(t)
Gompertz	12 ºC pH 5.5	Log N(t) = 3.79214 + 3.93009306exp{-exp [-0.04845 (t-20.63974)]}
	12 ºC pH 6.0	Log N(t) = 4.17734 + 4.31045923exp{-exp[0.046728 (t-21.40046)]}
	12 ºC pH 6.3	Log N(t) = 4.053301 + 4.15074063exp{-exp 0.056523 (t-17.69189)]}

Primary model	Secondary model of the square root
Baranyi and Roberts	µ_max = 0.0000267 × [(T - (-14.6619))²] × (pH -0.707962)
Gompertz	µ_max = 0.00000224 × [(T - (-64.1401))²] × (pH -0.631746)

Models	R ²	RMSE	Bias factor	Accuracy factor
1	0.7134	0.0243	0.9990	1.6233
2	0.2310	0.0351	0.9781	2.6231

Brasil

Brasil

Predictive modeling of Pseudomonas fluorescens growth under different temperature and pH values

Abstract

Introduction

Material and methods

Inoculum standardization and maintenance

Effect of storage temperature and pH of the medium on the growth of P. fluorescens in meat broth

Analysis of growth data for obtaining models

Validation of the results by statistical analysis of models

Results and discussion

Primary growth model of P. fluorescens in meat broth

Secondary growth model for P. fluorescens in meat broth

Conclusion

Acknowledgements

References

Publication Dates

History