Center for Biofilm Engineering

Biofilm Control/Antimicrobials

Research Area

The biofilm control team addresses issues related to improving control of   detrimental biofilms.  Our work is motivated by the nearly universal observation that microorganisms growing in biofilms are less susceptible to all types of antimicrobial agents than the same microorganisms when grown in conventional suspension cultures.  Our scientific approach is to investigate the fundamental physical, chemical, and biological mechanisms that protect biofilm cells from antimicrobial challenges compared to their free-floating counterparts.  We also conduct applied research for industrial sponsors in a number of projects.

Goals:

• Explain quantitatively the penetration of antimicrobial agents into biofilm.
• Characterize the nutrient-limited physiological state(s) of biofilm microorganisms and relate these starved physiological states to antimicrobial resistance.
• Investigate the possibility of a distinct and protected biofilm phenotype.
• Integrate these constituent resistance phenomena in mathematical models.
• Apply these insights to develop improved technologies for biofilm control.

Highlights:

We have shown that limited antimicrobial penetration into biofilm does happen and can dramatically decrease biofilm susceptibility. This mechanism is operative when the antimicrobial agent is reactively neutralized in the surface layers of the biofilm faster than it diffuses into the biofilm.  On the other hand, when the antimicrobial agent is not particularly reactive with biofilm constituents, the agent penetrates readily. Click here for publications related to transport limitations to antimicrobial efficacy.

Physiological Limitations to Antimicrobial Efficacy Against Biofilms
If a nutrient becomes limiting in the interior of a biofilm microcolony, the microorganisms in that region will be forced into a slow-growing or non-growing state.  It is well known that starved bacteria can be much less susceptible to a variety of antimicrobial challenges.  We are developing techniques to characterize the physiological heterogeneity of biofilm to enable us to test this hypothesis.  We have demonstrated pronounced physiological heterogeneity in biofilm using fluorescent staining techniques. Click here for publications related to physiological limitations to antimicrobial efficacy.

Electrical Enhancement of Antimicrobial Efficacy against Biofilm
When a weak direct current is applied to a biofilm during treatment with an antibiotic, killing efficacy is remarkably enhanced.   We have shown that, in the case of Pseudomonas aeruginosa treatment with tobramycin, the enhancement in antibiotic efficacy is probably due to the electrolytic generation of oxygen.  We are working with collaborators to develop commercial applications of the "bioelectric" technology for medical instrument sterilization.  Click here for publications related to electrical enhancement of antimicrobial efficacy.

Modeling Biofilm Antimicrobial Resistance 

We have developed several mathematical models that can explain biofilm resistance to antimicrobial agents based on quantitative descriptions of fundamental constituent processes such as diffusion, disinfection, and microbial growth.  Phenomena that these models can predict include profoundly retarded penetration of reactive antimicrobial agents, poor biofilm efficacy of growth-rate dependent antimicrobial agents, and the characteristic signature disinfection profile of a resistant biofilm phenotype.  Click here for publications related to modeling biofilm antimicrobial resistance.

Click here for more detail on mechanisms of antimicrobial resistance

For more information, email Dr. Phil Stewart.

04 January, 2008