TY - JOUR
T1 - Breaking the Vicious Cycle of Antibiotic Killing and Regrowth of Biofilm-Residing Pseudomonas aeruginosa
AU - Müsken, Mathias
AU - Pawar, Vinay
AU - Schwebs, Timo
AU - Bähre, Heike
AU - Felgner, Sebastian
AU - Weiss, Siegfried
AU - Häussler, Susanne
N1 - Copyright © 2018 American Society for Microbiology.
PY - 2018/12
Y1 - 2018/12
N2 - Biofilm-residing bacteria embedded in an extracellular matrix are protected from diverse physicochemical insults. In addition to the general recalcitrance of biofilm bacteria, high bacterial loads in biofilm-associated infections significantly diminish the efficacy of antimicrobials due to a low per-cell antibiotic concentration. Accordingly, present antimicrobial treatment protocols that have been established to serve the eradication of acute infections fail to clear biofilm-associated chronic infections. In the present study, we applied automated confocal microscopy on Pseudomonas aeruginosa to monitor dynamic killing of biofilm-grown bacteria by tobramycin and colistin in real time. We revealed that the time required for surviving bacteria to repopulate the biofilm could be taken as a measure for effectiveness of the antimicrobial treatment. It depends on the (i) nature and concentration of the antibiotic, (ii) duration of antibiotic treatment, (iii) application as monotherapy or combination therapy, and (iv) interval of drug administration. The vicious cycle of killing and repopulation of biofilm bacteria could also be broken in an in vivo model system by applying successive antibiotic dosages at intervals that do not allow full reconstitution of the biofilm communities. Treatment regimens that consider the important aspects of antimicrobial killing kinetics bear the potential to improve control of biofilm regrowth. This is an important and underestimated factor that is bound to ensure sustainable treatment success of chronic infections.
AB - Biofilm-residing bacteria embedded in an extracellular matrix are protected from diverse physicochemical insults. In addition to the general recalcitrance of biofilm bacteria, high bacterial loads in biofilm-associated infections significantly diminish the efficacy of antimicrobials due to a low per-cell antibiotic concentration. Accordingly, present antimicrobial treatment protocols that have been established to serve the eradication of acute infections fail to clear biofilm-associated chronic infections. In the present study, we applied automated confocal microscopy on Pseudomonas aeruginosa to monitor dynamic killing of biofilm-grown bacteria by tobramycin and colistin in real time. We revealed that the time required for surviving bacteria to repopulate the biofilm could be taken as a measure for effectiveness of the antimicrobial treatment. It depends on the (i) nature and concentration of the antibiotic, (ii) duration of antibiotic treatment, (iii) application as monotherapy or combination therapy, and (iv) interval of drug administration. The vicious cycle of killing and repopulation of biofilm bacteria could also be broken in an in vivo model system by applying successive antibiotic dosages at intervals that do not allow full reconstitution of the biofilm communities. Treatment regimens that consider the important aspects of antimicrobial killing kinetics bear the potential to improve control of biofilm regrowth. This is an important and underestimated factor that is bound to ensure sustainable treatment success of chronic infections.
KW - Animals
KW - Anti-Bacterial Agents/blood
KW - Biofilms/drug effects
KW - Colistin/blood
KW - Colonic Neoplasms/complications
KW - Colony Count, Microbial
KW - Disease Models, Animal
KW - Drug Administration Schedule
KW - Drug Dosage Calculations
KW - Drug Therapy, Combination/methods
KW - Female
KW - Mice
KW - Mice, Inbred BALB C
KW - Microbial Sensitivity Tests
KW - Pseudomonas Infections/complications
KW - Pseudomonas aeruginosa/drug effects
KW - Tobramycin/blood
KW - Treatment Outcome
U2 - 10.1128/AAC.01635-18
DO - 10.1128/AAC.01635-18
M3 - Journal article
C2 - 30297365
SN - 0066-4804
VL - 62
JO - Antimicrobial Agents and Chemotherapy
JF - Antimicrobial Agents and Chemotherapy
IS - 12
ER -