fibrin and Bacteroides-Infections

The production of fibrinous exudates plays an important role in determining the outcome of peritoneal infection. Large numbers of bacteria are sequestered within fibrin matrices, thereby retarding bacterial spread throughout the peritoneal cavity and into the bloodstream. This walling-off process is teleologically advantageous in that it lessens early rapid mortality. Recent studies have documented that this same process is probably integral to the development of residual infection in the peritoneum. Bacteria sequestered within fibrin deposits are protected from normal host clearance mechanisms, thereby permitting unopposed proliferation and ultimately the establishment of an abscess. A complete understanding of the cellular and noncellular aspects of the host response to peritoneal infection will suggest novel strategies both to treat and to prevent the development of intraabdominal abscesses and their attendant consequences.

Topics: Abscess; Bacteroides fragilis; Bacteroides Infections; Blood Coagulation Factors; Fibrin; Fibrinolysis; Humans; Peritoneal Cavity; Peritoneal Diseases

A fibrin clot model for intra-abdominal abscess formation was used to study the migratory properties of peritoneal cells from rats during the early stages of infection. Peritoneal cells and fibrin clot remnant were harvested 6 h after implantation of a sterile, singly infected (Escherichia coli or Bacteroides fragilis) or mixed infected (E. coli and B. fragilis) fibrin clot. Histological study of fibrin clots, removed 6 h after implantation, showed a deeper infiltration by host cells of B. fragilis infected clots compared to the others. This difference in infiltration by peritoneal cells was not due to differences in fibrinolytic activity of the bacterial strains. Differential cell counts of the peritoneal cells from rats implanted with sterile, singly and mixed infected fibrin clots showed distribution over subpopulations to be independent of the bacterial content of the infected clots used. In vitro migration assays showed no significant differences in migration by peritoneal cells from rats implanted with clots containing a different bacterial composition. Since B. fragilis infected fibrin clots were more deeply infiltrated by host defence cells than the other clots, and only mixed infected clots led to persistent abscesses in this model, we conclude that local conditions within the fibrin matrix rather than intrinsic cellular capacities of the host cells are important for the process of abscess formation.

Topics: Animals; Bacterial Capsules; Bacteroides fragilis; Bacteroides Infections; Cell Movement; Cells, Cultured; Escherichia coli Infections; Fibrin; Fibrinolysis; Humans; Male; Peritoneal Cavity; Rats; Rats, Wistar

Deposition of fibrin within the peritoneal cavity is an integral host response to local infection. To directly assess the role of fibrin deposition in the pathogenesis of intraabdominal abscess formation, the ability to induce abscesses in fibrinogen-depleted mice was examined. We hypothesized that systemic defibrinogenation with ancrod would limit the availability of fibrinogen for deposition within the peritoneal cavity and would therefore impair intraabdominal abscess formation. A gelatin capsule containing 50% sterile feces plus Bacteroides fragilis 1 x 10(9) CFU was inserted IP into control or defibrinogenated mice. System defibrinogenation resulted in alteration of the character of abscess formation, as manifested by reduced abscess size and degree of purulence. Abscesses were significantly smaller (0.18 +/- 0.02 gm [n = 29] vs. 0.09 +/- 0.02 gm [n = 11], p less than 0.01) and less purulent (p less than 0.001) in the ancrod-treated mice than in control animals, despite equal numbers of bacteria in the abscesses recovered from both groups. The effect of ancrod was specific for defibrinogenation, because IP repletion with fibrinogen reversed the ancrod effect on abscess size. In addition to its local effects, systemic fibrinogen depletion resulted in a significant elevation in mortality following IP infection (1 of 30 control animals vs. 10 of 23 ancrod-treated animals, p less than 0.01). However, this was not due to an increase in the magnitude of the B. fragilis bacteremia. These studies demonstrate that fibrin deposition contributes to the pathogenesis of purulent abscess formation and that systemic depletion of fibrinogen may alter host susceptibility to the consequences of infection.

Topics: Abdomen; Abscess; Afibrinogenemia; Ancrod; Animals; Bacteroides fragilis; Bacteroides Infections; Disease Susceptibility; Feces; Female; Fibrin; Male; Mice; Rats; Rats, Inbred Strains

Growth of Bacteroides fragilis and Escherichia coli was monitored during early stages of single (mono-) and mixed intra-abdominal infection in a rat fibrin clot model. When B. fragilis and E. coli were together involved in the infection, B. fragilis numbers increased about 6 h after an initial decline. This increase was not found with B. fragilis mono-infections. The numbers of E. coli increased rapidly in both mono- and mixed infections and stayed high for several days, but only mixed infection resulted in abscesses that persisted for more than 7 days. Macrophages, the main component of the peritoneal cellular defence mechanism, were outnumbered by polymorphonuclear leucocytes during the first 6 h of infection. Further characterisation of the macrophage population by means of monoclonal antibodies showed a shift from resident to exudate macrophages as the result of influx of the latter.

Topics: Abdomen; Animals; Bacteroides fragilis; Bacteroides Infections; Blood Coagulation; Cell Count; Colony Count, Microbial; Disease Models, Animal; Escherichia coli; Escherichia coli Infections; Fibrin; Humans; Male; Peritoneal Cavity; Rats; Rats, Inbred Strains

The synergic relationship between Escherichia coli and Bacteroides fragilis was examined in a model of intra-abdominal abscess formation. The addition of B. fragilis to E. coli in the fibrin clot inoculum increased abscess weight and residual numbers of E. coli in the abscess at 7 days. In a reciprocal fashion, E. coli was capable of enhancing B. fragilis persistence in abscesses. Neither heat-killed E. coli nor heat-killed B. fragilis was able to mimic the synergic effect of its live counterpart. Furthermore, B. fragilis culture filtrate was unable to reproduce the ability of live B. fragilis to act synergically with E. coli. For B. fragilis to act synergically with E. coli, it had to be inoculated locally with E. coli in the peritoneal cavity, indicating that an effect on systemic resistance by B. fragilis was an unlikely mechanism for the production of bacterial synergy. These studies suggest that the synergic relationship between bacteria in polymicrobial infections is a complex one, resulting from intimate interactions between bacteria and the host in the local milieu of the infection.

Topics: Abscess; Animals; Bacteroides fragilis; Bacteroides Infections; Disease Models, Animal; Escherichia coli; Escherichia coli Infections; Fibrin; Male; Peritonitis; Rats; Rats, Inbred Strains

We inoculated 120 rats with 2 X 10(9) Escherichia coli or 2 X 10(9) Bacteroides fragilis suspended in normal saline solution or incorporated into fibrin clots. In the control group, all animals died after inoculation with E coli, but none died after the inoculation with B fragilis; both were suspended in normal saline solution. Escherichia coli entrapped in fibrin did not cause mortality but did result in abscess formation in all animals. Bacteroides fragilis incorporated into fibrin clots resulted in abscess formation in the majority of animals. Treatment with gentamicin sulfate, ampicillin sulfate, and cefoxitin sodium completely abolished the mortality secondary to E coli suspended in normal saline solution but did not influence the rate of abscess formation secondary to E coli incorporated into fibrin clots. Similarly, cefoxitin and clindamycin phosphate did not significantly change abscess formation secondary to B fragilis incorporated into fibrin clots. We conclude that systemic antibiotics are ineffective in the prevention of abscesses secondary to bacteria trapped in fibrin, either because they do not reach bactericidal levels in the fibrin clot, as in the case of gentamicin, ampicillin, and clindamycin, or, as in the case of cefoxitin, because of the inoculum effect caused by the high number of bacteria. Fibrinogen or fibrin itself do not afford any protection of bacteria against the action of antibiotics.

Topics: Abscess; Ampicillin; Animals; Anti-Bacterial Agents; Ascites; Bacteroides fragilis; Bacteroides Infections; Blood Coagulation; Cefoxitin; Clindamycin; Escherichia coli; Escherichia coli Infections; Fibrin; Gentamicins; Male; Rats; Rats, Inbred Strains

We measured the rate of lethality and abscess formation in rats that underwent intraperitoneal implantation of fibrin clots contaminated with either Escherichia coli or Bacteroides fragilis alone or in combination, to determine whether the two organisms together would produce a synergistic infection. Ten-day mortality produced by 10(9) colony-forming units (CFU) of E coli was 33.3%. Encapsulated B fragilis led to 3.3% mortality. Escherichia coli (5 X 10(8) CFU) plus B fragilis (5 X 10(8) CFU) led to a sharp increase both in the rate and final ten-day mortality (80.0%). Eighty percent of the rats that received E coli (10(9) CFU within fibrin clots) had abscesses determined on the basis of grossly purulent material. All animals that received B fragilis and survived ten days contained abscesses. Synergy between E coli and B fragilis was noted to occur only when 5 X 10(8) CFU of each organism was present within the fibrin clot. Lower numbers did not produce significant synergy compared with controls that received either E coli or B fragilis. Quantitation of the number of organisms present at 24 hours within contaminated fibrin clots demonstrated a similar amount of growth of both organisms, either when added alone or in combination as copathogens.

Topics: Abscess; Animals; Bacteroides fragilis; Bacteroides Infections; Blood; Blood Coagulation; Disease Models, Animal; Escherichia coli; Escherichia coli Infections; Fibrin; Humans; Peritoneal Cavity; Peritonitis; Rats

An experimental model, where fibrin clots were inserted subcutaneously in rabbits, was adapted to study the in vivo efficacy of two cephalosporins against Bacteroides fragilis. The respective MIC's of cefamandole and cefoxitin against the microorganism were 16 microgram/ml and 1 microgram/ml. The clots were infected with 10(7) B. fragilis. Groups of seven animals received an intravenous bolus injection (100 mg/kg) of either drug. The serum levels of both drugs were similar to those seen in humans. The peak concentrations of cefamandole (40 microgram/mg) in the clots were found to be ten times higher than those of cefoxitin (4 microgram/mg). The log number of colony forming units in the clots averaged 7.5 at 0 h. At 6 hours, this number reached 8 in the untreated animals, 1.5 after cefoxitin, and 1.7 after cefamandole. The apparent in vitro superiority of cefoxitin against B. fragilis could not be demonstrated in vivo. This discrepancy between in vitro and in vivo data can be explained by the high degree of penetrance of cefamandole into the infected fibrin loci. In this animal system, both cefoxitin and cefamandole had similar in vivo activity against B. fragilis.

Topics: Animals; Bacteroides fragilis; Bacteroides Infections; Cefamandole; Cefoxitin; Cephalosporins; Fibrin; Half-Life; Kinetics; Rabbits