Inhaled antibiotic therapy: What drug? What dose? What regimen? What formulation?

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Journal of Cystic Fibrosis 1 (2002) S189 S193 Inhaled antibiotic therapy: What drug? What dose? What regimen? What formulation? A.L. Smith* Department of Molecular Microbiology & Immunology, University of Missouri-Columbia, Columbia, MO, USA Abstract Early studies of the use of antibiotics in patients with cystic fibrosis suggested that they would be of benefit in preventing or reducing infection by Pseudomonas aeruginosa. In seeking to optimize treatment, factors such as the drug used, the dose, the regimen and the formulation must be considered. Aminoglycosides are ideal for aerosolization because they have a long postantibiotic effect and have an acceptable taste. Tobramycin is one of the aminoglycosides with the lowest systemic toxicity, which enables the aerosol delivery of doses high enough to overcome the antagonistic effects of the sputum. The most dramatic benefits from inhaled tobramycin have been shown to occur in the first 2 4 weeks of administration. Continual administration for longer periods can result in the development of resistance and loss of the improvement in lung function. However, this resistance is transient, and susceptibility to tobramycin returns after a short drug holiday. Optimal drug administration therefore consists of a 4-week on, 4-week off cycle. Such a cycle also helps to maintain patient compliance. Successful drug delivery also depends upon a formulation that does not provoke bronchoconstriction, which demands a formulation that is both preservative free, and osmotically and ph balanced. This research has enabled the development of a novel formulation of tobramycin optimized for use as an inhalation therapy in cystic fibrosis. 2002 European Cystic Fibrosis Society. Published by Elsevier Science B.V. All rights reserved. Keywords: TOBI; Tobramycin; Cystic fibrosis; Pseudomonas aeruginosa 1. Introduction A number of antipseudomonal antibiotics have been aerosolized to patients with cystic fibrosis (CF). These include amikacin w1x, carbenicillin and gentamicin w2,3x, and tobramycin w4x. Many of the trials and ad hoc administration did not seek to define the amount of drug which must reach the lower respiratory tract to be active against the infecting bacteria, primarily P. aeruginosa. Often the dose was the amount dispensed by the pharmacy for a single parenteral administration to an average patient: 80 mg (in 2 ml) for gentamicin and tobramycin; 100 mg for amikacin; 80 mg for colistin methansulphonate; and 1000 mg for carbenicillin. Convenience appeared to be a major factor in selecting the dose, as well as the assumption that the majority of the drug placed in the nebulizer would be delivered to the lower respiratory tract of the patient. Although most of these studies showed some efficacy, there were others in which *Tel.: q1-573-882-8152. E-mail address: smithal@missouri.edu (A.L. Smith). no effect of aerosol antibiotic administration could be demonstrated. As a result, a review in 1985 concluded that routine administration of aerosolized antibiotics to patients with CF was not warranted w5x. However, the need for an antibiotic effective in the treatment of opportunistic pulmonary infections in CF remained. To meet this need, it was apparent that the administration of aerosolized antibiotics would need to be refined, with particular emphasis on optimizing the choice of drug, formulation and regimen. 2. What drug? Aminoglycoside antibiotics are among those commonly aerosolized because they are chemically stable, have a long post-antibiotic effect wstill able to exert a lethal effect on the target organism after the concentration has decreased to below the minimal inhibitory concentration (MIC) valuex, have a low background level of resistance, and have an acceptable taste. Tobramycin is one of the aminoglycosides with the lowest systemic toxicity, and early empiric studies revealed that aerosol admin- 1569-1993/02/$ - see front matter 2002 European Cystic Fibrosis Society. Published by Elsevier Science B.V. All rights reserved. PII: S1569-1993Ž 02. 00002-4

S190 A.L. Smith / Journal of Cystic Fibrosis 1 (2002) S189 S193 Fig. 1. The density of P. aeruginosa m and tobramycin (s,d) concentration in the sputum of 10 patients with CF being treated parenterally with ticarcillin (250 mg kg day intravenously) and y2 tobramycin (240 mg m day) during hospitalization for a pulmonary exacerbation. Tobramycin was quantified by: bioassay (s), or radioenzymatic assay (d). The number in parentheses indicates the number of patients completing each time point in the study. Error bars indicate the S.E. of the means. Reproduced from w7x with permission. Extending these studies to an in vitro system (in which the sputum concentration was 10% of the total volume, Fig. 2), we were able to show that there was no marked difference in chemical composition between sputum collected from patients with CF and sputum collected from patients with chronic bronchitis and bronchiectasis, and that both blocked the cidal activity of aminoglycosides. In both cases, the cidal activity of the aminoglycoside was completely inhibited by the presence of sputum, permitting bacterial growth even when the antibiotic concentration was 10 times the MIC (Fig. 3) w8x. Subsequent work was able to determine that the major inhibitory factor of aminoglycoside bioactivity was sputum glycoproteins w9x, although there was some inhibition by DNA binding and by divalent cations as well as monovalent ions. The recognition that binding was the major factor antagonistic against aminoglycoside activity, coupled with the availability of an in vitro system, permitted us to show that increasing the concentration of the aminoglycoside would ultimately result in a free fraction able to kill P. aeruginosa; we determined that this was the case for both gentamicin and tobramycin w6,8x. To define the activity that would be effective against P. aeruginosa in sputum (and in the patient), we studied istration of the intravenous formulation to a variety of patients appeared to be well tolerated. Tobramycin has further advantages that facilitated its study: it is a single molecule (unlike gentamicin, which is a mixture of three isomers); it can be quantified by existing, extremely accurate and sensitive enzymatic and radioisotopic-based assays; and it is available as a generic product. For these reasons, early studies of the Seattle group focused on tobramycin w5x. 3. What dose? Vaudaux and Waldvogel w6x showed that, due to tight binding to macromolecules (primarily DNA), aminoglycosides are biologically inactive in purulent exudates. Although they were primarily concerned with the activity in abscesses, in which the exudate is necrotic cells and polymorphonuclear leukocytes, it is well known that CF patients produce sputum that always has some purulence. We assayed sputum from patients being treated with intravenous tobramycin for a pulmonary exacerbation and found marked discrepancies between the total amount of drug present (at several time points throughout the course) by an enzymatic assay and the amount present based on biologic activity w7x (Fig. 1). Fig. 2. An ex vivo system to study interaction of antibiotics with sputum. CF sputum (1.0 g) mechanically pooled from 10 patients was placed in a sterile dialysis sack, which was then placed in 10 ml of nutrient broth with or without added antibiotics. Test bacteria were inoculated into the nutrient broth after a 4-h pre-incubation of the sputum and the culture media. Samples of the broth were removed at the times indicated and the density of the bacteria quantified.

A.L. Smith / Journal of Cystic Fibrosis 1 (2002) S189 S193 S191 multiples of the in vitro-determined minimal concentration of tobramycin which would inhibit growth. Using this in vitro system, we found that an aminoglycoside concentration, which was 25-fold the MIC, was necessary before cidal activity against six P. aeruginosa isolates from CF patients was observed w7x (Fig. 3). All these experiments used P. aeruginosa that were defined as susceptible on the basis of disk susceptibility testing, and were later confirmed to be so with a quantitative method (broth dilution). Thus, using standard assays, all these organisms were susceptible in vitro to tobramycin with a MICF4 mg ml, yet approximately 100 mg ml was required to kill them in the presence of the average CF sputum. Examination of a panel of sputum samples from CF patients at multiple US centers permitted us to show that there was marked variability in the antagonistic activity of the sputum against aminoglycoside killing capacity. Thus, to overcome the inhibitory activity of sputum in 100% of the patients (i.e. including those with the worst case sputum), the peak sputum tobramycin concentration had to be 100 times the MIC to ensure killing of P. aeruginosa. In the patient, this translates into a desired peak of 400 mg of tobramycinyg of sputum. Preliminary studies indicated that this peak sputum concentration was achievable with an ultrasonic nebulizer and aerosolizing an average of 660 mg of tobramycin to each patient. This produced a peak sputum tobramycin concentration 30 min after the dose of 400 12 000 mg g, with an average concentration of 4.5 mg g. Studies of the elimination of tobramycin from sputum w10x had indicated that the concentration would decrease to below the in vitro MIC at approximately 6 h. Taking into account the 2-h post-antibiotic effect seen in vitro, it was determined that the theoretically ideal administration frequency was every 8 h, and therefore the dose was administered three times daily. This dosage regimen was shown to be well tolerated in a 90-day study of 22 patients with CF w11x. Extensive testing of renal function indicated no nephrotoxicity, and testing of auditory acuity to 20 000 Hz (that frequency first affected by aminoglycosides) did not detect any ototoxicity. Vestibular function was also unaffected when tested with the dynamic Etest. With safety of high doses for 3 months demonstrated a double-blind, placebo-controlled, taste-masked, crossover study was performed in 71 patients with CF. This study revealed a marked decrease in sputum bacterial density with aerosol tobramycin administration (indicating killing of P. aeruginosa), and that this decrease in density correlated with an improvement in pulmonary function w12x. 4. What regimen? In the open, unblinded studies of the safety of daily aerosol tobramycin administration, serial measurements Fig. 3. Mean bacterial density of six P. aeruginosa isolates (tobramycin MIC -4 mg ml ) over time in sputum alone (s) and with the addition of tobramycin 10=MIC (m) and 25=MIC (j). Error bars indicate the S.E. of the mean. The experimental system is that described in Fig. 2, except the pre-incubation was 28 h. Reproduced from w7x with permission. of pulmonary function were performed w11x. It was noted that the most dramatic improvement in pulmonary function occurred 2 weeks after initiation of administra- Fig. 4. The change in pulmonary function wfev 1 (j), FVC (d), and RV TLC (m)x in 22 patients with CF during daily inhalation of tobramycin (mean dose 660 mg tid) for 90 days. Dashed lines indicate follow-up after discontinuation of administration (days 99 165). The forced vital capacity (FVC) and forced expiratory volume at one second (FEV ) are expressed as the mean percent change from the enroll- 1 ment value in liters. The ratio of the residual volume (RV) to the total lung capacity (TLC) is expressed as the mean percent change from enrollment. The standard deviation for the FVC at all time points range from 10 14% while for the FEV it was 22 25% and for the 1 RVyTLC, 5 8%. w11x Copyright 1989 John Wiley & Sons. This material is used by permission of Wiley-Liss Inc, a subsidary of John Wiley & Sons, Inc.

S192 A.L. Smith / Journal of Cystic Fibrosis 1 (2002) S189 S193 tion (Fig. 4). With continued administration, the improvement in mean FEV1 was maintained for an additional 2 weeks, but there was loss of the initial improvement in the force vital capacity. A similar trend was reflected in air trapping (RVyTLC ratio). These data indicated that maximum efficacy of aerosol tobramycin administration continues for no longer than 30 days. It is clear that P. aeruginosa can develop resistance during a 2-week course of antibiotics. For example, in a study of azlocillin and tobramycin, 6 out of 114 morphotypes (5%) isolated from 57 patients were resistant to tobramycin and azlocillin on enrolment w13x. At the end of the treatment, 17 out of 96 morphotypes (18%) isolated from 40 patients were now resistant to those two antibiotics. The follow-up culture, 2 8 weeks after the end of treatment, indicated that only four out of 48 morphotypes (8%) were resistant w13x. Because of the transient nature of resistance and the failure to maintain improved pulmonary function with daily administration greater than 30 days, an on-off regimen seemed best suited for patients with CF. To make the aerosol treatment of lung infection in patients with CF practical, the patients in the initial clinical trial w12x were surveyed to determine the most practical regimen for in-home use. This survey revealed that many of the patients had, in fact, skipped the middleof-the-day dose because it interfered with school or work. A further trial was conducted in 67 CF patients using a more concentrated formulation of 60 mg ml tobra- mycin delivered via the PARI LC (not plus in this study) nebulizer. This more concentrated formulation and jet nebuliser combination produced a median peak sputum concentration of 452 mg g and was well- tolerated w14x. Although this is only 33% of the peak concentration obtained with the larger volumes and the ultrasonic nebulizer used in the initial study w11x, the range of the sputum tobramycin concentrations over time (Fig. 5) was predicted to be cidal in 90% of the subjects. This calculation excluded those rare P. aeruginosa that scored as tobramycin-susceptible on disk testing but were in reality resistant, as well as those uncommon patients whose sputum was exceptionally active in blocking tobramycin activity. 5. What formulation? Fig. 5. The median, 10th and 90th percentile values of sputum tobramycin concentrations (mg g ) measured at 10, 60 and 120 min fol lowing completion of aerosol administration of tobramycin via ultra (j), sidestream (d), and parijet (m) nebulizers. With the Ultra, 600 mg of tobramycin (30 mg ml in 0.5 normal saline) was aerosolized in 12 min, while with the jet nebulizers, 300 mg of tobramycin (60 mg ml in 0.25 normal saline) was nebulized in approximately the same period of time. Reproduced from w14x with permission. Early studies aerosolizing kanamycin to CF patients resulted in bronchial irritation w15x. Bronchial irritation producing cough is undesirable, because an antibiotic which has just been deposited into the lower respiratory tract will immediately be cleared and so will not have time to exert its antimicrobial activity. Other studies w16x with aerosol administration of intravenous aminoglycosides indicated that certain formulations had a bronchoconstrictor activity when administered to some CF subjects, an undesirable side-effect in patients already suffering from obstructive lung disease. In our early studies to develop a widely usable formulation for tobramycin aerosolization, we found that the parenteral formulation from the pharmacy contained preservatives that could evoke bronchospasm not only in the patient, but even in the medical personnel (with asthma) conducting the study. It is now well recognized that the preservatives in intravenous formulations of antimicrobial agents can evoke cough and bronchospasm when inhaled w16 19x. To minimize bronchospasm andyor cough, the inhaled solution must have a ph close to neutrality w20x, be balanced for osmolarity, and it must contain an ion, which can readily permeate the airway epithelium w21x. Therefore, we prepared preservative-free tobramycin at a concentration of 60 mg ml in a solution contain- ing 0.25 normal saline and adjusted to ph 6.8"0.1 and balanced for osmolality. Without antimicrobial preservatives, the tobramycin formulation must be produced under sterile conditions and dispensed in a single-use vial. This formulation was used in the 67-patient clinical trial of inhaled tobramycin w14x and the subsequent large, placebo-controlled study w22x. 6. Discussion Early studies, in which parenteral antibiotic formulations were placed in nebulizers and aerosolized to patients with CF, showed some promise in a variety of regimens. However, concerns regarding the correct effective dose, occasional bronchospasm and cough following aerosol administration, and the emergence of P. aeruginosa resistant to the antibiotic aerosolized, curbed widespread use of this form of therapy.

A.L. Smith / Journal of Cystic Fibrosis 1 (2002) S189 S193 S193 In addition, concentrations far exceeding those available in parenteral formulations are necessary to achieve an adequate concentration of unbound tobramycin in sputum to kill P. aeruginosa after aerosol administration. This knowledge coupled with an understanding of the magnitude of the sputum s ability to block tobramycin cidal activity, and pilot studies indicating that long-term continuous administration becomes progressively less beneficial led to the development of airway-friendly sterile formulations without preservatives and balanced with respect to salt, ph and osmolarity. This formulation of tobramycin (TOBI ), administered intermittently rather than continuously, has been shown to be effective in decreasing the sputum density of P. aeruginosa and slowing the rate of decline in FEV 1. References w1x Schaad UB, Wedgewood-Krucko J, Suter S, Kraemer R. Efficacy of inhaled amikacin as adjunct to intravenous combination therapy (ceftazidime and amikacin) in cystic fibrosis. J Pediatr 1987;111:599 605. w2x Hodson ME, Penketh ARL, Batten JC. Aerosol carbenicillin and gentamicin treatment of Pseudomonas aeruginosa infection in patients with cystic fibrosis. Lancet 1981;21:1137 9. w3x Jensen T, Pedersen SS, Garne S, Heilmann C, Hoiby N, Koch C. Colistin inhalation therapy in cystic fibrosis patients with chronic Pseudomonas aeruginosa lung infection. J Antimicrob Chemother 1987;19:831 8. w4x Hoff G, Schotz PO, Paulsen J. Tobramycin treatment of Pseudomonas aeruginosa infections in cystic fibrosis. Scand J Infect Dis 1974;6:333 7. w5x MacLusky I, Levison H, Gold R, McLaughlin FJ. Inhaled antibiotics in cystic fibrosis: is there a therapeutic effect. J Pediatr 1986;108:861 5. w6x Vaudaux P, Waldvogel FA. Gentamicin inactivation in purulent exudates: role of cell lysis. J Infect Dis 1980;142:586 93. w7x Mendelman PM, Smith AL, Levy J, Weber A, Ramsey B, Davis RL. Aminoglycoside penetration, inactivation, and efficacy in cystic fibrosis sputum. Am Rev Respir Dis 1985;132:761 5. w8x Levy J, Smith AL, Kenny MA, Ramsey B, Schoenknecht FD. Bioactivity of gentamicin in purulent sputum from patients with cystic fibrosis or bronchiectasis: comparison with activity in serum. J Infect Dis 1983;148:1069 76. w9x Hunt BE, Weber A, Berger A, Ramsey B, Smith AL. Macromolecular mechanisms of sputum inhibition of tobramycin activity. Antimicrob Agents Chemother 1995;39:34 9. w10x Weber A, Smith A, Williams-Warren J, Ramsey B, Covert DS. Nebuliser delivery of tobramycin to the lower respiratory tract. Ped Pulm 1994;17:331 9. w11x Smith AL, Ramsey BW, Hedges DL, Hack B, Williams-Warren J, Weber A, Gore EJ, Redding GJ. Safety of aerosol tobramycin administration for 3 months to patients with cystic fibrosis. Ped Pulm 1989;7:265 71. w12x Ramsey BW, Dorkin HL, Eisenberg JD, Gibson RL, Harwood IR, Kravitz RM, Schidlow DV. Efficacy of aerosolized tobramycin in patients with cystic fibrosis. N Engl J Med 1993;328:1740 6. w13x Smith AL, Doershuk C, Goldman D, Gore E, Hillman B, Marks M, Moss B. Comparison of a b-lactam alone vs. b- lactam and an aminoglycoside for pulmonary exacerbation in cystic fibrosis. J Pediatr 1999;134:413 21. w14x Eisenberg J, Pepe M, Williams-Warren J, Vasiliev M, Montgomery AB, Smith A, Ramsey B. A comparison of peak sputum tobramycin concentration in patients with cystic fibrosis using jet and ultrasonic nebuliser systems. Chest 1997;111:955 62. w15x Ayres SM, Briesbach J, Giannelli S. A study of bronchial irritation and systemic absorption of aerosolized kanamycin. Curr Therap Res 1972;14:153 7. w16x Dally MB, Kurrle S, Breslin ABX. Ventilatory effects of aerosol gentamicin. Thorax 1978;33:54 6. w17x Beasley CR, Rafferty P, Holgate ST. Bronchoconstrictor properties of preservatives in ipratropium bromide (Atroven) nebuliser solution. Br Med J 1987;294:1197 8. w18x Beasley R, Rafferty P, Holgate ST. Adverse reactions to the non-drug constituents of nebuliser solutions. Br J Clin Pharmac 1988;25:283 7. w19x Asmus MJ, Sherman J, Hendeles L. Bronchoconstrictor additives in bronchodilator solutions. J Allergy Clin Immunol 1999;104:S53 S60. w20x Seidenberg J, Mir Y, von der Hardt H. Hypoxaemia after nebulised salbutamol in wheezy infants: the importance of aerosol acidity. Arch Dis Child 1991;66:672 5. w21x Eschenbacher WL, Boushey HA, Sheppard D. Alteration in osmolarity of inhaled aerosols causes bronchoconstriction and cough, but absence of a permeant anion causes cough alone. Am Rev Respir Dis 1984;129:211 5. w22x Ramsey BW, Pepe MS, Quan JM, Otto KL, Montgomery AB, Williams-Warren J, Vasiljev M. Intermittent administration of inhaled tobramycin in patients with cystic fibrosis. N Engl J Med 1999;340:23 30.