Abstract

INTRODUCTION

According to the recently adopted definition by FAO/WHO, probiotics are live microorganisms, which when administered in adequate amounts confer a health benefit on the host (Hemaiswarya et al. 2013Hemaiswarya S, Raja R, Ravikumar R, Carvalho IS. Mechanism of Action of Probiotics. Braz Arch Biol Technol. 2013; 56: 113-119.). Probiotics are not a new invention but have existed in traditional foods such as beverages, salty fishes, yogurt, different types of cheeses, etc since olden times (Amara and shibl 2013Amara AA, Shibal A. Role of Probiotics in health improvement, infection control and disease treatment and management-review. Saudi Pharmac J. 2013; doi: 10.1016/j.jsps.2013.07.001
https://doi.org/10.1016/j.jsps.2013.07.0... ). Several microbial groups have the potential to function as probiotics but the species of Lactobacillus and Bifidobacterium are the most commonly used as probiotics, including certain yeast and bacilli (Singh et al. 2011Singh K, Kallali B, Kumar A, Thaker V. Probiotics: A review. Asian Pac J Trop Biomed. 2011; S287-S290.). Most bacterial species of this class are formally classified as GRAS (generally recognized as safe) organisms. The popularity of these microbes is based on the millennia of use in food and feed that are used in probiotic dairy drinks and yoghurts since hundreds of years (Sanders 1999). Currently, consumers are very much concerned about the sensorial, nutritional and functional attributes of food worldwide. A number of health benefits, which may be direct or indirect such as enhanced barrier function, modulation of the mucosal immune system, production of antimicrobial agents, enhancement of digestion and absorption of food and alteration of the intestinal microflora (Hemaiswarya et al. 2013Hemaiswarya S, Raja R, Ravikumar R, Carvalho IS. Mechanism of Action of Probiotics. Braz Arch Biol Technol. 2013; 56: 113-119.), anti-mutagenic effects, anti-carcinogenic properties, improvement in lactose metabolism, reduction in serum cholesterol and immune system stimulation (Shah 2007Shah NP. Functional Cultures and Health Benefits. Int Dairy J. 2007; 17: 1262-1277.), better calcium absorption, prevention of allergy and reduction in dental decay are associated with the consumption of probiotics (Singh et al. 2011Singh K, Kallali B, Kumar A, Thaker V. Probiotics: A review. Asian Pac J Trop Biomed. 2011; S287-S290.).

According to a recent market research report, 'Probiotics Market (2009;2014)', the global probiotics market generated US$15.9 billion in 2008 and was expected to be worth US$ 32.6 billion by 2014 with a compound annual growth rate of 12.6% from 2009 to 2014. India is fast emerging as a potential market for probiotics in foods with several companies such as Nestle, Mother Dairy, Danisco, Chr Hansen, Yakult and Danone. The probiotic product industry in India is an estimated 20.6 million with a projected annual growth rate of 22.6% until 2015 (Ganguly et al. 2011Ganguly NK, Bhattacharya SK, Nair GB, Ramakrishna BS, Sachdev HPS, Batish VK. et al. ICMR-DBT guidelines for evaluation of probiotics in food. Indian J Med Res. 2011; 134: 22-25.). Probiotics in India generally come in two forms, viz., milk and fermented milk products with the former constituting a major chunk (50-60%) of the market. List of probiotic containing foods is wide and still growing. Main products existing in the market are dairy-based, including fermented milks, cheese, ice cream, buttermilk, milk powder, and yogurts, the latter accounting for the largest share of sales. Usually, dairy products are known as the 'best carrier' of probiotics.

Probiotic bacteria such as Lactobacillus and Bifidobacterium can play an important role in promoting human health in the gastrointestinal tract (Mitsuoka 1990Mitsuoka T. Bifidobacteria and their role in human health. J Ind Microbiol. 1990; 6: 263-268.). They actively contribute in the digestion, immune stimulation and inhibition of pathogens such as Bacteroides, Escherichia, Clostriduim and Proteus, which are potentially harmful bacteria found in the gastrointestinal tract (Ziemer and Gibson 1998Ziemer CJ, Gibson GR. An overview of Probiotics, Prebiotics and Symbiotic in the Functional Food Concept: Perspectives and Future Strategies. Int Dairy J. 1998; 8: 473-479.). Recently, systematic reviews on the health benefits of probiotics in details have been published (Aureli et al. 2011Aureli P, Capurso L, Castellazzi AM, Clerici M, Giovannini M, Morelli L. et al. Probiotics and health: An evidence-based review. Pharmacol Res. 2011; 63: 366-376.; Amara and Shibl 2013Amara AA, Shibal A. Role of Probiotics in health improvement, infection control and disease treatment and management-review. Saudi Pharmac J. 2013; doi: 10.1016/j.jsps.2013.07.001
https://doi.org/10.1016/j.jsps.2013.07.0... ). The effectiveness of the probiotic effects generally depends on the mechanisms by which they exerts their activities. Mostly, to treat a disease, the probiotics follow a set of mechanisms, which were recently reviewed (Hemaiswarya et al. 2013Hemaiswarya S, Raja R, Ravikumar R, Carvalho IS. Mechanism of Action of Probiotics. Braz Arch Biol Technol. 2013; 56: 113-119.). The primary mechanism for probiotic action is known as competitive colonization, or competitive suppression, best described as the proliferation of probiotic bacteria in the human intestine, leaving little space and food for the growth of any pathogens. Secondary, the by-products (i.e., lactic acid and acetic acid) secreted by these probiotics lowers the pH, thereby creating a hostile environment for the growth of pathogenic microorganisms. The secreted acids also increases the peristalsis, which also helps to speed pathogens out from the intestines (Ballongue 1992; Biavati et al. 2000Biavati B, Vescovo M, Torriabi S, Bottazzi V. Bifidobacteria: history, ecology, physiology and applications. Analyt Microbiol. 2000; 50: 117-131.).

Traditional, i.e., one variable at-a-time (OVAT) method of bacterial growth optimization is not only time consuming but also neglects interactions of different variables, which affects the yield. Process optimization through statistical method is a technique in which changes or adjustments are made in a process to get better results (Myers and Montgomery 2002Myers RM, Montgomery DC. Response Surface Methodology: Process and Product Optimization Using Designed Experiments. 2nd ed. Hoboken: Wiley-Interscience, 2002.). There are several techniques for process optimization such as Response Surface Methodology (RSM), Artificial Neural Networks (ANN), Genetic Algorithms (GA), etc. In these engineering applications, a response of interest is usually influenced by several variables and the objective of the engineering applications is to find the variables that can optimize the response. RSM is a tool to study the optimal process parameters that produce a maximum, or minimum value of the response and represents the direct and interactive effects of the process parameters through two and three-dimensional plots (Gangadharan et al. 2008Gangadharan D, Sivaramakrishnan S, Nampoothiri KM, Sukumaran RK, Pandey A. Response surface methodology for the optimization of alpha amylase production by Bacillus amyloliquefaciens. Bioresource Technol. 2008; 99: 4597-4602.). ANN is computational model of nervous systems. Natural organisms, however, do not possess only nervous systems but also have genetic information stored in the nucleus of their cells (genotype). The nervous system is part of the phenotype, which is derived from this genotype through a process, called development (Rajasekaran and Vijaylakshmi 2004Rajasekaran S, Vijaylakshmi PGS. Neural Networks Fuzzy Logic and Genetic Algorithms. 1st ed. New Delhi: Prentice Hall of India, 2004.). Using the method of neural networks (NN), the relationship between a set of independent variables X and the dependent variables Y can be obtained. From the given pairs of input X and output Y data, neural network directly learns and develops a relationship between them but does not yield any mathematical equation relating the variables. After the learning, this network is able to predict the correct output from an input data set that has not been previously used during the learning. GA is a tool by which the optimization problems can be accurately solved with in a limited use of computer time (Das 2005Das H. Empirical model development. Hand Book of Food Processing Operations Analysis. 1st ed. New Delhi: Asian Book Private Limited, 2005, 357-382 p.). Optimization of various bacterial strains in Erlenmeyer flasks using different optimization tools have been reported by several other authors (Nagarjun et al. 2005Nagarjun PA, Rao RS, Rajesham S, Rao LV. Optimization of Lactic Acid Production in SSF by Lactobacillus amylovorus NRRL B-4542 Using Taguchi Methodology. J Microbiol. 2005; 43: 38-43.; Kumari et al. 2009Kumari A, Mahapatra P, Banerjee R. Statistical optimization of culture conditions by response surface methodology for synthesis of lipase with Enterobacter aerogenes. Braz Arch Biol Technol. 2009; 52: 1349-1356.; Lima et al. 2009Lima CJBD, Coelho LF, Blanco KC, Contiero J. Response surface optimization of D (-)-lactic acid production by Lactobacillus SMI8 using corn steep liquor and yeast autolysate as an alternative nitrogen source. Afr J Biotechnol. 2009; 8: 5842-5846.; Negi and Banerjee, 2009Negi S, Banerjee R. Optimization of extraction and purification of Glucoamylase produced by Aspergillus awamori in solid state fermentation. Biotechnol Bioproc E. 2009; 14: 60-66.; Usmiati and Marwati, 2009Usmiati S, Marwati T. Selection and optimization process of bacteriocin production from Lactobacillus sp. Indones J Agric. 2009; 2: 82-92.; Coelho et al. 2011Coelho LF, Lima CJBD, Rodovalho CM, Bernardo MP, Contiero J. Lactic acid production by new Lactobacillus plantarum LMISM6 grown in molasses: optimization of medium composition. Braz J Chem Eng. 2011; 28: 27-36.; Meena et al. 2011Meena GS, Gupta S, Majumdar GC, Banerjee R. Growth Characteristics Modeling of Bifidobacterium bifidum Using RSM and ANN. Braz Arch Biol Technol. 2011; 54: 1357-1366.; Meena et al. 2013).

This study developed the empirical model to increase the cell growth of the mixed culture of B. bifidum and L. acidophilus (1:1 ratio) by optimizing the growth parameters such as temperature, pH, inoculum volume, incubation period and additional effect of different carbon and nitrogen sources employing RSM, ANN and GA.

MATERIALS AND METHODS

Micro-organisms and their growth conditions

Bifidum bifidum NCDC 255 and L. acidophilus NCDC 14 were obtained in freeze dried state from National Collection of Dairy Cultures (NCDC), National Dairy Research institute, Karnal, Haryana, India. The methods used for the microbial culture activation and pellet extraction was same as earlier reported (Meena et al. 2011Meena GS, Gupta S, Majumdar GC, Banerjee R. Growth Characteristics Modeling of Bifidobacterium bifidum Using RSM and ANN. Braz Arch Biol Technol. 2011; 54: 1357-1366.; Meena et al. 2013). Composition of the medium used for the growth of mixed culture of B. bifidum and L. acidophilus (1:1) contained (g/L) casein peptone 10, yeast extract 5, sodium acetate 5, Tween 80 1, MgSO₄ 0.2, MnSO₄0.05,K₂HPO₄ 2and its pH was maintained at 7.0. The growth of the mixed culturewas carried out in 250 mL Erlenmeyer flasks each containing 50 mL growth medium and maintained at 37 ⁰C. The cell biomass was determined by measuring the optical density (OD) of the medium after 24 h at 600 nm. Before measuring the OD, the liquid containing cells were centrifuged and washed with sterile distilled water for two times to remove the adhering medium constituents. All the solvents and reagents used in the present study were procured from Merck, Germany.

Experimental design

Selection of initial parameters

For the selection of initial parameters, 'one variable at a time method' was used. The different variables, viz. temperature, pH, volume of inoculum, age of inoculum and additional carbon and nitrogen sources were selected for the growth of mixed culture.

Empirical model development using RSM

In order to find the effect of different growth parameters on the predicted value of bacterial growth Y _p was obtained by conducting the experiments on different combination of independent variables (growth parameters), which was obtained from a standard experimental design. During the experiments, the response, or values of dependent variables obtained from each of the combinations of independent variables was measured. A mathematical relationship between the independent and dependent variables was developed. Using this model, the predicted value of response was find out within the domain of limiting values of independent variables. For the different growth parameters, it was desired to develop a polynomial model between the mixed culture growth and growth parameters to develop the following relationship between the coded values of independent variables, i.e., temperature (x ₁), pH (x ₂), inoculum volume (x ₃)_, inoculum age (x ₄)_, carbon sources (x ₅) and nitrogen sources (x ₆) and dependent variable (cell mass of mixed culture, Yp) as shown below.

Yp=b_o+b₁x₁+b₂x₂+b₃x₃+b₄x₄+b₅x₅+b₆x₆+b₇x₁2+b₈x₂2+b₉x₃2+b₁₀x₄2+b₁₁x₅2+b₁₂x₆2+b₁₃x₁x₂+b₁₄x₁x₃+b₁₅x₁x₄+b₁₆x₁x₅+b₁₇x₁x₆+b₁₈x₂x₃+b₁₉x₂x₄+b₂₀x₂x₅+b₂₁x₂x₆+b₂₂x₃x₄+b₂₃x₃x₅+b₂₄x₃x₆+b₂₅x₄x₅+b₂₆x₄x₆+b₂₇x₅x₆ (Eq. 1) Where b _o, b _1, b ₂.........etc. are the regression constants.

Experimental Modeling

Fractional factorial design

Fractional factorial design is a method by which the numbers of experiments are considerably reduced. This is used for the screening of independent variables, which have large effect on the dependent variables (Das 2005Das H. Empirical model development. Hand Book of Food Processing Operations Analysis. 1st ed. New Delhi: Asian Book Private Limited, 2005, 357-382 p.). Using two levels (+1 and -1) factorial design, two values of l and s were found out for all the experimental runs. Here, the values of l and s for two scarifying interactions were l ₁, s ₁, and l ₂, s ₂, respectively_. With the help of factorial design, different s values were identified as (s ₁= 0, s ₂ =0), (s ₁= 0, s ₂ =1), (s ₁= 1, s ₂ =0), and (s ₁= 1, s ₂ =1). All the experiments were conducted according to s ₁= 0 and s ₂ =0 design (Meena et al. 2011Meena GS, Gupta S, Majumdar GC, Banerjee R. Growth Characteristics Modeling of Bifidobacterium bifidum Using RSM and ANN. Braz Arch Biol Technol. 2011; 54: 1357-1366.), during present investigation.

Optimization

Artificial neural network modeling

In this present investigation, a feed forward back propagation neural network (Meena et al. 2011Meena GS, Gupta S, Majumdar GC, Banerjee R. Growth Characteristics Modeling of Bifidobacterium bifidum Using RSM and ANN. Braz Arch Biol Technol. 2011; 54: 1357-1366.; Meena et al. 2013) was used to evaluate its capability in cell mass yield prediction of mixed culture. In this process, ANN computed the error between the desired (predicted) response and the actual (experimental) response. The number of neurons in input layer, hidden layer and output layer of this neural network were kept as 6, 11 and 1, respectively. This ANN was first trained with reported data of B. bifidum (Meena et al. 2011Meena GS, Gupta S, Majumdar GC, Banerjee R. Growth Characteristics Modeling of Bifidobacterium bifidum Using RSM and ANN. Braz Arch Biol Technol. 2011; 54: 1357-1366.). After training, it was able to predict the cell mass yield of the mixed culture accurately through error minimization that was compared with the predicted value of cell mass yield obtained from RSM (Meena et al. 2013).

Genetic Algorithms

In order to maximize the cell mass yield of the mixed culture, GA was applied to the developed ANN based model (Meena et al. 2011Meena GS, Gupta S, Majumdar GC, Banerjee R. Growth Characteristics Modeling of Bifidobacterium bifidum Using RSM and ANN. Braz Arch Biol Technol. 2011; 54: 1357-1366.; Meena et al. 2013) by monitoring above mentioned six growth parameters. It was posed as the minimization of problem associated with the optimization studies. Genetic optimization was continued till the maximum cell mass yield obtained.

Software used

For the proper execution of ANN and GA, MATLAB 7.0 was used to develop the empirical model.

RESULTS AND DISCUSSION

Selection of initial parameters

Different growth variables for mixed culture growth were selected by OVAT method and results showed in Figure 1 (A - F). All these parameters, their variation and optimum values are given in Table 1.

Empirical model development

From the initial parameter selection, the maximum and minimum values of six independent parameters for mixed culture were fixed as shown in Table 2. Then, a model was developed between the coded values of independent variables (x ₁, x ₂, x ₃, x _4, x ₅ and x ₆ ) and dependent variable (Y _p) by conducting the experiments according to Fractional Factorial design. All these combinations are given in Table 3 with their corresponding l and s values.Various combination of process variable found at s ₁=0, s ₂=0 is shown in the Table 4 with their experimental value (Ye) for growth of mixed culture.

RSM is mainly used for the optimization of growth conditions, reaction parameter, or scaling-up the mixed culture growth conditions (Sen and Babu 2005Sen R, Babu KS. Modeling and optimization of the process conditions for biomass production and sporulation of a probiotic culture. Process Biochem. 2005; 40: 2531-2538.). Experimental data were fitted to the full quadratic equation and the design matrix and the fitness of each term was analyzed by the means of ANOVA (Kumari et al. 2008Kumari KS, Babu IS, Rao GH. Process optimization for citric acid production from raw glycerol using response surface methodology, Indian J Biotech. 2008; 7: 496-501.). Figure 2 shows the corresponding model coefficients (R 2 0.7949) together with the regression coefficient of determination. This was a measure of how well the regression model could be made to fit the raw data. A self-organizing feature map network was used to predict the growth condition parameters using each independent variable as input layer and growth of mixed culture as response. The least Mean Squared Error (MSE) value and a good prediction of the outputs of both training and validation sets were obtained with four neurons in the hidden layer (Dutta et al. 2004Dutta JR, Dutta PK, Banerjee R. Optimization of culture parameters for extracellular protease production from a newly isolated Pseudomonas sp. using response surface and artificial neural network models. Process Biochem. 2004; 39: 2193-2198.). The R² value between the actual and estimated responses was determined as 0.9591 (Fig. 3). In ANN modeling, the replicates at center point did not improve the prediction capability of the network because of the similar inputs.

D) were found out. The obtained model for the mixed culture was as given below.

Y_p = 0.8578 - 0.1016x₁ - 0.1506 x₂ + 0.0056x₃ - 0.0684x₄+ 0.1382x₅ + 0.3032x₆ + 0.0912x₁2 - 0.7072x₂2 + 0.1872x₃2+ 0.4722x₄2+ 0.2162x₅2-0.0357x ₆2+ 0.3180x₁x₂ + 0.0676x₁x₃ - 0.2590 x₁x₄ - 0.9292x₁x₅ + 1.3050x₁x₆ - 0.0168x₂x₃ - 0.2328x₂x₄ + 0.1855x₂x₅ - 0.0645x₂x₆ + 0.5151x₃x₄ + 0.2316x₃x₅ + 0.2224x₃x₆ - 0.2625x₄x₅ - .2625x₄x₆ -1.8158x₅x₆ (Eq. 2)

The predicted value of independent variable and corresponding experimental value for the mixed culture is shown in the Table 5. Genetic algorithms were applied on the data obtained from neural network using MATLAB7.0, which yielded similar results as of ANN but in very short time.

Table 5 showed the optimum value, or combination of different process parameters on which the bacterial growth measured by optical density (OD) was highest for the mixed culture.

In the present study, RSM, ANN and GA optimization methodologies were used to predict the growth model of the mixed culture of B. bifidum and L. acidophilus (1:1) and optimized the growth parameters. Both the models were capable to predict the combination of independent variables for maximum cell biomass of mixed culture but ANN showing more accuracy in estimation.

Regression coefficient (R 2) of ANN and RSM reflected that ANN was better than RSM. RSM was useful in getting insight information (e.g., interactions between different components) of the system directly, but ANN was also equally useful in the sensitivity analysis. ANN showed better modeling technique for data set showing nonlinear relationship over RSM. Thus, ANN could be a very powerful and flexible tool well suited for the development of empirical growth model due to an implicit corrective action arising from the training methodology and the associated estimation procedure. GA optimization results were similar to ANN but delivered within shortest use of computer time as compared to RSM and ANN. Present results showed that the higher cell mass yield of mixed culture was observed at 38°C, pH 6.5, inoculum volume and age 1.6 mL and 30 h, respectively, carbon content 42.31% (w/v) and nitrogen content (14.20%, w/v). This combination of independent variables could be of significant importance to starter culture producing industries in order to scale- up the production of B. bifidum and L. acidophilus on commercial scale more economically due to high cell mass yield.

REFERENCES

Publication Dates

History