Biofilms: microbial life on surfaces. (Perspective).Microorganisms attach to surfaces and develop biofilms. Biofilm-associated cells can be differentiated from their suspended counterparts by generation of an extracellular polymeric substance Extracellular polymeric substances are high-molecular weight compounds secreted by microorganisms into their environment.[1] These are mostly composed of polysaccharides and can either remain attached to the cell's outer surface, or be secreted into its growth medium. (EPS (Encapsulated PostScript) A PostScript file format used to transfer a graphic image between applications and platforms. EPS files contain PostScript code as well as an optional preview image in TIFF, WMF, PICT or EPSI, the latter being an ASCII-only format. ) matrix, reduced growth rates, and the up--and down-regulation of specific genes. Attachment is a complex process regulated by diverse characteristics of the growth medium, substratum sub·stra·tum n. pl. sub·stra·ta or sub·stra·tums 1. a. An underlying layer. b. A layer of earth beneath the surface soil; subsoil. 2. A foundation or groundwork. 3. , and cell surface. An established biofilm Biofilm An adhesive substance, the glycocalyx, and the bacterial community which it envelops at the interface of a liquid and a surface. When a liquid is in contact with an inert surface, any bacteria within the liquid are attracted to the surface and adhere structure comprises microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. cells and EPS, has a defined architecture, and provides an optimal environment for the exchange of genetic material between cells. Cells may also communicate via quorum sensing, which may in turn affect biofilm processes such as detachment. Biofilms have great importance for public health because of their role in certain infectious diseases and importance in a variety of device-related infections. A greater understanding of biofilm processes should lead to novel, effective control strategies for biofilm control and a resulting improvement in patient management. ********** For most of the history of microbiology, microorganisms have primarily been characterized as planktonic, freely suspended cells and described on the basis of their growth characteristics in nutritionally rich culture media. Rediscovery of a microbiologic phenomenon, first described by van Leeuwenhoek, that microorganisms attach to and grow universally on exposed surfaces led to studies that revealed surface-associated microorganisms (biofilms) exhibited a distinct phenotype with respect to gene transcription and growth rate. These biofilm microorganisms have been shown to elicit specific mechanisms for initial attachment to a surface, development of a community structure and ecosystem, and detachment. A Historical Basis A biofilm is an assemblage of surface-associated microbial cells that is enclosed in an extracellular polymeric substance matrix. Van Leeuwenhoek, using his simple microscopes, first observed microorganisms on tooth surfaces and can be credited with the discovery of microbial biofilms. Heukelekian and Heller (1) observed the "bottle effect" for marine microorganisms, i.e., bacterial growth and activity were substantially enhanced by the incorporation of a surface to which these organisms could attach. Zobell (2) observed that the number of bacteria on surfaces was dramatically higher than in the surrounding medium (in this case, seawater). However, a detailed examination of biofilms would await the electron microscope, which allowed high-resolution photomicroscopy at much higher magnifications than did the light microscope. Jones et al. (3) used scanning and transmission electron microscopy “TEM” redirects here. For other uses, see TEM (disambiguation). Transmission electron microscopy (TEM) is an imaging technique whereby a beam of electrons is transmitted through a specimen, then an image is formed, magnified and directed to appear either to examine biofilms on trickling filters in a wastewater treatment plant Wastewater treatment plant also called wastewater treatment works
fix·a·tive adj. , these researchers were also able to show that the matrix material surrounding and enclosing cells in these biofilms was polysaccharide polysaccharide: see carbohydrate. polysaccharide Any of a large class of long-chain sugars composed of monosaccharides. Because the chains may be unbranched or branched and the monosaccharides may be of one, two, or occasionally more kinds, . As early as 1973, Characklis (4) studied microbial slimes in industrial water systems and showed that they were not only very tenacious but also highly resistant to disinfectants such as chlorine. Based on observations of dental plaque and sessile sessile /ses·sile/ (ses´il) attached by a broad base, as opposed to being pedunculated or stalked. ses·sile adj. Permanently attached or fixed; not free-moving. communities in mountain streams, Costerton et al. (5) in 1978 put forth a theory of biofilms that explained the mechanisms whereby microorganisms adhere to living and nonliving materials and the benefits accrued by this ecologic niche. Since that time, the studies of biofilms in industrial and ecologic settings and in environments more relevant for public health have basically paralleled each other. Much of the work in the last 2 decades has relied on tools such as scanning electron microscopy (SEM) or standard microbiologic culture techniques for biofilm characterization. Two major thrusts in the last decade have dramatically impacted our understanding of biofilms: the utilization of the confocal confocal see confocal microscopy. laser scanning microscope to characterize biofilm ultrastructure ultrastructure /ul·tra·struc·ture/ (-struk?chur) the structure beyond the resolution power of the light microscope, i.e., visible only under the ultramicroscope and electron microscope. , and an investigation of the genes involved in cell adhesion and biofilm formation. Biofilm Defined A biofilm is an assemblage of microbial cells that is irreversibly associated (not removed by gentle rinsing) with a surface and enclosed in a matrix of primarily polysaccharide material. Noncellular materials such as mineral crystals, corrosion particles, clay or silt particles, or blood components, depending on the environment in which the biofilm has developed, may also be found in the biofilm matrix. Biofilm-associated organisms also differ from their planktonic (freely suspended) counterparts with respect to the genes that are transcribed. Biofilms may form on a wide variety of surfaces, including living tissues, indwelling indwelling /in·dwell·ing/ (in´dwel-ing) pertaining to a catheter or other tube left within an organ or body passage for drainage, to maintain patency, or for the administration of drugs or nutrients. medical devices, industrial or potable potable /pot·a·ble/ (po´tah-b'l) fit to drink. po·ta·ble adj. Fit to drink; drinkable. potable fit to drink. water system piping, or natural aquatic systems. The variable nature of biofilms can be illustrated from scanning electron micrographs of biofilms from an industrial water system and a medical device, respectively (Figures 1 and 2). The water system biofilm is highly complex, containing corrosion products, clay material, fresh water diatoms diatoms a series of unicellular algae, microscopic in size, with cell walls containing silica. Members of the family Diatomaceae. Their remains accumulate as geological deposits and are mined. See diatomaceous earth. , and filamentous filamentous /fil·a·men·tous/ (fil?ah-men´tus) composed of long, threadlike structures. filamentous composed of long, threadlike structures. bacteria. The biofilm on the medical device, on the other hand, appears to be composed of a single, coccoid coccoid resembling a coccus. organism and the associated extracellular polymeric substance (EPS) matrix. [FIGURE 1-2 OMITTED] Attachment The solid-liquid interface between a surface and an aqueous medium (e.g., water, blood) provides an ideal environment for the attachment and growth of microorganisms. A clear picture of attachment cannot be obtained without considering the effects of the substratum, conditioning films forming on the substratum, hydrodynamics hydrodynamics: see mechanics. Hydrodynamics The study of fluids in motion. The study is based upon the physical conservation laws of mass, momentum, and energy. of the aqueous medium, characteristics of the medium, and various properties of the cell surface. Each of these factors will be considered in detail. Substratum Effects The solid surface may have several characteristics that are important in the attachment process. Characklis et al. (6) noted that the extent of microbial colonization appears to increase as the surface roughness increases. This is because shear forces are diminished, and surface area is higher on rougher surfaces. The physicochemical physicochemical /phys·i·co·chem·i·cal/ (fiz?i-ko-kem´ik-il) pertaining to both physics and chemistry. phys·i·co·chem·i·cal adj. 1. Relating to both physical and chemical properties. properties of the surface may also exert a strong influence on the rate and extent of attachment. Most investigators have found that microorganisms attach more rapidly to hydrophobic, nonpolar nonpolar not having poles; not exhibiting dipole characteristics. surfaces such as Teflon and other plastics than to hydrophilic hydrophilic /hy·dro·phil·ic/ (-fil´ik) readily absorbing moisture; hygroscopic; having strongly polar groups that readily interact with water. hy·dro·phil·ic adj. materials such as glass or metals (7-9). Even though results of these studies have at times been contradictory because no standardized methods exist for determining surface hydrophobicity, some kind of hydrophobic interaction apparently occurs between the cell surface and the substratum that would enable the cell to overcome the repulsive forces active within a certain distance from the substratum surface and irreversibly attach. Conditioning Films A material surface exposed in an aqueous medium will inevitably and almost immediately become conditioned or coated by polymers from that medium, and the resulting chemical modification will affect the rate and extent of microbial attachment. Loeb and Neihof (10) were the first to report the formation of these conditioning films on surfaces exposed in seawater. These researchers found that films were organic in nature, formed within minutes of exposure, and continued to grow for several hours. The nature of conditioning films may be quite different for surfaces exposed in the human host. A prime example may be the proteinaceous conditioning film called "acquired pellicle pellicle /pel·li·cle/ (pel´ik'l) a thin scum forming on the surface of liquids. pel·li·cle n. A thin skin or film on the surface of a liquid. ," which develops on tooth enamel surfaces in the oral cavity. Pellicle comprises albumin, lysozyme lysozyme: see immunity. Lysozyme An enyme that was first identified and named by Alexander Fleming, who recognized its bacteriolytic properties. , glycoproteins, phosphoproteins, lipids, and gingival crevice fluid (11); bacteria from the oral cavity colonize col·o·nize v. col·o·nized, col·o·niz·ing, col·o·niz·es v.tr. 1. To form or establish a colony or colonies in. 2. To migrate to and settle in; occupy as a colony. 3. pellicle-conditioned surfaces within hours of exposure to these surfaces. Mittelman noted that a number of host-produced conditioning films such as blood, tears, urine, saliva, inter-vascular fluid, and respiratory secretions influence the attachment of bacteria to biomaterials (12). Ofek and Doyle (13) also noted that the surface energy of the suspending medium may affect hydrodynamic hy·dro·dy·nam·ic also hy·dro·dy·nam·i·cal adj. 1. Of or relating to hydrodynamics. 2. Of, relating to, or operated by the force of liquid in motion. interactions of microbial cells with surfaces by altering the substratum characteristics. Hydrodynamics In theory, the flow velocity immediately adjacent to the substratum/liquid interface is negligible. This zone of negligible flow is termed the hydrodynamic boundary layer. Its thickness is dependent on linear velocity; the higher the velocity, the thinner the boundary layer. The region outside the boundary layer is characterized by substantial mixing or turbulence. For flow regimes characterized as laminar laminar /lam·i·nar/ (lam´i-nar) 1. pertaining to a lamina or laminae. 2. laminated. 3. of, pertaining to, or being a streamlined, smooth fluid flow. or minimally turbulent, the hydrodynamic boundary layer may substantially affect cell-substratum interactions. Cells behave as particles in a liquid, and the rate of settling and association with a submerged surface will depend largely on the velocity characteristics of the liquid. Under very low linear velocities, the cells must traverse the sizeable hydrodynamic boundary layer, and association with the surface will depend in large part on cell size and cell motility. As the velocity increases, the boundary layer decreases, and cells will be subjected to increasingly greater turbulence and mixing. Higher linear velocities would therefore be expected to equate to more rapid association with the surface, at least until velocities become high enough to exert substantial shear forces on the attaching cells, resulting in detachment of these cells (14) This finding has been confirmed in studies by Rijnaarts et al. (15) and Zheng et al. (16). Characteristics of the Aqueous Medium Other characteristics of the aqueous medium, such as pH, nutrient levels, ionic strength, and temperature, may play a role in the rate of microbial attachment to a substratum. Several studies have shown a seasonal effect on bacterial attachment and biofilm formation in different aqueous systems (17,18). This effect may be due to water temperature or to other unmeasured, seasonally affected parameters. Fletcher (19,20) found that an increase in the concentration of several cations (sodium, calcium, lanthanum lanthanum (lăn`thənəm) [Gr.,=to lie hidden], metallic chemical element; symbol La; at. no. 57; at. wt. 138.9055; m.p. about 920°C;; b.p. about 3,460°C;; sp. gr. 6.19 at 25°C;; valence +3. , ferric ferric (fĕr`ĭk), iron in the +3 valence state. See ferrous. iron) affected the attachment of Pseudornonas fluorescens to glass surfaces, presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. by reducing the repulsive forces between the negatively charged bacterial cells and the glass surfaces. Cowan et al. (21) showed in a laboratory study that an increase in nutrient concentration correlated with an increase in the number of attached bacterial cells. Properties of the Cell Cell surface hydrophobicity, presence of fimbriae and flagella flagella /fla·gel·la/ (flah-jel´ah) [L.] plural of flagellum. flagella (fl , and production of EPS all influence the rate and extent of attachment of microbial cells. The hydrophobicity of the cell surface is important in adhesion because hydrophobic interactions tend to increase with an increasing nonpolar nature of one or both surfaces involved (i.e., the microbial cell surface and the substratum surface). Most bacteria are negatively charged but still contain hydrophobic surface components, as noted by Rosenberg and Kjelleberg (22). Fimbriae, i.e., nonflagellar appendages other than those involved in transfer of viral or bacterial nucleic acids (called pili pili /pi·li/ (pi´li) [L.] plural of pilus. pili plural of pilus. pili torti ), contribute to cell surface hydrophobicity. Most fimbriae that have been examined contain a high proportion of hydrophobic amino acid residues (22). Fimbriae play a role in cell surface hydrophobicity and attachment, probably by overcoming the initial electrostatic repulsion repulsion /re·pul·sion/ (re-pul´shun) 1. the act of driving apart or away; a force that tends to drive two bodies apart. 2. barrier that exists between the cell and substratum (23). A number of aquatic bacteria possess fimbriae, which have also been shown to be involved in bacterial attachment to animal cells (23). Rosenburg et al. (24) and Bullitt and Makowski (25) provided evidence for the role of fimbriae in bacterial attachment to surfaces. Other cell surface properties may also facilitate attachment. Several studies have shown that treatment of adsorbed cells with proteolytic enzymes caused a marked release of attached bacteria (26,27), providing evidence for the role of proteins in attachment. Bendinger et al. (9) found that mycolic acid-containing organisms (Corynebacterium Corynebacterium /Co·ry·ne·bac·te·ri·um/ (-bak-ter´e-um) a genus of bacteria including C. ac´nes, a species present in acne lesions, C. diphthe´riae, the etiologic agent of diphtheria, C. , Nocardia, and Mycobacterium mycobacterium Any of the rod-shaped bacteria that make up the genus Mycobacterium. The two most important species cause tuberculosis and leprosy in humans; another species causes tuberculosis in both cattle and humans. ) were more hydrophobic than were nonmycolic acid-containing bacteria, and increase in mycolic acid chain length generally coincided with increase in hydrophobicity. For most strains tested, adhesion was greater on hydrophobic materials. The O antigen component of lipopolysaccharide lipopolysaccharide /lipo·poly·sac·cha·ride/ (-pol?e-sak´ah-rid) 1. a molecule in which lipids and polysaccharides are linked. 2. (LPS LPS - Sets with restricted universal quantifiers. ["Logic Programming with Sets", G. Kuper, J Computer Sys Sci 41:44-64 (1990)]. ) has also been shown to confer hydrophilic properties to gram-negative bacteria. Williams and Fletcher (28) showed that mutants of P. fluorescens lacking the O antigen adhered in greater numbers to hydrophobic materials. As early as 1971, Marshall et al. (29) provided evidence based on SEM that attached bacteria were associated with the surface via fine extracellular polymeric fibrils. Fletcher et al. (30) found that treatment of attached freshwater bacteria with cations resulted in contraction of the initial adhesives (decrease in the cell distance from the substratum), supporting the idea that this material was an anionic an·i·on n. A negatively charged ion, especially the ion that migrates to an anode in electrolysis. [From Greek, neuter present participle of anienai, to go up : ana-, ana- polymer. Cations have been shown to cross-link the anionic groups of polymers (such as polysaccharides), resulting in contraction. Beech and Gaylarde (31) found that lectins Lectins A class of proteins of nonimmune origin that bind carbohydrates reversibly and noncovalently without inducing any change in the carbohydrate. Lectins bind a variety of cells having cell-surface glycoproteins (carbohydrate bound proteins) or glycolipids inhibited but did not prevent attachment. Glucosidase and N-acetylglucosaminidase reduced attachment for P. fluorescens, while NAG reduced attachment for Desulfovibrio desulfuricans. Lectins preferentially bind to polysaccharides on the cell surface or to the EPS. Binding of lectins by the cells would minimize the attachment sites and affect cell attachment if polysaccharides were involved in attachment. Zottola (32) confirmed the role of polysaccharides in attachment in studies with Pseudomonas fragi. Korber et al. (33) used motile mo·tile adj. 1. Moving or having the power to move spontaneously. 2. Of or relating to mental imagery that arises primarily from sensations of bodily movement and position rather than from visual or auditory sensations. and nonmotile strains of P fluorescens to show that motile cells attach in greater numbers and attach against the flow (backgrowth) more rapidly than do nonmotile strains. Nonmotile strains also do not recolonize Re`col´o`nize v. t. 1. To colonize again. or seed vacant areas on a substratum as evenly as motile strains, resulting in slower biofilm formation by the nonmotile organisms. Flagella apparently play an important role in attachment in the early stages of bacterial attachment by overcoming the repulsive forces associated with the substratum. In light of these findings, cell surface structures such as fimbriae, other proteins, LPS, EPS, and flagella all clearly play an important role in the attachment process. Cell surface polymers with nonpolar sites such as fimbriae, other proteins, and components of certain gram-positive bacteria (mycolic acids) appear to dominate attachment to hydrophobic substrata, while EPS and lipopolysaccharides lipopolysaccharides (lip´ōpol´ēsak´  rādz´),n.pl a compound or complex of lipid and carbohydrate. are more important in attachment to hydrophilic materials. Flagella are important in attachment also, although their role may be to overcome repulsive forces rather than to act as adsorbents or adhesives. The attachment of microorganisms to surfaces is a very complex process, with many variables affecting the outcome. In general, attachment will occur most readily on surfaces that are rougher, more hydrophobic, and coated by surface "conditioning" films. An increase in flow velocity, water temperature, or nutrient concentration may also equate to increased attachment, if these factors do not exceed critical levels. Properties of the cell surface, specifically the presence of fimbriae, flagella, and surface-associated polysaccharides or proteins, also are important and may possibly provide a competitive advantage for one organism where a mixed community is involved. Table I summarizes the variables important in cell attachment and biofilm formation. Gene Regulation by Attached Cells Evidence is mounting that up--and down-regulation of a number of genes occurs in the attaching cells upon initial interaction with the substratum. Davies and Geesey (34) demonstrated algC up-regulation in individual bacterial cells within minutes of attachment to surfaces in a flow cell system. This phenomenon is not limited to P. aeruginosa. Prigent-Combaret et al. (35) found that 22% of these genes were up-regulated in the biofilm state, and 16% were down-regulated. Becker et al. (36) showed that biofilms of Staphylococcus aureus were upregulated for genes encoding enzymes involved in glycolysis glycolysis (glīkŏl`ĭsĭs), term given to the metabolic pathway utilized by most microorganisms (yeast and bacteria) and by all "higher" animals (including humans) for the degradation of glucose. or fermentation (phosphoglycerate mutase, triosephosphate isomerase, and alcohol dehydrogenase) and surmised that the up-regulation of these genes could be due to oxygen limitation in the developed biofilm, favoring fermentation. A recent study by Pulcini (37) also showed that algD, algU, rpoS, and genes controlling polyphosphokinase (PPK Noun 1. PPK - a Marxist-Leninist terrorist group of Kurds trying to establish an independent Kurdish state in eastern Turkey Kurdistan Labor Pary, Kurdistan Workers Party, Partiya Karkeran Kurdistan ) synthesis were up-regulated in biofilm formation of P aeruginosa. Prigent-Combaret et al. (35) opined that the expression of genes in biofilms is evidently modulated by the dynamic physicochemical factors external to the cell and may involve complex regulatory pathways. Biofilm Structure Extracellular Polymeric Substances Biofilms are composed primarily of microbial cells and EPS. EPS may account for 50% to 90% of the total organic carbon of biofilms (38) and can be considered the primary matrix material of the biofilm. EPS may vary in chemical and physical properties, but it is primarily composed of polysaccharides. Some of these polysaccharides are neutral or polyanionic, as is the case for the EPS of gram-negative bacteria. The presence of uronic acids (such as D-glucuronic, D-galacturonic, and mannuronic acids) or ketal-linked pryruvates confers the anionic property (39). This property is important because it allows association of divalent divalent /di·va·lent/ (di-va´lent) bivalent; carrying a valence of two. di·va·lent adj. Bivalent. di·va cations such as calcium and magnesium, which have been shown to cross-link with the polymer strands and provide greater binding force in a developed biofilm (38). In the case of some gram-positive bacteria, such as the staphylococci, the chemical composition of EPS may be quite different and may be primarily cationic cationic having qualities dependent on having free cations available. cationic detergents are wetting agents that disrupt or damage cell membranes, denature proteins and inactivate enzymes. . Hussain et al. (40) found that the slime of coagulase-negative bacteria consists of a teichoic acid mixed with small quantities of proteins. EPS is also highly hydrated hy·drat·ed adj. Chemically combined with water, especially existing in the form of a hydrate. Adj. 1. hydrated - containing combined water (especially water of crystallization as in a hydrate) hydrous because it can incorporate large amounts of water into its structure by hydrogen bonding. EPS may be hydrophobic, although most types of EPS are both hydrophilic and hydrophobic (39). EPS may also vary in its solubility. Sutherland (39) noted two important properties of EPS that may have a marked effect on the biofilm. First, the composition and structure of the polysaccharides determine their primary conformation. For example, many bacterial EPS possess backbone structures that contain 1,3- or 1,4-[beta]-linked hexose hexose /hex·ose/ (hek´sos) a monosaccharide containing six carbon atoms in a molecule. hex·ose n. residues and tend to be more rigid, less deformable, and in certain cases poorly soluble or insoluble. Other EPS molecules may be readily soluble in water. Second, the EPS of biofilms is not generally uniform but may vary spatially and temporally. Leriche et al. (41) used the binding specificity of lectins to simple sugars to evaluate bacterial biofilm development by different organisms. These researchers' results showed that different organisms produce differing amounts of EPS and that the amount of EPS increases with age of the biofilm. EPS may associate with metal ions, divalent cations, other macromolecules Macromolecules A large molecule composed of thousands of atoms. Mentioned in: Gene Therapy macromolecules (such as proteins, DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. , lipids, and even humic substances) (38). EPS production is known to be affected by nutrient status of the growth medium; excess available carbon and limitation of nitrogen, potassium, or phosphate promote EPS synthesis (39). Slow bacterial growth will also enhance EPS production (39). Because EPS is highly hydrated, it prevents desiccation des·ic·ca·tion n. The process of being desiccated. des  ic·ca in some natural biofilms. EPS
may also contribute to the antimicrobial resistance properties of
biofilms by impeding the mass transport of antibiotics through the
biofilm, probably by binding directly to these agents (42).Biofilm Architecture Tolker-Nielsen and Molin noted that every microbial biofilm community is unique (43) although some structural attributes can generally be considered universal. The term biofilm is in some ways a misnomer misnomer n. the wrong name. MISNOMER. The act of using a wrong name. 2. Misnomers, may be considered with regard to contracts, to devises and bequests, and to suits or actions. 3.-1. , since biofilms are not a continuous monolayer mon·o·lay·er n. 1. A film or layer one molecule thick formed at the interface between water and either oil or air by a substance such as a partially esterified fatty acid that contains both hydrophobic and hydrophilic groups in the same surface deposit. Rather, biofilms are very heterogeneous, containing microcolonies of bacterial cells encased en·case tr.v. en·cased, en·cas·ing, en·cas·es To enclose in or as if in a case. en·case ment n. in an EPS matrix and separated from other
microcolonies by interstitial voids (water channels) (44). Figure 3
shows a biofilm of P. aeruginosa, Klebsiella pneumoniae, and
Flavobacterium spp. that has developed on a steel surface in a
laboratory potable water system. This image clearly depicts the water
channels and heterogeneity characteristic of a mature biofilm. Liquid
flow occurs in these water channels, allowing diffusion of nutrients,
oxygen, and even antimicrobial agents. This concept of heterogeneity is
descriptive not only for mixed culture biofilms (such as might be found
in environmental biofilms) but also for pure culture biofilms common on
medical devices and those associated with infectious diseases. Stoodley
et al. (45) defined certain criteria or characteristics that could be
considered descriptive of biofilms in general, including a thin base
film, ranging from a patchy monolayer of cells to a film several layers
thick containing water channels. The organisms composing the biofilm may
also have a marked effect on the biofilm structure. For example, James
et al. (46) showed that biofilm thickness could be affected by the
number of component organisms. Pure cultures of either K. pneumoniae or
P. aeruginosa biofilms in a laboratory reactor were thinner (15 [micro]
and 30 [micro] respectively), whereas a biofilm containing both species
was thicker (40 [micro]). Jones et al. noted that this could be because
one species enhanced the stability of the other.[FIGURE 3 OMITTED] Biofilm architecture is heterogeneous both in space and time, constantly changing because of external and internal processes. Tolker-Nielsen et al. (47) investigated the role of cell motility in biofilm architecture in flow cells by examining the interactions of P. aeruginosa and P. putida by confocal laser scanning microscopy Confocal laser scanning microscopy (CLSM or LSCM) is a technique for obtaining high-resolution optical images.[1] The key feature of confocal microscopy is its ability to produce in-focus images of thick specimens, a process known as . When these two organisms were added to the flow cell system, each organism initially formed small microcolonies. With time, the colonies intermixed, showing the migration of cells from one microcolony to the other. The microcolony structure changed from a compact structure to a looser structure over time, and when this occurred the cells inside the microcolonies were observed to be motile. Motile cells ultimately dispersed from the biofilm, resulting in dissolution of the microcolony. Interaction of Particles Structure may also be influenced by the interaction of particles of nonmicrobial components from the host or environment. For example, erythrocytes Erythrocytes Red blood cells. Mentioned in: Bartonellosis erythrocytes (ē·rithˑ·rō·sīts), n.pl red blood cells. and fibrin fibrin: see blood clotting. may accumulate as the biofilm forms. Biofilms on native heart valves provide a clear example of this type of interaction in which bacterial microcolonies of the biofilm develop in a matrix of platelets, fibrin, and EPS (48). The fibrin capsule that develops will protect the organisms in these biofilms from the leukocytes of the host, leading to infective endocarditis. Biofilms on urinary catheters may contain organisms that have the ability to hydrolyze hydrolyze to performance hydrolysis. urea in the urine to form free ammonia through the action of urease urease /ure·ase/ (u´re-as) an enzyme that catalyzes the hydrolysis of urea to ammonia and carbon dioxide; it is a nickel protein of microorganisms and plants that is used in clinical assays of plasma urea concentrations. . The ammonia may then raise the pH at the biofilm-liquid interface, resulting in the precipitation of minerals such as calcium phosphate (hydroxyapatite hydroxyapatite /hy·droxy·ap·a·tite/ (-ap´ah-tit) an inorganic calcium-containing constituent of bone matrix and teeth, imparting rigidity to these structures. ) and magnesium ammonium phosphate (struvite) (49). These minerals can then become entrapped in the biofilm and cause encrustation en·crust·a·tion n. Variant of incrustation. Noun 1. encrustation - the formation of a crust incrustation of the catheter; cases have been described in which the catheter became completely blocked by this mineral build-up. Minerals such as calcium carbonate, corrosion products such as iron oxides, anal soil particles may often collect in biofilms of potable and industrial water systems, providing yet another example of particle interactions with biofilms (50). The Established Community: Biofilm Ecology The basic structural unit of the biofilm is the microcolony. Proximity of cells within the microcolony (or between microcolonies) (Figure 4A and B) provides an ideal environment for creation of nutrient gradients, exchange of genes, and quorum sensing. Since microcolonies may be composed of multiple species, the cycling of various nutrients (e.g., nitrogen, sulfur, and carbon) through redox redox (rē`dŏks): see oxidation and reduction. reactions can readily occur in aquatic and soil biofilms. [FIGURE 4A-4B OMITTED] Gene Transfer Biofilms also provide an ideal niche for the exchange of extrachromosomal DNA (plasmids). Conjugation conjugation, in genetics conjugation, in genetics: see recombination. conjugation, in grammar conjugation: see inflection. (the mechanism of plasmid transfer) occurs at a greater rate between cells in biofilms than between planktonic cells (51-53). Ghigo (54) has suggested that medically relevant strains of bacteria that contain conjugative plasmids more readily develop biofilms. He showed that the F conjugative pilus pilus /pi·lus/ (pi´lus) pl. pi´li [L.] 1. a hair.pi´lial 2. one of the minute filamentous appendages of certain bacteria, associated with antigenic properties of the cell surface. (encoded by the tra operon of the F plasmid) acts as an adhesion factor for both cell-surface and cell-cell interactions, resulting in a three-dimensional biofilm of Escherichia coli. Plasmid-carrying strains have also been shown to transfer plasmids to recipient organisms, resulting in biofilm formation; without plasmids these same organisms produce only microcolonies without any further development. The probable reason for enhanced conjugation is that the biofilm environment provides minimal shear and closer cell-to-cell contact. Since plasmids may encode for resistance to multiple antimicrobial agents, biofilm association also provides a mechanism for selecting for, and promoting the spread of, bacterial resistance to antimicrobial agents. Quorum Sensing Cell-to-cell signaling has recently been demonstrated to play a role in cell attachment and detachment from biofilms. Xie et al. (55) showed that certain dental plaque bacteria can modulate expression of the genes encoding fimbrial fimbrial pertaining to or emanating from fimbriae. fimbrial cysts cysts in the region of the ovulation fossa; appear to cause no impediment to fertility except in very old mares where they may obstruct ovulation. expression (fimA) in Porphyromonas gingivalis. P gingivalis would not attach to Streptococcus streptococcus (strĕp'təkŏk`əs), any of a group of gram-positive bacteria, genus Streptococcus, some of which cause disease. cristatis biofilms grown on glass slides. P gingivalis, on the other hand, readily attached to S. gordonii. S. cristatus cell-free extract substantially affected expression of fimA in P gingivalis, as determined by using a reporter system. S. cristatus is able to modulate P gingivalis fimA expression and prevent its attachment to the biofilm. Davies et al. (56) showed that two different cell-to-cell signaling systems in P. aeruginosa, lasR-lasI and rhlR-rhII, were involved in biofilm formation. At sufficient population densities, these signals reach concentrations required for activation of genes involved in biofilm differentiation. Mutants unable to produce both signals (double mutant) were able to produce a biofilm, but unlike the wild type, their biofilms were much thinner, cells were more densely packed, and the typical biofilm architecture was lacking. In addition, these mutant biofilms were much more easily removed from surfaces by a surfactant Surfactant Definition Surfactant is a complex naturally occurring substance made of six lipids (fats) and four proteins that is produced in the lungs. It can also be manufactured synthetically. treatment. Addition of homoserine lactone to the medium containing the mutant biofilms resulted in biofilms similar to the wild type with respect to structure and thickness. Stickler stick·ler n. 1. One who insists on something unyieldingly: a stickler for neatness. 2. Something puzzling or difficult. et al. (57) also detected acylated homoserine lactone signals homoserine lactone signals in biofilms of gram-negative bacteria on urethral urethral pertaining to or emanating from urethra. urethral agenesis, urethral atresia failure of development of all or part of the urethra: characterized by complete urine retention. A rare cause of neonatal uremia. catheters. Yung-Hua et al. (58) showed that induction of genetic competence (enabling the uptake and incorporation of exogenous DNA by transformation) is also mediated by quorum sensing in S. mutans. Transformational frequencies were 10-600 times higher in biofilms than planktonic cells. Predation and Competition Bacteria within biofilms may be subject to predation by free-living protozoa, Bdellovibrio spp., bacteriophage, and polymorphonuclear leukocytes (PMNs) as a result of localized cell concentration. Murga et al. (59) demonstrated the colonization and subsequent predation of heterotrophic heterotrophic /het·ero·tro·phic/ (-tro´fik) not self-sustaining; said of microorganisms requiring a reduced form of carbon for energy and synthesis. biofilms by Hartmannella vermiformis, a free-living protozoon protozoon pl. protozoa [Gr.] any member of the Protozoa. . Predation has also been demonstrated with Acanthamoeba Acanthamoeba /Acan·tha·moe·ba/ (ah-kan?thah-me´bah) a genus of free-living ameboid protozoa (order Amoebida) found usually in fresh water or moist soil. Certain species, such as A. astronyxis, A. castellanii, A. culbertsoni, A. spp. in contact lens storage case biofilms (60). James et al. (46) noted that competition also occurs within biofilms and demonstrated that invasion of a Hyphomicrobium sp. biofilm by P. putida resulted in dominance by the P. putida, even though the biofilm-associated Hyphomicrobium numbers remained relatively constant. Stewart et al. (61) investigated biofilms containing K. pneumoniae and R aeruginosa and found that both species are able to coexist in a stable community even though P. aeruginosa growth rates are much slower in the mixed culture biofilm than when grown as a pure culture biofilm. P. aeruginosa grow primarily as a base biofilm, whereas K. pneumoniae form localized microcolonies (covering only about 10% of the area) that may have greater access to nutrients and oxygen. Apparently R aeruginosa can compete because it colonizes the surface rapidly and establishes a long-term competitive advantage. K. pneumoniae apparently survives because of its ability to attach to the P. aeruginosa biofilm, grow more rapidly, and out-compete the R aeruginosa in the surface layers of the biofilm. Interactions of Pathogenic Organisms Several frank bacterial pathogens have been shown to associate with, and in some cases, actually grow in biofilms, including Legionella pneumophila (59), S. aureus The aureus (pl. aurei) was a gold coin of ancient Rome valued at 25 silver denarii. The aureus was regularly issued from the 1st century BC to the beginning of the 4th century AD, when it was replaced by the solidus. (62), Listeria Listeria /Lis·te·ria/ (lis-ter´e-ah) a genus of gram-negative bacteria (family Corynebacterium); L. monocyto´genes causes listeriosis. Lis·te·ri·a n. monocytogenes (63), Campylobacter Campylobacter Genus of gram-negative spiral-shaped bacteria infecting mammals. Many species, especially C. fetus, cause miscarriage in sheep and cattle. C. jejuni is a common cause of food poisoning. Sources include meats (particularly chicken) and unpasteurized milk. spp. (64), E. coli 0157:H7 (65), Salmonella typhimurium (66), Vibrio cholerae (67), and Helicobacter pylori (68). Although all these organisms have the ability to attach to surfaces and existing biofilms, most if not all appear incapable of extensive growth in the biofilm. This may be because of their fastidious fas·tid·i·ous adj. 1. Possessing or displaying careful, meticulous attention to detail. 2. Difficult to please; exacting. 3. Having complex nutritional requirements. Used of microorganisms. growth requirements or because of their inability to compete with indigenous organisms. The mechanism of interaction and growth apparently varies with the pathogen, and at least for L. pneumophila, appears to require the presence of free-living protozoa to grow in the biofilm (59). Survival and growth of pathogenic organisms within biofilms might also be enhanced by the association and metabolic interactions with indigenous organisms. Camper et al. (65) showed that Salmonella typhimurium persisted in a model distribution system containing undefined heterotrophic bacteria from an unfiltered Please wikify (format) this article or section as suggested in the Guide to layout and the Manual of Style. Remove this template after wikifying. This article has been tagged since reverse osmosis water system for >50 days, which suggests that the normal biofilm flora of this water system provided niche conditions capable of supporting the growth of this organism. The picture of biofilms increasingly is one in which there is both heterogeneity and a constant flux, as this biological community adapts to changing environmental conditions and the composition of the community. Dispersal Biofilm cells may be dispersed either by shedding of daughter cells from actively growing cells, detachment as a result of nutrient levels or quorum sensing, or shearing of biofilm aggregates (continuous removal of small portions of the biofilm) because of flow effects. The mechanisms underlying the process of shedding by actively growing cells in a biofilm are not well understood. Gilbert et al. (69) showed that surface hydrophobicity characteristics of newly divided daughter cells spontaneously dispersed from either E. coli or P. aeruginosa biofilms differ substantially from those of either chemostat-intact biofilms or resuspended biofilm cells. These researchers suggested that these differences might explain newly divided daughter cells' detachment. Hydrophobicity was lowest for the newly dispersed cells and steadily increases upon continued incubation and growth. Alginate alginate /al·gi·nate/ (al´ji-nat) a salt of alginic acid; water-soluble alginates are useful as materials for dental impressions. is the major component of the EPS of P aeruginosa. Boyd and Chakrabarty (70) studied alginate lyase lyase /ly·ase/ (li´as) any of a class of enzymes that remove groups from their substrates (other than by hydrolysis or oxidation), leaving double bonds, or that conversely add groups to double bonds. production in P aeruginosa to determine whether increased expression of this enzyme affected the size of the alginate molecules (and therefore adhesion of the organisms). Inducing alginate lyase expression substantially decreased the amount of alginate produced, which corresponded with a significant increase in the number of detached cells. The authors suggested that the role of algL (the gene cassette for alginate lyase production) in wild type P. aeruginosa may be to cause a release of cells from solid surfaces or biofilms, aiding in the dispersal of these organisms. Polysaccharidase enzymes specific for the EPS of different organisms may possibly be produced during different phases of biofilm growth of these organisms. Detachment caused by physical forces has been studied in greater detail. Brading et al. (71) have emphasized the importance of physical forces in detachment, stating that the three main processes for detachment are erosion or shearing (continuous removal of small portions of the biofilm), sloughing (rapid and massive removal), and abrasion (detachment due to collision of particles from the bulk fluid with the biofilm). Characklis (72) noted that the rate of erosion from the biofilm increases with increase in biofilm thickness and fluid shear at the biofilm-bulk liquid interface. With increase in flow velocity, the hydrodynamic boundary layer decreases, resulting in mixing and turbulence closer to the biofilm surface. Sloughing is more random than erosion and is thought to result from nutrient or oxygen depletion within the biofilm structure (71). Sloughing is more commonly observed with thicker biofilms that have developed in nutrient-rich environments (72). Biofilms in fluidized beds, filters, and particle-laden environments (surface waters) may be subject to abrasion. Detachment is probably also species specific; P. fluorescens disperses and recolonizes a surface (in a flow cell) after approximately 5 h, V. parahaemolyticus after 4 h, and V. harveyi after only 2 h (73). This process probably provides a mechanism for cells to migrate from heavily colonized Colonized This occurs when a microorganism is found on or in a person without causing a disease. Mentioned in: Isolation areas that have been depleted of surface-adsorbed nutrients to areas more supportive of growth. The mode of dispersal apparently affects the phenotypic characteristics of the organisms. Eroded or sloughed aggregates from the biofilm are likely to retain certain biofilm characteristics, such as antimicrobial resistance properties, whereas cells that have been shed as a result of growth may revert quickly to the planktonic phenotype. A Public Health Perspective Clinical and public health microbiologists' recognition that microbial biofilms are ubiquitous in nature has resulted in the study of a number of infectious disease processes from a biofilm perspective. Cystic fibrosis, native valve endocarditis endocarditis (ĕn'dōkärdī`tĭs), bacterial or fungal infection of the endocardium (inner lining of the heart) that can be either acute or subacute. , otitis media, periodontitis periodontitis Inflammation of soft tissues around the teeth (see tooth). Poor dental hygiene leads to deposition of bacterial plaque on the teeth below the gum line, irritating and eroding nearby tissues. , and chronic prostatitis all appear to be caused by biofilm-associated microorganisms. A spectrum of indwelling medical devices or other devices used in the healthcare environment have been shown to harbor biofilms, resulting in measurable rates of device-associated infections (74). Table 2 provides a listing of microorganisms commonly associated with biofilms on indwelling medical devices. Biofilms of potable water distribution systems have the potential to harbor enteric enteric /en·ter·ic/ (en-ter´ik) within or pertaining to the small intestine. en·ter·ic adj. 1. Of, relating to, or within the intestine. 2. pathogens, L. pneumophila, nontuberculous mycobacteria, and possibly Helicobacter pylori. What is less clear is an understanding of how interaction and growth of pathogenic organisms in a biofilm result in an infectious disease process. Characteristics of biofilms that can be important in infectious disease processes include a) detachment of cells or biofilm aggregates may result in bloodstream or urinary tract infections or in the production of emboli emboli /em·bo·li/ (em´bo-li) plural of embolus. Emboli Plural of embolus. An embolus is something that blocks the blood flow in a blood vessel. , b) cells may exchange resistance plasmids within biofilms, c) cells in biofilms have dramatically reduced susceptibility to antimicrobial agents, d) biofilm-associated gram-negative bacteria may produce endotoxins, and e) biofilms are resistant to host immune system clearance. Please refer to the online appendix for an expanded discussion of each of these mechanisms (URL URL in full Uniform Resource Locator Address of a resource on the Internet. The resource can be any type of file stored on a server, such as a Web page, a text file, a graphics file, or an application program. : http://www.cdc.gov/ncid/eid/vol8/no9donlan.htm). A Prospectus for Future Research Research on microbial biofilms is proceeding on many fronts, with particular emphasis on elucidation of the genes specifically expressed by biofilm-associated organisms, evaluation of various control strategies (including medical devices treated with antimicrobial agents and antimicrobial locks) for either preventing or remediating biofilm colonization of medical devices, and development of new methods for assessing the efficacy of these treatments. Research should also focus on the role of biofilms in antimicrobial resistance, biofilms as a reservoir for pathogenic organisms, and the role of biofilms in chronic diseases. The field of microbiology has come to accept the universality of the biofilm phenotype. Researchers in the fields of clinical, food and water, and environmental microbiology have begun to investigate microbiologic processes from a biofilm perspective. As the pharmaceutical and health-care industries embrace this approach, novel strategies for biofilm prevention and control will undoubtedly emerge. The key to success may hinge upon a more complete understanding of what makes the biofilm phenotype so different from the planktonic phenotype. Dr. Donlan is the team leader for the Biofilm Laboratory in the Division of Healthcare Quality Promotion at the Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. . His research interests include the study of biofilms on indwelling medical devices, biofilms and antimicrobial resistance, and interaction of pathogens with potable water biofilms.
Table 1. Variables important in cell attachment and biofilm formation
Properties of the Properties of the Properties of the cell
substratum bulk fluid
Texture or roughness Flow velocity Cell surface
hydrophobicity
Hydrophobicity pH Fimbriae
Conditioning film Temperature Flagella
Cations Extracellular polymeric
substances
Presence of
antimicrobial
agents
Table 2. Microorganisms commonly associated with biofilms on
indwelling medical devices
Microorganism Has been isolated from biofilms on
Candida albicans Artifical voice prosthesis
Central venous catheter
Intrauterine device
Coagulase-negative Artificial hip prosthesis
staphylococci Artificial voice prosthesis
Central venous catheter
Intrauterine device
Prosthetic heart valve
Urinary catheter
Enterococcus spp. Artificial hip prosthesis
Central venous catheter
Intrauterine device
Prosthetic heart valve
Urinary catheter
Klebsiella pneumoniae Central venous catheter
Urinary catheter
Pseudomonas aeruginosa Artificial hip prosthesis
Central venous catheter
Urinary catheter
Staphylococcus aureus Artificial hip prosthesis
Central venous catheter
Intrauterine device
Prosthetic heart valve
Rodney M. Donlan, Centers for Disease Control and Prevention, Atlanta, Georgia, USA References (1.) Heukelekian H, Heller A. Relation between food concentration and surface for bacterial growth. J Bacteriol 1940;40:547-58. (2.) Zobell CE. The effect of solid surfaces on bacterial activity. J Bacteriol 1943 ;46:39-56. (3.) Jones HC, Roth IL, Saunders WM III. Electron microscopic study of a slime layer. J Bacteriol 1969;99:316-25. (4.) Characklis WG. Attached microbial growths-II. Frictional resistance due to microbial slimes. Water Res 1973;7:1249-58. (5.) Costerton JW, Geesey GG, Cheng K-J. How bacteria stick. Sci Am 1978;238:86-95. (6.) Characklis WG, McFeters GA, Marshall KC. Physiological ecology in biofilm systems. In: Characklis WG, Marshall KC, editors. Biofilms. New York: John Wiley & Sons; 1990. p. 341-94. (7.) Fletcher M, Loeb GI. Influence of substratum characteristics on the attachment of a marine pseudomonad pseudomonad Any of a large and varied group of rod-shaped, often curved bacteria. Many can move, propelled by one or more flagella. Some aquatic species are attached to surfaces by long strands or stalks. to solid surfaces. Appl Environ Microbiol 1979;37:67-72. (8.) Pringle JH, Fletcher M. Influence of substratum wettability on attachment of freshwater bacteria to solid surfaces. Appl Environ Microbiol 1983;45:811-17. (9.) Bendinger B, Rijnaarts HHM HHM Humoral Hypercalcemia of Malignancy HHM Hierarchical Holographic Modeling HHM Heart Health Monitor HHM Hand Held Module HHM Human Head Modeling HHM HDL Hierarchy Manager (Prime Technology) , Altendorf K, Zehnder AJB AJB America’s Job Bank AJB African Journal of Biotechnology AJB Amt für Jugend und Berufsberatung (German: office for youth and vocational guidance) AJB American Journal of Botany AJB Australian Journal of Botany . Physicochemicai cell surface and adhesive properties of coryneform coryneform /co·ry·ne·form/ (-form) denoting or resembling organisms of the family Corynebacteriaceae. coryneform denoting or resembling organisms of the family Corynebacteriaceae. See also diphtheroid. bacteria related to the presence and chain length of mycolic acids. Appl Environ Microbiol 1993;59:3973-77. (10.) Loeb GI, Neihof RA. Marine conditioning films. Advances in Chemistry 1975;145:319-35. (11.) Marsh PD. Dental plaque. In: Lappin-Scott HM, Costerton JW, editors. Microbial biofilms. Cambridge: Cambridge University Press Cambridge University Press (known colloquially as CUP) is a publisher given a Royal Charter by Henry VIII in 1534, and one of the two privileged presses (the other being Oxford University Press). ; 1995. p. 282-300. (12.) Mittelman MW. Adhesion to biomaterials. In: Fletcher M, editor. Bacterial adhesion: molecular and ecological diversity. New York: Wiley-Liss, Inc.; 1996. p. 89-127. (13.) Ofek I, Doyle RJ. Bacterial adhesion to cells and tissues. In: Ofek I, Doyle RJ, editors. New York: Chapman & Hall; 1994. (14.) Characklis WG. Microbial fouling. In: Characklis WG, Marshall KC, editors. Biofilms. New York: John Wiley & Sons; 1990. p. 523-84. (15.) Rijnaarts HH, Norde W, Bouwer EJ, Lyklema J, Zehnder. Bacterial adhesion under static and dynamic conditions. Appl Environ Microbiol 1993;59:3255-65. (16.) Zheng D, Taylor GA, Gyananath G. Influence of laminar flow velocity and nutrient concentration on attachment of marine bacterioplankton. Biofouling bi·o·foul·ing n. The impairment or degradation of something, such as a ship's hull or mechanical equipment, as a result of the growth or activity of living organisms. 1994;8:107-20. (17.) Donlan RM, Pipes WO, Yohe TL. Biofilm formation on cast iron substrata in water distribution systems. Water Res 1994;28:1497-1503. (18.) Fera P, Siebel MA, Characklis WG, Prieur D. Seasonal variations in bacterial colonization of stainless steel, aluminum, and polycarbonate surfaces in a seawater flow system. Biofouling 1989;1:251-61. (19.) Fletcher M. The applications of interference reflection microscopy to the study of bacterial adhesion to solid surfaces. In: Houghton DR, Smith RN, Eggins HOW, editors. Biodeterioration 7. London: Elsevier Applied Science; 1988. p. 31-5. (20.) Fletcher M. Attachment of Pseudomonas fluorescens to glass and influence of electrolytes on bacterium-substratum separation distance. J Bacteriol 1988; 170:2027-30. (21.) Cowan MM, Warren TM, Fletcher M. Mixed species colonization of solid surfaces in laboratory biofilms. Biofouling 1991;3:23-34. (22.) Rosenberg M, Kjelleberg S. Hydrophobic interactions in bacterial adhesion. Advances in Microbial Ecology 1986;9:353-93. (23.) Corpe WA. Microbial surface components involved in adsorption adsorption, adhesion of the molecules of liquids, gases, and dissolved substances to the surfaces of solids, as opposed to absorption, in which the molecules actually enter the absorbing medium (see adhesion and cohesion). of microorganisms onto surfaces. In: Bitton G, Marshall KC, editors. Adsorption of microorganisms to surfaces. New York: John Wiley & Sons; 1980. p. 105-44. (24.) Rosenberg M, Bayer EA, Delarea J, Rosenberg E. Role of thin fimbriae in adherence and growth of Acinetobacter calcoaceticus RAG-I on hexadecane. Appl Environ Microbiol 1982;44:929-37. (25.) Bullitt R, Makowski L. Structural polymorphism of bacterial adhesion pili. Nature 1995;373:164-7. (26.) Bashan Y, Levanony H. Active attachment of Azospirillum brasilense Cd to quartz sand and to a light-textured soil by protein bridging. J Gen Microbiol 1988;134:2269-79. (27.) Danielsson A, Norkrans B, Bjornsson A. On bacterial adhesion--the effect of certain enzymes on adhered cells in a marine Pseudomonas Pseudomonas A genus of gram-negative, nonsporeforming, rod-shaped bacteria. Motile species possess polar flagella. They are strictly aerobic, but some members do respire anaerobically in the presence of nitrate. sp. Bot Marina 1977;20:13-7. (28.) Williams V, Fletcher M. Pseudomonas fluorescens adhesion and transport through porous media are affected by lipopolysaccharide composition. Appl Environ Microbiol 1996;62:1004. (29.) Marshall KC, Stout R, Mitchell R. Mechanisms of the initial events in the sorption sorption /sorp·tion/ (sorp´shun) the process or state of being sorbed; absorption or adsorption. sorp·tion n. Adsorption or absorption. of marine bacteria to surfaces. J Gen Microbiol 1971 ;68:337-48. (30.) Fletcher M, Lessman JM, Loeb GI. Bacterial surface adhesives and biofilm matrix polymers of marine and freshwater bacteria. Biofouling 1991;4:129-40. (31.) Beech IB, Gaylarde CC. Adhesion of Desulfovibrio desulfuricans and Pseudomonas fluorescens to mild steel surfaces. J Appl Bacteriol 1989;67:2017. (32.) Zottola EA. Characterization of the attachment matrix of Pseudomonas fragi attached to non-porous surfaces. Biofouling 1991 ;5:37-55. (33.) Korber DR, Lawrence JR, Sutton B, Caldwell DE. Effect of laminar flow velocity on the kinetics of surface recolonization Re`col`o`ni`za´tion n. 1. A second or renewed colonization. by [Mot.sup.+] and [Mot.sup-] Pseudomonas fluorescens. Microb Ecol 1989; 18:1-19. (34.) Davies DG, Geesey GG. Regulation of the alginate biosynthesis Biosynthesis The synthesis of more complex molecules from simpler ones in cells by a series of reactions mediated by enzymes. The overall economy and survival of the cell is governed by the interplay between the energy gained from the breakdown of compounds gene algC in Pseudornonas aeruginosa during biofilm development in continuous culture. Appl Environ Microbiol 1995;61:860-7. (35.) Prigent-Combaret C, Vidal O, Dorel C, Lejeune P. Abiotic a·bi·ot·ic adj. Nonliving: The abiotic factors of the environment include light, temperature, and atmospheric gases. a surface sensing and biofilm-dependent regulation of gene expression Gene modulation redirects here. For information on therapeutic regulation of gene expression, see therapeutic gene modulation.
. in Escherichia coli. J Bacteriol 1999; l 81:5993-6002. (36.) Becker P, Hufnagle W, Peters G, Herrmann M. Detection of different gene expression in biofilm-forming versus planktonic populations of Staphylococcus aureus using micro-representational-difference analysis. Appl Environ Microbiol 2001 ;67:2958-65. (37.) Pulcini E. The effects of initial adhesion events on the physiology of Pseudomonas aeruginosa [Ph.D. dissertation]. Bozeman (MT): Montana State University Montana State University, at Bozeman; land-grant; coeducational; chartered 1893. It is primarily a technical institution specializing in agriculture, engineering, and applied sciences. The Museum of the Rockies is there. ; 2001. (38.) Flemming H-C, Wingender J, Griegbe, Mayer C. Physico-chemical properties of biofilms. In: Evans LV, editor. Biofilms: recent advances in their study and control. Amsterdam: Harwood Academic Publishers; 2000. p. 19-34. (39.) Sutherland 1W. Biofilm exopolysaccharides: a strong and sticky framework. Microbiology 2001; 147:3-9. (40.) Hussain M, Wilcox MH, White PJ. The slime of coagulase-negative staphylococci: biochemistry and relation to adherence. FEMS Microbiol Rev 1993;104:191-208. (41.) Leriche V, Sibille P, Carpentier B. Use of an enzyme-linked lectinsorbent assay to monitor the shift in polysaccharide composition in bacterial biofilms. Appl Environ Microbiol 2000;66:1851-6. (42.) Donlan RM. Role of biofilms in antimicrobial resistance. ASAIO ASAIO American Society for Artificial Internal Organs J 2000;46;S47-S52. (43.) Tolker-Nielsen T, Molin S. Spatial organization of microbial biofilm communities. Microb Eco12000;40:75-84. (44.) Lewandowski Z. Structure and function of biofilms. In: Evans LV, editor. Biofilms: recent advances in their study and control. Amsterdam: Harwood Academic Publishers; 2000. p. 1-17. (45.) Stoodley P, Boyle JD, Dodds I, Lappin-Scott HM. Consensus model of biofilm structure, In: Wimpenny JWT JWT J. Walter Thompson (agency) JWT Java Windows Terminal JWT Just War Theory JWT Jim Wolf Technology JWT Java Workflow Tooling JWT John Wayne Trail (US Army Yakima Training Center) JWT Justified War Theory , Gilbert PS, Lappin-Scott HM, Jones M, editors. Biofilms: community interactions and control. Cardiff, UK: Bioline; 1997. p. 1-9. (46.) James GA, Beaudette L, Costerton JW. Interspecies bacterial interactions in biofilms. Journal of Industrial Microbiology 1995; 15:257-62. (47.) Tolker-Nielsen T, Brinch UC, Ragas PC, Andersen JB, Jacobsen CS, Molin S. Development and dynamics of Pseudomonas sp. biofilms. J Bacteriol 2000; 182:6482-9. (48.) Durack DT. Experimental bacterial endocarditis. IV Structure and evolution of very early lesions. J Pathol 1975; 115:81-9. (49.) Tunney MM, Jones DS, Gorman SP. Biofilm and biofilm-related encrustations of urinary tract devices. In: Doyle R J, editor. Methods in enzymology Methods in Enzymology is a series of scientific publications on the topics of biochemistry by the Academic Press, now part of Elsevier. Each volume is centered on a specific topic of biochemistry, such as DNA repair, yeast genetics, or biology of the nitric oxide. , vol. 310. Biofilms. San Diego: Academic Press; 1999. p. 558-66. (50.) Donlan RM. Biofilm control in industrial water systems: approaching an old problem in new ways. In: Evans LV, editor. Biofilms: recent advances in their study and control. Amsterdam: Harwood Academic Publishers; 2000. p. 333-60. (51.) Ehlers LJ, Bouwer EJ. RP4 plasmid transfer among species of Pseudomonas in a biofilm reactor. Water Sci Technol 1999;7:163-171. (52.) Roberts AP, Pratten J, Wilson M, Mullany P. Transfer of a conjugative transposon transposon /trans·po·son/ (trans-po´zon) a small mobile genetic (DNA) element that moves around the genome or to other genomes within the same cell, usually by copying itself to a second site but sometimes by splicing itself out of its , Tn5397 in a model oral biofilm. FEMS Microbiol Lett 1999; 177:636. (53.) Hausner M, Wuertz S. High rates of conjugation in bacterial biofilms as determined by quantitative in situ analysis. Appl Environ Microbiol 1999;65:3710-13. (54.) Ghigo J-M J-M Jelinski-Moranda (reliability model) . Natural conjugative plasmids induce bacterial biofilm development. Nature 2001 ;412:442-5. (55.) Xie H, Cook GS, Costerton JW, Bruce G, Rose TM, Lamont RJ. Intergeneric communication in dental plaque biofilms. J Bacteriol 2000; 182:7067-9. (56.) Davies DG, Parsek MR, Pearson JP, Iglewski BH, Costerton JW, Greenberg EP. The involvement of cell-to-cell signals in the development of a bacterial biofilm. Science 1998;280:295-8. (57.) Stickler DJ, Morris NS, McLean RJC RJC Republican Jewish Coalition RJC Rosthern Junior College (Canada) RJC Raffles Junior College (Singapore) RJC Regional Justice Center RJC Rutland Jewish Center , Fuqua C. Biofilms on indwelling urethral catheters produce quorum-sensing signal molecules in situ and in vitro. Appl Environ Microbiol 1998;64:3486-90. (58.) Yung-Hua L, Lau PCY PCY Per Calendar Year PCY Powel Crosley, Jr. YMCA (Cincinnati, Ohio) PCY Pounds per Cubic Yard PCY Paradise Canyon Elementary School (La Canada, CA) PCY Pittsburgh, Chartiers, & Youghiogheny Railway Company , Lee JH, Ellen RP, Cvitkovitch DG. Natural genetic transformation of Streptococcus mutans growing in biofilms. J Bacteriol 2001;183:897-908. (59.) Murga R, Forster TS, Brown E, Pruckler JM, Fields BS, Donlan RM. The role of biofilms in the survival of Legionella pneumophila in a model potable water system. Microbiology 2001; 147:3121-6. (60.) McLaughlin-Borlace L, Stapleton F, Matheson M, Dart JKG JKG Jonkoping, Sweden - Axamo (Airport Code) . Bacterial biofilm on contact lenses and lens storage cases in wearers with microbial keratitis keratitis Inflammation of the cornea (see eye). The conjunctiva may also be inflamed (keratoconjunctivitis). Depending on the cause, including dryness of the eye (from low tear production or inability to close the eye), chemical or physical injury, or certain . J Appl Microbiol 1998;84:827-38. (61.) Stewart PS, Camper AK, Handran SD, Huang C-T C-T Cretaceous-Tertiary (geologic boundary; also K-T, CT) , Warnecke M. Spatial distribution and coexistence of Klebsiella pneumoniae and Pseudomonas aeruginosa in biofilms. Microb Ecol 1997;33:2-10. (62.) Raad II, Sabbagh MF, Rand KH, Sherertz RJ. Quantitative tip culture methods and the diagnosis of central venous catheter-related infections. Diagn Microbiol Infect Dis 1992; 15:13-20. (63.) Wirtanen G, Alanko T, Mattila-Sandholm T. Evaluation of epifluorescence image analysis of biofilm growth on stainless steel surfaces. Colloids and Surfaces B: Biointerfaces 1996;5:319-26. (64.) Buswell CM, Herlihy YM, Lawrence LM, McGuiggan JTM JTM Je T'aime (French: I Love You) JTM Job Transfer & Manipulation JTM Joint Technical Manual JTM Jackass the Movie (movie) JTM Jack T. , Marsh PD, Keevil CW, et al. Extended survival and persistence of Campylobacter spp. in water and aquatic biofilms and their detection by immunofluorescent-antibody and -rRNA staining. Appl Environ Microbiol 1998;64:733-41. (65.) Camper AK, Wamecke M, Jones WL, McFeters GA. Pathogens in model distribution system biofilms. Denver: American Water Works Association American Water Works Association (AWWA) is an international nonprofit professional organization dedicated to the improvement of drinking water quality and supply. It was founded in 1881 and, as of 2007, there are approximately 60,000 AWWA members world-wide. Research Foundation; 1998. (66.) Hood SK, Zottola EA. Adherence to stainless steel by foodborne microorganisms during growth in model food systems. Int J Food Microbiol 1997;37:145-53. (67.) Watnick PI, Kolter R. Steps in the development of a Vibrio cholerae E1 Tot biofilm. Mol Microbiol 1999;34:586-95. (68.) Stark RM, Gerwig G J, Pitman RS, Potts LF, Williams NA, Greenman J, et al. Biofilm formation by Helicobacter pylori. Lett Appl Microbiol 1999;28:121-6. (69.) Gilbert P, Evans DJ, Brown MRW (Mount Rainier ReWritable) See Mount Rainier. . Formation and dispersal of bacterial biofilms in vivo and in situ. J Appl Bacteriol Symposium Supplement 1993;74:67S-78S. (70.) Boyd A, Chakrabarty AM. Role of alginate lyase in cell detachment of Pseudomonas aeruginosa. Appl Environ Microbiol 1994;60:2355-9. (71.) Brading MG, Jass J, Lappin-Scott HM. Dynamics of bacterial biofilm formation. In: Lappin-Scott HM, Costerton JW, editors. Microbial biofilms. Cambridge: Cambridge University Press; 1995. p. 46-63. (72.) Characklis WG. Biofilm processes. In: Characklis WG, Marshall KC, editors. Biofilms. New York: John Wiley & Sons; 1990. p. 195-231. (73.) Korber DR, Lawrence JR, Lappin-Scott HM, Costerton JW. Growth of microorganisms on surfaces. In: Lappin-Scott HM, Costerton JW, editors. Microbial biofilms. Cambridge: Cambridge University Press; 1995. p. 15-45. (74.) Donlan RM. Biofilms and device-associated infections. Emerg Infect Dis 2001 ;7:277-81. If he dared, a philosopher dreaming before a water painting by Monet would develop the dialectics of the iris and water lily, the dialectics of the straight leaf and the leaf that is calmly, peacefully, heavily lying on the water's surface. This is the very dialectic of the aquatic plant. Reacting to some kind of spirit of revolt, the one wants to spring up against its native element. The other is loyal to its element. The water lily has understood the lesson of calm taught by still waters. With such a dialectical dream, one might feel the soft, extremely delicate verticality that can be seen in the life of still waters. But the painter feels all that instinctively and knows how to find in the reflections a sure principle that makes up, vertically, the peaceful world of water. --Gaston Bachelard (1884-1962), French philosopher, about the work of painter Claude Monet Address for correspondence: Rodney M. Donlan, Biofilm Laboratory, Division of Healthcare Quality Promotion, National Center for Infectious Diseases, Centers for Disease Control and Prevention, Mailstop C16, 1600 Clifton Road, N.E., Atlanta, GA 30333, USA; fax: 404-639-3822; e-mail: rld8@cdc.gov |
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