TY - JOUR
T1 - Adhesion of Lactobacillus acidophilus, Escherichia coli and Staphylococcus epidermidis to polymer and urinary catheter surfaces
AU - Reid, Gregor
AU - Hawthorn, Lesley Ann
AU - Eisen, Andrea
AU - Stephen Beg, H.
N1 - Funding Information:
This work was funded by The Medical Research Council of Canada, and in part by the Physician’s Services Incorporated Foundation. Dr G. Reid is an Ontario Ministry of Health Career Scientist. MS Andrea Eisen was supported by a Life Sciences Award from the University of Toronto, and Mr Stephen Beg received funding from the Government of Ontario. We are grateful for the
PY - 1989/12/15
Y1 - 1989/12/15
N2 - The present study was undertaken to investigate bacterial adhesion to biomaterial surfaces, with a long term goal of lowering the incidence of urinary sepsis related to catheter colonization. The main thrust of our investigations has been to use lactobacilli to interfere with uropathogenic infection. The latest experiments demonstrated that L. acidophilus T-13 adhered well to polymer surfaces, with a negative linear correlation with substratum surface tension (determined by the equation of state approach). The organisms adhered well to commercially manufactured silkolatex urinary catheter material (94% coverage within 9 has measured by image analysis). The adhesion of S. epidermidis strain 1938 did not relate to polymer surface tension and these organisms adhered best to sulfonated polystyrene (72% coverage) and fluorinated ethylene propylene (48% coverage). Time course experiments demonstrated that the adhesion of the staphylococci increased dramatically within 1 to 3 h (48% coverage of sulfonated polystyrene after 3 h), reaching a plateau around 9 h. A pyelonephritogenic strain of E. coli adhered very poorly to all polymers tested. Contact angle measurements indicated that lactobacilli surface hydrophobicity was altered by growth conditions and that there were large differences between strains. The net surface charge was negative for all specimens tested and there was a significant difference between the electrophoretic mobilities for lactobacilli grown in urine compared to urine plus sugars. These studies indicate that bacterial, substratum and fluid components can influence bacterial surface charge and hydrophobicity, leading to alteration of bacterial adhesion to biomaterials.
AB - The present study was undertaken to investigate bacterial adhesion to biomaterial surfaces, with a long term goal of lowering the incidence of urinary sepsis related to catheter colonization. The main thrust of our investigations has been to use lactobacilli to interfere with uropathogenic infection. The latest experiments demonstrated that L. acidophilus T-13 adhered well to polymer surfaces, with a negative linear correlation with substratum surface tension (determined by the equation of state approach). The organisms adhered well to commercially manufactured silkolatex urinary catheter material (94% coverage within 9 has measured by image analysis). The adhesion of S. epidermidis strain 1938 did not relate to polymer surface tension and these organisms adhered best to sulfonated polystyrene (72% coverage) and fluorinated ethylene propylene (48% coverage). Time course experiments demonstrated that the adhesion of the staphylococci increased dramatically within 1 to 3 h (48% coverage of sulfonated polystyrene after 3 h), reaching a plateau around 9 h. A pyelonephritogenic strain of E. coli adhered very poorly to all polymers tested. Contact angle measurements indicated that lactobacilli surface hydrophobicity was altered by growth conditions and that there were large differences between strains. The net surface charge was negative for all specimens tested and there was a significant difference between the electrophoretic mobilities for lactobacilli grown in urine compared to urine plus sugars. These studies indicate that bacterial, substratum and fluid components can influence bacterial surface charge and hydrophobicity, leading to alteration of bacterial adhesion to biomaterials.
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U2 - 10.1016/0166-6622(89)80347-6
DO - 10.1016/0166-6622(89)80347-6
M3 - Article
AN - SCOPUS:0024901048
SN - 0166-6622
VL - 42
SP - 299
EP - 311
JO - Colloids and Surfaces
JF - Colloids and Surfaces
IS - 3-4
ER -