NON-DAIRY PROBIOTIC BEVERAGE :

APPLICATION OF Lactobacillus plantarum EM1 AND Lactobacillus pentosus

EM1 CULTURES AS INOCULUM IN FERMENTED LEGUMES AND

1 SWEET CORN MILK

  

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_{1 1 1} Binardo Adi Seno , Amelia Juwana , Lindayani , and Laksmi Hartayanie

Post Graduate Program of Food Technology Department - Soegijapranata Catholic University,

Semarang

Email : b3an_ardo@yahoo.com

  

ABSTRACT

  Probiotic means living microorganisms when in adequate amounts confer a health benefit. Most of the probiotic foods are dairy products, so they cannot be consumed by humans who are allergic to milk proteins, have severe lactose intolerance or vegetarian way of diet. Consequently,

  “milk” from legumes and cereal has become a very interesting food because they have excessive nutritive value and health characteristics. This research used four fermented probiotic beverage, i.e. three based on legumes products (soybean, mung bean and kidney bean) and sweet corn milk. The products were fermented for 40 days with selected lactic acid bacteria Lactobacillus plantarum strain EM1 and Lactobacillus pentosus strain EM 1, which has been isolated from “sayur asin” (Indonesian fermented vegetables). The results showed that the total amount of lactic acid bacteria (LAB) in all samples have met the standard to be probiotic beverage according to National Standard of Indonesia (2009) and also CODEX STAN (2003). LAB viability in the storage is fairly stable, which L. plantarum EM1 has the higher viability (65.16%-97.52%) than L. pentosus EM1 (58.89-96.72%), but two types of strain are not significantly different with the L.bulgaricus as a control (70.75%-98.76%). Biochemical changes occurred until 40 days storage and cause the difference of the probiotic beverage characteristics. After storage for 40 days, fermented

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  sweet corn with L. plantarum EM1 as inoculum contained the highest LAB 3.9 x 10

  

CFU/ml, the highest LAB viability 90.65%, pH 4.24, sugar content 7.53°brix, total acid

0.54% and protein content 2.75%. Based on the results, were concluded that L.

  EM1 and L. pentosus EM1 can be utilized as inoculum in all probiotic

  plantarum beverages.

  Keywords: probiotic, Lactobacillus, legumes milk, sweet corn milk

  1. Introduction

  The term “probiotic” means living microorganism, which in sufficient numbers exert health benefits on the host. Clinical evidence provided by maintaining or improving their intestinal microbial balance. These microorganisms, mainly Lactobacilli and/or Bifidobacteria have numerous health promoting effects and also strengthening of the immune system to prevent many diseases. Some health-related effects from probiotics were managing lactose intolerance, prevention of colon cancer, reduction of cholesterol and triacylglycerol plasma concentration, lowering blood pressure, reducing inflammation and allergic symptoms and also suppression of pathogenic microorganisms (Çakır 2003, Scherezenmeir and De Vrese 2001, Dunne, et al. 2001, Dugas, et al. 1999 in Yavuzdurmaz, H. 2007). Furthermore, World Health Organisation (WHO) deemed probiotics to be the next most important immune defense systems because of its antibiotic resistance ability which significantly increased in recent years (Bengmark 2000 in Wadher, K.J., Mahore, J.G & Umekar, M.J, 2010).

  Most of the commercially probiotics are milk-based fermented foods, which mostly cannot be consumed by people who are allergic to milk proteins, have severe lactose intolerance or vegetarian way of diet. Potential substrate sources to produce non- dairy probiotic beverages are legumes and cereals, which now have been improved and processed as

  “milk”. In nutrition, legumes have highly nutritional compound, for example richness in protein, essential fatty acid especially unsaturated fatty acids, soluble and insoluble dietary fibers, vitamin and minerals. Moreover, legumes have functional compounds like isoflavones in soybeans as antioxidants

  (Božanić, 2006) and oleanolic acid in mung beans as antioxidants and immune systems (Somova, 2003 & Raphael and Kuttan, 2003). Sweet corn is also highly nutritional compounds especially high in dietary fiber, niacin & folate and also some minerals. Recently, corn milk processed from sweet corn by pasteurized or UHT treatment is popular because the attractive color, aroma and appearance, together with the sweetness of the corn milk, are the main sensory characteristics that are sought by its consumers (Supavititpatana, 2010).

  This study aims to develop some probiotic products based on legumes and sweet corn milk using LAB which has been isolated from “sayur asin” (Indonesian fermented vegetables).

  The preliminary studies have successfully isolated LAB from “sayur asin” which produced from the fermentation of “sawi pahit” (Brassica juncea var. Czern) (Evelyne, 2011). In this study, the changes of LAB population, the cell viabillity during storage at 4 C and some major chemical characteristic in probiotic based legumes and sweet corn milk were assessed.

  2. Material and Methods

2.1. Preparation of Legumes & Sweet Corn Milk

  The legumes (soybeans, mungbeans and kidney beans) and sweet corn “Hybrida” variety was purchased from supplier and market in Semarang. All 250 grams legumes (soybean, mungbeand and kidney bean) and sweet corn were sorted,washed, soaked for 8 hours, and peeled. Samples were boiled about 15 minutes and then blended with water with ratio 1:8. The extracts were filtered with cheese cloth and then cooked with 2 % sugar. After that, added with skim milk 5% and gelatin 1%, boiled with mild heat and stirred 5 minutes. (Widowati & Misgiyarta, 2003).

  2.3. Starter Culture Preparation

  Bacteria which used to make the probiotic beverages are Lactobacillus

  plantarum EM1, Lactobacillus pentosus EM1 (isolated from

  “sayur asin” from preliminary study), and Lactobacillus bulgaricus as a control. All bacteria were suspended with aquadest with OD around 0.1-0.2 nm. Bacteria suspensions were put into legumes and sweet corn based milk in ratio 1:4 for each inoculum (40 ml legume /

  o

  sweet corn based beverages added with 10 ml inoculum), and incubated at 37 C for 24 hours (Usmiati & Utami, 2008 with modification).

  2.4. Preparation of Probiotic Drink from Legumes and Sweet Corn Milk

  Legumes and sweet corn based milk which have been cooked poured into 15 erlenmeyer 300 ml and then added with inoculum for 3% (3 ml) and incubated for 24 hours under room temperature (37º C). After incubation, the probiotic milk were stored in refrigeration temperature (4º C) for about 40 days. These probiotic milk were tested after incubation and during storage every 10 days until day 40 storage. All of probiotic beverage will be tested the amount of Lactic Acid Bacteria contained by standard plate count, the viability of Lactic Acid Bacteria and biochemical changes for storage period (pH, sugar contents and protein contents)

  2.5. Enumeration of Lactic Acid Bacteria

  MRS agar was used for the enumeration of lactic acid bacteria. One milliliter of appropriate serial dilutions of each samples were pour-plated onto the media (surface platting method). After 48 h of incubation at 37

  ⁰C, the colonies on the plates were counted based on Standard Plate Count (SPC) and the CFU/ml were calculated. (Hadioetomo, 1993 with modification)

  2.6.Viability Test of Probiotic Bacteria

  The viability test was done in MRS agar media using surface plating method with vary of dilution series. Viability of probiotics was counted based on logarithmic ratio on total bacteria per ml before and after storage and was presented in percent (%). The equation was:

  (log cfu / ml after storage ) Viability (%) = x 100 %

  (log cfu / ml before storage ) (Rizqiati et al., 2008).

  2.7. Chemical Analysis

  Chemical analysis involved pH measurements and titratable acidity (Chandan et

  

al ., 2006 with modification and Wijaningsih, 2008), sugar contents by refractometer

(Nielsen, 1998) and protein contents (AOAC, 1995).

3. Result and Discussion

3.1.Total Lactic Acid Bacteria in Legume and Sweet Corn Based Milk

  From Table 1, 2, 3 and 4 can be seen that the amount of LAB both in soy bean

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  milk, mung bean milk, kidney bean milk and sweet corn milk were above 10 CFU/ml from day 1 until day 30 storage although the amount of bacteria decreased during storage. According to National Standard of Indonesia (Standar Nasional Indonesia or SNI) number 7552: 2009 and CODEX STAN 2003, the minimum amount of bacteria

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  for fermented milk must reach 1x10 CFU/ml. Therefore, both legume and sweet corn based milk have met the standard to be probiotic beverage for all cultures (L.bulgaricus,

  the total lactic acid bacteria are L.plantarum EM1, L.pentosus EM1). During storage,

decreased, may be due to the storage temperature is not fully inhibit the activity of the

metabolism so that the availability of nutrients in the medium diminished and unable to

support further growth of this bacteria. Lidya and Djenar, (2000) in Sumarsih et al., (2011),

added the decrease caused by the growing accumulation of toxic metabolic results of

bacteria cells.

  Table 1. Total Lactic Acid Bacteria of Soy Bean Based Milk Total Lactic Acid Bacteria (CFU/ml) in Soy Bean Milk

  Day

  L. bulgaricus L. plantarum EM1 L. pentosus EM1

  8

  8

  8

  1 1.56 x 10 2.56 x 10 3.06 x 10

  7

  7

  7

  10 2.52 x 10 1.97 x 10 2.28 x 10

  7

  7

  7

  20 1.46 x 10 1.64 x 10 1.91 x 10

  6

  6

  6

  30 3.70 x 10 4.90 x 10 1.70 x 10

  6

  5

  5

  40 1.10 x 10 3.00 x 10 1.00 x 10

  Source: Yani, 2012

  Table 2. Total Lactic Acid Bacteria of Mung Bean Based Milk Total Lactic Acid Bacteria (CFU/ml) in Mung Bean Milk

  Day

  L. bulgaricus L. plantarum EM1 L. pentosus EM1

  7

  7

  7

  1 1.84 x 10 2.23 x 10 2.11 x 10

  7

  7

  7

  10 1.85 x 10 1.02 x 10 1.21 x 10

  6

  6

  6

  20 5.90 x 10 7.70 x 10 7.30 x 10

  6

  6

  6

  30 1.20 x 10 2.20 x 10 3.90 x 10

  5

  6

  5

  40 9.00 x 10 1.60 x 10 5.00 x 10

  Source: Dewi, 2012

  Table 3. Total Lactic Acid Bacteria of Kidney Bean Based Milk Total Lactic Acid Bacteria (CFU/ml) in Soy Bean Milk

  Day

  L. bulgaricus L. plantarum EM1 L. pentosus EM1 _{7 7 7}

  1 2.40 x 10 2.75 x 10 2.40 x 10 _{7 7 6} 10 1.29 x 10 1.58 x 10 5.89 x 10 _{6 6 6} 20 8.71 x 10 9.77 x 10 4.79 x 10 _{6 6 6} 30 4.90 x 10 6.46 x 10 3.31 x 10 _{6 6 5} 40 3.24 x 10 3.02 x 10 1.00 x 10

  Source: Ria, 2012

  Table 4. Total Lactic Acid Bacteria of Sweet Corn Based Milk Total Lactic Acid Bacteria (CFU/ml) in Soy Bean Milk

  Day

  L. bulgaricus L. plantarum EM1 L. pentosus EM1 _{7 7 7}

  1 1.6 x 10 1.9 x 10 2.2 x 10 _{6 7 7} 10 8.3 x 10 1.2 x 10 1.2 x 10 _{6 7 6} 20 6.2 x 10 1.1 x 10 9.4 x 10 _{6 6 6}

  5.0 x 10 7.5 x 10 8.2 x 10

  30 _{6 6 6}

  3.0 x 10 3.9 x 10 2.8 x 10

  40 Source: Kosasih, 2012

3.2.Viability of Lactic Acid Bacteria in Legume and Sweet Corn Based Milk

  From Table 5,6,7,8 can be found that the viability of L. plantarum EM1 in soy bean, mung bean, kidney bean, and sweet corn milk were higher compared with L.

  

pentosus EM 1 from day 1 until day 40 storage. L. plantarum EM1 has higher stability

  towards certain conditions such as low pH and high acid. Beside concentrations of total acids and pH, cell viability as affected by many factors especially physico-chemical properties and processing parameters, include the strains used, interaction between species present, culture conditions, the fermentation medium (carbohydrate source), hydrogen peroxide content due to bacterial metabolism, availability of nutrients, growth promoters and inhibitors, dissolved oxygen incubation temperature, fermentation time and storage temperature (Rajiv I. Dave, 1998). Table 5. Viability of Lactic Acid Bacteria in Soy Bean Based Milk

  Viability of Lactic Acid Bacteria in Soy Bean Based Milk (%) Day

  EM1 EM1

  L. bulgaricus L. plantarum L. pentosus

  10

  90.35

  86.68

  86.69

  20

  87.42

  85.73

  85.75

  30

  80.22

  79.55

  73.38

  40

  73.75

  65.16

  58.89 Source: Yani, 2012 Table 6. Viability of Lactic Acid Bacteria in Mung Bean Based Milk

  Viability of Lactic Acid Bacteria in Mung Bean Based Milk (%) Day

  EM1 EM1

  L.bulgaricus L.plantarum L.pentosus

  10

  98.76

  95.37

  96.72

  20

  93.12

  93.74

  93.72

  30

  83.63

  86.26

  90.03

  40

  81.84

  84.35

  77.87 Source: Dewi, 2012 Table 7. Viability of Lactic Acid Bacteria in Kidney Bean Based Milk

  Viability of Lactic Acid Bacteria in Soy Bean Based Milk (%) Day

  L. bulgaricus L. plantarum EM1 L. pentosus EM1

  10 96,34 96,77 91,73 20 94,04 93,95 90,51 30 90,65 91,53 88,35 40 88,21 87,10 67,75

  Source: Ria, 2012

  Table 8. Viability of Lactic Acid Bacteria in Sweet Corn Based Milk Viability of Lactic Acid Bacteria in Soy Bean Based Milk (%)

  Day

  L. bulgaricus L. plantarum EM1 L. pentosus EM1

  10 96,24 97,52 96,32 20 94,44 96,70 94,96 30 93,18 94,64 94,14

  90,13 90,65 87,87

  40 Source: Kosasih, 2012

3.3. Biochemical Changes of Probiotik Drink

  Lactic acid is one of major product of sugar degradation due to the bacterial fermentation via glycolysis pathway while lactic and acetic acids via pentose phosphate pathway. Figure 1, 2, 3, 4 shows the changes of total acidity and total sugar content in all probiotic drink samples during period of storage. The initial content of total acid ranges from 0.27-0.62% while the final total acid content ranges from 0.36-0.62% for all samples. This final value of total acid have met the regulation for fermented milk probiotik (minimal 0.3%) based on CODEX, 2003. The highest total acid content up to is showed by Lactobacillus plantarum EM1 inoculated in kidney bean probiotic drink after 40 days storage.

  Figure 1-4. Total Acid and Sugar Content of Legumes and Sweet Corn Probiotic Drink Probiotic drink fermentation involves the conversion of sugar to lactic and acetate acid by lactic acid bacteria, resulted in pH reduction. Table 9 shows the pH changes during fermentation both of L. plantarum EM1 and L. pentosus EM1 for 40 days storage. The range of final pH in all samples met the standard of pH probiotic drink from fermented milk. Hutkins & Nannen, 1993 in Kraszewska & Wzorek, 2007 added that growth of strains belonging to genus Lactobacillus in medium rich in nutrient components can cause decrease of pH to value 3.0.

  Table 9. pH and Protein Content Legumes and Sweet Corn Probiotic Drink for 40 Days Storage

  

Charac- Source L. bulgaricus L. plantarum EM1 L. pentosus EM1

teristic Initial After 40 Initial After 40 Initial After 40 days days days

  3,97 ± 0,01 3,98 ± 0,01 3,95 ± 0,01 4,03 ± 0,00 3,98 ± 0,01 4,00 ± 0,00 pH Soy bean

  4,03 4,03 4,45 4,20 4,06 3,86  0,01  0,00  0,01  0,00  0,01  0,00 Mung bean

  4,02 ± 0,00 3,99 ± 0,00 Kidney bean 4,06 ± 0,00 4,02 ± 0,00 4,07 ± 0,01 4,00 ± 0,00

  4,13 ± 0,02 4,11± 0,00 4,29 ± 0,00 4,24± 0,00 4,17 ± 0,00 4,10 ± 0,00 Sweet Corn

  1,97 ± 0,02 2,23 ± 0,02 2,12 ± 0,01 2,75 ± 0,04 2,16 ± 0,02 2,13 ± 0,02 Protein Soy bean

  2,96 2,73 3,00 3,02 2,84  0,03  0,04  0,08 2,80  0,25  0,02 Content Mung bean  0,10

  2,02 ± 0,01 2,16 ± 0,02 2,22 ± 0,04 (%) Kidney bean 2,07 ± 0,02 2,24 ± 0,01 2,09 ± 0,03

  2,75 ± 0,01 3,17 ± 0,03 2,72 ± 0,12 3,21 ± 0,02 2,85 ± 0,01 3,35 ± 0,16 Sweet Corn

  Proteolysis is required by LAB for growth and also acid production (Thomas & Pritchard, 1987 in Maurad & Meriem, 2008). In this study, two strains have shown good proteolysis in soybean, mungbean and sweetcorn probiotic drink (Table 9). But after 40 days storage in refrigerator, only mungbean and sweetcorn probiotic drink have met the regulation of fermented probiotik drink (minimal 2,7%) according to Codex, 2003.

4. CONCLUSION AND FUTURE STUDY

  From the result of total bacteria and viability of Lactic Acid Bateria in legume and sweet corn based milk, can be seen that both bacteria (L. plantarum EM1 and L.

  EM1) have potential to be used as inculum or starter in legume based milk to

  pentosus

  produce probiotic beverage. Sweet corn inoculated with Lactobacillus plantarum EM1 after 40 days storage has the best characteristics as a probiotic based on total LAB, cell viability, and other biochemical characteristics such as pH, total acid and protein content. Moreover, future study is needed to evaluate the sensory aspects of legumes and sweet corn based milk which made using these two bacteria as inoculum and to evaluate the survival of Lactobacillus plantarum EM1 and Lactobacillus penthosus EM1 in probiotic drink in simulated gastrointestinal conditions.

  ACKNOWLEDGEMENT

  We would like to thank Dr. Lindayani, MP and Dra. Laksmi Hartayanie, MP (Lecturer in Under Graduate and Post Graduate Program of Food Technology), as our advisors. And for Margaretha Evelyne (Post Graduate Program of Food Technology), Citra Dewi, Tabitha Yani, Amelia Kosasih and Elizabeth Ria (Under Graduate Program of Food Technology) for the permission to use the data to complete the paper.

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