SHELF LIFE EXTENSION OF LOCALLY PREPARED CITRULLUS LANATUS (WATERMELON) JUICE USING SPECIES OF LACTOBACILLUS ISOLATED FROM FERMENTED MAIZE

ABTRACT

Two Lactobacillus specie isolates designated L1 and L2, isolated from fermented maize (Akamu) and identified as Lactobacillus plantarum and Lactobacillus brevis respectively. Each isolate was used at three different treatment concentrations (0.5ml, 1.0ml and 2.0ml) to treat and preserve locally produced watermelon juice stored at ambient temperature for seven days. Bacteriocin extracted from each isolate was also used in the preservation of watermelon juice. The watermelon juice was divided into nine samples (control, L1 0.5ml, L1 1.0ml, L1 2.0ml, L2 0.5ml, L2 1.0ml, L2 2.0ml, L1Bacteriocin and L2Bactriocin). After inoculation, the juice samples were subjected to chemical and microbial analyses on 24 hour-interval for seven days. The microbial analysis showed that the control, L1 0.5ml and L2 0.5ml had higher bacterial load of 5.9 x 105cfu/ml 4.4 x105cfu/ml and 4.6 x 105cfu/ml respectively for four storage days, and decreased later, and fungal load of 5.9 x 103cfu/ml 5.2 x 103cfu/ml and 5.2 x 103cfu/ml respectively. The samples preserved with L1 2.0ml and L2 2.0ml had lower bacterial load of 2.8 x 105cfu/ml and 2.9 x 105cfu/ml respectively and fungal load of 2.3 x 103cfu/ml for each. The results of this study revealed that the concentration of preservative affects the nature and microbial load of micro-organisms found in fruit juices during storage.

TABLE OF CONTENTS

Title                                                                                                                                        i

Certification                                                                                                                           ii

Dedication                                                                                                                              iii

Acknowledge                                                                                                                          iv

Table of contents                                                                                                                    v

List of tables                                                                                                                           viii

List of figures                                                                                                                         ix

Abstract                                                                                                                                  x

Chapter One   

1.1       Introduction                                                                                                                1

1.2       Aim and objectives of the study                                                                                 6

Chapter Two

2.1       Origin and distribution of watermelon                                                                       7

2.2       History Review of watermelon                                                                                  7

2.3       Watermelon varieties                                                                                                 9

2.4       Nutritional and medicinal value of watermelon                                                         12

2.5       Economic importance and uses of watermelon                                                          16

2.6       Lactic acid bacteria                                                                                                    17

2.7       Lactobacillus                                                                                                              19

2.7.1    Classification of Lactobacillus species                                                                      19

2.7.2    Metabolites from Lactobacillus                                                                                 21

2.7.3    Antimicrobial activity of Lactobacillus                                                                     23

Chapter Three

3.1       Procurement of materials                                                                                           25

3.2       Isolation of Lactobacillus species                                                                              25

3.2.1    Characterization of isolates                                                                                        25

3.2.2    Biochemical tests                                                                                                        26

3.2.3    Sugar utilization test                                                                                                   26

3.3       Identification of Lactobacillus isolates                                                                      26

3.4       Production of watermelon juice                                                                                 26

3.5       Treatment of juice with Lactobacillus                                                                       27

3.6       Shelf life studies                                                                                                         28

3.6.1    Determination of total solid content                                                                           28

3.6.2    Determination of total titratable acidity                                                                     29

3.6.3    Determination of pH                                                                                                   30

3.6.4    Determination of microbial load                                                                                30

3.6.5    Sensory evaluation                                                                                                     31

3.7       Statistical analyses                                                                                                      32

Chapter Four

Results                                                                                                                        33

Chapter Five

5.1       Discussion                                                                                                                   48

5.6       Conclusion                                                                                                                  50

5.2       Recommendation                                                                                                       50

References                                                                                                                              51

LIST OF TABLES

Tables               Title                                                        page

1          Summary of the different varieties of watermelon                                                    11

2          Phytoconstituents of Citrullus lanatus                                                                       15

3          Metabolic products of Lactobacillus species with antimicrobial properties                    21

4          Morphological, physiological and biochemical characteristics of isolates                        35

5          The bacterial count of the preserved watermelon juice                                             45

6          The fungal count of the preserved watermelon juice                                                 46

7          Mean scores of the sensory evaluation of the watermelon juice on day 4               47

LIST OF FIGURES

Figures            Title                                                    page

1          The damage caused by an inhibitor agent (Enterocin AS-48)

produced by a LAB strain on L. Monocytogenes cell                                               18

2          The pH, total titratable acidity, total solid and sugar level tests for control             36

3          The pH, total titratable acidity, total solid and sugar level tests for L1 0.5ml         37

4          The pH, total titratable acidity, total solid and sugar level tests for L1 1.0ml         38

5          The pH, total titratable acidity, total solid and sugar level tests for L1 2.0ml         39

6          The pH, total titratable acidity, total solid and sugar level tests for L2 0.5ml         40

7          The pH, total titratable acidity, total solid and sugar level tests for L2 1.0ml         41

8          The pH, total titratable acidity, total solid and sugar level tests for L2 2.0ml         42

9          The pH, total titratable acidity, total solid and sugar level tests for L1 bacteriocin 43

10        The pH, total titratable acidity, total solid and sugar level tests for L2 bacteriocin 44

CHAPTER ONE

1.1       INTRODUCTION

The increasing demand for fresh-tasting, healthy, nutritious and ready-to-eat foods has stimulated the expansion of minimally processed fruit and vegetable markets worldwide (Abadias et al., 2008 and Oms-Oliu et al., 2010). Processing of the products resulting from natural fruits and vegetables has been observed to increase certain reactions leading to susceptibility to microbes. From a consumer perspective, increasing scientific evidence for consumption of fresh fruits for prevention of biological problems, demand for low-calorie diet and increasing microbiological and pesticide content in processed food has increased the consumption of ready-to-eat vegetables and fruits (Rico et al., 2007). This health based option for customers has been short lived due many inappropriate or manipulative storage conditions that again lead to microbiological spoilage and disease (Abadias et al., 2008).

Fruits and vegetables are an essential part of human nutrition. Unfortunately, the daily intake of fruits and vegetables is estimated to be lower than the recommendation of the World Health Organization (WHO), who suggest a dietary intake of 450g and 500g of fruits and vegetables, respectively. Vegetables and fruits are strongly recommended in the human diet because they are rich in antioxidants, vitamins, dietary fibres and minerals. The majority of vegetables and fruits consumed in the human diet are fresh, minimally processed, pasteurized or cooked by boiling in water or microwaving, and vegetables can be canned, dried, or juiced or made into paste, salads, sauces, or soups (Dalia et al., 2015).

Fresh vegetables or those that have been minimally processed have a particularly short shelf-life because they are subjected to rapid microbial spoilage. In addition, the above cooking processes can cause a number of potentially undesirable changes in physical characteristics and chemical composition. Therefore, these drawbacks could be reduced by novel technologies, such as new packaging systems, high-hydrostatic pressure processing, ionization radiation and pulsed electric fields. The use of natural antimicrobial preservatives is considered to be the simplest and most valuable biological technique to keep and/or enhance the safety, nutrition, palatability and shelf life of fruits and vegetables (Devlieghere et al., 2004).

Modern technologies in food processing and microbiological food safety standards have reduced but not eliminated the likelihood of food-related illness and product spoilage in industrialized countries. Food spoilage refers to the damage of the original nutritional value, texture and flavor of the food that eventually renders the food harmful to people and unsuitable to eat. The increasing consumption of precooked food, prone to temperature abuse, and the importation of raw foods from developing countries results in outbreaks of food-borne illness (Nath et al., 2014). One of the concerns in food industry is the contamination by pathogens, which are frequent causes of food borne diseases. In order to achieve improved food safety against pathogens, food industry makes use of chemical preservatives or physical treatments (e.g. high temperatures). These preservation techniques have many drawbacks which includes the proven toxicity of the chemical preservatives (e.g. nitrites), the alteration of the organoleptic and nutritional properties of foods, and especially recent consumer demands for safe but minimally processed products without additives. Currently, there is a strong debate about the safety aspects of chemical preservatives due to impairment/reduction of the nutritional value of food, episodes of adverse food reactions, cardiovascular disease, many carcinogenic and teratogenic attributes as well as residual toxicity (Calo-mata et al., 2008). Processing at high temperature extensively damages the organoleptic, nutritional and physicochemical properties of the food. Refrigerators are either expensive to maintain or means for their maintenance (electricity) are lacking and this method of preservation makes the food prone to microbial and other sources of contamination (Amin, 2014).

To harmonize consumer demands with the necessary safety standards, traditional means of controlling microbial spoilage and safety hazards in foods are being replaced by combinations of innovative technologies that include biological antimicrobial systems such as lactic acid bacteria (LAB) and/or their metabolites (Nath et al., 2013). The increasing demand for safe food has increased the interest in replacing chemical additives by natural products, without injuring the host or the environment. Hence, the last two decades have seen intensive investigation on Lactic acid bacteria (LAB) and their antimicrobial products to discover new bacteriocinogenic LAB strains that can be used in food preservation.

Biopreservation refers to extended storage life and enhanced safety of foods using the natural microflora and (or) their antibacterial products. It can be defined as the extension of shelf life and food safety by the use of natural or controlled microbiota and/or their antimicrobial compounds (Ananou et al., 2007). One of the most common forms of food biopreservation is fermentation, a process based on the growth of microorganisms in foods, whether natural or added. It employs the breakdown of complex compounds, production of acids and alcohols, synthesis of Vitamin-B12, riboflavin and Vitamin-C precursor, ensures antifungal activity and improvement of organoleptic qualities such as, production of flavor and aroma compounds. The organisms involved mainly comprise lactic acid bacteria, which produce organic acids and other compounds that, in addition to antimicrobial properties, also confer unique flavours and textures to food products. Compounds such as organic acids, bacteriocins, diacetyl and acetaldehyde, enzymes, CO2, hydrogen peroxide etc. contribute to antimicrobial activity by microbiota (Nath et al., 2014 and Ananou et al., 2007).

Traditionally, a great number of foods have been protected against spoiling by natural processes of fermentation. Currently, fermented foods are increasing in popularity (60% of the diet in industrialized countries) (Holzapfel et al., 1995) and, to assure the homogeneity, quality, and safety of products, they are produced by the intentional application in raw foods of different microbial systems (starter/protective cultures). The starter cultures can be defined as preparations of one or several systems of microorganisms that are applied to initiate the process of fermentation during food manufacture (Wigley, 1999), fundamentally in the dairy industry and, currently, extended to other fermented foods such as meat, vegetable products, and juices. The bacteria used are selected depending on food type with the aim of positively affecting the physical, chemical, and biological composition of foods, providing attractive flavour properties for the consumer. To be used as starter cultures, microorganisms must fulfill the standards of Generally Recognized As Safe (GRAS) status by people and the scientific community and present no pathogenic nor toxigenic potential (Dass, 1999).

For the starter cultures, generally LAB, metabolic activity, such as acid production in cheese, is of great technological importance, whereas antimicrobial activity is secondary. However, for the protective culture, generally LAB also, the objectives are the opposite and must always take into account an additional factor for safety as its implantation must reduce the risk of growth and survival of pathogenic microorganisms (Holzapfel et al., 1995). An ideal strain would fulfill both the metabolic and antimicrobial traits.

The hurdle concept stated that the microbial safety, stability, sensorial, and nutritional qualities of foods are based on the application of combined preservative factors (called hurdles) that microorganisms present in the food are unable to overcome. Thus, hurdle technology refers to the combination of different preservation methods and processes to inhibit microbial growth (Leistner, 1978). An intelligent application of this technology requires a better understanding of the occurrence and interaction of different hurdles in foods as well as the physiological responses of microorganisms during food preservation.

Using an adequate mix of hurdles is not only economically attractive; it also serves to improve not only microbial stability and safety, but also the sensory and nutritional qualities of a food. In the past and often still today, hurdle technology has been applied empirically without knowledge of the governing principles in the preservation of a particular food. In industrialized countries, hurdle technology is of great interest in the food industry for extending the shelf life and safety of minimally processed foods, such as those that display low fat contents and/or salt (Leistner, 2000). Similarly, it is applied in fermented or refrigerated foods in which low temperature is often the only hurdle to be overcome (e.g. during distribution), which can lead to the alteration and intoxication of the foods. In developing countries, most foods are stored without refrigeration and are stabilized by the empiric use of hurdle technology. Several traditional foods have already been optimized by the intentional application of  hurdles for safety and stability enhancement (Ananou, 2007).

The need to incorporate novel and effective combinations has spurred interest for natural and biological preservatives such as Lactic Acid Bacteria and their antimicrobial compounds.

1.2       AIM AND OBJECTIVES OF THE STUDY

The aim of this study was to evaluate potential use of some species of Lactobacillus as biopreservative agents in fruit (watermelon) juice. Therefore, the work has been developed with the following objective:

1.     To isolate, identify and characterize potentially antagonistic Lactobacillus species found in locally prepared fermented maize (Akamu).

2.     To use some of the Lactobacillus species isolated from the fermented maize (Akamu) to extend the shelf life of locally prepared watermelon juice.

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