Review Article
Biosurfactants in Pharmaceutical Industry (A Mini-Review)
Department of Pharmacognosy and Biotechnology, Faculty of Pharmacy,Mazandaran University of Medical Sciences, Sari, Iran
A surfactant is an amphiphilic agent with both lipophilic and hydrophilic structural moieties in its molecule. Surfactants are widely used for industrial, agricultural, food, cosmetic and pharmaceutical applications. Most of these compounds are chemically synthesized and potentially cause environmentally and toxically problems (Schramm et al., 2003; Makkar and Rockne, 2003). However, it is only in the past few decades that surface active molecules of microbial origin, referred to as biosurfactants, have gained considerable interest (Desai and Banat, 1997; Healy et al., 1996). Biosurfactants are surface-active metabolites produced by microorganisms when grown on water miscible or oily substrates: they either remain adherent to microbial cell surfaces or are secreted in the culture broth (Abouseouda et al., 2008; Correa-Bicca et al., 1999; Cunha et al., 2004; Das and Mukherjee, 2007). They possess the characteristic property of reducing the surface and interfacial tensions using the same mechanisms as chemical surfactants (Singh et al., 2007). Microbial surfactants constitute a diverse group of surface-active molecules and are known to occur in a variety of chemical structures, such as glycolipids, lipopeptides and lipoproteins, fatty acids, neutral lipids, phospholipids and polymeric and particulate structures (Desai and Banat, 1997). The features that make them commercially promising alternatives to chemically synthesized surfactants are their lower toxicity, higher biodegradability and hence, greater environmental compatibility, better foaming properties (useful in mineral processing) and stable activity at extremes of pH, salinity and temperature (Amiriyan et al., 2004; Batista et al., 2006; Bento et al., 2005; Bhattacharyya et al., 2003; Bodour et al., 2003; Cameotra and Makkar, 2004; Chen et al., 2007; Christofi and Ivshina, 2002; Cohen and Exerowa, 2007). Unlike chemical surfactants, which are mostly derived from petroleum feedstock, these molecules can be produced by microbial fermentation processes (Fusconi et al., 2010; Silva et al., 2009) using cheaper agrobased substrates and waste materials (Fox and Bala, 2000; Maneerat, 2005; Nitschke et al., 2004; Panilaitis et al., 2007; Rashedi et al., 2005; Rivardo et al., 2009; Rivera et al., 2007; Rodrigues et al., 2006a).
Although, most biosurfactants are considered to be secondary metabolites, some may play essential roles for the survival of biosurfactant-producing microorganisms through facilitating nutrient transport or microbe-host interactions or by acting as biocide agents (Dehghan-Noudeh et al., 2005; Deziel et al., 1996; Fernandes et al., 2007; Rodrigues et al., 2006a). Biosurfactant roles include increasing the surface area and bioavailability of hydrophobic water-insoluble substrates, heavy metal binding (Kavamura and Esposito, 2010; Hoffiman et al., 2010), bacterial pathogenesis and biofilm formation (Fiechter, 1992; Gautam and Tiagi, 2006; Healy et al., 1996; Simoes et al., 2010).
In various industrial processes, they are potentially useful surface-active agents for emulsion (Dhakephalkar et al., 2010; Amaral et al., 2009; Huang et al., 2010). Polymerization, wetting, foaming, phase dispersion, emulsification and de-emulsification (Kosaric, 1992; Martinez-Checa et al., 2007). Biosurfactants have also been found to possess several properties of therapeutic and biomedical importance (Gudiana et al., 2010). They have antibacterial, antifungal (Joshi et al., 2008) and antiviral properties; they inhibit fibrin clot formation and they have anti-adhesive action against several pathogenic microorganisms (Mulligan, 2005; Rodrigues et al., 2004, 2006a; Singh and Cameotra, 2004).
Recently, biosurfactants received much attention in nanobiotechnology criteria (Koopmans and Aggeli, 2010; Palanisamy, 2008; Rodriguez et al., 2010; Cevc and Vierl, 2010; Solanki and Murthy, 2010; Reddy et al., 2009; Palanisamy and Riachur, 2009).
Surface-active compounds produced by microorganisms are of two main types, those that reduce surface tension at the air-water interface (biosurfactants) and those that reduce the interfacial tension between immiscible liquids, or at the solid-liquid interface (bioemulsifiers). Biosurfactants usually exhibit emulsifying capacity but bioemulsifiers do not necessarily reduce surface tension (Kakugawa et al., 2002; Konishi et al., 2007; Langer et al., 2006; Freitas et al., 2009).
Here, we discuss the role and applications of biosurfactants focusing on medicinal pharmaceutical perspectives.
BIOSURFACTANT CLASSIFICATION
Unlike chemically synthesized surfactants, which are classified according to the nature of their polar grouping, biosurfactants are categorized mainly by their chemical composition and their microbial origin. According to the studies of Desai and Banat (1997) and Gautam and Tiagi (2006), biosurfactants, based on the structure of their hydrophilic part, are mainly classified into 5 categories:
• | Glycolipids |
• | Lipopeptides |
• | Fatty acids |
• | Polymer type |
• | Particulate biosurfactants (Desai and Banat, 1997; Gautam and Tiagi, 2006). |
Glycolipids: Most known biosurfactants are glycolipids. They are carbohydrates in combination with long-chain aliphatic acids or hydroxyaliphatic acids. Among the glycolipids, the best known are rhamnolipids, trehalolipids and sophorolipids (Morita et al., 2006; Sullivan, 1998; Thanomsub et al., 2007).
Lipopeptides and lipoproteins: A large number of cyclic lipopetides including decapeptide antibiotics (gramicidins) and lipopeptide antibiotics (polymyxins) possess remarkable surface-active properties.
Fatty acids, phospholipids and neutral lipids: Several bacteria and yeasts produce large quantities of fatty acid and phospholipid surfactants during growth on n-alkanes.
Polymeric biosurfactants: The best-studied polymeric biosurfactants are emulsan, liposan, mannoprotein and other polysaccharide-protein complexes.
Particulate biosurfactants: Extracellular membrane vesicles partition hydrocarbons to form a microemulsion which plays an important role in alkane uptake by microbial cells (Monteiro et al., 2007; Mukherjee et al., 2006; Ortiz et al., 2006).
Thus the majority of biosurfactants include low-molecular-weight glycolipids (GLs), lipopeptides (LPS), flavolipids (FLs), phospholipids and high-molecular-weight polymers such as lipoproteins, lipopolysaccharide-protein complexes and polysaccharide-protein-fatty acid complexes. Biosurfactants have a great deal of structural diversity. The common lipophilic moiety of a biosurfactant molecule is the hydrocarbon chain of a fatty acid, whereas the hydrophilic part is formed by ester or alcohol groups of neutral lipids, by the carboxylate group of fatty acids or amino acids (or peptides), organic acid in the case of flavolipids, or, in the case of glycolipids, by the carbohydrate (Rodrigues et al., 2006b; Ruiz-Garc et al., 2005; Santa Annal et al., 2002; Singh et al., 2007).
Potential applications of biosurfactants in industries: Surfactants offer extraordinary benefits to many industries. They are involved in infinite number of different industrial processes and physicochemical phenomenon; increasing mobility, increasing solubility, lubrication, removing soil or scouring (Pei et al., 2009; Lai et al., 2009), wetting, rewetting, softening, retarding dyeing rate, fixing dyes, making emulsions, stabilizing dispersions, coagulating suspended solids, making foams (Hirata et al., 2009), preventing foam formation and defoaming (Kosaric, 1992; Zang and Miller, 1992; Zouboulis et al., 2003). The most significant application of biosurfactants was studied in bioremediation for example in removing heavy metals from soils (Asci et al., 2010; Wang and Mulligan, 2009a, b; Gusiatin et al., 2009; Mullingan, 2009; Frazetti et al., 2009; Nayak et al., 2009).
In addition of all these benefits, biosurfactants have a large number of bioactivities: inhibit bacterial growth (Flagas and Makris, 2009; Sabate et al., 2009), toxic effects, immune stimulant, tumor growth inhibition, antibiotic, cell lysis (haemolysis) (Dehghan-Noudeh et al., 2005), plant pathogenicity (Joshi et al., 2008), effects on migration of human neutrophils, respiratory action (anti- asthma activity), food digestion (Nitschke and Costa, 2007), inhibition of cell wall synthesis, fungicidal properties (Joshi et al., 2008) or enzyme stimulation, bio regulatory effects, etc. Hence they play part in many processes in nature (Rodrigues et al., 2006b).
These molecules have an unlimited number of uses that involves every industry and every aspect of life: oil industry, pharmaceuticals, testing quality of condoms, hygiene an cosmetics, cement, beer and beverages, textiles, paint, detergents and cleaning (Rai and Mukherjee, 2010) and food processing (Arauz et al., 2009). However, the applications depend on applied properties and the mechanism of action.
Potential applications of biosurfactants in pharmaceutics: Kakugawa et al. (2002), as well as Mukherjee et al. (2006) demonstrated that the biosurfactants could have a wide range of applications in pharmaceutical fields.
Gene delivery: The establishment of an efficient and safe method for introducing exogenous nucleotides into mammalian cells is critical for basic sciences and clinical applications such as gene therapy. Among various methods for gene transfection, (Zhang et al., 2010; Fujita et al., 2009; Liu et al., 2010) lipofection using cationic liposomes is considered to be a promising way to deliver foreign gene to the target cells without side-effects. Although, several kinds of cationic liposomes for lipofection have been developed, further studies are still required to develop a non-viral vector which has comparable efficiency to viral vectors (Inoh et al., 2001, 2004; Kitamato et al., 2002; Maitani et al., 2007; Okayama et al., 1997).
Kitamato et al. (2002) demonstrated that in comparison with commercially available cationic liposomes, liposomes based on biosurfactants show increasing efficiency of gene transfection. Ueno et al. (2007) have been developing some new techniques and methodologies for the liposome- based gene transfection. They introduced biosurfactants in this field. They examined MEL-A-containing liposomes for gene transfection.
Immunological adjuvants: Bacterial lipopeptides constitute potent non-toxic and non-pyrogenic immunological adjuvants when mixed with conventional antigens. A marked enhancement of the humoral immune response was obtained with the low molecular mass antigens iturin AL, herbicolin A and microcystin (MLR) coupled to poly-L-lysine (MLR-PLL) in rabbits and in chickens (Rodrigues et al., 2006b).
Inhibition the adhesion of pathogenic organisms to solid surfaces: Biosurfactants have been found to inhibit the adhesion of pathogenic organisms to solid surfaces or to infection sites (Das et al., 2009); thus, prior adhesion of biosurfactants to solid surfaces might constitute a new and effective means of combating colonization by pathogenic microorganisms (Rivardo et al., 2009). Pre-coating vinyl urethral catheters by running the surfactin solution through them before inoculation with media resulted in a decrease in the amount of biofilm formed by Salmonella typhimurium, Salmonella enterica, E. coli and Proteus mirabilis (Rodrigues et al., 2004). Furthermore, Rodrigues et al. (2004) demonstrated that biosurfactants greatly reduced microbial numbers on prostheses and also induced a decrease in the airflow resistance that occurs on voice prostheses after biofilm formation.
Recovery of intracellular products: Surfactants have also been used to permeabilise or lyse cells after fermentation as part of the protocol for recovery of intracellular products. Reverse micelle solutions were used for selective permeabilization of Escherichia coli to facilitate extraction of penicillin acylase. This process can be achieved by using biosurfactants (Singh et al., 2007).
It is well known that highest efficiencies in terms of overall release of intracellular proteins from microbial cells are achieved through aggressive mechanical cell disintegration methods. However, in addition to releasing intracellular proteins, these methods solubilize most of the protein components associated with cell walls, organelles and membranes. More selective permeabilization, achieved by using reagents which render the cell envelope more porous are beneficial for selective release of target proteins where the objective is to obtain an extracted product with a high specific activity or where further protein purification is required. Biosurfactants can be the reagents of choice for membrane permeabilization (Desai and Banat, 1997).
Thus, in the recovery of purified intracellular proteins use of selected biosurfactants to permeabilise cells with selective protein release represents a promising purification option. In selecting biosurfactants for these applications the primary consideration is the efficiency and selectivity of the surfactant in permeabilizing cells with the selective release of the desired product. It is also important to insure the chosen biosurfactant has no negative impact on the stability or activity of the product since biosurfactants may bind to proteins and other bioactive molecules (Desai and Banat, 1997; Singh et al., 2007).
Antimicrobial activity: The diverse structures of biosurfactants confer them to display versatile performance (Ajesh and Sreejith, 2009; Zhao et al., 2010). By its structure, biosurfactant is supposed to exert its toxicity on the cell membrane permeability as a detergent like effect. One useful property of many biosurfactants is their antimicrobial activity (Rahman and Ano, 2009). Several biosurfactants have strong antibacterial, antifungal and antiviral activity. Other medically relevant uses of biosurfactants include their role as anti-adhesive agents to pathogens, making them useful for treating many diseases and as therapeutic and probiotic agents. The MEL, a glycolipid biosurfactant, exerted the growth inhibition and differentiation-inducing activities against human leukemia cell lines by directly affect intracellular signal transduction through phosphate cascade system (Tabatabaee et al., 2005; Tahzibi et al., 2004; Techaoei et al., 2007; Thaniyavarn et al., 2006).
Das et al. (2009) have reported a biosurfactant produced by marine B. circulans that had a potent antimicrobial activity against Gram-positive and Gram-negative pathogenic and semi-pathogenic microbial strains including MDR strains.
Fernandes et al. (2007) investigated the antimicrobial activity of biosurfactants from Bacillus subtillis R14 against 29 bacterial strains. Their results demonstrated that lipopeptides have a broad spectrum of action, including antimicrobial activity against microorganisms with multidrug-resistant profiles (Fernandes et al., 2007).
Rodrigues et al. (2006c) mentioned in their review about biosurfactants that MELs produced by Candida antartica, rhamnolipids produced by P. aeruginosa and lipopeptides produced by B. subtilis31 and B. licheniformis have been shown to have antimicrobial activities (Rodrigues et al., 2006d).
Biosurfactants for cosmetics: Many biosurfactant properties such as emulsification and de-emulsification, foaming, water binding capacity, spreading and wetting properties effect on viscosity and on product consistency, can efficiently be utilized by the above industry.
Surfactants as emulsifiers, foaming agents, solubilizers, wetting agents, cleansers, antimicrobial agents, mediators of enzyme action in various dosage forms like creams, lotions, liquids, pastes, powders, sticks, gels, films, sprays could be used and may be replaced by biosurfactants (Tugrul and Cansunar, 2005; Tuleva et al., 2002; Ueno et al., 2007; Urum and Pekdemir, 2004; Villeneuve, 2007; Youssef et al., 2007).
Cosmetic products using surfactants including; insect repellents, antacids, bath products, acne pads, antidandruff products, contact lens solution, hair colours and care products, deodorants, nail care, body massage accessories, lipsticks, lip makers, eye shades, mascaras, soap, tooth pastes and polishes, denture cleansers, adhesives, antiperspirants, lubricated condoms, baby products, foot care, mousses, antiseptics, shampoos, conditioners, shampoos, conditioners, shave and depilatory products, moisturizers, health and beauty products (Schramm et al., 2003). All of these applications could be replaced by using biosurfactants.
Chemically synthesized surface-active compounds are widely used in the pharmaceutical, cosmetic, petroleum and food industries. However, with the advantages of biodegradability and production on renewable-resource substrates, biosurfactants may eventually replace their chemically synthesized counterparts. So far, the use of biosurfactants has been limited to a few specialized applications because biosurfactants have been economically uncompetitive. There is a need to gain a greater understanding of the physiology, genetics and biochemistry of biosurfactant-producing strains and to improve process technology to reduce production costs (Youssef et al., 2004, 2007; Zang and Miller, 1992; Zouboulis et al., 2003).