Local macromolecule diffusion coefficients in structurally non-uniform bacterial biofilms using fluorescence recovery after photobleaching (FRAP).

Pure culture Pseudomonas putida biofilms were cultivated under controlled conditions to a desired overall biofilm thickness, then employed within classical half-cell diffusion chambers to estimate, from transient solute concentrations, the effective diffusion coefficient for several macromolecules of increasing molecular weight and molecular complexity. Results of traditional half-cell studies were found to be erroneous due to the existence of microscopic water channels or crevasses that perforate the polysaccharidic gel matrix of the biofilm, sometimes completely to the supporting substratum. Thus, half-cell devices measure a composite transfer coefficient that may overestimate the true, local flux of solutes in the biofilm polysaccharide gel matrix. An alternative analytical technique was refined to determine the local diffusion coefficients on a micro-scale to avoid the errors created by the biofilm architectural irregularities. This technique is based upon the Fluorescence Return After Photobleaching (FRAP), which allows image analysis observation of the transport of fluorescently labeled macromolecules as they migrate into a micro-scale photobleached zone. The technique can be computerized and allows one to map the local diffusion coefficients of various solute molecules at different horizontal planes and depths in a biofilm. These mappings also indirectly indicate the distribution of water channels in the biofilm, which was corroborated independently by direct microscopic observation of the settling of fluorescently-labeled latex spheres within the biofilm. Fluorescence return after photobleaching results indicate a significant reduction in the solute transport coefficients in biofilm polymer gel vs. the same value in water, with the reduction being dependent on solute molecule size and shape.

[1]  P. Stewart,et al.  A review of experimental measurements of effective diffusive permeabilities and effective diffusion coefficients in biofilms , 1998, Biotechnology and bioengineering.

[2]  R. Ramphal,et al.  The binding of anti-pseudomonal antibiotics to macromolecules from cystic fibrosis sputum. , 1988, The Journal of antimicrobial chemotherapy.

[3]  P. Wahl,et al.  Study of the translational diffusion of macromolecules in beads of gel chromatography by the FRAP method. , 1988, Biophysical chemistry.

[4]  Robert I. Cukier,et al.  Diffusion of Brownian spheres in semidilute polymer solutions , 1984 .

[5]  F. Ruiz-Beviá,et al.  Diffusivity measurement in calcium alginate gel by holographic interferometry , 1989 .

[6]  W. G. Characklis Bioengineering report: Fouling biofilm development: A process analysis , 1981 .

[7]  D. Allison,et al.  Resistance of bacterial biofilms to antibiotics: a growth-rate related effect? , 1988, The Journal of antimicrobial chemotherapy.

[8]  W. G. Characklis,et al.  Transport of 1‐μm latex particles in pseudomonas aeruginosa biofilms , 1993 .

[9]  S. Edwards,et al.  The Theory of Polymer Dynamics , 1986 .

[10]  Charles S. Johnson,et al.  Probe Diffusion in Polyacrylamide Gels as Observed by Means of Holographic Relaxation Methods: Search for a Universal Equation , 1990 .

[11]  Lee Sp A potential mechanism of action of colloidal bismuth subcitrate: diffusion barrier to hydrochloric acid. , 1982 .

[12]  U. Rother,et al.  Interaction of complement components with a serum-resistant strain of Salmonella typhimurium , 1975, Infection and immunity.

[13]  Nichols,et al.  Inhibition of tobramycin diffusion by binding to alginate , 1988, Antimicrobial Agents and Chemotherapy.

[14]  N. Hodges,et al.  Antibiotic interaction and diffusion through alginate and exopolysaccharide of cystic fibrosis-derived Pseudomonas aeruginosa. , 1988, The Journal of antimicrobial chemotherapy.

[15]  J. Fyfe,et al.  The instability of mucoid Pseudomonas aeruginosa: fluctuation test and improved stability of the mucoid form in shaken culture. , 1979, Journal of general microbiology.

[16]  Howard Brenner,et al.  The Constrained Brownian Movement of Spherical Particles in Cylindrical Pores of Comparable Radius: Models of the Diffusive and Convective Transport of Solute Molecules in Membranes and Porous Media , 1977 .

[17]  Margaret Katherine Banks,et al.  Assessment of biofilm ecodynamics , 1990 .

[18]  K. Whaley,et al.  Macromolecules released from polymers: diffusion into unstirred fluids. , 1990, Biomaterials.

[19]  Alan H. Muhr,et al.  Diffusion in gels , 1982 .

[20]  Z Lewandowski,et al.  Measurement of local mass transfer coefficient in biofilms , 1995, Biotechnology and bioengineering.

[21]  P. Gennes Reptation of a Polymer Chain in the Presence of Fixed Obstacles , 1971 .

[22]  W. Brown,et al.  Decay time distributions from dynamic light scattering for aqueous poly(vinyl alcohol) gels and semidilute solutions , 1990 .

[23]  D. Sellen Laser light scattering study of polyacrylamide gels , 1987 .

[24]  G. Wagman,et al.  Binding of Aminoglycoside Antibiotics to Filtration Materials , 1975, Antimicrobial Agents and Chemotherapy.

[25]  P. Stilbs,et al.  Fourier transform pulsed-gradient spin-echo studies of molecular diffusion , 1987 .

[26]  L. Favro,et al.  Theory of the Rotational Brownian Motion of a Free Rigid Body , 1960 .

[27]  P. Oostveldt,et al.  Quantitative fluorescence in confocal microscopy , 1990 .

[28]  S. Wijmenga,et al.  Rotational diffusion of short DNA fragments in polyacrylamide gels: An electric birefringence study , 1986, Biopolymers.

[29]  J. Fyfe,et al.  Mucoid Pseudomonas aeruginosa and cystic fibrosis: resistance of the mucoid from to carbenicillin, flucloxacillin and tobramycin and the isolation of mucoid variants in vitro. , 1978, The Journal of antimicrobial chemotherapy.

[30]  D Rodbard,et al.  Unified theory for gel electrophoresis and gel filtration. , 1970, Proceedings of the National Academy of Sciences of the United States of America.

[31]  D. Marquardt An Algorithm for Least-Squares Estimation of Nonlinear Parameters , 1963 .

[32]  W. Webb,et al.  Mobility measurement by analysis of fluorescence photobleaching recovery kinetics. , 1976, Biophysical journal.

[33]  J. Lawrence,et al.  Determination of Diffusion Coefficients in Biofilms by Confocal Laser Microscopy , 1994, Applied and environmental microbiology.

[34]  J. Bryers,et al.  Effects of carbon and oxygen limitations and calcium concentrations on biofilm removal processes , 1991, Biotechnology and bioengineering.

[35]  W. Gujer,et al.  Mass transfer mechanisms in a heterotrophic biofilm , 1985 .

[36]  J. F. Nicholls,et al.  Diffusion of charged ions in mucus gel: effect of net charge. , 1987, Biorheology.

[37]  R. Treloar,et al.  Diffusion and binding measurements within oral biofilms using fluorescence photobleaching recovery methods. , 1995, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[38]  A. G. Ogston,et al.  The spaces in a uniform random suspension of fibres , 1958 .

[39]  P. Stewart,et al.  Comparison of recalcitrance to ciprofloxacin and levofloxacin exhibited by Pseudomonas aeruginosa bofilms displaying rapid-transport characteristics , 1997, Antimicrobial agents and chemotherapy.

[40]  Effects of Network Structure on the Phase Transition of Acrylamide-Sodium Acrylate Copolymer Gels , 1984 .

[41]  H. Cypionka Sulfide-controlled continuous culture of sulfate-reducing bacteria , 1986 .

[42]  D. Sellen The diffusion of compact macromolecules within hydrogels , 1986 .

[43]  Rune Bakke,et al.  Biofilm thickness measurements by light microscopy , 1986 .

[44]  H. Pruul,et al.  Protective Role of Smooth Lipopolysaccharide in the Serum Bactericidal Reaction , 1971, Infection and Immunity.

[45]  E. Cussler,et al.  Mass transfer in pH-sensitive hydrogels , 1989 .

[46]  B. Mattiasson,et al.  Physiology of immobilized cells. , 1990 .

[47]  H. Lappin-Scott,et al.  Relationship between mass transfer coefficient and liquid flow velocity in heterogenous biofilms using microelectrodes and confocal microscopy. , 1997, Biotechnology and bioengineering.

[48]  J. Guenet,et al.  Enhanced low-angle scattering from moderately concentrated solutions of atactic polystyrene and its relation to physical gelation , 1986 .

[49]  J. Hearst,et al.  A polarized photobleaching study of DNA reorientation in agarose gels. , 1990, Biochemistry.

[50]  C. Robertson,et al.  The effective diffusive permeability of a nonreacting solute in microbial cell aggregates , 1988, Biotechnology and bioengineering.

[51]  Peter A. Wilderer,et al.  Structure and function of biofilms. , 1989 .

[52]  R. Mills,et al.  A Study of Diffusion in the Ternary System, Labeled Urea-Urea-Water, at 25° by Measurements of the Intradiffusion Coefficients1 of Urea2 , 1965 .