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We investigated biofilms of two pathogens, Acinetobacter baumannii and Staphylococcus aureus, to characterize mechanisms by which the extracellular polymeric substance (EPS) found in biofilms can protect bacteria against tobramycin exposure. To do so, it is critical to study EPS-antibiotic interactions in a homogeneous environment without mass transfer limitations. Consequently, we developed a method to grow biofilms, harvest EPS, and then augment planktonic cultures with isolated EPS and tobramycin. We demonstrated that planktonic cultures respond differently to being treated with different types of EPS (A. baumannii versus S. aureus) in the presence of tobramycin. By harvesting EPS from the biofilms, we found that A. baumannii EPS acts as a "universal protector" by inhibiting tobramycin activity against bacterial cells regardless of species; S. aureus EPS did not show any protective ability in cell cultures. Adding Mg(2+) or Ca(2+) reduced the protective effect of A. baumannii EPS. Finally, when we selectively digested the proteins or DNA of the EPS, we found that the protective ability did not change, suggesting that neither has a significant role in protection. To the best of our knowledge, this is the first study that demonstrates how EPS protects pathogens against antibiotics in a homogeneous system without mass transfer limitations. Our results suggest that EPS protects biofilm communities, in part, by adsorbing antibiotics near the surface. This may limit antibiotic diffusion to the bottom of the biofilms but is not likely to be the only mechanism of protection.

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RATIONALE: Recent studies of inhaled tobramycin in subjects with cystic fibrosis (CF) find less clinical improvement than previously observed. Nonhuman data suggest that in some strains of Pseudomonas aeruginosa, azithromycin can antagonize tobramycin. OBJECTIVES: We tested the hypothesis that concomitant azithromycin use correlates with less improvement in key outcome measures in subjects receiving inhaled tobramycin while not affecting those receiving a comparative, nonaminoglycoside inhaled antibiotic. METHODS: We studied a cohort of 263 subjects with CF enrolled in a recent clinical trial comparing inhaled tobramycin with aztreonam lysine. We performed a secondary analysis to examine key clinical and microbiologic outcomes based on concomitant, chronic azithromycin use at enrollment. MEASUREMENTS AND MAIN RESULTS: The cohort randomized to inhaled tobramycin and reporting azithromycin use showed a significant decrease in the percent predicted FEV1 after one and three courses of inhaled tobramycin when compared with those not reporting azithromycin use (28 d: -0.51 vs. 3.43%, P < 0.01; 140 d: -1.87 vs. 6.07%, P < 0.01). Combined azithromycin and inhaled tobramycin use was also associated with earlier need for additional antibiotics, lesser improvement in disease-related quality of life, and a trend toward less reduction in sputum P. aeruginosa density. Subjects randomized to inhaled aztreonam lysine had significantly greater improvement in these outcome measures, which were unaffected by concomitant azithromycin use. Outcomes in those not using azithromycin who received inhaled tobramycin were not significantly different from subjects receiving aztreonam lysine. Azithromycin also antagonized tobramycin but not aztreonam lysine in 40% of P. aeruginosa clinical isolates tested in vitro. CONCLUSIONS: Oral azithromycin may antagonize the therapeutic benefits of inhaled tobramycin in subjects with CF with P. aeruginosa airway infection.

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Results from this laboratory have shown that bone metabolism is directly related to extracellular pH and that high concentrations of tobramycin released from impregnated polymethylmethacryrate (PMMA) beads has pH-dependent toxic effects on bone. In the present study, beneficial effects of calcium hydroxide-impregnated PMMA were investigated regarding tobramycin toxicity and bone metabolism in chick embryo tibiae in vitro. Also using Ca(OH)2 as a pH regulator, the antibiotic efficacy of tobramycin-impregnated PMMA was evaluated with respect to inhibition of Staphylococcus aureus growth. When Ca(OH)2 was added to PMMA beads containing tobramycin, the beads released hydroxyl and calcium ions into the culture medium and released more antibiotic than beads containing only tobramycin. Bone metabolism (glycolysis, total protein synthesis, and collagen synthesis) was enhanced by Ca(OH)2-impregnated beads with or without tobramycin. Additionally, bacterial growth was inhibited more strongly when S. aureus was incubated with tobramycin- and Ca(OH)2-impregnated PMMA disks than with disks containing only tobramycin. This study demonstrates the feasibility of adding Ca(OH)2 to tobramycin-impregnated PMMA beads as a regulator of local pH and a promoter of bone metabolism for protection of bone when high concentrations of tobramycin are used to treat osteomyelitis. It also suggests that lower concentrations of antibiotic may be effective if Ca(OH)2 and tobramycin are administered simultaneously.

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The effect of ceftriaxone on tobramycin-induced nephrotoxicity was investigated. Female Sprague-Dawley rats were treated during 4 and 10 days with saline (NaCl, 0.9%), ceftriaxone at a dose of 100 mg/kg of body weight/12 h subcutaneously, tobramycin at doses of 40 and 60 mg/kg/12 h intraperitoneally, or the combination ceftriaxone-tobramycin. Creatinine levels in serum were significantly higher in animals treated with tobramycin alone given at 60 mg/kg/12 h during 10 days, compared with control animals (P < 0.01) or animals receiving the combination tobramycin-ceftriaxone (P < 0.01). After 10 days of treatment, ceftriaxone did not accumulate in renal tissue but did reduce the renal intracortical accumulation of tobramycin (P < 0.05). Tobramycin given alone at either 40 or 60 mg/kg/12 h induced a significant inhibition of sphingomyelinase activity compared with control animals (P < 0.05). However, this enzyme activity was significantly less inhibited when tobramycin was injected in combination with ceftriaxone (P < 0.05). Ceftriaxone alone had no effect on the activity of this enzyme. The [3H]thymidine incorporation into the DNA of renal cortex was also significantly lower in animals treated with tobramycin-ceftriaxone compared with animals receiving tobramycin alone (P < 0.05). The 24-h urinary excretion of beta-galactosidase was significantly reduced in animals treated with the combination tobramycin-ceftriaxone compared with the administration of tobramycin alone at 40 and 60 mg/kg/12 h after 5 and 10 days (P < 0.05). Histologically, ceftriazone induced very few cellular alterations and reduced considerably the presence of typical signs of tobramycin nephrotoxicity. This investigation demonstrated that ceftriaxone protects animals against tobramycin-induced nephrotoxicity.

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OBJECTIVE: Inactivation of aminoglycosides by beta-lactam antimicrobials both in vitro and in vivo has been documented. Such an interaction has not previously been documented between carbapenems and aminoglycosides. Examination of serum concentrations of tobramycin in a patient receiving both agents suggested that this interaction might exist. The purpose of this study was to look at this question in an in vitro model. METHODS: Low concentrations of tobramycin (10 micrograms/mL) were incubated with imipenem/cilastatin (concentrations of 10, 20, and 40 micrograms/mL) in human serum at 37 degrees C. Aliquots of these solutions were withdrawn at 0, 6, 24, 72, and 120 hours and assayed for tobramycin concentrations using a fluorescence polarization immunoassay. Aliquots of tobramycin 10 micrograms/mL and carbenicillin 200 micrograms/mL were analyzed in the same manner, as a positive control. High concentrations of tobramycin (800 micrograms/mL) and imipenem (5000 micrograms/mL)/cilastatin were incubated together at 21 degrees C and sampled at 0, 6, 24, and 72 hours for tobramycin concentrations. RESULTS: The degradation rates for low-concentration tobramycin and the various concentrations of imipenem/cilastatin were not statistically different from those of the controlled incubations. In contrast, carbenicillin significantly enhanced the degradation rate of tobramycin at this concentration (half-life 72 hours and a 34 percent loss at 24 hours, p = 0.0028). Higher in vitro concentrations of imipenem (5000 micrograms/mL)/cilastatin and tobramycin (800 micrograms/mL) resulted in significant, but moderate degradation over controlled incubations (half-life 80 hours and 10 percent loss at 12 hours, p = 0.0031). CONCLUSIONS: These results suggest that inactivation of tobramycin is not a problem at common clinically achievable imipenem serum concentrations in patients.

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In vivo inactivation of aminoglycosides by antipseudomonal penicillins in patients with renal failure can be a significant problem when these drugs are used together in certain gram-negative infections. Our article illustrates the possible magnitude of this interaction and the resultant effect on aminoglycoside pharmacokinetic parameters. Penicillin concentrations remain relatively unaffected by this interaction. This article stresses the need for close monitoring of aminoglycoside concentrations when combined with antipseudomonal penicillins in this patient population.

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At clinically achievable levels (e.g., 25 micrograms/ml), sulbactam exerted no effect on aminoglycoside concentrations when incubated together in pooled serum at 37 degrees C for up to 24 h. Sulbactam alone and in combination with ampicillin or cefoperazone inactivated tobramycin, gentamicin, netilmicin, and amikacin in vitro when the sulbactam concentration was 200 to 225 micrograms/ml. At 75 micrograms/ml, sulbactam inactivated only tobramycin. Inactivation of tobramycin by high concentrations of sulbactam occurred even at -20 degrees C, but not at -70 degrees C, and was influenced by the serum matrix.

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We compared the in vitro activity of mezlocillin and piperacillin, alone and in combination with tobramycin or gentamicin, against clinical isolates of gram-negative bacilli from hospitalized patients with 100 distinct episodes of nosocomial bacteremia. The minimum inhibitory concentrations (MICs) necessary to inhibit 50% and 90% of isolates showed that piperacillin was most active against Pseudomonas aeruginosa. The MIC needed to inhibit 90% of isolates also showed that mezlocillin was more active against Enterobacter cloacae. Activities of the two acylaminopenicillins were comparable against the rest of the isolates. Combining the acylaminopenicillins with either gentamicin or tobramycin decreased the MICs fourfold or more for both combinations. Synergy occurred more frequently with mezlocillin-gentamicin (12%), followed by piperacillin-tobramycin (9%), mezlocillin-tobramycin (6%), and piperacillin-gentamicin (5%). Antagonism for Enterobacteriaceae isolates was observed most frequently with the combination of piperacillin plus tobramycin (20%), followed by mezlocillin plus tobramycin (17.6%), piperacillin plus gentamicin (12.9%), and mezlocillin plus gentamicin (8.2%). There are very few differences in the activities of mezlocillin and piperacillin combined with either gentamicin or tobramycin versus nosocomial gram-negative bloodstream isolates.

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We examined the protective effect of inositol hexasulfate (IS6) against tobramycin (TOB)-induced nephrotoxicity. In the electrophoretic analysis, TOB alone and IS6 alone were observed as single spots on the cathode and anode sides, respectively. However, in the mixture of TOB and IS6 preincubated at 37 degrees C for 3 hr, the tailing of the spots of TOB and IS6 were observed from the origin to the cathode and the anode sides, respectively, and the overlapping of the spots of TOB and IS6 was recognized at the origin. These results indicated that TOB directly interacted with IS6 in vitro. Assay of TOB binding to rat kidney brush border membranes (BBMs) indicated that IS6 inhibited the binding of TOB to BBMs through an interaction of TOB and IS6. No significant reduction in intrarenal TOB level was observed in the rats given TOB (90 mg/kg, s.c.) and IS6 (153 or 610 mg/kg, s.c.). However, the treatment of rats with a combination of TOB and IS6 reduced the degree of necrosis of renal tubular cells and also suppressed the increases in urinary protein, urinary enzyme activities, blood urea nitrogen and plasma creatinine induced by TOB. Additionally, we detected a complex of TOB and IS6 in the urine of rats given both compounds simultaneously. These results indicate that IS6 protects against TOB-induced nephrotoxicity and that the protective action of IS6 may be due to the inhibition of TOB binding to BBMs through an interaction of TOB with IS6.

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Salt depletion is known to potentiate aminoglycoside nephrotoxicity, while salt replacement attenuates it. Recent studies have shown that ticarcillin protects against tobramycin and gentamicin nephrotoxicity. It has been suggested that this protection is due to an interaction between ticarcillin and the aminoglycoside. However, it can also be explained by the salt load associated with ticarcillin administration. This study was conducted to examine this question. Tobramycin was administered to eight groups of rats at 100 mg/kg per day intraperitoneally for 10 days. Group 1 rats were salt depleted, while group 2 rats were on a normal salt diet. Rats in groups 3 through 8 were also salt depleted but received, in addition, the following interventions intraperitoneally: group 3, ticarcillin, 300 mg/kg per day (0.37 to 0.39 meq of Na supplement per day); group 4, ticarcillin, 300 mg per day (1.56 meq of Na supplement per day); group 5, ticarcillin, 300 mg/kg per day, and NaCl supplement (1.17 to 1.19 meq/day), resulting in a total load of 1.56 meq/day; group 6, piperacillin, 400 mg/day (0.76 meq of Na supplement per day and equimolar to the ticarcillin dose [300 mg/day] in group 4 rats); group 7, piperacillin, 400 mg/day, and NaCl supplement (0.8 meq/day) for a total Na load of 1.56 meq/day; and group 8, 1.56 meq of Na per day as NaCl. Rats in groups 2, 4, 5, 7, and 8, which received a normal salt diet or its equivalent Na supplement, had no significant change in creatinine clearance (CLCR) over the 10-day period. The remaining groups sustained significant reductions in CLCR, as follows: group 1, -53.0% (P < 0.05); group 3, -66.2% (P < 0.05); group 6, -79.8% (P < 0.05). A positive correlation was found between the concentration of tobramycin in the kidneys and the percent change in CLCR at the end of the study. Concentrations of drugs in plasma were highest in group 1 rats, lowest in the rats in groups in which protection was observed, and moderately elevated in the remaining groups of rats. The results of this study suggest the following: (i) that the protective effect of ticarcillin against tobramycin nephrotoxicity is secondary to the obligatory sodium load associated with it, (ii) pharmacokinetic and pharmacodynamic interactions between salt and tobramycin are proposed to explain this effect, (iii) the nephrotoxicity of tobramycin is probably related to the degree of accumulation of the drug in the kidney, and (iv) an in vivo interaction between tobramycin and ticarcillin does not contribute to the protective effect of the penicillin but may influence concentrations in plasma, especially under conditions of severe renal impairment.

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We investigated the effect of pyridoxal-5'-phosphate (PALP) on tobramycin (TOB)-induced nephrotoxicity in rats. Paper electrophoretic analysis showed that in the mixture of TOB and PALP, the spot corresponding to TOB alone almost disappeared and the spot associated with TOB overlapped with that associated with PALP, although the spots of TOB alone and PALP alone were observed as single spots on the cathode and anode sides, respectively. The overlapping of both compounds indicated that TOB could directly interact with PALP in vitro. In the assay of TOB binding to renal brush border membranes (BBMs), PALP significantly inhibited the binding of TOB to BBMs by interacting with TOB outside of BBMs vesicles. Intrarenal TOB levels in rats receiving TOB and PALP were lower than those in rats given TOB alone. Combination with PALP markedly suppressed the urinary protein content, urinary N-acetyl-beta-D-glucosaminidase activity and blood urea nitrogen content elevated by TOB, and also reduced the degree of TOB-induced renal tubular cell necrosis. These results indicate that PALP protects the rat kidneys from TOB-induced nephrotoxicity and that the protective effect of PALP may be due to the reduced intrarenal TOB concentration and less binding to TOB to BBMs induced by the interaction of PALP with TOB.

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Apalcillin, at concentrations of 75, 150, 300, and 600 micrograms/ml, was combined in vitro with amikacin, gentamicin, netilmicin, or tobramycin. Incubation at 37 degrees C resulted in an apalcillin concentration-dependent and time-dependent decrease of aminoglycoside activity of up to 60%. Amikacin was the most stable and tobramycin was the least stable aminoglycoside under the conditions tested.

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The in vitro inactivation of tobramycin when combined with each of six cephalosporins in samples of human serum was investigated. Each of six cephalosporins (cefazolin sodium, cefoxitin sodium, cefamandole nafate, moxalactam disodium, cefoperazone sodium, and cefotaxime sodium) was added to human serum samples containing tobramycin sulfate 8 micrograms/mL to produce final cephalosporin concentrations of approximately 250 and 1000 micrograms/mL. Duplicate solutions were prepared and stored at either 0 or 21 degrees C. Solutions containing tobramycin 8 micrograms/mL alone and with carbenicillin disodium in four concentrations were prepared as controls. Samples were assayed using a fluorescence polarization immunoassay (TDX) at 0, 2, 4, 8, 12, 24, and 48 hours to determine tobramycin concentration; two of the carbenicillin-tobramycin solutions were frozen immediately for assay 53 hours later. Tobramycin concentrations in the admixtures were compared with those in tobramycin reference samples. At both temperatures, samples containing tobramycin with cefamandole 250 micrograms/mL or cefotaxime 250 micrograms/mL showed less than 10% inactivation of tobramycin for at least 48 hours. At 0 degrees C, tobramycin retained greater than 90% activity when combined with cefoperazone 250 and 1000 micrograms/mL. In samples containing cefazolin 250 micrograms/mL at 0 degrees C and cefoperazone 250 micrograms/mL at 21 degrees C, tobramycin was stable for 24 hours. Only samples containing moxalactam stored at 21 degrees C showed greater than 16% inactivation of tobramycin at 48 hours. Under these study conditions, tobramycin is only moderately inactivated in vitro when combined with clinically achievable concentrations of the tested cephalosporins (excluding moxalactam) and then stored for up to 48 hours.(ABSTRACT TRUNCATED AT 250 WORDS)

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We studied sputum tobramycin concentrations after intravenous administration in 10 cystic fibrosis patients. Tobramycin concentrations were determined by a bioassay and a radioenzymatic assay (REA). The bacterial density of Pseudomonas aeruginosa in sputum was examined serially during therapy. Bioactivity of tobramycin in the sputum was low and increased little during treatment. In contrast, tobramycin content (as assayed by REA) showed a progressive accumulation of the drug to high concentrations: a mean of 82 micrograms/g sputum after 3 wk of therapy in 4 patients. Pseudomonas aeruginosa was eradicated from the sputum in 3 of 4 patients receiving antibiotic therapy for 3 wk. Eradication correlated with tobramycin sputum concentrations measured by REA, which were 20-fold greater than the apparent tobramycin inhibitory concentration. A bactericidal effect of aminoglycosides in the presence of sputum in vitro could only be reliably produced with concentrations 25-fold the MIC. We conclude that tobramycin penetrates cystic fibrosis (CF) sputum and accumulates over time. Although CF sputum antagonized the bioactivity of aminoglycosides, 3 wk of intravenous therapy combined with an antipseudomonal beta-lactam antibiotic may be effective in eradication of P. aeruginosa from sputum of certain CF patients.

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We examined the effects of mixing tobramycin with three cephalosporins, cefazolin, cefamandole, and moxalactam. Each cephalosporin was prepared from standard powder and diluted with human serum to concentrations of 50, 250, and 500 micrograms/ml and added to 10 micrograms/ml of tobramycin in human serum. Temperature environments of 4 degrees C (refrigeration), 24 degrees C (room temperature), and 37 degrees C (body temperature) were used and sampled at 0 hours (control), and at 8, 24, and 48 hours. The results indicated no inactivation of tobramycin by any of the cephalosporins, regardless of temperature, concentration, or contact time. These results indicate that significant inactivation of tobramycin does not occur when it is combined in vitro with moxalactam, cefamandole, or cefazolin.

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It is well known that in vitro the combination of carbenicillin, ticarcillin, or other antipseudomonal penicillins with gentamicin, tobramycin, or other aminoglycoside antibiotics results in the inactivation of the antibacterial activity of the aminoglycoside. To assess the influence of the in vivo interaction of tobramycin and ticarcillin on experimental nephrotoxicity, male Fischer 344 rats were given either tobramycin alone (120 mg/kg per day), tobramycin (120 mg/kg per day) and ticarcillin (250 mg/kg per day) concomitantly, or the combination of these drugs at the same doses that had been preincubated for 24 h and at the time of delivery contained but 63 and 25%, respectively, of the initial concentrations of tobramycin and ticarcillin as measured by conventional analytical procedures. Initial experiments were conducted to determine the concentrations of the antibiotics in serum achieved after administration of each test solution. After a single dose of the test solution, ticarcillin concentrations in serum were higher and more prolonged in rats given tobramycin plus ticarcillin than in rats given ticarcillin alone. After 7 days of exposure to the test solutions, inulin clearance in animals given tobramycin alone was 0.15 +/- 0.1 (mean +/- 2 standard errors) ml/min per 100 g of body weight as compared with 0.53 +/- 0.1 in rats given tobramycin and ticarcillin concomitantly, 0.59 +/- 0.1 in animals given the partially inactivated tobramycin-ticarcillin mixture, and 0.79 +/- 0.1 in control rats. Although there was some improvement in inulin clearance in the group containing tobramycin alone, the three treatment groups maintained the same rank relationship in inulin clearance through 14 days of treatment. Real histology confirmed the attenuation of tubular injury in animals given tobramycin and ticarcillin concomitantly. There was no evidence of toxicity from the presumed inactivation complexes of tobramycin-ticarcillin. These results document an in vivo protective effect of ticarcillin on experimental tobramycin nephrotoxicity.

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Hydroxylamine was evaluated and found to be a highly effective agent for the in vitro prevention of penicillin inactivation of tobramycin. This inactivation reaction resulted in an underestimation of tobramycin concentrations and was dependent on time, temperature, amount and type of penicillin, and amount of tobramycin. Plasma samples containing tobramycin and three clinically relevant concentrations of ticarcillin, carbenicillin, azlocillin, or piperacillin were incubated with and without hydroxylamine, and tobramycin concentrations were monitored at 0, 12, 24, 48, and 72 h. The inactivation reaction was found to be completely inhibited by hydroxylamine (1 mg/ml) compared with a 27 to 50% loss of measured tobramycin concentration in the unprotected tobramycin-penicillin samples. Hydroxylamine did not interfere with the Emit enzyme immunoassay (Syva Co.) at either high or low tobramycin concentrations. Hydroxylamine was effective in inhibiting the tobramycin inactivation at both room and refrigerator temperatures and was 100% effective in protecting tobramycin on a 1:1 molar basis.

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