Bactericidal activity of beta-lactams and amikacin against Haemophilus influenzae: effect on endotoxin release

Different endotoxin release and IL-6 plasma levels after antibiotic administration in surgical intensive care patients

Despite the use of broad-spectrum antibiotics, aggressive fluid resuscitation, vasopressor support, the mortality associated with Gram-negative sepsis and septic shock has not decreased significantly in the last two decades. The consequences of host exposure to endotoxin and the relationship of antibiotic administration to endotoxin release have become important areas of intense interest. In vitro studies have demonstrated that there was a difference in endotoxin release between PBP-3 specific antibiotics (β-lactam antibiotics) and PBP-2 specific antibiotics (carbapenems). This is the first clinical report of surgical patients admitted to the surgical and anaesthesiology intensive care unit on the missing endotoxin release after imipenem treatment; however cefotaxime and ceftriaxone showed significantly more positive endotoxin tests in the plasma when compared to imipenem. Ciprofloxacin and vancomycin were intermediate in endotoxin release and tobramycin did not cause endotoxin release. There were also significant differences in endotoxin neutralizing capacity. IL-6 levels were decreased after imipenem faster than after ceftriaxone or cefotaxime; ciprofloxacin seemed to increase IL-6. Endotoxin may be harmful in patients where the immune system has been continuously challenged. Timing, dosage, or combination with other compounds as well as the effect of antibiotics on macrophages need to be tested in larger clinical trials. In this respect a consecutive study was started.

Differences in mode of action of (β-lactam antibiotics influence morphology, LPS release and in vivo antibiotic efficacy

Antibiotic mediated release of endotoxin (lipopolysaccharide, LPS) from Gram-negative bacteria is implicated in septic shock. The β-lactam (cell wall active) class, in particular, has been deemed responsible for release of greater quantities of LPS than other classes of antibiotics. However, it is becoming increasingly recognized that variations in the ability to liberate free LPS exist within the β-lactam subclasses. Until recently, LPS-release studies have primarily included the cephalosporin, monobactam, and penicillin β-lactams, but not the carbapenem subclass. We document here that carbapenems significantly liberate less LPS than other β-lactam subclasses, and that disparity in LPS release also occurs within the carbapenems as well (i.e. imipenem vs meropenem). The propensity to release LPS correlates with the cumulative PBP binding affinity of each β-lactam antibiotic regardless of subclass. A direct correlation has been established between antibiotic concentration, frequency of antibiotic exposure, differential LPS release, PBP specificity (morphology, rate of bacterial lysis or cell mass) and antibiotic efficacy in two mouse models of infection. In the first, differences in the pathogenic (endotoxic) potential of potently biologically active smooth LPS (S-LPS) and poorly biologically active rough chemotype LPS (R-LPS) expressing bacteria underscores the in vivo importance of endotoxin in mediating lethality following antibiotic chemotherapy. Endotoxin is, however, not innately toxic and thus its lethal effects are mediated through LPS stimulation of host cells (i.e. macrophages) to produce deleterious levels of cytokines. In the second experimental model, therefore, the toxic effects of antibiotic-liberated endotoxin have been abrogated by pretreatment of mice with carrageenan (CGN) prior to challenge with endotoxin or Gram-negative bacteria. CGN treatment eliminates or markedly reduces the numbers of LPS-responsive mediator cells thus affecting mortality. In both animal models, an in vivo role for LPS is demonstrated through differential changes in antibiotic efficacy (ED 50) in response to differential effects of LPS via modulation of the endotoxic sensitivity/responsiveness of the host. We conclude that antibiotic class, concentration, dosing intervals (timing) and perhaps, method of treatment (i.e. bolus vs infusion) may each be important in the survival of experimental animals severely infected with Gram-negative bacteria.

Antibiotic-induced release of inflammatory mediators from bacteria in experimentalKlebsiella pneumoniae-induced sepsis

In a fibrin-clot model of sepsis, developed in mice, treatment with the antibiotics ceftazidime (Cfz) and ofloxacin (Ofl) caused significant (p < 0.01) release of endotoxin and TNF-alpha after 4.5 h when compared with control (untreated) and amikacin (Ami) treated group. Except for control group, the level of bacteremia declined in all three antibiotic-treated groups. The results suggest that antibiotic therapy, irrespective of the agent used, results in an increase in endotoxin levels in vivo. The amount of endotoxin liberated by Ami was much smaller than with Cfz and Ofl therapy, which makes it an appropriate agent for the treatment of sepsis. An increase in the level of TNF-alpha along with endotoxin is suggestive of increased inflammatory response.

High-dose antibiotic therapy is superior to a 3-drug combination of prostanoids and lipid A derivative in protecting irradiated canines

There is an urgent need to develop non-toxic radioprotectors. We tested the efficacy of a 3-drug combination (3-DC) of iloprost, misoprostol, and 3D-MPL (3-deacylated monophosphoryl lipid A) and the effects of postirradiation clinical support with high doses of antibiotics and blood transfusion. Canines were given 3-DC or the vehicle and exposed to 3.4 Gy or 4.1 Gy of 60Co radiation. Canines irradiated at 4.1 Gy were also given clinical support, which consisted of blood transfusion and antibiotics (gentamicin, and cefoxitin or cephalexin). Peripheral blood cell profile and 60-day survival were used as indices of protection. At 3.4 Gy, 3-DC- or vehicle-treated canines without postirradiation clinical support survived only for 10 to 12 days. Fifty percent of the canines treated with 3-DC or vehicle and provided postirradiation clinical support survived 4.1-Gy irradiation. Survival of canines treated with vehicle before irradiation significantly correlated with postirradiation antibiotic treatments, but not with blood transfusion. The recovery profile of peripheral blood cells in 4.1 Gy-irradiated canines treated with vehicle and antibiotics was better than drug-treated canines. These results indicate that therapy with high doses of intramuscular aminoglycoside antibiotic (gentamicin) and an oral cephalosporin (cephalexin) enhanced survival of irradiated canines. Although blood transfusion correlated with survival of 3-DC treated canines, there were no additional survivors with 3-DC treated canines than the controls.

Antibiotic induced endotoxin release and clinical sepsis: a review

Sepsis and peritonitis have not lost much of their danger for patients. The mortality rate in peritonitis has only marginally decreased during the last 30 years despite aggressive surgical and sophisticated intensive care treatment. In intra-abdominal infection and peritonitis source control remains the mainstay of treatment, although general principles and denominators of successful source control need to be established. Endotoxin has been recognized as a major player in the pathogenesis of sepsis and its significance in clinical disease has been investigated in clinical studies for more than 20 years. Since the Sixties there is a growing interest in the effect of antibiotics and other compounds on the release of endotoxin. The effect of antibiotics on the release of endotoxin and inflammatory parameters, e.g., cytokines, remains to be clarified despite a growing body of in-vitro studies, animal studies and a few clinical studies. The purpose of this review is to evaluate the evidence of endotoxin release in clinical studies and the effect that antibiotic treatment may have in-vitro, in-vivo and in clinical studies on endotoxin and cytokine release. In-vitro antibiotic-induced endotoxin release may depend on antibiotic class, presence of serum, type of organism, site of antibiotic action and Gram-stain. Endotoxin release may be different in late or early lysis, proportional to the number of killed pathogens. Morphology of bacteria may have an impact on endotoxin release and phagocytosis. Antibiotic-treated animals may show higher endotoxin levels with a higher survival rate than untreated animals. Plasma endotoxin may increase despite decreasing bacteremia. There may be a similar killing rate by different antibiotics but a difference in endotoxin release. Intestinal endotoxin does not necessarily correlate to the level of gram-negative bacteria. However, the alteration of the gut content by pretreatment may be associated with reduced endotoxemia and increased survival. Antibiotic-induced endotoxin release may be different depending on the type of infection, the location of infection, the virulence of strains, Gram-stain, mode of application and dosage of antibiotic. Different antibiotics may induce the release of different forms of endotoxin which may be lethal for sensitized animals. The combination of antibiotics with inhibitors of endotoxin or the pro-inflammatory response may be responsible for increased survival by decrease of endotoxin release. The clinical significance of antibiotic-induced endotoxin release is documented only in a few clinical disorders, e.g., meningitis, urosepsis. The difference in endotoxin release by PBP 2-specific antibiotics, e.g., imipenem, and PBP 3-specific antibiotics, e.g., ceftazidime, may not be visible in each study. Patients with increased multi-organ failure (MOF) scores may profit from treatment with antibiotics known to decrease endotoxin. In conclusion, the clinical significance of antibiotic-induced endotoxin release remains to be clarified. Type of pathogen and its virulence may be more important than recently suggested. gram-positive pathogens were just recently recognized as an important factor for the development of the host response. In case of fever of unknown origin in intensive care patients either failure of treatment, e.g., failure of source control in intra-abdominal infection, or a side effect of antibiotic treatment, e.g., endotoxin release, should be considered as a cause of the fever.

Lincomycin-induced endotoxin release in Escherichia coli sepsis: evidence for release in vitro and in vivo

OBJECTIVE

To evaluate the propensity of lincomycin and clindamycin to induce release of endotoxin, the authors investigated endotoxin release in Escherichia coli isolated from a patient who developed septic shock following lincomycin treatment.

METHODS

Endotoxin release from the E. coli isolate exposed to lincomycin, clindamycin, and ceftazidime were determined in vitro and in vivo.

RESULTS

In vitro, this E. coli released significantly larger amounts of endotoxin after exposure for 6 hours to lincomycin or clindamycin versus no antibiotic; however, endotoxin release with these antibiotics was significantly less than with ceftazidime. There was no significant difference in in vitro endotoxin release between small (8 mg/L) and large (0.5 minimum inhibitory concentration [MIC]) doses of these antibiotics, and 0.5 MICs of lincomycin and clindamycin were 1024 and 256 mg/L, respectively. These results were supported by scanning electron microscopic observations, which demonstrated that lincomycin, clindamycin, and ceftazidime induced formation of filamentous cells. In addition, plasma endotoxin concentrations after treatment for 4 hours with lincomycin, clindamycin, and ceftazidime (5 mg/kg) were at least 20-fold higher than with no antibiotic in an E. coli sepsis rat model.

CONCLUSION

Results of this study suggest that the bacteriostatic antibiotics, lincomycin and clindamycin, induce endotoxin release in the treatment of E. coli infections.

Endotoxin release from Escherichia coli after exposure to tobramycin: dose-dependency and reduction in cefuroxime-induced endotoxin release

OBJECTIVE

To study the release of free endotoxin from Escherichia coli exposed to varying concentrations of the penicillin-binding protein (PBP) 3-specific beta-lactam antibiotic cefuroxime, the aminoglycoside tobramycin, and a combination of the two, and to test the relationship between bacterial killing rate and endotoxin release.

METHODS

A clinical isolate of Escherichia coli in logarithmic phase was exposed to 0.1, 2, 10, and 50 x minimum inhibitory concentration (MIC) of cefuroxime, tobramycin, and a combination of the two. Samples for viable counts and endotoxin analysis were drawn immediately before and after the addition of the antibiotics and at 1, 2, 4, 6, and 24 h. All experiments were performed in triplicate. For the analysis of endotoxin, a chromogenic limulus amoebocyte lysate assay was used.

RESULTS

Endotoxin liberation was found to be proportional to the number of killed bacteria for each antibiotic regimen at each concentration level justifying the endotoxin-liberating potential to be expressed as release of endotoxin per killed bacterium, an expression that was independent of the inoculum size. At all concentration levels there was a statistically significant difference between the treatments, with the highest release of endotoxin per killed bacterium for cefuroxime, lower for tobramycin and the lowest for the combination of the two drugs (P < 0.001). With increasing doses, there was a significant reduction (P < 0.001) in the propensity to release endotoxin. When the bacterial killing rate was correlated to the propensity to release endotoxin in bacteria exposed to tobramycin or the combination of tobramycin and cefuroxime, a significant negative correlation was found (P < 0.01). This reduction in endotoxin release was not caused by an unspecific endotoxin binding of tobramycin.

CONCLUSIONS

Addition of tobramycin reduced the cefuroxime-induced endotoxin release per killed bacterium to a level which was even lower than that of tobramycin alone in spite of an increased killing rate. Increasing concentrations of tobramycin led to reduction in endotoxin release, which may be of benefit when dosing aminoglycosides once daily.

New criteria for selecting the proper antimicrobial chemotherapy for severe sepsis and septic shock

The mortality rate resulting from severe bacterial sepsis, particularly that associated with shock, still approaches 50% in spite of appropriate antimicrobial therapy and optimum supportive care. Bacterial endotoxins that are part of the cell wall are one of the cofactors in the pathogenesis of sepsis and septic shock and are often induced by antimicrobial chemotherapy even if it is administered rationally. Not all antimicrobial agents are equally capable of inducing septic shock; this is dependant on their mechanism of action rather than on the causative pathogen species. The quantity of endotoxin released depends on the drug dose and whether filaments or spheroplast formation predominates. Some antibiotics such as carbapenems, ceftriaxone, cefepime, glycopeptides, aminoglycosides and quinolones do not have the propensity to provoke septic shock because their rapid bactericidal activity induces mainly spheroplast or fragile spheroplast-like bacterial forms.

Impact of cefuroxime administration on endotoxin (LPS) and tumour necrosis factor-alpha (TNFalpha) blood levels in patients suffering from acute pyelonephritis: a preliminary report

It has been suggested that treatment of systemic infections caused by Gram-negative bacteria with beta-lactam agents might add to the inflammatory process by resulting in the release of endotoxins (LPS) upon death of the Gram-negative bacteria. To evaluate that hypothesis, 25 patients with acute pyelonephritis of Gram-negative aetiology were given intravenous cefuroxime 1.5 g tid. Blood samples were collected at various time intervals for blood culture and for the determination of LPS, tumour necrosis factor-alpha (TNFalpha) and cefuroxime levels. LPS remained elevated at levels equal to those before the administration of cefuroxime over the first 24 h of therapy. A positive correlation was detected between LPS and drug levels 6 h after the initiation of therapy. Fever persisted in 50, 37.5 and 16.7% of patients 48, 72 and 96 h after the start of treatment, respectively, followed by a rise of LPS at levels above the baseline. Blood cultures taken at the same time were sterile. A wide range of TNFalpha levels were found at similar times of sampling, indicating that LPS triggers considerable TNFalpha production in the serum of some patients but not in others. It is concluded that antibiotic-induced endotoxaemia is a phenomenon that might be observed in patients receiving cefuroxime and that might be responsible for the persistence of fever despite negative blood cultures.

Antibiotic-induced release of bacterial cell wall components in the pathogenesis of sepsis and septic shock: a review

This article reviews the new criteria for selecting the proper antimicrobial agent and dosage regimen for standard treatment of severe sepsis, with the intention of preventing septic shock. After introducing new concepts on the pathogenesis of sepsis and septic shock, the authors analyze the parameters of betalactam antibacterial activity, the antibiotic-induced release of bacterial endotoxin and the interrelationships between pharmacokinetics and pharmacodynamics of antibiotics in the search for an optimum dosage regimen of antimicrobial mono- or polytherapy for severely ill septic patients admitted to the intensive care unit.

The significance of endotoxin release in experimental and clinical sepsis in surgical patients--evidence for antibiotic-induced endotoxin release?

Sepsis and peritonitis remain a serious challenge for surgical patients, despite improvement in surgical therapy and intensive care and the introduction of new powerful antibiotics. Recent in vitro studies revealed the potential of certain antibiotics, e.g. penicillin-binding protein (PBP) 3-specific antibiotics, to cause antibiotic-induced endotoxin release. Other types of antibiotics, e.g., PBP 2-specific antibiotics, were associated with no or less endotoxin release. Further in vitro experiments and investigations in animals support the hypothesis of antibiotic-induced endotoxin release, but there is little clinical evidence. The clinical significance of endotoxin is subject of open dispute with many pro's and contra's. Endotoxin, although an important trigger, may not be the only factor to induce cytokine release, e.g., peptidoglycans were able to stimulate cells to release cytokines. Gram-positive pathogens have gained more importance in clinical sepsis and may not be sufficiently reflected in current clinical studies. The hypothesis that neutralization of endotoxin and pro-inflammatory cytokines is beneficial in sepsis was seriously challenged by the results of recent clinical and experimental studies. The better understanding of mechanisms in endotoxin-induced cell activation and cell, cell-receptor and soluble receptor interactions led to new treatment options. Recent reports on the complex pathogenesis of peritonitis and the detection of pathogen-related factors with intraperitoneal immune response may have implications on clinical studies investigating the potential of new compounds and the effect of antibiotics on endotoxin release. However, only few reports are available on the clinical significance of antibiotic-induced endotoxin release, and association of endotoxin release with pathogens, mortality or alteration of physiological parameters were not observed. With regard to the particulars of these studies, e.g., a small study population or low mortality rate, mortality may not be an ideal outcome parameter for these studies. There is clinical evidence for antibiotic-induced endotoxin release. However, the need for well-designed and performed studies using newly developed monitoring devices in intensive care therapy is obvious.

Differential induction of pro- and anti-inflammatory cytokines in whole blood by bacteria: effects of antibiotic treatment

The in vitro production of interleukin-1beta (IL-1beta), IL-6, and the IL-1 receptor antagonist (IL-1ra) in whole blood upon stimulation with different bacterial strains was measured to study the possible relationship between disease severity and the cytokine-inducing capacities of these strains. Escherichia coli, Neisseria meningitidis, Neisseria gonorrhoeae, Bacteroides fragilis, Capnocytophaga canimorsus, Staphylococcus aureus, Enterococcus faecalis, Streptococcus pneumoniae, and Streptococcus pyogenes induced the cytokines IL-1beta, IL-6, and IL-1ra. Gram-negative bacteria induced significantly higher levels of proinflammatory cytokine production than gram-positive bacteria. These differences were less pronounced for the anti-inflammatory cytokine IL-1ra. In addition, blood was stimulated with E. coli killed by different antibiotics to study the effect of the antibiotics on the cytokine-inducing capacity of the bacterial culture. E. coli treated with cefuroxime and gentamicin induced higher levels of IL-1beta and IL-6 production but levels of IL-1ra production similar to that of heat-killed E. coli. In contrast, ciprofloxacin- and imipenem-cilastatin-mediated killing showed a decreased or similar level of induction of cytokine production as compared to that by heat-killed E. coli; polymyxin B decreased the level of production of the cytokines.

In vivo TNF induction by culture supernatants of antibiotic-treated Escherichia coli 07:K1. Role of antibiotic class and concentration

Antibiotics may cause an excess release of lipopolysaccharide (LPS) from bacteria and thereby promote the production of tumour necrosis factor (TNF). TNF was measured in the serum of Swiss mice challenged with filtered supernatant of Escherichia coli O7:K1 that had been exposed to various antibiotics in vitro. Expressed as a function of a standardized number of cells remaining after 6 h of exposure to gentamicin, ceftazidime, ciprofloxacin or imipenem, TNF leves associated with antibiotic exposure always exceeded those of controls. However, if differences in the remaining number of bacteria were not taken into account, TNF induction by supernatant of control untreated cultures was greater than that elicited by supernatant from any of the antibiotic-treated cultures. With the exception of imipenem, low-dose antibiotic exposure (0.5 x MIC) invariably induced higher TNF levels than did high-dose exposure (10 x MIC). Considerable antibiotic class- and concentration-related differences were noted. LAL equivalent amounts of LPS released by different antibiotics may diverge in their capacity to induce TNF. Our results do not support the notion that the use of rapidly bactericidal and lytic antibiotics should be avoided.

Cerebrospinal fluid penetration of amikacin in children with community-acquired bacterial meningitis

The penetration of amikacin into the cerebrospinal fluid (CSF) was studied with 16 children (mean age, 1 year and 9 months; range, 4 months to 8 years) with community-acquired bacterial meningitis. Amikacin was given intravenously at a dose of 7.5 mg/kg of body weight twice daily. CSF was collected on day 1, at the expected peak concentration of amikacin in CSF. The mean (standard deviation) concentration of amikacin in CSF was 1.65 (1.6) mg/liter. Concentrations of amikacin in CSF correlated significantly with CSF glucose levels on admission. The mean concentrations of amikacin in CSF were 2.9, 1.1, and 0.20 mg/liter in patients with CSF glucose levels of < 1, 1 to 2, and > 2 mmol/liter, respectively. Thus, amikacin penetrates the blood-brain barrier substantially in children with bacterial meningitis and achieves particularly high concentrations when CSF glucose level is < 1 mmol/liter on admission.