Open access peer-reviewed chapter

Waste Degradation and Utilization by Lactic Acid Bacteria: Use of Lactic Acid Bacteria in Production of Food Additives, Bioenergy and Biogas

Written By

Galina Novik, Olga Meerovskaya and Victoria Savich

Submitted: 03 October 2016 Reviewed: 18 April 2017 Published: 06 September 2017

DOI: 10.5772/intechopen.69284

From the Edited Volume

Food Additives

Edited by Desiree Nedra Karunaratne and Geethi Pamunuwa

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Abstract

Lactic acid bacteria (LAB) are one of the most well-studied bacterial groups known from ancient times. These valuable microorganisms are used in numerous areas, especially food industry and medicine. LAB produce a wide range of compounds for food upgrading. Moreover, LAB can find special applications like generation of bioenergy not affecting the surrounding environment. The article considers physiological and biochemical processes determining valuable characteristics of the bacteria, potential applications of LAB and their products, especially in food industry and bioenergy sector, and discusses LAB potential contribution into solution of waste disposal problem.

Keywords

  • lactic acid bacteria
  • metabolites
  • waste degradation
  • food additives
  • bioenergy

1. Introduction

Lactic acid bacteria (LAB) named so for the appropriate ability to ferment carbohydrates into lactic acid are one of the most studied and used groups of microorganisms. These bacteria have been applied in food processing since ancient times. The first pure culture of LAB was obtained in 1873; however, milk souring and lactic acid producing bacteria were considered as the same microorganisms until the beginning of twentieth century [1]. Today LAB represent a vast and diverse microbial group playing an important role in dairy, baking technology, fish and meat processing. Moreover, LAB are components of normal human microflora and can be used as probiotics to provide health benefits. Thus, LAB find wide applications in food industry and medicine. In addition, it is possible to use the bacteria and their products in other fields, such as generation of bioenergy, wood protection, agriculture, bioremediation of environment and so on.

Lactic acid is the main product of LAB synthesis primarily consumed by food industry. These microorganisms are also sources of low calorie sugars, ethanol, aroma compounds, bacteriocins, exopolysaccharides (EPS) and several vitamins utilized in various areas [2].

LAB can be found in any environment rich in carbohydrates. Waste substrates containing these substances, especially food residues, provide an excellent opportunity for LAB cultivation and fabrication of derived products, cost reduction and refuse disposal. Some carbohydrate compounds can be extracted from wastes, like chitin.

This article presents data on taxonomy, identification, physiology and metabolism of LAB, applications of the bacteria and their products, especially in food industry and contribution in production of bioenergy and biogas.

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2. Lactic acid bacteria (LAB): taxonomy and identification, physiological and metabolic processes

LAB represent a diverse microbial group united by the ability to produce lactic acid from various substrates. The first pure culture of LAB, now known as Lactococcus lactis, was isolated in 1873 by Lister [1]. Originally the term “lactic acid bacteria” denoted “milk souring organisms,” but it came out of use after publication of the monograph by Orla-Jensen (1919) formulating the principles of modern LAB classification [3]. Taxonomic affiliation of the bacteria based on cellular morphology, mode of glucose fermentation, growth temperatures and range of sugar utilization distinguished four core genera: Lactobacillus, Leuconostoc, Pediococcus and Streptococcus. The above-mentioned characteristics are still very important for current identification of LAB, despite development of molecular methods. Today LAB are referred to phylum Firmicutes, order Lactobacillales, genera Aerococcus, Alloiococcus, Carnobacterium, Enterococcus, Lactobacillus, Lactococcus, Leuconostoc, Oenococcus, Pediococcus, Streptococcus, Symbiobacterium, Tetragenococcus, Vagococcus and Weissella. Sometimes species of Bifidobacterium genus (phylum Actinobacteria) are assigned to LAB [4]. This genus was distinguished as a separate taxon in 1973 [5]. Until that moment, Bifidobacterium was incorporated in other genera, including Lactobacillus.

Because of LAB beneficial properties, their correct identification is vital for further industrial and medical use. Phenotypic methods are cheaper compared to genotypic methods, but similar phenotypes displayed by strains do not always correspond to similar or even closely related genotypes. Phenotypic methods also differ by poor reproducibility and ambiguity of some techniques often caused by complex growth conditions, weak discriminatory power and massive arrangements for large-scale studies. Among these methods, protein profiling seems quite reliable for LAB identification. However, even this procedure demands high workload and lacks discriminatory power on the subspecies level, for example, in the Lactobacillus acidophilus group [6].

In turn, genotypic methods are not dependent on growth conditions of microorganisms and exhibit various levels of differentiation, from species to individual strains (typing), but they are labor-consuming. Sequencing of the 16S rRNA gene is the most popular molecular tool of identification. Some features make this gene an attractive research object: it is present in all bacteria; 16S rRNA function has remained stable over a long period, so random sequence changes reflect measure of time; the gene is large enough (approximately 1500 bp) to contain statistically significant sequence information [7]. Besides sequencing of 16S rRNA gene, it is possible to carry out hybridization of oligonucleotide probes to reveal taxonomic groups with different specificity from domain to species level. In case of intraspecific identification, other methods are practiced. They include DNA fingerprinting techniques: restriction fragment length polymorphism analysis involving the digestion of genomic DNA with restriction enzymes to large fragments fractionated using pulsed-field gel electrophoresis; randomly amplified polymorphic DNA analysis applying arbitrary primers for amplification of corresponding DNA fragments; amplified restriction length polymorphism method combining two previous techniques and so on. All these methods are successfully used in identification and differentiation of LAB [8].

LAB are Gram-positive rods and cocci characterized by the absence of catalase (although some strains can produce pseudocatalase), tolerance to low pH values and lack of spore formation. These bacteria do not synthesize components of respiratory chains such as cytochromes and porphyrins and cannot generate ATP via proton-gradient mechanism. Therefore, LAB produce ATP predominantly by fermentation of sugars. Because of lack of cytochromes and porphyrins, LAB do not use oxygen, but they can grow in its presence. Protection from oxygen by-products (e.g. H2O2) is provided by peroxidases [9].

The distinctive feature of LAB is production of lactic acid. They are chemotrophic microorganisms deriving necessary energy from oxidation of chemical compounds, especially sugars. There are two fermentation pathways: homofermentative and heterofermentative. Homofermentative bacteria produce lactic acid as the major metabolite through glycolysis or Embden-Meyerhof-Parnas pathway generating two moles of lactate per mole of glucose. Pentoses and gluconate are not fermented by microorganisms via obligate homofermentative pathway due to lack of enzyme phosphoketolase. This type of fermentation is inherent, for example, to some species of the genus Lactobacillus (L. acidophilus, L. delbrueckii, L. helveticus, L. salivarius).

In turn, heterofermentative microorganisms using pentose phosphoketolase pathway (hexose monophosphate shunt/6-phosphogluconate pathway) produce equimolar amounts of lactate, CO2 and ethanol (Figure 1). Genera Leuconostoc, Oenococcus, Weissella and some lactobacilli (L. brevis, L. buchneri, L. fermentum, L. reuteri) are characterized by this type of fermentation. Hexoses other than glucose enter the major pathways after different isomerization and phosphorylation steps [10].

Figure 1.

(a) Homefermentative and (b) heterofermentative pathways of lactic acid production. Key enzymes: (1) glucokinase; (2) fructose-1,6-diphosphate aldolase; (3) glyceradehyde-3-phosphate dehydrogenase; (4) pyruvate kinase; (5) lactate dehydrogenase; (6) glucose-6-phosphate dehydrogenase; (7) 6-phospho-gluconate dehydrogenase; (8) phosphoketolase; (9) acetaldehyde dehydrogenase and (10) alcohol dehydrogenase.

Genus Bifidobacterium differs from LAB by alternative way of sugar conversion known as bifid shunt. Hexoses are degraded through several stages to acetyl-phosphate 2-glyceraldehyde-3-phosphate. The latter is metabolized by Embden-Meyerhof-Parnas pathway to lactic and acetic acid in the ratio 2:3. This pathway yields 2.5 moles ATP per mole of glucose, whereas homofermentative lactic acid fermentation generates 2 moles of ATP per mole of glucose [11].

Many LAB are able to ferment pentoses. They can digest them heterofermentatively by entering the phosphogluconate pathway as either ribulose-5-phosphate or xylulose-5-phosphate. Pentoses are converted into lactate and acetate, with no CO2 evolved [12]. Disaccharides are previously split enzymatically into monosaccharides that enter the appropriate pathways [11].

The proteolytic system of LAB converts proteins to peptides and then to amino acids essential for bacterial growth. The branched-chain amino acids (valine, leucine and isoleucine), the aromatic amino acids (tyrosine, tryptophan and phenylalanine) and the sulfur-containing amino acids (methionine and cysteine) are the main amino acid sources for flavor compounds, such as aldehydes, alcohols and esters, generated using two distinct routes: transamination and elimination [13]. The proteolytic system of LAB includes three major components: cell-wall bound proteinase initiating degradation of extracellular milk protein casein into oligopeptides; transporters taking up the peptides into the cell and various intracellular peptidases degrading the peptides into shorter fragments and amino acids. Components of the proteolytic system are diverse in various groups of LAB as well as in distinct strains. Some enzymes are only found in a few LAB strains, such as cell-wall bound proteinase PrtP. Other ferments, like aminopeptidases PepC, PepN and PepM, and proline peptidases, PepX and PepQ, are represented in all genomes, usually with one gene per genome. It appears logical that bacteria with extensive set of proteolytic enzymes show certain advantages when applied in manufacturing of various compounds [14].

Lipid metabolism proceeds as the breakdown of lipids by lipases into fatty acids and glycerol. LAB are able to produce lipases, but they are less efficient if compared with other microorganisms, such as Pseudomonas, Aeromonas, Acinetobacter or Candida, and mostly intracellular. Besides, not all LAB synthesize these enzymes. Only one quarter of lipase-producing strains were detected among 103 tested LAB from the genera Lactobacillus, Lactococcus, Leuconostoc, Pediococcus and Streptococcus. The majority belonged to Lactococcus species [15]. LAB can perform unique fatty acid transformation reactions: isomerization, hydration, dehydration and saturation. Some products of lipid metabolism, e.g. conjugated linoleic acid, can be used for medicinal and nutraceutical purposes [16]. Esterases of LAB are able to catalyze both hydrolysis of fat glycerides with release of free fatty acids and ester synthesis from glycerides and alcohols via transferase reaction. Esterases display the highest activity on monoglycerides, with inferior activity on diglycerides. However, their activities on the specific glycerides and ρ-nitrophenyl or β-naphthyl esters of fatty acids decrease as the carbon-chain length of the esterified fatty acid increases [17].

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3. Applications of LAB

LAB are applied in food production and preservation from the ancient times. Nowadays, LAB find wide use in various areas such as synthesis of chemicals and pharmaceuticals or manufacturing of probiotics for agriculture and medicine. Nevertheless, food industry remains to be the domain of broad LAB application. LAB strains were granted “Qualified Presumption of Safety” and “Generally Regarded as Safe” status by the European Food Safety Authority (EFSA) and Food and Agriculture Organization of the United Nations (FAO), respectively. They are used in manufacturing of dairy, meat, baking and vegetable products all over the world [1821]. These bacteria also allay product allergenicity and ensure longer preservation of fermented foods [22]. LAB can be involved in the delivery of functional biomolecules and ingredients into high quality gluten-free cereal products [23]. In the seafood industry, LAB are usually applied for product conservation, with the exception of traditional fish sauces in Southeast Asia. In recent years, novel fish products with various flavor and biochemical characteristics have been developed [24, 25].

Another direction of LAB application is beverage production. LAB are important components of the wine-making process: they are responsible for malolactic fermentation following alcoholic fermentation by yeast. Nearly all red wines and many white wines are obtained by these two fermentation steps. When all reducing sugars are converted to ethanol, yeast concentration declines and LAB start to grow consuming residual sugars and transforming numerous wine components. New aromas may improve wine bouquet, whereas those revealed during alcoholic fermentation by yeast are likely to vanish or change after malolactic fermentation. Some strains of LAB could even spoil wine during the process [26].

LAB are part of normal microflora of gastrointestinal and genitourinary tracts, hence they are used as components of probiotics. Beneficial effects of probiotics are provided by several mechanisms. Antagonistic action toward pathogenic bacteria may be manifested by decreasing the luminal pH through production of volatile short-chain fatty acids (SCFA), such as acetic, lactic or propionic acid; rendering specific nutrients not digestible by pathogens; decreasing the redox potential of the luminal environment; producing hydrogen peroxide under anaerobic conditions and specific inhibitory compounds such as bacteriocins affecting other bacteria [27, 28]. Besides the above-mentioned synthesis of various compounds, probiotics can be engaged in barrier function, modulation of the mucosal immune system, enhancement of food digestion and absorption and alteration of the intestinal microflora [29].

LAB can be used to control a wide range of diseases: diarrhea of various etiology [30], allergy [3133], inflammatory bowel diseases [34] and hepatic diseases [35]. LAB are applied in the treatment of tumors such as colorectal cancer by several mechanisms: bacteria are able to cause apoptosis of tumor cells; they possess antioxidative activity; LAB stimulate immune response for cancer prevention and therapy; they are able to modify expression levels of selected genes and LAB suppress proliferation of cancer cells via synergistic action of adherence to tumor cells and production of SCFA [36]. Some LAB display cholesterol-lowering and antihypertensive effects and alleviate the symptoms of lactose intolerance in lactase-deficient individuals [3740]. LAB were shown to promote immunomodulatory impact on human organism [41, 42].

LAB facilitate target delivery of valuable substances. Selenium is an essential trace element that protects organism from oxidative stress, helps maintain defense barrier against infections, modulates growth and development, provides for normal aging process, minimizes pregnancy complications and improves fertility and antiviral activity. Selenium-enriched probiotics have been shown to confer several health benefits on the host due to their antioxidative, antipathogenic, antimutagenic, anticancerogenic and anti-inflammatory activities [43].

LAB can be applied in prevention and treatment of animal diseases. Viruses, such as the infectious pancreatic necrosis virus and infectious hematopoietic necrosis virus, cause acute diseases of rainbow trout (Oncorhynchus mykiss) and several salmon species. The purified dextrans of Lactobacillus sakei MN1 and Leuconostoc mesenteroides RTF10 have shown functional activity against these viruses [44]. In some cases, Enterococcus strains demonstrated prophylactic and therapeutic effect and stimulated immune response, growth and digestion in farm stock and pets [45]. Several studies testing the influence of various LAB species on pigs, poultry and ruminants established the elevated titer of beneficial bacteria and the reduction of potential pathogen load [46].

LAB and their products exhibit antifungal properties applicable in agriculture, food and wood industry. Fungi cause numerous diseases of crops and decrease yields. In addition, they impart an unpleasant smell, taste or appearance to feed and foodstuffs and produce a wide array of mycotoxins, making nutriment unsuitable for consumption. They cause adverse effects up to lethal cases after penetration into human or animal body [47]. LAB are able to inhibit fungal growth and to dispose of mycotoxins. The activity of LAB can be explained by synthesis of various compounds, competition for nutrients in the medium and/or acidification of the growth medium. Detoxification capacity can be related to adsorption of mycotoxins by the bacterial cell [4850]. Even heat-killed cells of LAB may reduce toxin concentrations to safe levels in milk. Heat inactivation significantly enhanced aflatoxin M1 removal by LAB [51]. Members of genera Lactococcus, Pediococcus, Leuconostoc and Lactobacillus are the most promising bacteria to inhibit fungal growth [50, 52, 53]. Both lactococci and yeast could delay or prevent the fungal deterioration of the baked food [53]. A multitude of studies showed LAB ability to block fungal spoilage of fresh fruits and vegetables, baked and dairy products and silage [54]. Besides, LAB were shown to inhibit the growth of wood-rotting fungi and subsequent wood decay [55].

1,3-Propanediol is a monomer in polymerization process producing polytrimethylene terephthalate, and it can also be used in the production of polyurethanes, polyesters and polyethers. A large number of microorganisms, including LAB, are capable of converting glycerol into 1,3-propanediol. The 1,3-propanediol concentration achieved in batch cultivation of Lactobacillus diolivorans equalled 41.7 g/L. This value could be increased to 84.5 g/L by co-feeding glucose and glycerol (in 0.1 molar ratio) and by adding vitamin B12, the co-factor of glycerol dehydratases [56]. Recent studies have revealed possibility of applying LAB in biosurfactant production. Biosurfactants are a structurally diverse group of surface-active substances used in agriculture, food production, chemistry, cosmetics and pharmaceutics [57].

LAB potential application area is bioremediation, e.g. treatment of wastewaters containing azo dyes. The latter make up the largest group of synthetic chemicals that are widely used in manufacturing of textile, leather, cosmetics, food and paper. During the industrial process, approximately 10–15% of the spent dye is discharged into wastewater. Azo pigments and their catabolic intermediates, like aromatic amines, distinguished by mutagenic and carcinogenic properties, obstruct light and oxygen transfer into water bodies, consequently affecting aquatic life. The research data indicate that the chemical can be catabolized and utilized by LAB strains and its degradation products are less toxic to growing Sorghum bicolor culture than the original azo pigment [58].

LAB and their products can be used for crude oil recovery. One third to a half of the world oil reserves are deposited in carbonate rock. They tend to have very low permeability that can be improved by acid injection. Microbial acid producers, like LAB, may provide a solution for the problem. They are injected with nutrient substrate into the well where bacteria produce lactic acid reacting with CaCO3. The water solubility of formed calcium lactate is approximately 80g/L as compared to 15mg/L for CaCO3. Lactic acid may also be used for the removal of carbonate or iron scale from oilfield equipment [59].

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4. Waste degradation and utilization by lactic acid bacteria

One-third of food intended for human consumption is lost or wasted globally at all steps from initial agricultural production to final household consumption. It amounts to about 1.3 billion tons per year [60]. Food wastes are mainly composed of carbohydrate polymers, such as starch, cellulose and hemicelluloses, plus lignin, proteins, lipids, organic acids and inorganic remainder. Total sugar and protein contents are in the range of 35.5–69 and 3.9–21.9%, respectively [61]. LAB may grow in any environment rich in carbohydrates, so that they can be found in various food products (milk, meat and vegetables), plants, as part of the normal human and animal microbiota. Food wastes are potential sources of nutrients for growth of LAB and production of valuable compounds.

Large volumes of waste generated by fishing, aquaculture or food processing are dumped into the sea without pretreatment. It causes grave environmental problems. This challenge can be met by introducing rich organic nutrients in the formulated optimum media for microbial cultivation. Enzymatic hydrolysate of octopus processing wastewater served as a good source for LAB growth (L. lactis and Pediococcus acidilactici) and synthesis of bacteriocins (nisin and pediocin, respectively). The maximal production of biomass and nisin by L. lactis was observed in the media with low concentration of enzyme papain and short time of hydrolysis (4 h). In case of pediocin, the highest production was attained in the media hydrolyzed with papain, trypsin and pepsin within 10 h period. Consequently, marine peptones are promising alternative nutrients in the media and their fermentation is a possible solution of wastewater problem [62]. Fish viscera waste can be used in preparation of silage intended as animal feed. Application of LAB makes bio-silage process simpler, faster, more environmentally friendly and cost-efficient than chemical technology. LAB strains produce metabolites and adjust pH values for bio-silage fermentation and preservation [63].

Brown juice, waste of the green crop drying industry, contains nutrients such as carbohydrates, organic acids, vitamins and minerals suitable for production of L-lysine. Pretreatment is required to convert brown juice into a stable, storable product that can be used for microbial fermentation. Traditional heat sterilization at 121°C for 20 min in batch procedure or at 140°C for a few seconds in continuous process inactivates valuable enzymes and consumes a lot of energy. When LAB deplete the constituent carbohydrates, the juice can be heat sterilized and used as a nutrient and water source for L-lysine production by Corynebacterium after addition of a carbon source and neutralization of the lactic acid by, e.g., ammonia. Alternatively, the lactic acid present in the medium can be utilized by Corynebacterium and converted to L-lysine [64].

LAB can be used for waste preservation. Fermentation of hatchery wastes, including infertile eggs, dead embryos, cull chicks and shells from hatched chicks, by bacteria Pediococcus acidilactici and Lactobacillus plantarum and products of Streptococcus faecium M74 exerted significant effects upon nutritional composition of the treated substrate. Additionally, LAB action reduces or eliminates pathogenic bacteria such as Salmonella species and Escherichia coli. These are important steps in recycling hatchery by-products into feed ingredients instead of landfilling waste [65]. Rations with fermented hatchery wastes showed no negative effect on broiler chicken. Their body weight gain and feed conversion at all stages were comparable to the control. In some cases, the parameters such as ready to cook carcass and wing yield significantly exceeded control values [66].

Lactic acid is the main product of LAB. The use of waste substrates for production of lactic acid by LAB is described in Section 6.

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5. Food additives. Waste for the production of chitin and chitosan

Food additive is any substance added to food to improve its quality. These compounds are used in production, processing, treatment, packaging, transportation or storage of food. Food additives are applied to secure safety and freshness of products that could be spoiled by environment and microorganisms, to upgrade food nutritional value or modify taste, texture and appearance of consumable products. LAB are known to promote food quality and flavor from ancient times, but they also produce specific beneficial compounds that can be used for food supplementation or for extraction of valuable substances such as chitin.

Microbial contamination poses serious safety and quality problems in food industry. Bacteriocins are antimicrobial peptides produced by bacteria, which possess the ability to kill or inhibit other bacteria. The bacteriocins were first characterized in Gram-negative bacteria, but later they were observed in other bacterial groups, including LAB. These compounds are often confused with other antimicrobials or antibiotics. Unlike most antibiotics, which are secondary metabolites, bacteriocins are usually ribosomally synthesized and sensitive to proteases, whereas generally harmless to the human body and surrounding environment. Besides, bacteriocins have narrower spectrum of activity opposite to antibiotics. Bacteriocins are generally divided into several classes. Class I, or the lantibiotics, are small (<5 kDa) thermally stable peptides that contain lanthionine, methyllanthionine and dehydrated amino acids. Subclass Ia are linear structure peptides with membrane-disrupting mode of action, and subclass Ib are globular structure peptides with cellular enzymatic action. Class II containing small (<10 kDa) heat-stable, unmodified non-lanthionine membrane-active peptides is subdivided into five subclasses. Subclass IIa are pediocin-like Listeria-active peptides with a consensus amino acid sequence Tyr-Gly-Asn-Gly-Val-Xaa-Cys in the N-terminal position. Subclass IIb consists of two different unmodified peptides forming a fully active poration complex. Subclass IIc are circular peptides. Sublass IId are linear, non-pediocin-like, single-peptide bacteriocins and subclass IIe bacteriocins are non-ribosomal siderophore-type post-translation modification peptides with the serine-rich carboxy-terminal region. Class III bacteriocins are large molecular weight (>30 kDa), thermally unstable proteins that can be further subdivided into two distinct groups with respect to cell lysis. Class IV forms large complexes with other macromolecules [6769]. Due to sensitivity to proteases, bacteriocins are probably digested in the gastrointestinal tract into small peptides and amino acids. Since bacteriocin-producing bacteria are present in many types of food since ancient times, bacteriocins are considered as basically safe food additives [67]. The main perspective for these compounds is food preservation. There are many studies regarding the role of bacteriocins in conservation of dairy, meat, seafood and vegetable products [7073]. However, only few bacteriocins are used as commercial biopreservatives. The most well-studied and used bacteriocin is nisin, first isolated from L. lactis ssp. lactis in 1928 [74]. Nisin approved as food additive in more than 50 countries, including USA and Europe, is marketed as Nisaplin®. It was included into the European food additive list under the number E234 with no recorded adverse effects. Nisin inhibits closely related species as well as food-borne pathogens such as Listeria monocytogenes and many other Gram-positive spoilage microorganisms [70]. Another commercially available bacteriocin is pediocin PA-1, marketed as Alta® 2341, which inhibits growth of L. monocytogenes [72].

Exopolysaccharides (EPS) of LAB are branched, repeating units of sugars or sugar derivatives produced extracellularly. They are involved in the protection of bacteria from adverse factors. EPS of LAB are versatile in molecular weight, linkages, solubility and degree of branching. The molecular mass of EPS ranges from 10 to 1000 kDa. Most LAB produce polysaccharides extracellularly from sucrose by glycansucrases or intracellularly by glycosyltransferases from sugar nucleotide precursors [75]. These compounds are widely applied in food industry as adjuvants, emulsifiers, carriers, stabilizers, sweeteners, bulking agents, extenders and so on. [76, 77]. EPS of LAB also find use in medicine. They prevent blood coagulation and facilitate blood flow, tissue transfer, tumor treatment, serve as lubricants, carriers, osmotic and hypocholesterolemic agents, etc. [77].

Low calorie sugars of LAB origin are recognized as vital ingredients in diabetic foodstuffs. Mannitol, sorbitol, xylitol, erythritol and D-tagatose are sweeteners produced by LAB. Mannitol is used as a sweet-tasting bodying and texturing agent. It retards sugar crystallization and is intended to increase the shelf life of foods. Crystalline mannitol exhibiting very low hygroscopicity is indispensable in products that keep stability at high humidity. The polyol is usually manufactured by high pressure hydrogenation of fructose/glucose mixtures; however, bacteria can also be used as sources of the compound. Lactobacillus intermedius B-3693 was shown to yield mannitol from fructose. For example, 0.70 g of mannitol per gram of fructose can be produced from 250 g/L fructose. It was established that one-third of fructose could be replaced by glucose, maltose, galactose, mannose, raffinose or starch with glucoamylase, or two-thirds of fructose could be replaced by sucrose for successful mannitol production [78]. D-tagatose can be used as a low-calorie sweetener. The sweetness profile of D-tagatose is similar to that of sucrose, but it is detected a bit sooner than that of sucrose. D-tagatose is catabolized via tagatose-6-phosphate pathway, a branch of galactose metabolism, by some microorganisms such as Lactobacillus casei and L. lactis. L-arabinose isomerase used in tagatose production was found in L. plantarum and Bifidobacterium longum [79]. Sorbitol is a low-calorie sugar alcohol widely used in food industry. This polyol has a relative sweetness of around 60% when compared to sucrose and displays 20 times higher solubility in water than mannitol. Sorbitol is applied as sweetener, humectant, texturizer and softener in production of chewing gum, candies, desserts, ice cream and diabetic food. L. plantarum produces sorbitol with efficiency 61~65% from fructose-6-phosphate by reverting the sorbitol catabolic pathway in a mutant strain deficient for both L- and D-lactate dehydrogenase activities [80]. D-xylitol is a 5-carbon polyol used as a natural sweetener in food and confectionary industry and known for its anticariogenic properties. The recombinant strain L. lactis was able to produce D-xylitol during cometabolism of glucose and D-xylose. Xylitol synthesis reached productivity 2.72 g/L/h [81]. Oenococcus oeni has been reported to produce erythritol. This polyol is another compound that can be used as sugar substitute [82].

Antioxidant is the compound inhibiting oxidation of other molecules by free radicals. Although synthetic antioxidants are more effective, natural antioxidants are characterized by simpler structure, higher stability and safe immune response. Substances with potential antioxidant activity have been derived from many animal and plant sources. LAB products also show this kind of activity [83]. Some studies demonstrated LAB contribution in production of peptides showing antioxidant activity, with potential food and pharmaceutical applications [84, 85]. However, further investigations are required to evaluate prospects of peptides.

Vitamins are substances essential for metabolic processes. They regulate biochemical reactions in the cell. Some of them function as precursors of coenzymes. Humans are incapable of synthesizing most vitamins, so that they have to be provided from food or synthesized by gut microflora. Regretfully, vitamins are easily degraded during food processing or cooking. Certain strains of LAB possess the property to synthesize vitamins and hence can be engaged in elaboration of enriched fermented foods. Studies indicated LAB production of B-group vitamins and vitamin K [86, 87].

Conjugated linoleic acid (CLA) isomers are other compounds with important physiological properties. CLA represent the family of octadecadienoic acid (18:2) isomers, which have a pair of conjugated double bonds along the alkyl chain. There are 28 known CLA isomers. They are characterized by anticancer, antidiabetic, antiatherosclerotic and antiosteoporosis activities, complemented by defattening and immune-stimulating functions. The use of LAB and Bifidobacteria allows to increase CLA content of fermented dairy products, with no adverse effects described to date. Attempts to raise CLA productivity of LAB have been reported [88].

Apart from nutrient balance, a key food characteristic is flavor. Consumers need not only healthy but also delicious food. LAB showed ability to degrade phenolic acids generating compounds responsible for aroma. Phenolic compounds are directly related to sensory food characteristics such as flavor, astringency and color. In addition, they show antioxidant activity [89]. LAB metabolize phenolic acids by decarboxylation and/or reduction. The products of phenolic acid decarboxylase action are vinylcatechol, vinylphenol, vinylguaiacol, pyrogallol and catechol; reduction of hydroxycinnamic acids yields dihydrocaffeic and dihydroferulic acids [9092]. Strains with high enzymatic activities can be used to enhance the flavor of cheeses [93]. The volatile flavor components, which predominantly determine the typical odor of cheese, are subsequently derived from the activity of amino acid converting enzymes [94].

Chitin is a polysaccharide composed of N-acetyl-D-glucosamine units. It is the second most abundant biopolymer on Earth after cellulose and it is a structural component of the arthropod exoskeleton and of the cell walls of algae, fungi and yeast. Chitin is the source of chitosan, polysaccharide with numerous applications in the area of food and nutrition, in agriculture and environmental protection, medical, dietetic and cosmetic products. Chitin is widely used to immobilize enzymes and whole cells further engaged in clarification of fruit juices and processing of milk [95]. Chitosan and its derivatives can be applied as thickeners and stabilizers for sauces, fungistatic and antibacterial coating for fruit, preservatives, dietary fibers and cholesterol reducers [96]. Chitin and chitosan are non-toxic compounds displaying excellent biological properties such as biodegradation in the human body, immunological, antibacterial and wound-healing activity [97100]. They also possess chelating ability and adsorption capacity and promote disposal of unwanted substances or extraction of valuable compounds [101]. Derivatives such as chitosan-sugar complexes show the potential to act as better antimicrobial and antioxidant agents than chitosan itself. Antimicrobial activity of chitosan is displayed by several mechanisms. The available amino group in chitosan structure provides for absorption of the nutrients necessary for bacterial growth. Interaction between the positive charge of chitosan molecule and the negative charge of microbial cell membrane changes membrane permeability. Chitosan film formation over the surface of microbial cell membrane prevents the nutrients from getting into the cell [102].

Chitin is associated with proteins, lipids, pigments and mineral deposits. Therefore, chitinous materials have to be pretreated to remove by-components. Chitin can be extracted by various ways, including LAB introduction. However, demineralization and deproteinization of the chitinous material depend primarily on fermentation conditions. Ninety-one percent of deproteinization with lower level of demineralization can be reached under optimal conditions by L. helveticus using date juice as an alternative to glucose that decreased the degree of deproteinization to 76% [103]. The other strain Pediococcus acidolactici CFR2182 carried out efficient fermentation of shrimp waste resulting in 97.9% deproteinization and 72.5% demineralization [104]. The epiphytic L. acidophilus SW01 culture isolated from shrimp waste quickly removed minerals and proteins from that substrate to residual 0.73 and 7.8% values, respectively, after 48 h fermentation. In the pilot scale fermentation, the mineral and protein contents fell to 0.98 and 8.44%, respectively, after 48 h fermentation [105]. The combination of lactic acid bacteria (Lactobacillus paracasei) and protease-producing bacteria (Serratia marcescens) can also be effective for extraction of chitin. LAB intensely dissolved mineral CaCO3 by producing organic acid and S. marcescens degraded proteins by producing extracellular proteases. The extent of demineralization reached the highest mark of 97.2%, but the percentage of deproteinization in cofermentation was 52.6% on day 7 due to unfavorably low pH for proteolytic activity [106]. Mixed cultures of L. lactis and Teredinobacter turnirae displayed splendid activity in mineral and protein removal, respectively, and promoted chitin extraction, especially when T.turnirae was first inoculated [107]. LAB can recover chitin with accessory compounds such as pigment astaxanthin reported to be an excellent antioxidant and anticarcinogenic substance [108]. Microbial method is more effective for isolation of chitin when compared with chemical method. Adding Fe (NO3)3 as extra nitrogen source increases yield twice. Organic acids, like lactic acid, can be produced at low cost by bacteria, are less harmful to the environment and can preserve characteristics of the purified chitin, whereas the organic salts from demineralization process can be used as environmentally friendly deicing agents or as preservatives [109].

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6. Lactic acid: use of waste substrates for production of lactic acid by LAB

Lactic acid, or 2-hydroxypropanoic acid, is water soluble and highly hygroscopic organic acid with ubiquitous distribution in nature. Lactic acid was discovered in 1780 by C.W. Scheele in sour milk, and in 1881 Fermi obtained this compound by fermentation, resulting in its industrial production. Lactic acid is widely used in food, pharmaceutical, cosmetic and other manufacturing sectors. In the chemical industry, lactic acid is treated as a raw material for production of lactate ester, propylene glycol, 2,3-pentanedione, propanoic acid, acrylic acid, acetaldehyde and dilactide. This compound can even be used for fabrication of polylactic acid (PLA), sustainable bioplastic material mainly applied in packaging. Lactic acid functions as a descaling agent, pH regulator, neutralizer, chiral intermediate, solvent, humectant, cleaning aid, slow acid-release, metal complexing and antimicrobial agents. Technical-grade lactic acid is used in leather tanning industry as an acidulant for deliming hides. Besides moisturizing and pH adjusting effect, the substance is characterized by antimicrobial activity, skin lightening and hydrating action in cosmetic industry. In medicine, lactic acid is applied in tableting, prostheses, surgical sutures, controlled drug delivery systems and electrolyte solutions [110]. However, food industry is the main consumer of lactic acid. Food and food-related applications account for approximately 85% of lactic acid demand, whereas the other industrial sectors cover the remaining 15% [111]. Lactic acid and its salts are used as antimicrobials, flavor enhancers, stabilizers, thickeners, humectants, emulsifiers, firming and leavening agents and so on [110, 112]. Lactic acid is applied in a wide variety of foodstuffs, such as candies, bread and bakery products, soft drinks, soups, sherbets, dairy products, beer, jams and jellies, mayonnaise and processed eggs [113].

The global lactic acid demand estimated to be 714.2 kilo tons in 2013 is expected to reach 1960.1 kilo tons by 2020 [114]. Substrates for lactic acid production should be characterized by cheapness, low contamination level, year-round availability, rapid fermentation rate and high yields of lactic acid from fermentation.

Food waste has high starch content and is rich in nutrients, including lipids and proteins, and therefore it represents a potential renewable resource for lactic acid production. Additionally, protease, temperature and CaCO3 cause significant linear effects on production, whereas α-amylase and yeast extract show minor effects. Under the optimal conditions, L. plantarum produced maximum amount of lactic acid from dining hall food waste [115]. Municipal organic solid waste (MOSW) is the discharge consisting of kitchen and garden residues. MOSW possesses high energy and nutritional value for lactic acid production. Lactic acid productivity after 24 h was 0.79 ± 0.05 g/L/h in fermenters with pH 5.0 and 0.71 ± 0.05 g/L/h in fermenters with uncontrolled pH [116].

Sugarcane juice containing 13–16% sucrose is renewable, abundant and cheap source of carbon for lactic acid production. Lactobacillus sp. strain FCP2 grown on sugarcane juice for 5 days produced 104 g/L lactic acid with 90% yield. Higher yield (96%) and productivity (2.8 g/L/h) were obtained when the strain was cultured on 3% w/v sugarcane juice for 10 h. Addition of cheap nitrogen sources such as silk worm larvae, beer yeast autolysate and shrimp waste led to increase in lactic acid production over that attained with yeast extract [117]. Molasses is the by-product of refining sugarcane or sugar beet. It contains sucrose (31%), glucose (9.5%), fructose (10%), nitrogen (0.95%) and may be used as cheap and available medium for production of various compounds, including lactic acid. L. delbrueckii mutant Uc-3 in batch fermentation process produced 166 g/L lactic acid from 400 g/L molasses [118]. Lactic acid concentration 134.9 g/L was recorded at molasses concentration 333 g/L using Enterococcus faecalis culture [119]. Glycerol is the main by-product of biodiesel industry and it can be utilized as a carbon source to yield organic acids, e.g. lactic acid. Strain Lactobacillus sp. CYP4 produced 39.41 mM lactic acid with conversion percentage 39.27% [120]. Liquid waste from potato processing industry (chips manufacturing) can be used as substrate for lactic acid production. Waste with MRS medium (lacking peptone, yeast extract and glucose, but containing malt extract, galactose and manganese sulfate) in 4:1 ratio provided for 16.09 g/L concentration of lactic acid by L.casei culture [121].

Brewers’ spent grain (BSG) represents the major by-product of brewing industry accounting for about 85% of total residues left after the mashing and lautering processes and it is available in large amounts all year around [122]. Chemical composition of BSG varies depending on the barley variety, the harvest time, malting and mashing conditions; however, its hydrolysates are suitable substrates for lactic acid production. Generation of the desired metabolite through fermentation of hydrolysate resulting from BSG pretreatment with aqueous ammonia was 96% higher than that following acid-alkaline treatment and constituted 17.49 g/L. The maximum value was obtained after addition of nitrogen source (yeast extract) to aqueous ammonia-treated BSG (22.16 g/L) [123]. Additional use of invertase from grape juice for sucrose hydrolysis of canned pineapple syrup, a food processing waste, resulted in lactic acid concentrations 20 and 92 g/L generated by L. lactis from 20 and 100 g total sugars/L [124].

About 30% of annual global cheese whey production remains underutilized, ending up as waste or animal feed [125]. Besides, most dairy manufactures do not have proper treatment systems for whey disposal. The main components of whey are lactose (approximately 70–72% of the total solids), whey proteins (approximately 8–10%) and minerals (approximately 12–15%) utilized by LAB with lactic acid production. Various studies with free and immobilized cells proved efficiency of LAB application [126]. Scotta is the main by-product of ricotta cheese production containing proteins (0.15–0.22%), salts (1.0–1.13%) and lactose (4.8–5.0%). Scotta may be considered as a source of lactose and other nutrients with potential biotechnological applications such as lactic acid production. The addition of nutritional supplements to medium with scotta led to lactic acid productivity about 2 g/L/h. The use of mixed cultures reduces the need for nutrient supply, with no detrimental effects on the production parameters as compared to pure cultures [127]. Mussel processing waste, liquid by-product of industrial steam treatment of mussels, contains glycogen as the main component that can be utilized by LAB with protein and phosphorus supply and pH control [128].

Deficiency of the nitrogen source usually decreases yield of lactic acid. Moreover, nitrogen source is the most expensive component of microbial growth media. Ram horn hydrolysate (RHH) was shown to be rich in both organic and inorganic compounds and hence considered as an excellent source of nitrogen and minerals in fermentation medium because of its amino acid and mineral contents. The optimal concentration of RHH for production of lactic acid was 6%. Concentrations higher than 6% had an inhibitory effect due to high amounts of heavy metals. 44 g/L concentration of lactic acid was generated on medium with RHH by 26 h of fermentation with nearly 100% sugar consumption in contrast to control medium (36 g/L and the degree of sugar consumption 82%) [129].

Experiments with production of lactic acid were performed on pineapple juice waste [130], waste potato starch [131], cassava powder [132], waste banana [133], kitchen waste [134] and fish waste [135].

Lignocellulosic hydrolysates also can be used for lactic acid production. Lignocellulosic biomass, organic material of biological origin, represents the most abundant global source of unutilized biomass. Lignocellulosics are typically composed of cellulose (insoluble fibers of β-1,4-glucan), hemicellulose (noncellulosic polysaccharides, such as xylans, mannans and glucans) and lignin (a complex polyphenolic structure) with lesser amounts of minerals, oils and other components. The proportion of biomass constituents varies among species. LAB are not able to digest these components, therefore, pretreatment and enzymatic hydrolysis stages are essential [136]. For example, dilute acid pretreatment efficiently hydrolyzes hemicellulose to xylose, arabinose and glucose and thereby enables further enzymatic digestion of cellulose to glucose. The obtained compounds are utilized by LAB. However, substances toxic to fermentative organisms such as furfural, phenolic derivatives and inorganic acids are also produced during the pretreatment process. Strains S3F4 (L. brevis) and XS1T3-4 (Lactobacillus plantrum) exhibited the ability to utilize various sugars present in dilute-acid hydrolysates of corn stover and corncobs, especially S3F4 converting hydrolysates into lactic acid without detoxification. The strain showed strong resistance to the potential inhibitors, furfural, and ferulic acid. The maximum lactic acid concentration achieved by S3F4 fermentation was 39.1g/L from corncob hydrolysate [137].

The food processing industry generates significant amounts of solid wastes. For example, over 50% of the orange fruit is transformed into peel waste during the juice making process [138]. Food processing wastes are usually utilized via cattle feeding, burning and landfills, but they contain significant amounts of carbohydrates, proteins and lipids that could be used to produce valuable compounds such as lactic acid. Research with different agricultural (orange, banana and potato) peel wastes fermented by mixed cultures showed that lactic acid was the predominant chemical produced in all fermentation broths. The abundance of LAB rapidly increased during fermentation and genus Lactobacillus dominated at the end of process [139]. LAB, mainly Lactobacillus species, successfully produced lactic acid from other lignocellulosic substrates (Table 1).

Lignocellulosic substratesBacteriaLactic acid productionReferences
Alfalfa fiberLactobacillus delbrueckii0.606 g/g[140]
Lactobacillus pentosus0.59 g/g
Apple pomaceLactobacillus rhamnosus32.5 g/L[141]
Cellulosic biosludgesLactobacillus rhamnosus39.4 g/L[142]
Chips of oak woodEnterococcus faecalis24-93 g/L[143]
Milled newspaperLactobacillus delbrueckii24 g/L[144]
Municipal solid wasteLactobacillus pentosus65 g/L[145]
Pine needlesCo-culture of Lactobacillus delbrueckii and Lactobacillus pentosus45.10 g/L[146]
Recycled paper sludgeLactobacillus rhamnosus73 g/L[147]
Sugarcane bagasseLactococcus lactis10. 85 g/L[148]
Turmeric residueLactobacillus paracasei97.13 g/L[149]
Vine-trimming wastesLactobacillus pentosus21.8 g/L[150]
Waste cardboardLactobacillus coryniformis0.514 g/g[151]
Wheat strawLactobacillus pentosus6.6–6.7 g/L[152]
Lactobacillus brevis4–4.7 g/L
Wood chips of Eucalyptus globulusLactobacillus delbrueckii48–62 g/L[153]

Table 1.

Lignocellulosic substrates in lactic acid production.

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7. Use of LAB in production of bioenergy and biogas

The latest decades have witnessed growing interest in production of green energy. Fossil fuels adversely influence the environment owing to emission of carbon dioxide, triggering search for inexpensive renewable sources of energy that do not affect the surrounding nature. Microbial fuel cells (MFC) are devices that utilize organic and inorganic wastes and transform their chemical energy into electrical energy. MFC consist of anode and cathode chambers, physically separated by a proton exchange membrane (PEM). Microorganism in the anode section oxidizes the organic substrates and produces electrons and protons. The protons are conducted to the cathode chamber through PEM, and the electrons are conveyed via external circuit. Protons and electrons are reacting in the cathode chamber along with parallel reduction of oxygen to water. A steady current is generated by this process within the wire connecting anode and cathode. Besides generation of bioelectricity, MFC additionally resolve problem concerning utilization of waste [154].

MFC research has been conducted during several decades, but studies engaging LAB for generation of bioenergy were initiated only in recent years. Fe(III)-reducing bacterium Enterococcus gallinarum MG25 turned out to be electrochemically active strain. It appears that MG25 can transfer electrons to the electrode as electron acceptor, so that the strain is expected to have promising MFC application prospects [155]. L. lactis is normally homolactic bacterium under anaerobic conditions. It lacks the genes that encode biosynthesis of heme. When a source of heme is provided, the respiratory chain is activated and the bacterium can oxidize NADH using O2 as terminal electron acceptor. If lower potential terminal electron acceptors are engaged, such as hexacyanoferrate, ferric citrate or cupric chloride, the electron transfer chain is not required in its entirety up to cytochrome oxidase step, with final electron transmission carried out mostly by quinones. L. lactis was observed to perform extracellular electron transfer to anodes by utilizing at least two soluble redox mediators (one of these two mediators was 2-amino-3-dicarboxy-1,4-naphthoquinone) with acetate and pyruvate production and electricity generation [156]. Mixed cultures also can be used in MFC. While Shewanella oneidensis or L. lactis alone cannot generate electric current from glucose, they can do so in co-culture. L. lactis converts glucose into lactate, which serves as electron donor to S. oneidensis [157]. Lactobacillus bulgaricus was tested as producer of electricity. The maximum power (201.8 mW/m2) was generated at optical density 0.5 by connecting in series MFC reactors with potassium permanganate as the electrolyte solution [158]. Further on, electricity output reached power density 393.23 mW/m2 with LAB application [159]. Indium tin oxide (ITO) conductive glass anode modified by chitosan (CS) and α-Fe2O3 nanoparticles using LAB as the source of electrons raised considerably electricity generation. The maximum power density values of ITO blank, ITO/(CS/α-Fe2O3)4/CS and ITO/(CS/α-Fe2O3)8/CS were 0.035, 0.124 and 0.084W/m2, respectively. The higher roughness of ITO/(CS/α-Fe2O3)4/CS resulted in higher specific surface area available for growth of bacteria [160]. Following the trend, further development of MFC engaging LAB can be expected. Noteworthy, wastes are often applied in this technology, resolving thereby waste utilization problem.

Microbial electrolysis cell (MEC) is a technology similar to MFC, but this system recovers energy from substrates as valuable chemical compounds, like hydrogen. The latter is formed by reduction of protons with the transferred electrons in MEC. A microbial consortium demonstrated the ability to consume cheese whey as the sole carbon source yielding electricity or hydrogen. Cheese whey was fermented mainly by lactic acid bacteria (Enterococcus genus) and exoelectrogenic activity was expressed by Geobacter sp., utilizing acetate derived from fermentation as electron donor. The coulombic efficiency was 49±8% in the MFC system. In the MEC, hydrogen production reached 0.8 LH2/LREACTOR/d and it proved the potentiality of cheese whey to be a good carbon source for bioenergy production [161].

Added to MEC and MFC, LAB may be involved in the production of biofuels such as hydrogen, methane (biogas), ethanol and butanol. Hydrogen is one of the most attractive energy carriers alternative to conventional fossil fuels. It does not affect environment and produces only water vapor and heat energy as the result of its burning. Hydrogen is a highly efficient energy source; its specific energy value equals 33 Wh/g. For comparison, the specific energy of methane is 14.2 Wh/g and coal is 9.1 Wh/g. The biological processes leading to hydrogen production are dark fermentation, photofermentation, direct and indirect biophotolysis, as well as anaerobic respiration of sulfate-reducing bacteria under conditions of sulfate depletion [162]. LAB are unable to produce hydrogen themselves, but can influence hydrogen generation by increasing or decreasing its production. LAB can act as seeds for self-flocculated granule formation in hydrogen generation [163]. Another research revealed relation between the number of LAB and hydrogen production from simulated cheese processing wastewater via anaerobic fermentation using mixed microbial communities. More than 50% of the bacteria were Lactobacillus and about 5% of the isolates were hydrogen-producing Clostridia species. When H2 production in the bioreactors decreased, concurrent reduction in the cell titer of genus Lactobacillus was also observed. It can be connected with pH important for H2 production [164]. Leuconostocaeae were one of the predominant microbes in hydrogen-producing consortia in other experiment. Their role in the process is discussed [165]. When mixed cultures were used, Lactobacillus amylovorus utilized algal starch for lactic acid production and Rhodobium marinum produced hydrogen in the presence of light using lactic acid as an electron donor [166]. Products of LAB such as lactic acid also showed positive effect on hydrogen production. The addition of lactic acid to starch-containing medium could improve the hydrogen production rate and hydrogen production yield from 4.31 to 8.23 mL/h and from 5.70 to 9.08 mmol H2/g starch, respectively. The authors guessed that enhanced hydrogen production was associated with a shift from acetic acid and ethanol formation to synthesis of butyric acid as the predominant metabolite. The increase in hydrogen yield was attributed to the increase in the available residual NADH for H2 production. However, when lactic acid was used as the sole carbon source, no significant hydrogen generation was observed [167]. Clostridium diolis JPCC H-3 on medium with acetic acid and lactic acid produced 2.85 mL H2/5 mL solution as compared to the control (0.63/5 mL solution) [168]. Rhodobacter sphaeroides GL-1 immobilized on polyurethane foam in a continuous flow bioreactor converted lactic acid to H2 with an efficiency of 86% [169]. The hydrogen yield of R. sphaeroides RV was found to depend on lactic acid concentration, and maximum bacterial activity was observed at 100 mM influent lactic acid [170]. Nevertheless, other studies showed negative influence of LAB on hydrogen production. L. paracasei, Enterococcus durans and their supernatants inhibited hydrogen production via excretion of bacteriocins which have a deleterious effect on other bacteria. The inhibition of hydrogen production can be reduced by heat treatment for 30 min at temperatures ranging from 50 to 90°C and partially removed in the presence of protease trypsin inactivating bacteriocins [171]. The bacteriocin-producing LAB (mostly Lactobacillus spp.) were found to suppress hydrogen production during fermentation of cheese whey wastewater. At the same time, the highest H2 yields were obtained when growth of Lactococcus spp. was associated with Leuconostoc pseudomesenteroides, although Lactococcus spp. is not recognized as hydrogen-producing strain [172]. Competition for resources between bacteria also reduces hydrogen production [173175].

Biogas is a renewable energy source, which can be used as gaseous vehicle fuel and replace natural gas as a feedstock for producing chemicals and materials. Concerning biogas production, LAB are not directly involved in its generation, but the bacteria are able to influence methane yield. Crop characteristics, process parameters and management measures have a major impact on biogas yield. Ensiling with inoculated LAB is an appropriate method of storing feedstock for biogas production. Ensiling, prolonged storage and biological silage additives showed positive effects on methane yield of up to 11%. These could be attributed to increase in ratio of organic acids and alcohols. Changes in composition of fermentation products during ensiling and storage duration compensate for silage losses. Silage additives either accelerate the ensiling process or stabilize the silage [176, 177]. Different crops showed various need in ensiling promoters. Additive-free ensiling resulted in minor losses (0–13%) in the methane potential of sugar beet tops, but more substantial losses (17–39%) in the methane potential of grass. Ensiling with supplements improved the methane potential of both substrates by 19–22% [178]. High concentrations of ethanol and butyric acid following clostridial and heterofermentative lactic acid bacterial fermentations were also accompanied by elevated specific CH4 yield from grass [179]. The methane yield of maize silage treated with heterofermentative LAB was measured higher than from the corresponding solid residue, while the treatment of amaranth showed a significant decrease in methane yield from silage in contrast to solid residue [180]. Other studies showed that LAB failed to raise methane yield or had little effect [181183]. One experiment indicated that silage from maize straw not exposed to ensiling preparations was characterized by the highest biogas yield [184]. LAB could not stimulate total methane production, but they were able to promote the methane production rate at the beginning of the process [183]. The other products, like food waste, could also serve as methane sources. However, lactic acid pre-fermentation of food waste caused acid inhibition of the methanogenesis. Methane yield was a bit higher compared to the control, but significantly lower when ethanol pre-fermentation was used [185]. Lactic acid exerted extremely negative influence on methanogenesis of kitchen waste [186]. Although application of LAB in the ensiling process does not always increase methane yield, these bacteria conduce preservation of silage used in biogas production. LAB lead to PH drop by producing organic acids (mainly lactic and acetic acids) and decrease risk of microbial contamination [187].

Ethanol is another renewable energy source derived from plant biomass. Global production of ethanol increased from 17.25 billion L in 2000 to over 46 billion L in 2007 [188]. Yeasts are one of the main producers of ethanol. Nevertheless, ethanol generation process may be influenced by several factors, including microbial contamination. LAB are very abundant in the process because of their tolerance to ethanol, low pH and high temperature. Some strains are able to grow in media with 16% ethanol [189]. Diverse species of LAB can be found in the bioethanol process [190, 191]. It was shown that lactic acid may affect yeast viability [192]. However, due to the above-mentioned features and ability to produce ethanol (heterofermentative pathway), LAB can also be considered as biofuel sources. L. buchneri NRRL B-30929 ferments solely glucose at pH 4.0 into lactate and ethanol at molar ratio 1.03:1. Equimolar amounts of ethanol and lactate are produced when only xylose is available for the strain [193]. Recombinant strain L. plantarum containing several genes of Sarcina ventriculi produced slightly more ethanol (90–130 mM) than the control [194].

Biobutanol is another promising fuel. Compared to ethanol, butanol is distinguished by higher energy content, higher octane number, lower latent heat, lower solubility in water, higher vapor pressure and inferior corrosive capacity. Additionally, butanol can be directly included in the current design of internal combustion engines. The species Clostridia are the natural producers of butanol. However, they are difficult to culture and butanol is characterized by toxicity to bacteria at concentrations over 20 g/L, far below its solubility in water (~70 g/L) [195]. As a consequence, other microorganisms are screened for butanol production. Due to high degree of alcohol tolerance, LAB became objects for genetic manipulations to select butanol-producing strains. The recombinant L. brevis strain containing the clostridial genes crt, bcd, etfB, etfA and hbd was able to synthesize up to 300 mg/L butanol comparable to recombinant E. coli (580 and 552 mg/L) and Pseudomonas putida (120 mg/L) cultures [196198]. Recombinant strains of L. lactis and L. buchneri containing clostridial thiolase produced about 28 and 66 mg/L butanol, respectively [199]. Some L. brevis strains were found to produce 2-butanol without recombination. These strains converted meso-2,3-butanediol to 2-butanol in a synthetic medium, but none of them showed the same ability in a complex medium such as MRS. It appears that the process is inhibited by some kind of repression mechanism [200].

LAB effects on energy generation are controversial. It was shown that LAB can be used for energy generation in MFC and MEC and production of butanol. However, influence of the bacteria on hydrogen, biogas and ethanol processes is complicated. LAB fail to generate hydrogen and biogas, but they and their products are able to increase or decrease the output of biofuels. Concerning ethanol, LAB may reduce yeast product yields or act as substrate providers. Contradictory impact of LAB on bioenergy generation requires further research to minimize negative effects and gain maximum benefits.

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8. Use of LAB in food industry

Fermentation is the important process for manufacturing of products with desirable biochemical characteristics with the aid of microorganisms or enzymes. Fermentation plays at least five roles:

  1. Enrichment of the diet through development of a diversity of flavors, aromas and textures in food substrates.

  2. Preservation of food via lactic acid, ethanol, acetic acid and alkaline fermentations.

  3. Biological upgrading of food substrates with proteins, essential amino acids, fatty acids and vitamins.

  4. Detoxification in the course of food fermentation.

  5. Saving cooking time and fuel requirements [201].

LAB from ancient times have been used in production of traditional foodstuffs. LAB are important microorganisms involved in manufacturing various dairy products such as yogurt, kefir, cheese, butter and so on. The latter account for about 20% of the global output of fermented products [202]. LAB can be divided into two groups depending on optimal growth temperature: mesophilic (20–30°C) and thermophilic (30–45°C). The flavor, texture and consistency may vary considerably when mesophilic or thermophilic cultures are used. Dairy industry mainly consumes starter cultures selected and maintained by subcultivation in milk. Several steps are carried out to obtain the required products [203, 204]:

  1. Selection of starter cultures, optimization of medium and cultural conditions. These factors affect the yield of the product and its characteristics.

  2. Pretreatment. This step includes various processes such as clarification, fat separation, standardization, evaporation, de-aeration, homogenization, pasteurization and so on. Pretreatment aim is to adjust dairy substrate characteristics and eliminate microorganisms able to interfere with fermentation process. The milk is then cooled to the appropriate fermentation temperature.

  3. Fermentation. After pretreatment step, starter cultures are added and incubated at optimal temperature for the definite period. The bacteria ingest the lactose and release some compounds, like lactic acid. Production of lactic acid results in increased acidity causing milk proteins to denature and aggregate and growth inhibition of other acid-sensitive species.

  4. Postfermentation step. After the end of fermentation process, the product may be subjected to downstream processing and upgrading (addition of flavorings, homogenization, filtration, etc.).

  5. Packing, labeling, storage and market distribution of the product.

Manufacturing of fermented meat, soy, vegetables and baking products using LAB is carried out by a similar scheme. LAB provide the characteristic flavor and produce acids (e.g. lactic acid) that lower pH of the products and inhibit growth of spoilage microorganisms [205].

As mentioned in Section 5, LAB are sources of various compounds that can be used as food additives. Studies showed high efficiency of LAB in product enrichment with these additives. L. amylovorus CRL887 was able to produce significant concentrations of folate, or vitamin B9 (81.2 ± 5.4 μg/L), on folate-free cultural medium. Co-fermentation with B9 producing starter cultures L. bulgaricus CRL871 and Streptococcus thermophilus CRL803 and CRL415 yielded yogurt with high folate concentration (263.1 ± 2.4 μg/L). A single portion of the product provides for 15% of the recommended dietary allowance [206]. L. plantarum was shown to increase about twofold and threefold riboflavin (vitamin B2) content in pasta and bread, respectively [207]. L. reuteri CRL1098 from sourdough was able to produce vitamin B12 or cobalamin [208]. L. lactis ssp. cremoris YIT 2012 and Leuconostoc lactis YIT 3001 produced 9–123 μg of vitamin K2/L in defatted dry milk and soymilk medium, respectively, providing beneficial property for dietary supplement [209].

Concerning bacteriocins, nisin has been approved worldwide to use as a natural food preservative in food industry. It demonstrated a long record of food preservation efficiency [210]. Other bacteriocins also have practical applications. Paracin C produced by L. paracasei CICC 20241 induced extensive cell damage and disintegration of Alicyclobacillus acidoterrestris causing spoilage of fruit juices. The bacteriocin additionally reduced thermal resistance of bacterial spores [211]. L. paracasei subsp. tolerans from kefir produced bacteriocin inhibiting both fungi and bacteria [212]. Bacteriocin produced by P. acidilactici showed suppressing and bactericidal effect on L. monocytogenes in meat products [213]. Lactobacillus species isolated from different fermented cereal gruels demonstrated inhibitory action on growth of various target organisms [214]. Bacteriocin of Enterococcus faecium CN-25 isolated from fermented fish product completely inhibited growth of L. monocytogenes at the minimum concentration 2.38 mg/mL [215].

CLA-producing strains may be used in the food industry to derive products with increased CLA content. Strains of the genera Bifidobacterium, Lactobacillus and Lactococcus are able to enrich skim milk with CLA (in the range of 40–50 μg CLA/mL) [216]. Administration of Lactobacillus strains led to significant increase in CLA concentrations 0.2–1.2 mg/g fat in eggs and 0.3–1.88 mg/g fat in broiler chicken cuts [217]. L. plantarum from fermented pickle brines exhibited high CLA-producing ability in the presence of linoleic acid [218].

EPS of LAB have a wide application range. They can be used to modify certain food features. Incorporation of EPS may provide viscosity, stability and water-binding functions that may contribute positively to the odor, texture and taste of fermented dairy products [219]. S. thermophilus zlw TM11 induced high exopolysaccharide content (380 mg/L) and viscosity (7716 mPa/s) of fermented milk. The co-culture of this strain with L. delbrueckii subsp. bulgaricus 3 4.5 caused low syneresis (8.5%), better texture and sensory perception of fermented yogurt [220]. EPS from S. thermophilus MR-1C significantly increased moisture retention in low-fat mozzarella. The cheese with low moisture content has a tough and rubbery texture and requires more heat for melting [221]. EPS-producing LAB were used in the production of Swedish ropy milk with proper level of viscosity [222]. Sour cream fermented by S. thermophilus strains producing capsular exopolysaccharides was characterized by low syneresis, high apparent viscosity and increased adhesiveness and gumminess [223]. EPS-producing strains of S. thermophilus showed reduced freezing mortality when LAB were introduced into frozen dairy desserts as a source of β-galactosidase hydrolyzing lactose and producing the absorbable monosaccharides glucose and galactose [224]. Besides dairy industry, EPS are used in bakery. Weissella cibaria WC4 and L. plantarum LP9 were able to produce EPS that increased the viscosity of baked product and the resulting bread was distinguished by higher specific volume and lower firmness [225]. EPS can improve not only taste, structure, consistency and shelf life of food products but also probiotic characteristics. Fermented milk with EPS-producing S. thermophilus culture and purified EPS resuspended in milk were effective for gastritis prevention [226]. Three strains of L. delbrueckii subsp. bulgaricus isolated from home-made yogurt produced high amounts of EPS and showed cholesterol lowering effects [227].

Reactive oxygen species and free radicals take part in the development of degenerative diseases such as cancer, atherosclerosis and diabetes [228]. Foods containing antioxidative materials may be applied for prevention of these diseases. LAB demonstrated antioxidant activity and could be used in the production of food with required properties. The radical-scavenging activity of water/salt-soluble extracts from sourdough fermented by pool of LAB was significantly higher than in control chemically acidified dough. The highest activity was found for whole wheat, spelt, rye and kamut sourdoughs [85]. It was also demonstrated that LAB strains were able to produce antioxidant activity in dairy products. The formation of 4–20 kDa peptides was accompanied by elevated radical scavenging activity [229]. L. plantarum KFRI 00144, L. delbrueckii subsp. latis KFRI 01181, Bifidobacteriumbreve KFRI K-101 and Bifidobacterium thermophilum KFRI 00748 were able to efficiently biotransform isoflavone glucosides to their bioactive aglycones during soybean fermentation. Isoflavones are known for their potential bioactive antioxidant properties and radical scavenging capacity. It has been shown that isoflavone glucosides were poorly absorbed in the small intestine compared with their aglycones, so that soybean fermented by LAB could be regarded as a potent antioxidant and radical scavenging dietary source [230].

LAB are able to alter flavor and taste characteristics of fermented food. Prolonged wheat and rye fermentations performed by LAB resulted in sourdoughs with acidic (Lactobacillus fermentum IMDO 130101, L. plantarum IMDO 130201 and Lactobacillus crustorum LMG 23699), butter-like (L. amylovorus DCE 471), or fruity flavor (L. sakei CG1). Carbonyls, including alcohols, acids, aldehydes, hydrocarbon-substituted furans, ketones, esters, pyrazines and pyrrolines, are recognized as important bread flavoring agents [231]. Concerning cheese, proteolysis and the subsequent amino acid catabolism are of primary significance for the development of flavor, irrespective of the cheese variety. Amino acids are major precursors for volatile aroma compounds [94]. Taste and flavor of wines are determined by alcoholic and the following malolactic fermentation. Most red and white wines upon malolactic fermentation display more exquisite taste, with an improved bouquet. On the contrary, light red wines and some white wines are characterized by the grape aromas and the vivacity which fades with malolactic fermentation [26].

Production of polyols such as mannitol by bacterial fermentation is a promising method. Fermentation process could have several advantages over the chemical synthesis, such as complete conversion of fructose to mannitol, absence of hardly disposable side products, moderate production conditions and no strict need of highly purified substrates [232]. However, mannitol is still produced industrially by high pressure hydrogenation of fructose/glucose mixtures in aqueous solution at high temperature [233]. It is the same case with other polyols [234].

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9. Conclusion

LAB represent a versatile group of microorganisms. Owing to their valuable properties, LAB have been used in food production since ancient times. Development of natural sciences led to discovery of LAB as normal part of human and animal microflora. LAB are recognized as safe microorganisms and they are mainly applied in food industry for production of dairy, meat, bread, fish and vegetable products and in medicine as probiotics. LAB are known to synthesize a wide range of compounds consumed in various areas. LAB produce bacteriocins, vitamins, low calorie sugars, EPS and other valuable substances regarded as additives improving safety, quality and flavor of foodstuffs. However, one of the main LAB products is lactic acid used in food processing, pharmaceutics, cosmetics and other industrial sectors. Steadily growing market demand for this commodity urges researchers and manufacturers to seek less expensive substrates for its synthesis. Many studies deal with industrial and household wastes as appropriate sources for lactic acid production.

Ongoing research revealed encouraging LAB application prospects in other fields, such as agriculture, bioremediation of environment, chemical industry and so on. Need in green energy instead of fossil fuels focused keen interest on bacteria as sources of energy, including LAB. Despite contradictory results, further investigations could resolve problems caused by inhibitory effects of LAB and thus increase biofuel yields.

References

  1. 1. Fennema OF, Hui YH, Karel M, Walstra P, Whitaker JR. Lactic acid bacteria (microbiological and functional aspects). In: Salminen S, von Wright A, editors. Food Science and Technology a Series of Monographs, Textbooks, and Reference Books. 3rd ed. New York: Marcel Dekker, Inc.; 2004. pp. 19-30.
  2. 2. Leroy F, De Vuyst L. Lactic acid bacteria as functional starter cultures for the food fermentation industry. Trends in Food Science & Technology. 2004;15(2):67-78. DOI: 10.1016/j.tifs.2003.09.004
  3. 3. Orla-Jensen S. The Lactic Acid Bacteria. Copenhagen: Host and Son; 1919.
  4. 4. Liu W, Pang H, Zhang H, Cai Y. Biodiversity of lactic acid bacteria. In: Zhang H, Cai Y, editors. Lactic Acid Bacteria. Netherlands: Springer; 2014. pp. 103-203. DOI: 10.1007/978-94-017-8841-0_2
  5. 5. Poupard JA, Husain I, Norris RF. Biology of the bifidobacteria. Bacteriological Reviews. 1973;37(2):136-165.
  6. 6. Temmerman R, Huys G, Swings J. Identification of lactic acid bacteria: culture-dependent and culture-independent methods. Trends in Food Science & Technology. 2004;15(7):348-359. DOI: 10.1016/j.tifs.2003.12.007
  7. 7. Patel JB. 16S rRNA gene sequencing for bacterial pathogen identification in the clinical laboratory. Molecular Diagnosis. 2001;6(4):313-21. DOI: 10.1007/BF03262067
  8. 8. Amor KB, Vaughan EE, de Vos WM. Advanced molecular tools for the identification of lactic acid bacteria. The Journal of Nutrition. 2007;137(3 Suppl 2):741S-747S.
  9. 9. Stieglmeier M, Wirth R, Kminek G, Moissl-Eichinger C. Cultivation of anaerobic and facultatively anaerobic bacteria from spacecraft-associated clean rooms. Applied and Environmental Microbiology. 2009;11(75):3484-3491. DOI: 10.1128/AEM.02565-08.
  10. 10. Lahtinen S, Ouwehand AC, Salminen S, von Wright A, editors. Lactic Acid Bacteria: Microbiological and Functional Aspects. 4th ed. USA: CRC Press; 2011. 798 p.
  11. 11. Idler C, Venus J, Kamm B. Microorganisms for the production of lactic acid and organic lactates. In: Kamm B, editor. Microorganisms in Biorefineries. Berlin, Heidelberg: Springer; 2015. pp. 225-273. DOI: 10.1007/978-3-662-45209-7_9
  12. 12. Kandler O. Carbohydrate metabolism in lactic acid bacteria. Antonie van Leeuwenhoek. 1983;49(3):209-224. DOI: 10.1007/BF00399499
  13. 13. Liu M, Nauta A, Francke C, Siezen RJ. Comparative genomics of enzymes in flavor-forming pathways from amino acids in lactic acid bacteria. Applied and Environmental Microbiology. 2008;74(15):4590-4600. DOI: 10.1128/AEM.00150-08.
  14. 14. Liu M, Bayjanov JR, Renckens B, Nauta A, Siezen RJ. The proteolytic system of lactic acid bacteria revisited: a genomic comparison. BMC Genomics. 2010;11:36. DOI: 10.1186/1471-2164-11-36.
  15. 15. Meyers SA, Cuppett SL, Hutkins RW. Lipase production by lactic acid bacteria and activity on butter oil. Food Microbiology. 1996;13(5):383-389. DOI: 10.1006/fmic.1996.0044
  16. 16. Ogawa J, Kishino S, Ando A, Sugimoto S, Mihara K, Shimizu S. Production of conjugated fatty acids by lactic acid bacteria. Journal of Bioscience and Bioengineering. 2005;100(4):355-364. DOI: 10.1263/jbb.100.355
  17. 17. Holland R, Liu SQ, Crow VL, Delabre ML, Lubbers M, Bennett M, Norris G. Esterases of lactic acid bacteria and cheese flavour: Milk fat hydrolysis, alcoholysis and esterification. International Dairy Journal. 2005;15(6):711-718. DOI: 10.1016/j.idairyj.2004.09.012
  18. 18. Chelule PK, Mokoena MP, Gqaleni N. Advantages of traditional lactic acid bacteria fermentation of food in Africa. In: Méndez-Vilas A, editor. Current research, technology and education topics in applied microbiology and microbial biotechnology. Vol. 2. Spain: Formatex; 2010. pp. 1160-1167.
  19. 19. Rhee SJ, Lee JE, Lee CH. Importance of lactic acid bacteria in Asian fermented foods. Microbial Cell Factories. 2011;10(Suppl 1):S5. DOI: 10.1186/1475-2859-10-S1-S5
  20. 20. Kongo JM. Lactic acid bacteria – R & D for food, health and livestock purposes. Rijeka, Croatia: InTech; 2013. 658 p. DOI: 10.5772/2825
  21. 21. Gemechu T. Review on lactic acid bacteria function in milk fermentation and preservation. African Journal of Food Science. 2015;9(4):170-175. DOI: 10.5897/AJFS2015.1276
  22. 22. El-Ghaish S, Ahmadova A, Hadji-Sfaxi I, El Mecherfi KE, Bazukyan I, Choiset Y, RabesonaH, Sitohy M, Popov YG, Kuliev AA, Chobert J-M, Haertle T, Mozzi F. Potential use of lactic acid bacteria for reduction of allergenicity and for longer conservation of fermented foods. Trends in Food Science & Technology. 2011;22(9):509-516. DOI: 10.1016/j.tifs.2011.05.003
  23. 23. Arendt EK, Moroni A, Zannini E. Medical nutrition therapy: use of sourdough lactic acid bacteria as a cell factory for delivering functional biomolecules and food ingredients in gluten free bread. Microbial Cell Factories. 2011;10(Suppl 1):S15. DOI: 10.1186/1475-2859-10-S1-S15
  24. 24. Glatman L, Drabkin V, Gelman A. Using lactic acid bacteria for developing novel fish food products. Journal of the Science of Food and Agriculture. 2000;80(3):375-380. DOI: 10.1002/1097-0010(200002)80:3<375::AID-JSFA539>3.0.CO;2-S
  25. 25. Françoise L. Occurrence and role of lactic acid bacteria in seafood products. Food Microbiology. 2010;27(6):698-709. DOI: 10.1016/j.fm.2010.05.016
  26. 26. Lonvaud-Funel A. Lactic acid bacteria in the quality improvement and depreciation of wine. Antonie Van Leeuwenhoek. 1999;76(1-4):317-331. DOI: 10.1023/A:1002088931106
  27. 27. Naidu AS, Bidlack WR, Clemens RA. Probiotic spectra of lactic acid bacteria (LAB). Critical Reviews in Food Science and Nutrition. 1999;39(1):13-126. DOI: 10.1080/10408699991279187
  28. 28. Reis JA, Paula AT, Casarotti SN, Penna ALB. Lactic acid bacteria antimicrobial compounds: Characteristics and applications. Food Engineering Reviews. 2012;4(2):124-140. DOI: 10.1007/s12393-012-9051-2
  29. 29. Fioramonti J, Theodorou V, Bueno L. Probiotics: What are they? What are their effects on gut physiology? Best Practice & Research Clinical Gastroenterology. 2003;17(5):711-724. DOI: 10.1016/S1521-6918(03)00075-1
  30. 30. Heyman M. Effect of lactic acid bacteria on diarrheal diseases. Journal of the American College of Nutrition. 2000;19(2 Suppl):137S-146S. DOI: 10.1080/07315724.2000.10718084
  31. 31. Wang MF, Lin HC, Wang YY, Hsu CH. Treatment of perennial allergic rhinitis with lactic acid bacteria. Pediatric Allergy and Immunology. 2004;15(2):152-158. DOI: 10.1111/j.1399-3038.2004.00156.x
  32. 32. Pohjavuori E, Viljanen M, Korpela R, Kuitunen M, Tiittanen M, Vaarala O, Savilahti E. Lactobacillus GG effect in increasing IFN-gamma production in infants with cow's milk allergy. The Journal of Allergy and Clinical Immunology. 2004;114(1):131-136. DOI: 10.1016/j.jaci.2004.03.036
  33. 33. Hayashi A, Kimura M, Nakamura Y, Yasui H. Anti-atopic dermatitis effects and the mechanism of lactic acid bacteria isolated from Mongolian fermented milk. ​The Journal of Dairy Research. 2009;76(2):158-164. DOI: 10.1017/S0022029908003725.
  34. 34. del Carmen S, de Moreno de LeBlanc A, Miyoshi A, Santos Rocha C, Azevedo V, LeBlanc JG. Potential application of probiotics in the prevention and treatment of inflammatory bowel diseases. Ulcers. 2011;2011:1-13. DOI: 10.1155/2011/841651
  35. 35. Solga SF. Probiotics can treat hepatic encephalopathy. Medical Hypotheses. 2003;61(2):307-313. DOI: 10.1016/S0306-9877(03)00192-0
  36. 36. Zhong L, Zhang X, Covasa M. Emerging roles of lactic acid bacteria in protection against colorectal cancer. World Journal of Gastroenterology. 2014;20(24):7878-7886. DOI: 10.3748/wjg.v20.i24.7878
  37. 37. Alm L. Effect of fermentation on lactose, glucose, and galactose content in milk and suitability of fermented milk products for lactose intolerant individuals. Journal of Dairy Science. 1982;65(3):346-352. DOI: 10.3168/jds.S0022-0302(82)82198-X
  38. 38. Agerholm-Larsen L, Bell ML, Grunwald GK, Astrup A. The effect of a probiotic milk product on plasma cholesterol: A meta-analysis of short-term intervention studies. European Journal of Clinical Nutrition. 2000;54(11):856-860.
  39. 39. Hlivak P, Odraska J, Ferencik M, Ebringer L, Jahnova E, Mikes Z. One-year application of probiotic strain Enterococcus faecium M-74 decreases serum cholesterol levels. Bratislavské lekárske listy. 2005;106(2):67-72.
  40. 40. Tsai JS, Lin YS, Pan BS, Chen TJ. Antihypertensive peptides and γ-aminobutyric acid from prozyme 6 facilitated lactic acid bacteria fermentation of soymilk. Process Biochemistry. 2006;41(6):1282-1288. DOI: 10.1016/j.procbio.2005.12.026
  41. 41. Shida K, Kiyoshima-Shibata J, Kaji R, Nagaoka M, Nanno M. Peptidoglycan from lactobacilli inhibits interleukin-12 production by macrophages induced by Lactobacillus casei through Toll-like receptor 2-dependent and independent mechanisms. Immunology. 2009;128(1 Suppl):e858-869. DOI: 10.1111/j.1365-2567.2009.03095.x.
  42. 42. Di Cagno R, Mazzacane F, Rizzello CG, Vincentini O, Silano M, Giuliani G, De AngelisM, Gobbetti M. Synthesis of isoflavone aglycones and equol in soy milks fermented by food-related lactic acid bacteria and their effect on human intestinal Caco-2 cells. Journal of Agricultural and Food Chemistry. 2010;58(19):10338-10346. DOI:10.1021/jf101513r
  43. 43. Pophaly SD, Singh P, Kumar H, Tomar SK, Singh R. Selenium enrichment of lactic acid bacteria and bifidobacteria: A functional food perspective. Trends in Food Science & Technology. 2014;39(2):135-145. DOI: 10.1016/j.tifs.2014.07.006
  44. 44. Nácher-Vázquez M, Ballesteros N, Canales Á, Rodríguez Saint-Jean S, Pérez-Prieto SI, Prieto A, Aznar R, López P. Dextrans produced by lactic acid bacteria exhibit antiviral and immunomodulatory activity against salmonid viruses. Carbohydrate Polymers. 2015;124:292-301. DOI: 10.1016/j.carbpol.2015.02.020.
  45. 45. Franz CM, Huch M, Abriouel H, Holzapfel W, Gálvez A. Enterococci as probiotics and their implications in food safety. International Journal of Food Microbiology. 2011;151(2):125-140. DOI: 10.1016/j.ijfoodmicro.2011.08.014
  46. 46. Gaggìa F, Mattarelli P, Biavati B. Probiotics and prebiotics in animal feeding for safe food production. International Journal of Food Microbiology. 2010;141:S15-S28. DOI: 10.1016/j.ijfoodmicro.2010.02.031
  47. 47. Zain ME. Impact of mycotoxins on humans and animals. Journal of Saudi Chemical Society. 2011;15(2):129-144. DOI: 10.1016/j.jscs.2010.06.006
  48. 48. Broberg A, Jacobsson K, Ström K, Schnürer J. Metabolite profiles of lactic acid bacteria in grass silage. Applied and Environmental Microbiology. 2007;73(17):5547-5552. DOI: 10.1128/AEM.02939-06
  49. 49. Franco TS, Garcia S, Hirooka EY, Ono YS, dos Santos JS. Lactic acid bacteria in the inhibition of Fusarium graminearum and deoxynivalenol detoxification. Journal of Applied Microbiology. 2011;111(3):739-748. DOI: 10.1111/j.1365-2672.2011.05074.x.
  50. 50. Dalié DKD, Deschamps AM, Richard-Forget F. Lactic acid bacteria – Potential for control of mould growth and mycotoxins: A review. Food Control. 2010;21(4):370-380. DOI: 10.1016/j.foodcont.2009.07.011
  51. 51. Bovo F, Corassin CH, Rosim RE, de Oliveira CA. Efficiency of lactic acid bacteria strains for decontamination of aflatoxin M1 in phosphate buffer saline solution and in skimmed milk. Food and Bioprocess Technology. 2013;6(8):2230-2234. DOI: 10.1007/s11947-011-0770-9
  52. 52. Magnusson J, Ström K, Roos S, Sjögren J, Schnürer J. Broad and complex antifungal activity among environmental isolates of lactic acid bacteria. FEMS Microbiology Letters. 2003;219(1):129-135. DOI: 10.1016/S0378-1097(02)01207-7
  53. 53. Varsha KK, Priya S, Devendra L, Nampoothiri KM. Control of spoilage fungi by protective lactic acid bacteria displaying probiotic properties. Applied Biochemistry and Biotechnology. 2014;172(7):3402-3413. DOI: 10.1007/s12010-014-0779-4.
  54. 54. Crowley S, Mahony J, van Sinderen D. Current perspectives on antifungal lactic acid bacteria as natural bio-preservatives. Trends in Food Science & Technology. 2013;33(2):93-109. DOI: 10.1016/j.tifs.2013.07.004.
  55. 55. O’Callahan DR, Singh T, McDonald IR. Evaluation of lactic acid bacterium from chilli waste as a potential antifungal agent for wood products. Journal of Applied Microbiology. 2012;112(3):436-442. DOI: 10.1111/j.1365-2672.2011.05226.x
  56. 56. Pflügl S, Marx H, Mattanovich D, Sauer M. 1,3-Propanediol production from glycerol with Lactobacillus diolivorans. Bioresource Technology. 2012;119:133-140. DOI: 10.1016/j.biortech.2012.05.121
  57. 57. Sharma D, Saharan BS, Kapil S. Biosurfactants of Lactic Acid Bacteria. Switzerland: Springer International Publishing; 2016. 86 p. DOI: 10.1007/978-3-319-26215-4
  58. 58. Elbanna K, Hassan G, Khider M, Mandour R. Safe biodegradation of textile azo dyes by newly isolated lactic acid bacteria and detection of plasmids associated with degradation. Journal of Bioremediation & Biodegradation. 2010;1:110-118. DOI: 10.4172/2155-6199.1000110
  59. 59. Coleman JK, Brown MJ, Moses V, Burton CC. Enhanced Oil Recovery. WO1992015771 A1. September 17, 1992
  60. 60. Gustavsson J, Cederberg C, Sonesson U, Van Otterdijk R, Meybeck A. Global food losses and food waste – Extent, causes and prevention. Rome: Food and Agriculture Organization (FAO); 2011. 29 p.
  61. 61. Kiran EU, Trzcinski AP, Ng WJ, Liu Y. Bioconversion of food waste to energy: A review. Fuel. 2014;134:389-399. DOI: 10.1016/j.fuel.2014.05.074
  62. 62. Vázquez JA, Murado MA. Enzymatic hydrolysates from food wastewater as a source of peptones for lactic acid bacteria productions. Enzyme and Microbial Technology. 2008;43(1):66-72. DOI: 10.1016/j.enzmictec.2008.01.015
  63. 63. Vázquez JA, Nogueira M, Durán A, Prieto MA, Rodríguez-Amado I, Rial D, GonzálezMP, Murado MA. Preparation of marine silage of swordfish, ray and shark visceral waste by lactic acid bacteria. Journal of Food Engineering. 2011;103(4):442-448. DOI: 10.1016/j.jfoodeng.2010.11.014
  64. 64. Thomsen MH, Kiel P. Selection of lactic acid bacteria for acidification of brown juice (grass juice), with the aim of making a durable substrate for L‐lysine fermentation. Journal of the Science of Food and Agriculture. 2008;88(6):976-983. DOI: 10.1002/jsfa.3176
  65. 65. Deshmukh AC, Patterson PH. Preservation of hatchery waste by lactic acid fermentation. 1. Laboratory scale fermentation. Poultry Science. 1997;76(9):1212-1219.
  66. 66. Deshmukh AC, Patterson PH. Preservation of hatchery waste by lactic acid fermentation. 2. Large-scale fermentation and feeding trial to evaluate feeding value. Poultry Science. 1997;76(9):1220-1226.
  67. 67. Cleveland J, Montville TJ, Nes IF, Chikindas ML. Bacteriocins: safe, natural antimicrobials for food preservation. International Journal of Food Microbiology. 2001;71(1):1-20. DOI: 10.1016/S0168-1605(01)00560-8
  68. 68. Zacharof MP, Lovitt RW. Bacteriocins produced by lactic acid bacteria a review article. APCBEE Procedia. 2012;2:50-56. DOI: 10.1016/j.apcbee.2012.06.010
  69. 69. Yang SC, Lin CH, Sung CT, Fang JY. Antibacterial activities of bacteriocins: Application in foods and pharmaceuticals. Frontiers in Microbiology. 2014;5:241. DOI: 10.3389/fmicb.2014.00241
  70. 70. Calo-Mata P, Arlindo S, Boehme K, de Miguel T, Pascoal A, Barros-Velazquez J. Current applications and future trends of lactic acid bacteria and their bacteriocins for the biopreservation of aquatic food products. Food and Bioprocess Technology. 2008;1(1):43-63. DOI 10.1007/s11947-007-0021-2
  71. 71. Sobrino-López A, Martín-Belloso O. Use of nisin and other bacteriocins for preservation of dairy products. International Dairy Journal. 2008;18(4):329-343. DOI: 10.1016/j.idairyj.2007.11.009
  72. 72. Settanni L, Corsetti A. Application of bacteriocins in vegetable food biopreservation. International Journal of Food Microbiology. 2008;121(2):123-138. DOI: 10.1016/j.ijfoodmicro.2007.09.001
  73. 73. Woraprayote W, Malila Y, Sorapukdee S, Swetwiwathana A, Benjakul S, Visessanguan W. Bacteriocins from lactic acid bacteria and their applications in meat and meat products. Meat Science. 2016;120:118-132. DOI: 10.1016/j.meatsci.2016.04.004
  74. 74. Rogers LA, Whittier ED. Limiting factors in lactic acid fermentation. Journal of Bacteriology. 1928;16:211-229.
  75. 75. Patel AK, Michaud P, Singhania RR, Soccol CR, Pandey A. Polysaccharides from probiotics: new developments as food additives. Food Technology and Biotechnology. 2010;48(4):451-463.
  76. 76. De Vuyst L, Degeest B. Heteropolysaccharides from lactic acid bacteria. FEMS Microbiology Reviews. 1999;23(2):153-177. DOI: 10.1111/j.1574-6976.1999.tb00395.x
  77. 77. Patel S, Majumder A, Goyal A. Potentials of exopolysaccharides from lactic acid bacteria. Indian Journal of Microbiology. 2012;52(1):3-12. DOI: 10.1007/s12088-011-0148-8
  78. 78. Saha BC, Nakamura LK. Production of mannitol and lactic acid by fermentation with Lactobacillus intermedius NRRL B‐3693. Biotechnology and Bioengineering. 2003;82(7):864-871. DOI: 10.1002/bit.10638
  79. 79. Kim P. Current studies on biological tagatose production using L-arabinose isomerase: A review and future perspective. Applied Microbiology and Biotechnology. 2004;65(3):243-249. DOI: 10.1007/s00253-004-1665-8
  80. 80. Ladero V, Ramos A, Wiersma A, Goffin P, Schanck A, Kleerebezem M, Hugenholtz J, Smid EJ, Hols P. High-level production of the low-calorie sugar sorbitol by Lactobacillus plantarum through metabolic engineering. Applied and Environmental Microbiology. 2007;73(6):1864-1872. DOI: 10.1128/AEM.02304-06
  81. 81. Nyyssölä A, Pihlajaniemi A, Palva A, von Weymarn N, Leisola M. Production of xylitol from D-xylose by recombinant Lactococcus lactis. Journal of Biotechnology. 2005;118(1):55-66. DOI: 10.1016/j.jbiotec.2005.03.014
  82. 82. Veiga-da-Cunha M, Santos H, Van Schaftingen E. Pathway and regulation of erythritol formation in Leuconostoc oenos. Journal of Bacteriology. 1993;175(13):3941-3948.
  83. 83. Soleymanzadeh N, Mirdamadi S, Kianirad M. Antioxidant activity of camel and bovine milk fermented by lactic acid bacteria isolated from traditional fermented camel milk (Chal). Dairy Science & Technology. 2016;96(4):443-457. DOI: 10.1007/s13594-016-0278-1
  84. 84. Abubakr MA, Hassan Z, Imdakim MMA. Antioxidant activity of lactic acid bacteria (LAB) fermented skim milk as determined by 1,1-diphenyl-2-picrylhydrazyl (DPPH) and ferrous chelating activity (FCA). African Journal of Microbiology Research. 2012;6(34):6358-6364. DOI: 10.5897/AJMR12.702
  85. 85. Coda R, Rizzello CG, Pinto D, Gobbetti M. Selected lactic acid bacteria synthesize antioxidant peptides during sourdough fermentation of cereal flours. Applied and Environmental Microbiology. 2012;78(4):1087-1096. DOI: 10.1128/AEM.06837-11
  86. 86. O’Connor EB, Barrett E, Fitzgerald G, Hill C, Stanton C, Ross RP. Production of vitamins, exopolysaccharides and bacteriocins by probiotic bacteria. In: Tamime AY, editor. Probiotic Dairy Products. Oxford, UK: Blackwell Publishing; 2005. pp. 167-194. DOI: 10.1002/9780470995785.ch8
  87. 87. Capozzi V, Russo P, Dueñas MT, López P, Spano G. Lactic acid bacteria producing B-group vitamins: a great potential for functional cereals products. Applied Microbiology and Biotechnology. 2012;96(6):1383-1394. DOI: 10.1007/s00253-012-4440-2
  88. 88. Kuhl GC, De Dea Lindner J. Biohydrogenation of linoleic acid by lactic acid bacteria for the production of functional cultured dairy products: A review. Foods. 2016;5(1):13. DOI: 10.3390/foods5010013
  89. 89. Rodríguez H, Curiel JA, Landete JM, de las Rivas B, López de Felipe F, Gómez-Cordovés C, Mancheño JM, Muñoz R. Food phenolics and lactic acid bacteria. International Journal of Food Microbiology. 2009;132(2-3):79-90. DOI: 10.1016/j.ijfoodmicro.2009.03.025.
  90. 90. van Beek S, Priest FG. Decarboxylation of substituted cinnamic acids by lactic acid bacteria isolated during malt whisky fermentation. Applied and Environmental Microbiology. 2000;66(12):5322-5328. DOI: 10.1128/AEM.66.12.5322-5328.2000
  91. 91. Curiel JA, Rodríguez H, Landete JM, de las Rivas B, Muñoz R. Ability of Lactobacillus brevis strains to degrade food phenolic acids. Food Chemistry. 2010;120(1):225-229. DOI: 10.1016/j.foodchem.2009.10.012
  92. 92. Svensson L, Sekwati-Monang B, Lutz DL, Schieber A, Gänzle MG. Phenolic acids and flavonoids in nonfermented and fermented red sorghum (Sorghum bicolor (L.) Moench). Journal of Agricultural and Food Chemistry. 2010;58(16):9214-9220. DOI: 10.1021/jf101504v.
  93. 93. González L, Sacristán N, Arenas R, Fresno JM, Tornadijo ME. Enzymatic activity of lactic acid bacteria (with antimicrobial properties) isolated from a traditional Spanish cheese. Food Microbiology. 2010;27(5):592-597. DOI: 10.1016/j.fm.2010.01.004
  94. 94. Smit G, Smit BA, Engels WJ. Flavour formation by lactic acid bacteria and biochemical flavour profiling of cheese products. FEMS Microbiology Reviews. 2005;29(3):591-610. DOI: 10.1016/j.femsre.2005.04.002
  95. 95. Krajewska B. Application of chitin- and chitosan-based materials for enzyme immobilizations: A review. Enzyme and Microbial Technology. 2004;35(2-3):126-139. DOI: 10.1016/j.enzmictec.2003.12.013
  96. 96. Rinaudo M. Chitin and chitosan: properties and applications. Progress in Polymer Science. 2006;31(7):603-632. DOI: 10.1016/j.progpolymsci.2006.06.001
  97. 97. Nishimura K, Nishimura S, Nishi N, Saiki I, Tokura S, Azuma I. Immunological activity of chitin and its derivatives. Vaccine. 1984;2(1):93-99. DOI: 10.1016/S0264-410X(98)90039-1
  98. 98. Shigemasa Y, Saito K, Sashiwa H, Saimoto H. Enzymatic degradation of chitins and partially deacetylated chitins. International Journal of Biological Macromolecules. 1994;16:43-49.
  99. 99. Tokura S, Ueno K, Miyazaki S, Nishi N. Molecular weight dependent antimicrobial activity by chitosan. Macromolecular Symposia. 1997;120:1-9. DOI: 10.1002/masy.19971200103
  100. 100. Kweon DK, Song SB, Park YY. Preparation of water-soluble chitosan/heparin complex and its application as wound healing accelerator. Biomaterials. 2003;24:1595-1601. DOI: 10.1016/S0142-9612(02)00566-5
  101. 101. Synowiecki J, Al-Khateeb NA. Production, properties, and some new applications of chitin and its derivatives. Critical Reviews in Food Science and Nutrition. 2003;43(2):145-171. DOI: 10.1080/10408690390826473
  102. 102. Mahae N, Chalat C, Muhamud P. Antioxidant and antimicrobial properties of chitosan-sugar complex. International Food Research Journal. 2011;18(4):1543-1551.
  103. 103. Adour L, Arbia W, Amrane A, Mameri N. Combined use of waste materials – recovery of chitin from shrimp shells by lactic acid fermentation supplemented with date juice waste or glucose. Journal of Chemical Technology and Biotechnology. 2008;83(12):1664-1669. DOI: 10.1002/jctb.1980
  104. 104. Bhaskar N, Suresh PV, Sakhare PZ, Sachindra NM. Shrimp biowaste fermentation with Pediococcus acidolactici CFR2182: Optimization of fermentation conditions by response surface methodology and effect of optimized conditions on deproteination/demineralization and carotenoid recovery. Enzyme and Microbial Technology. 2007;40(5):1427-1434. DOI: 10.1016/j.enzmictec.2006.10.019
  105. 105. Duan S, Li L, Zhuang Z, Wu W, Hong S, Zhou J. Improved production of chitin from shrimp waste by fermentation with epiphytic lactic acid bacteria. Carbohydrate Polymers. 2012;89(4):1283-1288. DOI: 10.1016/j.carbpol.2012.04.051
  106. 106. Jung WJ, Jo GH, Kuk JH, Kim KY, Park RD. Extraction of chitin from red crab shell waste by cofermentation with Lactobacillus paracasei subsp. tolerans KCTC-3074 and Serratia marcescens FS-3. Applied Microbiology and Biotechnology. 2006;71(2):234-237. DOI: 10.1007/s00253-005-0126-3
  107. 107. Aytekin O, Elibol M. Cocultivation of Lactococcus lactis and Teredinobacter turnirae for biological chitin extraction from prawn waste. Bioprocess and Biosystems Engineering. 2010;33(3):393-399. DOI: 10.1007/s00449-009-0337-6
  108. 108. Pacheco N, Garnica-González M, Ramírez-Hernández JY, Flores-Albino B, GimenoM, Bárzana E, Shirai K. Effect of temperature on chitin and astaxanthin recoveries from shrimp waste using lactic acid bacteria. Bioresource Technology. 2009;100(11):2849-2854. DOI: 10.1016/j.biortech.2009.01.019
  109. 109. Khanafari A, Marandi R, Sanatei S. Recovery of chitin and chitosan from shrimp waste by chemical and microbial methods. Journal of Environmental Health Science & Engineering. 2008;5(1):1-24.
  110. 110. Wee YJ, Kim JN, Ryu HW. Biotechnological production of lactic acid and its recent applications. Food Technology and Biotechnology. 2006;44(2):163-172.
  111. 111. John RP, Nampoothiri KM, Pandey A. Fermentative production of lactic acid from biomass: an overview on process developments and future perspectives. Applied Microbiology and Biotechnology. 2007;74(3):524-534. DOI 10.1007/s00253-006-0779-6
  112. 112. Litchfield JH. Microbiological production of lactic acid. Advances in Applied Microbiology. 1996;42:45-95.
  113. 113. Reddy G, Altaf MD, Naveena BJ, Venkateshwar M, Kumar EV. Amylolytic bacterial lactic acid fermentation – A review. Biotechnology Advances. 2008;26(1):22-34. DOI: 10.1016/j.biotechadv.2007.07.004
  114. 114. SpecialChem. [Internet]. 2014. Available from: http://www.specialchem4bio.com/news/2014/05/23/global-lactic-acid-market-to-grow-at-a-cagr-of-15-5-from-2014-20-grand-view-research#sthash.McKc8RdH.dpuf. [Accessed: January 18, 2017]
  115. 115. Ye ZL, Lu M, Zheng Y, Li YH, Cai WM. Lactic acid production from dining‐hall food waste by Lactobacillus plantarum using response surface methodology. Journal of Chemical Technology and Biotechnology. 2008;83(11):1541-1550. DOI: 10.1002/jctb.1968
  116. 116. Probst M, Walde J, Pümpel T, Wagner AO, Insam H. A closed loop for municipal organic solid waste by lactic acid fermentation. Bioresource Technology. 2015;175:142-151. DOI: 10.1016/j.biortech.2014.10.034
  117. 117. Timbuntam W, Sriroth K, Tokiwa Y. Lactic acid production from sugar-cane juice by a newly isolated Lactobacillus sp. Biotechnology Letters. 2006;28(11):811-814. DOI 10.1007/s10529-006-9003-0
  118. 118. Dumbrepatil A, Adsul M, Chaudhari S, Khire J, Gokhale D. Utilization of molasses sugar for lactic acid production by Lactobacillus delbrueckii subsp. delbrueckii mutant Uc-3 in batch fermentation. Applied and Environmental Microbiology. 2008;74(1):333-335. DOI: 10.1128/AEM.01595-07
  119. 119. Wee YJ, Kim JN, Yun JS, Ryu HW. Utilization of sugar molasses for economical L(+)-lactic acid production by batch fermentation of Enterococcus faecalis. Enzyme and Microbial Technology. 2004;35(6):568-573. DOI: 10.1016/j.enzmictec.2004.08.008
  120. 120. Prada-Palomo Y, Romero-Vanegas M, Díaz-Ruíz P, Molina-Velasco D, Guzmán-LunaC. Lactic acid production by Lactobacillus sp. from biodiesel derived raw glycerol. CT&F – Ciencia, Tecnología y Futuro. 2012;5(1):57-66
  121. 121. Afifi MM. Enhancement of lactic acid production by utilizing liquid potato wastes. International Journal of Biological Chemistry. 2011;5(2):91-I02. DOI: 10.3923/ijbc.2011.91.102
  122. 122. Mussatto SI, Dragone G, Roberto IC. Brewers' spent grain: generation, characteristics and potential applications. Journal of Cereal Science. 2006;43(1):1-14. DOI: 10.1016/j.jcs.2005.06.001
  123. 123. Liguori R, Soccol CR, Vandenberghe LP, Woiciechowski AL, Ionata E, Marcolongo L, Faraco V. Selection of the strain Lactobacillus acidophilus ATCC 43121 and its application to brewers’ spent grain conversion into lactic acid. BioMed Research International, 2015;2015:240231. DOI: 10.1155/2015/240231
  124. 124. Ueno T, Ozawa Y, Ishikawa M, Nakanishi K, Kimura T. Lactic acid production using two food processing wastes, canned pineapple syrup and grape invertase, as substrate and enzyme. Biotechnology Letters. 2003;25(7):573-577. DOI: 10.1023/A:1022888832278
  125. 125. Affertsholt T. Market developments and industry challenges for lactose and lactose derivatives. In: IDF Symposium “Lactose and Its Derivatives”; 14-16 May 2007, Moscow, Russia
  126. 126. Panesar PS, Kennedy JF, Gandhi DN, Bunko K. Bioutilisation of whey for lactic acid production. Food Chemistry. 2007;105(1):1-14. DOI: 10.1016/j.foodchem.2007.03.035
  127. 127. Secchi N, Giunta D, Pretti L, García MR, Roggio T, Mannazzu I, Catzeddu P. Bioconversion of ovine scotta into lactic acid with pure and mixed cultures of lactic acid bacteria. Journal of Industrial Microbiology & Biotechnology. 2012;39(1):175-181. DOI: 10.1007/s10295-011-1013-9
  128. 128. Pintado J, Guyot JP, Raimbault M. Lactic acid production from mussel processing wastes with an amylolytic bacterial strain. Enzyme and Microbial Technology. 1999:24(8-9):590-598. DOI: 10.1016/S0141-0229(98)00168-9
  129. 129. Kurbanoglu EB, Kurbanoglu NI. Utilization for lactic acid production with a new acid hydrolysis of ram horn waste. FEMS Microbiology Letters. 2003;225(1):29-34. DOI: 10.1016/S0378-1097(03)00472-5
  130. 130. Busairi AM. Conversion of pineapple juice waste into lactic acid in batch and fed-batch fermentation systems. Reaktor. 2008;12(2):98-101. DOI: 10.14710/reaktor.12.2.98-101
  131. 131. Palaniraj R, Nagarajan P. Kinetic studies in production of lactic acid from waste potato starch using Lactobacillus casei. International Journal of ChemTech Research. 2012;4(4):1601-1614.
  132. 132. Wang L, Zhao B, Liu B, Yang C, Yu B, Li Q, Ma C, Xu P, Ma Y. Efficient production of L-lactic acid from cassava powder by Lactobacillus rhamnosus. Bioresource Technology. 2010;101(20):7895-7901. DOI: 10.1016/j.biortech.2010.05.018
  133. 133. Chan-Blanco Y, Bonilla-Leiva AR, Velazquez AC. Using banana to generate lactic acid through batch process fermentation. Applied Microbiology and Biotechnology. 2003;63(2):147-152. DOI: 10.1007/s00253-003-1374-8
  134. 134. Wang XM, Wang QH, Ren NQ, Wang XQ. Lactic acid production from kitchen waste with a newly characterized strain of Lactobacillus plantarum. Chemical and Biochemical Engineering Quarterly. 2005;19(4):383-389.
  135. 135. Gao MT, Hirata M, Toorisaka E, Hano T. Acid-hydrolysis of fish wastes for lactic acid fermentation. Bioresource Technology. 2006;97(18):2414-2420. DOI: 10.1016/j.biortech.2005.10.002
  136. 136. Abdel-Rahman MA, Tashiro Y, Sonomoto K. Lactic acid production from lignocellulose-derived sugars using lactic acid bacteria: Overview and limits. Journal of Biotechnology. 2011;156(4):286-301. DOI: 10.1016/j.jbiotec.2011.06.017
  137. 137. Guo W, Jia W, Li Y, Chen S. Performances of Lactobacillus brevis for producing lactic acid from hydrolysate of lignocellulosics. Applied Biochemistry and Biotechnology. 2010;161(1-8):124-136. DOI: 10.1007/s12010-009-8857-8
  138. 138. Martin MA, Siles JA, Chica AF, Martin A. Biomethanization of orange peel waste. Bioresource Technology. 2010;101(23):8993-8999. DOI: 10.1016/j.biortech.2010.06.133
  139. 139. Liang S, Gliniewicz K, Gerritsen AT, McDonald AG. Analysis of microbial community variation during the mixed culture fermentation of agricultural peel wastes to produce lactic acid. Bioresource Technology. 2016;208:7-12. DOI: 10.1016/j.biortech.2016.02.054.
  140. 140. Sreenath HK, Moldes AB, Koegel RG, Straub RJ. Lactic acid production by simultaneous saccharification and fermentation of alfalfa fiber. Journal of Bioscience and Bioengineering. 2001;92(6):518-523.
  141. 141. Gullón B, Yáñez R, Alonso JL, Parajó JC. L-lactic acid production from apple pomace by sequential hydrolysis and fermentation. Bioresource Technology. 2008;99(2):308-319. DOI: 10.1016/j.biortech.2006.12.018
  142. 142. Romaní A, Yáñez R, Garrote G, Alonso JL. SSF production of lactic acid from cellulosic biosludges. Bioresource Technology. 2008;99(10):4247-4254. DOI: 10.1016/j.biortech.2007.08.051
  143. 143. Wee YJ, Yun JS, Park DH, Ryu HW. Biotechnological production of L(+)-lactic acid from wood hydrolyzate by batch fermentation of Enterococcus faecalis. Biotechnology Letters. 2004;26(1):71-74. DOI: 10.1023/B:BILE.0000009464.23026.e0
  144. 144. Abe SI, Takagi M. Simultaneous saccharification and fermentation of cellulose to lactic acid. Biotechnology and Bioengineering. 1991;37(1):93-96. DOI: 10.1002/bit.260370113
  145. 145. McCaskey TA., Zhou SD, Britt SN, Strickland R. Bioconversion of municipal solid waste to lactic acid by Lactobacillus species. Applied Biochemistry and Biotechnology. 1994;45(1):555-568. DOI: 10.1007/BF02941830
  146. 146. Ghosh MK, Ghosh UK. Utilization of pine needles as bed material in solid state fermentation for production of lactic acid by Lactobacillus strains. BioResources. 2011;6(2):1556-1575.
  147. 147. Marques S, Santos JA, Gírio FM, Roseiro JC. Lactic acid production from recycled paper sludge by simultaneous saccharification and fermentation. Biochemical Engineering Journal. 2008;41(3):210-216. DOI: 10.1016/j.bej.2008.04.018
  148. 148. Laopaiboon P, Thani A, Leelavatcharamas V, Laopaiboon L. Acid hydrolysis of sugarcane bagasse for lactic acid production. Bioresource Technology. 2010;101(3):1036-1043. DOI: 10.1016/j.biortech.2009.08.091
  149. 149. Nguyen CM, Kim JS, Nguyen TN, Kim SK, Choi GJ, Choi YH, Jang KS, Kim JC. Production of L-and D-lactic acid from waste Curcuma longa biomass through simultaneous saccharification and cofermentation. Bioresource Technology. 2013;146:35-43. DOI: 10.1016/j.biortech.2013.07.035
  150. 150. Bustos G, Moldes AB, Cruz JM, Domínguez JM. Production of fermentable media from vine‐trimming wastes and bioconversion into lactic acid by Lactobacillus pentosus. Journal of the Science of Food and Agriculture. 2004;84(15):2105-2112. DOI: 10.1002/jsfa.1922
  151. 151. Yáñez R, Alonso JL, Parajó JC. D‐Lactic acid production from waste cardboard. Journal of Chemical Technology and Biotechnology. 2005;80(1):76-84. DOI: 10.1002/jctb.1160
  152. 152. Garde A, Jonsson G, Schmidt AS, Ahring BK. Lactic acid production from wheat straw hemicellulose hydrolysate by Lactobacillus pentosus and Lactobacillus brevis. Bioresource Technology. 2002;81(3):217-223. DOI: 10.1016/S0960-8524(01)00135-3
  153. 153. Moldes AB, Alonso JL, Parajo JC. Multi-step feeding systems for lactic acid production by simultaneous saccharification and fermentation of processed wood. Bioprocess Engineering. 2000;22(2):175-180. DOI: 10.1007/s004490050028
  154. 154. Rahimnejad M, Adhami A, Darvari S, Zirepour A, Oh SE. Microbial fuel cell as new technology for bioelectricity generation: A review. Alexandria Engineering Journal. 2015;54(3):745-756. DOI: 10.1016/j.aej.2015.03.031
  155. 155. Kim GT, Hyun MS, Chang IS, Kim HJ, Park HS, Kim BH, Kim SD, Wimpenny JW, Weightman AJ. Dissimilatory Fe(III) reduction by an electrochemically active lactic acid bacterium phylogenetically related to Enterococcus gallinarum isolated from submerged soil. Journal of Applied Microbiology. 2005;99(4):978-987. DOI: 10.1111/j.1365-2672.2004.02514.x
  156. 156. Freguia S, Masuda M, Tsujimura S, Kano K. Lactococcus lactis catalyses electricity generation at microbial fuel cell anodes via excretion of a soluble quinone. Bioelectrochemistry. 2009;76(1):14-18. DOI: 10.1016/j.bioelechem.2009.04.001
  157. 157. Rosenbaum MA, Bar HY, Beg QK, Segrè D, Booth J, Cotta MA, Angenent LT. Shewanella oneidensis in a lactate-fed pure-culture and a glucose-fed co-culture with Lactococcus lactis with an electrode as electron acceptor. Bioresource Technology. 2011;102(3):2623-2628. DOI: 10.1016/j.biortech.2010.10.033
  158. 158. Arbianti R, Utami T, Hermansyah H, Novitasari D, Kristin E, Trisnawati I. Performance optimization of Microbial Fuel Cell (MFC) using Lactobacillus bulgaricus. Makara Journal of Technology. 2013;17(1):32-38. DOI: 10.7454/mst.v17i1.1925
  159. 159. Jingna Y, Yudi S, Yi G. Property and mechanism of electricity production on lactic acid bacteria Microbial Fuel Cells. Chemical Industry and Engineering. 2014;5:008.
  160. 160. Wang M, Yang Z, Xia M, Fan L, Xuejun Z, Wei S, Zou T. Performance improvement of microbial fuel cells by lactic acid bacteria and anode modification. Environmental Engineering Science. 2017;34(4):251-257. DOI: 10.1089/ees.2016.0110
  161. 161. Rago L, Baeza JA, Guisasola A. Bioelectrochemical hydrogen production with cheese whey as sole substrate. Journal of Chemical Technology and Biotechnology. 2017;92(1):173-179. DOI: 10.1002/jctb.4987
  162. 162. Sikora A, Błaszczyk M, Jurkowski M, Zielenkiewicz U. Lactic acid bacteria in hydrogen-producing consortia: on purpose or by coincidence? In: Kongo M, editor. Lactic Acid Bacteria – R & D for Food, Health and Livestock Purposes. Rijeka: InTech; 2013. pp. 488-514. DOI: 10.5772/50364
  163. 163. Hung CH, Lee KS, Cheng LH, Huang YH, Lin PJ, Chang JS. Quantitative analysis of a high-rate hydrogen-producing microbial community in anaerobic agitated granular sludge bed bioreactors using glucose as substrate. Applied Microbiology and Biotechnology. 2007;75(3):693-701. DOI: 10.1007/s00253-007-0854-7
  164. 164. Yang P, Zhang R, McGarvey JA, Benemann JR. Biohydrogen production from cheese processing wastewater by anaerobic fermentation using mixed microbial communities. International Journal of Hydrogen Energy. 2007;32(18):4761-4771. DOI: 10.1016/j.ijhydene.2007.07.038
  165. 165. Chojnacka A, Błaszczyk MK, Szczęsny P, Nowak K, Sumińska M, Tomczyk-Żak K, Zielenkiewicz U, Sikora A. Comparative analysis of hydrogen-producing bacterial biofilms and granular sludge formed in continuous cultures of fermentative bacteria. Bioresource Technology. 2011;102(21):10057-10064. DOI: 10.1016/j.biortech.2011.08.063
  166. 166. Kawaguchi H, Hashimoto K, Hirata K, Miyamoto K. H2 production from algal biomass by a mixed culture of Rhodobium marinum A-501 and Lactobacillus amylovorus. Journal of Bioscience and Bioengineering. 2001;91(3):277-282. DOI: 10.1016/S1389-1723(01)80134-1
  167. 167. Baghchehsaraee B, Nakhla G, Karamanev D, Margaritis A. Effect of extrinsic lactic acid on fermentative hydrogen production. International Journal of Hydrogen Energy. 2009;34(6):2573-2579. DOI: 10.1016/j.ijhydene.2009.01.010
  168. 168. Matsumoto M, Nishimura Y. Hydrogen production by fermentation using acetic acid and lactic acid. Journal of Bioscience and Bioengineering. 2007;103(3):236-241. DOI: 10.1263/jbb.103.236
  169. 169. Fedorov AS, Tsygankov AA, Rao KK, Hall DO. Hydrogen photoproduction by Rhodobacter sphaeroides immobilised on polyurethane foam. Biotechnology Letters. 1998;20(11):1007-1009. DOI: 10.1023/A:1005402904462
  170. 170. Fascetti E, Todini O. Rhodobacter sphaeroides RV cultivation and hydrogen production in a one-and two-stage chemostat. Applied Microbiology and Biotechnology. 1995;44(3-4):300-305. DOI: 10.1007/BF00169920
  171. 171. Noike T, Takabatake H, Mizuno O, Ohba M. Inhibition of hydrogen fermentation of organic wastes by lactic acid bacteria. International Journal of Hydrogen Energy. 2002;27(11-12):1367-1371. DOI: 10.1016/S0360-3199(02)00120-9
  172. 172. Gomes BC, Rosa PRF, Etchebehere C, Silva EL, AmâncioVaresche MB. Role of homo-and heterofermentative lactic acid bacteria on hydrogen-producing reactors operated with cheese whey wastewater. International Journal of Hydrogen Energy. 2015;40(28):8650-8660. DOI: 10.1016/j.ijhydene.2015.05.035
  173. 173. Ren N, Xing D, Rittmann BE, Zhao L, Xie T, Zhao X. Microbial community structure of ethanol type fermentation in bio‐hydrogen production. Environmental Microbiology. 2007;9(5):1112-1125. DOI: 10.1111/j.1462-2920.2006.01234.x
  174. 174. Jo JH, Jeon CO, Lee DS, Park JM. Process stability and microbial community structure in anaerobic hydrogen-producing microflora from food waste containing kimchi. Journal of Biotechnology. 2007;131(3):300-308. DOI: 10.1016/j.jbiotec.2007.07.492
  175. 175. Wang X, Zhao YC. A bench scale study of fermentative hydrogen and methane production from food waste in integrated two-stage process. International Journal of Hydrogen Energy. 2009;34(1):245-254. DOI: 10.1016/j.ijhydene.2008.09.100
  176. 176. Herrmann C, Heiermann M, Idler C. Effects of ensiling, silage additives and storage period on methane formation of biogas crops. Bioresource Technology. 2011:102(8):5153-5161. DOI :10.1016/j.biortech.2011.01.012
  177. 177. Xu R, Zhang BY, Yang FY. Effects of silage additives on biogas production of hybrid penisetum. Advanced Materials Research. 2015;1070-1072:112-120. DOI: 10.4028/www.scientific.net/AMR.1070-1072.112
  178. 178. Lehtomäki, A. Biogas Production from Energy Crops and Crop Residues. Finland: University of Jyväskylä; 2006. 91 p.
  179. 179. McEniry J, Allen E, Murphy JD, O'Kiely P. Grass for biogas production: The impact of silage fermentation characteristics on methane yield in two contrasting biomethane potential test systems. Renewable Energy. 2014;63:524-530. DOI: 10.1016/j.renene.2013.09.052
  180. 180. Haag NL, Nägele HJ, Fritz T, Oechsner H. Effects of ensiling treatments on lactic acid production and supplementary methane formation of maize and amaranth – An advanced green biorefining approach. Bioresource Technology. 2015;178:217-225. DOI: 10.1016/j.biortech.2014.08.048
  181. 181. Pakarinen O, Lehtomäki A, Rissanen S, Rintala J. Storing energy crops for methane production: Effects of solids content and biological additive. Bioresource Technology. 2008;99(15):7074-7082. DOI: 10.1016/j.biortech.2008.01.007
  182. 182. Kreuger E, Nges IA, Björnsson L. Ensiling of crops for biogas production: Effects on methane yield and total solids determination. Biotechnology for Biofuels. 2011;4:44. DOI: 10.1186/1754-6834-4-44
  183. 183. Menardo S, Balsari P, Tabacco E, Borreani G. Effect of conservation time and the addition of lactic acid bacteria on the biogas and methane production of corn stalk silage. BioEnergy Research. 2015;8(4):1810-1823. DOI: 10.1007/s12155-015-9637-7
  184. 184. Przybył J, Kot W, Wojcieszak D, Mioduszewska N, Durczak K. Biogas yield of maize straw. Inżynieria Rolnicza. 2013;17(148):103-111.
  185. 185. Zhao N, Yu M, Wang Q, Song N, Che S, Wu C, Sun X. Effect of ethanol and lactic acid pre-fermentation on putrefactive bacteria suppression, hydrolysis, and methanogenesis of food waste. Energy & Fuels. 2016;30(4):2982-2989. DOI: 10.1021/acs.energyfuels.5b02779
  186. 186. Zhang B, Cai WM, He PJ. Influence of lactic acid on the two-phase anaerobic digestion of kitchen wastes. Journal of Environmental Sciences. 2007;19(2):244-249. DOI: 10.1016/S1001-0742(07)60040-0
  187. 187. Pahlow G, Muck RE, Driehuis F, Oude Elferink SJWH, Spoelstra SF. Microbiology of ensiling. In: Buxton DR, Muck RE, Harrison JH, editors. Silage Science and Technology. Agronomy Monograph 42. Madison: American Society of Agronomy; 2003. pp. 31-93. DOI: 10.2134/agronmonogr42.c2
  188. 188. Balat M, Balat H. Recent trends in global production and utilization of bio-ethanol fuel. Applied Energy. 2009;86(11):2273-2282. DOI: 10.1016/j.apenergy.2009.03.015
  189. 189. Gold RS, Meagher MM, Hutkins R, Conway T. Ethanol tolerance and carbohydrate metabolism in lactobacilli. Journal of Industrial Microbiology. 1992;10(1):45-54. DOI: 10.1007/BF01583633
  190. 190. Schell DJ, Dowe N, Ibsen KN, Riley CJ, Ruth MF, Lumpkin RE. Contaminant occurrence, identification and control in a pilot-scale corn fiber to ethanol conversion process. Bioresource Technology. 2007;98(15):2942-2948. DOI: 10.1016/j.biortech.2006.10.002
  191. 191. Lucena BT, dos Santos BM, Moreira JL, Moreira JL, Nunes AC, Azevedo V, Miyoshi A, Thompson FB, de Morais MA Jr. Diversity of lactic acid bacteria of the bioethanol process. BMC Microbiology. 2010;10(1):298. DOI: 10.1186/1471-2180-10-298
  192. 192. Narendranath NV, Thomas KC, Ingledew WM. Acetic acid and lactic acid inhibition of growth of Saccharomyces cerevisiae by different mechanisms. Journal of the American Society of Brewing Chemists. 2001;59(4):187-194. DOI: 10.1094/ASBCJ-59-0187
  193. 193. Liu S, Skinner-Nemec KA, Leathers TD. Lactobacillus buchneri strain NRRL B-30929 converts a concentrated mixture of xylose and glucose into ethanol and other products. Journal of Industrial Microbiology & Biotechnology. 2008;35(2):75-81. DOI: 10.1007/s10295-007-0267-8
  194. 194. Liu S, Nichols NN, Dien BS, Cotta MA. Metabolic engineering of a Lactobacillus plantarum double Ldh knockout strain for enhanced ethanol production. Journal of Industrial Microbiology and Biotechnology. 2006;33(1):1-7. DOI: 10.1007/s10295-005-0001-3
  195. 195. Nair NU, Shao Z, Zhao H, Sullivan RP, McLachlan M, Johannes T, Zhao H. Biobutanol from yeast: A synergistic genome and protein engineering approach. In: The 2008 AIChE Annual Meeting, Conference Proceedings, Philadelphia, PA, USA. November 16-21, 2008.
  196. 196. Atsumi S, Cann AF, Connor MR, Shen CR, Smith KM, Brynildsen MP, Chou KJ, Hanai T, Liao JC. Metabolic engineering of Escherichia coli for 1-butanol production. Metabolic Engineering. 2008;10(6):305-311. DOI: 10.1016/j.ymben.2007.08.003
  197. 197. Nielsen DR, Leonard E, Yoon SH, Tseng HC, Yuan C, Prather KL. Engineering alternative butanol production platforms in heterologous bacteria. Metabolic Engineering. 2009;11(4-5):262-273. DOI: 10.1016/j.ymben.2009.05.003
  198. 198. Berezina OV, Zakharova NV, Brandt A, Yarotsky SV, Schwarz WH, Zverlov VV. Reconstructing the clostridial n-butanol metabolic pathway in Lactobacillus brevis. Applied Microbiology and Biotechnology. 2010;87(2):635-646. DOI: 10.1007/s00253-010-2480-z
  199. 199. Liu S, Bischoff KM, Qureshi N, Hughes SR, Rich JO. Functional expression of the thiolase gene thl from Clostridium beijerinckii P260 in Lactococcus lactis and Lactobacillus buchneri. New Biotechnology. 2010;27(4):283-288. DOI: 10.1016/j.nbt.2010.03.007
  200. 200. Ghiaci P, Lameiras F, Norbeck J, Larsson C. Production of 2-butanol through meso-2, 3-butanediol consumption in lactic acid bacteria. FEMS Microbiology Letters. 2014;360(1):70-75. DOI: 10.1111/1574-6968.12590
  201. 201. Steinkraus KH. Introduction to indigenous fermented foods. In: Steinkraus KH, editor. Handbook of Indigenous Fermented Foods. New York: Marcel Dekker; 1995. pp. 1-6.
  202. 202. Liu SN, Han Y, Zhou ZJ. Lactic acid bacteria in traditional fermented Chinese foods. Food Research International. 2011;44:643-651. DOI: 10.1016/j.foodres.2010.12.034
  203. 203. Canadian Dairy Commission. Fermented Milk Products. 2011. http://www.milkingredients.ca/index-eng.php?id=180 [Accessed: April 6, 2017].
  204. 204. Bylund G. Dairy Processing Handbook. Tetra Pak International S.A.; 2015. 486 p.
  205. 205. Nip WK. (2007). Fermented products and their manufacture. In: Hui YH, editor. Handbook of Food Products Manufacturing. USA: CRC Press/Taylor & Francis; 2007. pp. 45−84. DOI: 10.1002/9780470113554.ch2
  206. 206. Laiño JE, Juarez del Valle M, Savoy de Giori G, LeBlanc JG. Applicability of a Lactobacillus amylovorus strain as co-culture for natural folate bio-enrichment of fermented milk. International Journal of Food Microbiology. 2014;191:10-16. DOI: 10.1016/j.ijfoodmicro. 2014.08.031
  207. 207. Capozzi V, Menga V, Digesu AM, De Vita P, van Sinderen D, Cattivelli L, Fares C, Spano G. Biotechnological production of vitamin B2-enriched bread and pasta. Journal of Agricultural and Food Chemistry. 2011;59(14):8013-8020. DOI: 10.1021/jf201519h
  208. 208. Taranto MP, Vera JL, Hugenholtz J, De Valdez GF, Sesma F. Lactobacillus reuteri CRL1098 produces cobalamin. Journal of Bacteriology. 2003;185(18):5643-5647. DOI: 10.1128/JB.185.18.5643-5647.2003
  209. 209. Morishita T, Tamura N, Makino T, Kudo S. Production of menaquinones by lactic acid bacteria. Journal of Dairy Science. 1999;82(9):1897-1903. DOI: 10.3168/jds.S0022-0302(99)75424-X
  210. 210. Davies EA, Bevis HE, Delves-Broughton J. The use of the bacteriocin, nisin, as a preservative in ricotta-type cheeses to control the food-borne pathogen Listeria monocytogenes. Letters in Applied Microbiology. 1997;24(5):343-346. DOI: 10.1046/j.1472-765X.1997.00145.x
  211. 211. Pei J, Yue T, Yuan Y, Dai L. Activity of paracin C from lactic acid bacteria against Alicyclobacillus in apple juice: Application of a novelty bacteriocin. Journal of Food Safety. 2017;00:e12350. DOI: 10.1111/jfs.12350
  212. 212. Miao J, Guo H, Ou Y, Liu G, Fang X, Liao Z, Ke C, Chen Y, Zhao L, Cao Y. Purification and characterization of bacteriocin F1, a novel bacteriocin produced by Lactobacillus paracasei subsp. tolerans FX-6 from Tibetan kefir, a traditional fermented milk from Tibet, China. Food Control. 2014;42:48-53. DOI: 10.1016/j.foodcont.2014.01.041
  213. 213. Nielsen JW, Dickson JS, Crouse JD. Use of a bacteriocin produced by Pediococcus acidilactici to inhibit Listeria monocytogenes associated with fresh meat. Applied and Environmental Microbiology. 1990;56(7):2142-2145
  214. 214. Sanni AI, Onilude AA, Ogunbanwo ST, Smith SI. Antagonistic activity of bacteriocin produced by Lactobacillus species from ogi, an indigenous fermented food. Journal of Basic Microbiology. 1999;39(3):189-195. DOI: 10.1002/(SICI)1521-4028(199906)39:33.3.CO;2-I
  215. 215. Sonsa-Ard N, Rodtong S, Chikindas ML, Yongsawatdigul J. Characterization of bacteriocin produced by Enterococcus faecium CN-25 isolated from traditionally Thai fermented fish roe. Food Control. 2015;54:308-316. DOI: 10.1016/j.foodcont.2015.02.010
  216. 216. Rodríguez-Alcalá LM, Braga T, Malcata FX, Gomes A, Fontecha J. Quantitative and qualitative determination of CLA produced by Bifidobacterium and lactic acid bacteria by combining spectrophotometric and Ag+-HPLC techniques. Food Chemistry. 2011;125(4):1373-1378. DOI: 10.1016/j.foodchem.2010.10.008
  217. 217. Herzallah S. Enrichment of conjugated linoleic acid (CLA) in hen eggs and broiler chickens meat by lactic acid bacteria. British Poultry Science. 2013;54(6):747-752. DOI: 10.1080/00071668.2013.836734
  218. 218. Liu P, Shen SR, Ruan H, Zhou Q, Ma LL, He GQ. Production of conjugated linoleic acids by Lactobacillus plantarum strains isolated from naturally fermented Chinese pickles. Journal of Zhejiang University. Science. B. 2011;12(11):923-930. DOI: 10.1631/jzus.B1100072
  219. 219. Duboc P, Mollet B. Applications of exopolysaccharides in the dairy industry. International Dairy Journal. 2001;11(9):759-768. DOI: 10.1016/S0958-6946(01)00119-4
  220. 220. Han X, Yang Z, Jing X, Yu P, Zhang Y, Yi H, Zhang L. Improvement of the texture of yogurt by use of exopolysaccharide producing lactic acid bacteria. BioMed Research International. 2016;2016:1-6. DOI: 10.1155/2016/7945675
  221. 221. Low D, Ahlgren JA, Horne D, McMahon DJ, Oberg CJ, Broadbent JR. Role of Streptococcus thermophilus MR-1C capsular exopolysaccharide in cheese moisture retention. Applied and Environmental Microbiology. 1998;64(6):2147-2151.
  222. 222. Macura D, Townsley PM. Scandinavian ropy milk: Identification and characterization of endogenous ropy lactic streptococci and their extracellular excretion. Journal of Dairy Science. 1984;67:735-744.
  223. 223. Adapa S, Schmidt KA. Physical properties of low-fat sour cream containing exopolysaccharide producing lactic acid. Journal of Food Science. 1998;63:901-903. DOI: 10.1111/j.1365-2621.1998.tb17922.x
  224. 224. Hong SH, Marshall RT. Natural exopolysaccharides enhance survival of lactic acid bacteria in frozen dairy desserts. Journal of dairy science. 2001;84(6):1367-1374. DOI: 10.3168/jds.S0022-0302(01)70167-1
  225. 225. Di Cagno R, De Angelis M, Limitone A, Minervini F, Carnevali P, Corsetti A, Gaenzle M, Ciati R, Gobbetti M. Glucan and fructan production by sourdough Weissella cibaria and Lactobacillus plantarum. Journal of Agricultural and Food Chemistry. 2006;54(26):9873-9881. DOI: 10.1021/jf061393+
  226. 226. Rodríguez C, Medici M, Rodríguez AV, Mozzi F, Font de Valdez G. Prevention of chronic gastritis by fermented milks made with exopolysaccharide-producing Streptococcus thermophilus strains. Journal of Dairy Science. 2009;92(6):2423-2434. DOI: 10.3168/jds.2008-1724
  227. 227. Tok E, Aslim B. Cholesterol removal by some lactic acid bacteria that can be used as probiotic. Microbiology and Immunology. 2010;54(5):257-264. DOI: 10.1111/ j.1348-0421.2010.00219.x
  228. 228. Beckman KB, Ames BN. The free radical theory of aging matures. Physiological Reviews. 1998;78(2):547-581.
  229. 229. Virtanen T, Pihlanto A, Akkanen S, Korhonen H. Development of antioxidant activity in milk whey during fermentation with lactic acid bacteria. Journal of Applied Microbiology. 2007;102:106-115. DOI: 10.1111/j.1365-2672.2006.03072.x
  230. 230. Pyo YH, Lee TC, Lee YC. Effect of lactic acid fermentation on enrichment of antioxidant properties and bioactive isoflavones in soybean. Journal of Food Science. 2005;70:S215–S220. DOI: 10.1111/j.1365-2621.2005.tb07160.x
  231. 231. Ravyts F, De Vuyst L. Prevalence and impact of single-strain starter cultures of lactic acid bacteria on metabolite formation in sourdough. Food microbiology. 2011;28(6):1129-1139. DOI: 10.1016/j.fm.2011.03.004
  232. 232. Soetaert W, Vanhooren PT, Vandamme EJ. Production of mannitol by fermentation. Carbohydrate Biotechnology Protocols. 1999;10:261-275. DOI: 10.1007/978-1-59259-261-6_21
  233. 233. Saha BC, Racine FM. Biotechnological production of mannitol and its applications. Applied Microbiology and Biotechnology. 2011;89(4):879-891. DOI: 10.1007/s00253-010-2979-3
  234. 234. Monedero V, Pérez-Martínez G, Yebra MJ. Perspectives of engineering lactic acid bacteria for biotechnological polyol production. Applied Microbiology and Biotechnology. 2010;86(4):1003-1015. DOI: 10.1007/s00253-010-2494-6

Written By

Galina Novik, Olga Meerovskaya and Victoria Savich

Submitted: 03 October 2016 Reviewed: 18 April 2017 Published: 06 September 2017