Tolerance and Pharmacokinetic Interactions of Rifabutin and Clarithromycin in Human Immunodeficiency Virus-Infected Volunteers

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Antimicrobial Agents and Chemotherapy, March 1998, p. 631-639, Vol. 42, No. 3
0066-4804/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Tolerance and Pharmacokinetic Interactions of Rifabutin and Clarithromycin in Human Immunodeficiency Virus-Infected Volunteers

Richard Hafner,¹^,^* James Bethel,² Maureen Power,¹ Bernard Landry,³ Mary Banach,² Larry Mole,⁴ Harold C. Standiford,⁵ Stephen Follansbee,⁶ Princy Kumar,⁷ Ralph Raasch,⁸ David Cohn,⁹ David Mushatt,¹⁰ and George Drusano¹¹

Division of AIDS, National Institute of Allergy and Infectious Diseases, National Institutes of Health,¹ Westat,² and Social & Scientific Systems, Inc.,³ Rockville, Maryland; Veterans Administration Medical Center, Palo Alto, California⁴; Institute of Human Virology, University of Maryland School of Medicine, and the Veterans Administration Medical Center, Baltimore, Maryland⁵; Davies Medical Center, San Francisco, California⁶; Georgetown University, Washington, D.C.⁷; University of North Carolina at Chapel Hill, Chapel Hill, North Carolina⁸; Denver Disease Control Service and University of Colorado Health Sciences Center, Denver, Colorado⁹; Tulane University School of Medicine, New Orleans, Louisiana¹⁰; and Albany Medical College, Albany, New York¹¹

Received 14 April 1997/Returned for modification 9 October 1997/Accepted 21 December 1997

	ABSTRACT

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This study evaluated the tolerance and potential pharmacokinetic interactions between clarithromycin (500 mg every 12 h) andrifabutin (300 mg daily) in clinically stable human immunodeficiencyvirus-infected volunteers with CD4 counts of <200 cells/mm³. Thirty-four subjects were randomized equally to either regimenA or regimen B. On days 1 to 14, subjects assigned to regimenA received clarithromycin and subjects assigned to regimen B receivedrifabutin, and then both groups received both drugs on days 15to 42. Of the 14 regimen A and the 15 regimen B subjects who startedcombination therapy, 1 subject in each group prematurely discontinuedtherapy due to toxicity, but 19 of 29 subjects reported nausea,vomiting, and/or diarrhea. Pharmacokinetic analysis included datafor 11 regimen A and 14 regimen B subjects. Steady-state pharmacokineticparameters for single-agent therapy (day 14) and combination therapy(day 42) were compared. Regimen A resulted in a mean decreaseof 44% (P = 0.003) in the clarithromycin area under the plasmaconcentration-time curve (AUC), while there was a mean increaseof 57% (P = 0.004) in the AUC of the clarithromycin metabolite14-OH-clarithromycin. Regimen B resulted in a mean increase of99% (P = 0.001) in the rifabutin AUC and a mean increase of 375%(P < 0.001) in the AUC of the rifabutin metabolite 25-O-desacetyl-rifabutin.The usefulness of this combination for prophylaxis of Mycobacteriumavium infections is limited by frequent gastrointestinal adverseevents. Coadministration of clarithromycin and rifabutin resultsin significant bidirectional pharmacokinetic interactions. Theresulting increase in rifabutin levels may explain the increasedfrequency of uveitis observed with concomitant use of these drugs.

	INTRODUCTION

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Mycobacterium avium complex (MAC) disease is a frequent cause of morbidity and mortality in patients with late-stage humanimmunodeficiency virus (HIV) infection (3, 4). In commonwith other mycobacterial infections, treatment of MAC infectionswith combinations of drugs appears to be necessary to improveefficacy and to prevent the emergence of resistance. Clarithromycinand rifabutin are agents commonly used for both the treatmentand the prophylaxis of MAC infection. Clarithromycin is a macrolideantibiotic with a high level of activity against MAC, with MICsat which 90% of isolates are inhibited (MIC₉₀s) reportedly rangingbetween 1 and 4 µg/ml for clinical isolates (2, 17, 19).MAC strains isolated from patients without previous macrolidetherapy are uniformly susceptible to clinically achievable clarithromycinlevels. A dose-ranging, single-agent-treatment trial of clarithromycindemonstrated impressive clinical activity in the reduction orelimination of MAC bacteremia (8). The MIC₉₀s of rifabutinrange between 0.25 and 2 µg/ml, although typically $<=$ 60% of thestrains are susceptible to the drug at levels obtained with presentdosing practices (18, 37). The 25-O-desacetyl metabolite ofrifabutin has in vitro activity similar to that of rifabutin (41).Rifabutin was effective for MAC prophylaxis in a placebo-controlled,double-blind trial (31). The combination of rifabutin and clarithromycinwas found to have additive activity in vitro (23, 26) in macrophages(27) and the beige mouse model (24).

Clarithromycin is a known inhibitor (22) and rifabutin is a known inducer (5) of hepatic microsomal cytochrome P-450enzymes. The effect of enzyme inhibition by clarithromycin appearswith the first dose, but it is not maximized until after severaldoses (15). Enzyme induction by rifabutin was demonstrated at7 days by the increased metabolism of antipyrine (32), and autoinductionof rifabutin metabolism was detected at 10 days in studies withhealthy volunteers (28). Pharmacokinetic interactions betweenclarithromycin and rifabutin could cause significant changes inthe systemic exposure of both parent compounds and their primarymetabolites and could have important implications for the safetyand effectiveness of therapy against MAC. In a group of patientstreated with clarithromycin for lung disease due to MAC, meanlevels of clarithromycin were decreased in those also receivingrifabutin at 600 mg/day, indicating that this dosage of rifabutinappeared to induce clarithromycin metabolism (43). This studywas designed to evaluate the tolerance of combination therapyand the potential pharmacokinetic interactions between clarithromycinand rifabutin in a population with late-stage HIV infection.

	MATERIALS AND METHODS

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Subjects. Thirty-four clinically stable HIV-infected adult volunteers provided written, informed consent according to the institutionalguidelines of the participating centers prior to enrollment. Patientswere excluded for known MAC bacteremia or a compatible syndrome,CD4 counts of >200 cells/mm³, acute opportunistic infection or malignancy, a serum creatininelevel of >2.0 mg/dl, a bilirubin level of >2.0 mg/dL, aspartateaminotransferase and alanine aminotransferase levels more thanfive times the upper limit of normal, a history of sensitivityor intolerance to the study drugs, or recent use of clarithromycin(within 14 days) or rifabutin (within 30 days). Patients requiringdrugs likely to interact pharmacokinetically with the study agentswere excluded, with the exception that azoles for acute treatmentor maintenance therapy for fungal infections were permitted.

Study design. Volunteers were randomized equally to one of two regimens. Regimen A consisted of clarithromycin, at 500 mg every 12 h for2 weeks (days 1 to 14), followed by a combination of the sameclarithromycin dose plus rifabutin, 300 mg once daily for an additional4 weeks (days 15 to 42). Regimen B used the same doses of studydrugs used for regimen A, but the subjects received rifabutinduring days 1 to 14 and the combination of rifabutin and clarithromycinduring days 15 to 42. Subjects were instructed to take the dailyrifabutin dose with the morning dose of clarithromycin. Clinicalevaluations and hematologic and biochemical profiles were repeatedevery 2 weeks over an 8-week period, with the last study visitoccurring 2 weeks after the discontinuation of study drugs. Tomonitor compliance, missed doses were self-reported by the studyparticipants. Subjects experiencing a possible drug-related toxicityof grade 3 or higher, as defined by the Division of AIDS Tablefor Grading Severity of Adult Adverse Experiences, were permanentlydiscontinued from study therapy and were followed until the resolutionof the toxicity.

Pharmacokinetic sampling occurred on day 14, the time at which steady state for either clarithromycin alone (regimen A) orrifabutin alone (regimen B) is presumed to occur, day 15 (day1 of combination therapy), and day 42 (presumed combination steadystate). Subjects fasted for 12 h before and 2 h after study drugadministration, but they were allowed water and concomitant medications.For subjects receiving regimen A, blood was obtained predosingand at 0.25, 0.5, 0.75, 1, 1.5, 2, 3, 4, 6, 8, and 12 h afterdosing on days 14 and 15. For days 42 and 43, blood was also obtainedat hours 16, 24, 36, and 48. For subjects receiving regimen B,blood was obtained predosing and at 0.5, 1, 1.5, 2, 3, 4, 6, 8,12, 16, and 24 h after dosing on days 14 and 15. For days 42 to45, blood was also obtained at hours 36, 48, 72, and 96. At weeks3, 4, and 5, blood was obtained within 1 hour prior to the administrationof the next dose of combination study medication for determinationof trough levels. Blood samples for drug level assays were centrifugedwithin 1 h of collection, and the plasma was aliquotted and frozenat $-$ 70°C until it was assayed.

Study drugs. Clarithromycin was provided as 500-mg tablets by Abbott Laboratories (Abbott Park, Ill.), and rifabutin was provided as 150-mgcapsules by Adria Laboratories (currently Pharmacia & Upjohn,Kalamazoo, Mich.).

Drug assays. The concentrations of the drugs in plasma were determined by validated high-pressure liquid chromatographic techniques (10,25). The concentrations of clarithromycin and 14 (R)-hydroxyclarithromycin(14-OH-clarithromycin) in plasma were determined by Harris Laboratories(Lincoln, Nebr.); rifabutin and 25-O-desacetyl-rifabutin concentrationsin plasma were determined by BAS Analytics (West Lafayette, Ind.).

The clarithromycin assay had a sensitivity of 0.0156 µg/ml and was linear from 0.0156 to 8.00 µg/ml. The between-day percentcoefficients of variation were 10.1% at 0.0606 µg/ml, 10.7% at0.25 µg/ml, and 6.4% at 2.00 µg/ml. The sensitivity and linearityrange were the same for 14-OH-clarithromycin. For this metabolite,the between-day percent coefficients of variation of assay were5.1% at 0.065 µg/ml, 10.9% at 0.25 µg/ml, and 9.5% at 2.00 µg/ml.

The rifabutin and 25-o-desacetyl-rifabutin assays each required two standard curves. Linearity was acceptable within eachstandard curve range. The rifabutin low standard curve rangedfrom 0.005 to 0.060 µg/ml and the high standard curve ranged from0.060 to 0.800 µg/ml. The between-day percent coefficients ofvariation for rifabutin were 17.4% at 0.00726 µg/ml, 10.8% at0.029 µg/ml, 9.82% at 0.144 µg/ml, and 8.2% at 0.726 µg/ml. Forthe 25-o-desacetyl-rifabutin metabolite, the low standard curveranged from 2.5 to 30 ng/ml and the high standard curve rangedfrom 30 to 400 ng/ml. The between-day percent coefficients ofvariation for 25-o-desacetyl-rifabutin were 19.7% at 0.00319 µg/ml,12.0% at 0.0127 µg/ml, 10.9% at 0.0634 µg/ml, and 12.1% at 0.319µg/ml.

Statistical considerations. It was projected that a sample of 12 evaluable subjects would provide at least an 80% power (with $alpha$ = 0.05) for one-sidedtests of the hypothesis that combination therapy would be toleratedby 67% or more of the subjects receiving each regimen againstthe alternative that only 33% could tolerate the therapy. Thebaseline characteristics of the subject groups were compared bythe Student t test and the chi-square test. The study was alsodesigned to determine if apparent drug clearance for each agent,as measured by the mean change in the area under the plasma concentration-timecurve (AUC), would be significantly modified in the presence ofthe other drug.

The LAGRAN software of Rocci and Jusko (34) was used to compute AUC. The maximal concentration (C_max) and the time to C_max(T_max) were determined by inspection of interpolated curves. $lambda$ _z,the terminal elimination rate constant, was determined by fittinga log-linear regression to the data for the last four time pointsof the terminal phase; in cases of a delayed T_max, fewer pointswere used. AUC_0- is the presumed steady-state valuefor each drug and its metabolite during the period between doses.For day 15, the AUC_0- (the AUC from time zero toinfinity) of the drug initiated on that day was calculated asAUC_{0-C_n} + C_n/ $lambda$ _z, where C_n is the concentrationat the last measurable time point. Treatment arms were comparedby two-sample t tests.

	RESULTS

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Subject characteristics. A total of 34 volunteers, 17 receiving each regimen, were enrolled into the study at six participating centers between 16June 1992 and 27 October 1992. Thirty-two subjects began the single-drugtherapy to which they were randomized, and 29 of these subjectsinitiated combination therapy on day 15. Data for 11 volunteersrandomized to regimen A and 14 volunteers randomized to regimenB were included in the pharmacokinetic analysis (Table 1).

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TABLE 1. Study enrollment, withdrawal, and completion rates^a

The baseline characteristics of the 32 study volunteers who started a study drug are presented in Table 2. At enrollment,the mean CD4 cell counts were 67 and 82 cells/mm³ (P = 0.25) for regimen A subjects and regimen B subjects, respectively.The only characteristic for which there was a significant differenceat the baseline was weight (P = 0.02), but there was no significantdifference in body surface area (P = 0.13). There were no statisticallysignificant differences in the baseline characteristics of the26 subjects who completed the study compared to those of the 6subjects who did not complete the study (data not shown).

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TABLE 2. Baseline characteristics of the 32 subjects who started study drugs^a

Drug tolerance and adverse events. After 1 week of combination therapy, one regimen A subject experienced grade 3 myalgia and one regimen B subject experiencedgrade 3 leukopenia; each subject discontinued the study drugs.The 95% confidence intervals for the proportion tolerating combinationtherapy are as follows: for regimen A subjects (13 of 14 subjects),80.7 to 99.6%; for regimen B subjects (14 of 15 subjects), 81.9to 99.7%. In neither regimen was the hypothesis of at least 67%tolerance rejected (P $>=$ 0.97).

Gastrointestinal (GI) symptoms were reported frequently, with 19 of 29 (65.5%) subjects reporting nausea, vomiting, or diarrheaevents during combination therapy. All except three of these GIevents were grade 1; one subject had a single report of grade2 nausea (defined as four to five episodes per day or vomitingfor 1 week or longer) at week 1, and two others had reports ofgrade 2 diarrhea (defined as five to seven loose stools per dayor nocturnal loose stools) at week 3. Of these 19 subjects, 9had only one type of GI symptom (3 subjects had nausea and 6 subjectshad diarrhea) and 11 had multiple symptoms (5 subjects had nauseaand diarrhea, 2 subjects had nausea and vomiting, and 4 subjectshad all three symptoms). The GI complaints were persistent in16 volunteers who reported the same symptom on 2 or more consecutiveweekly visits during combination therapy. HIV-related conditionsoccurring during the study included herpes simplex in 1 subjectand oral candidiasis in 12 subjects.

Effect of rifabutin on clarithromycin pharmacokinetics. Data for three regimen A subjects who received combination therapy were not used in the pharmacokinetics analysis; one subjecthad poor study drug compliance, one subject prematurely withdrewfrom the study due to an adverse event, and technical problemsprevented the use of one subject's samples. Table 3 presentsthe estimated values of the pharmacokinetic parameters, includingthe AUC_0-12, C_max, and T_max of clarithromycin and 14-OH-clarithromycin,for regimen A subjects on days 14, 15, and 42. Figure 1 displaysthe AUCs of clarithromycin (Fig. 1a) and 14-OH-clarithromycin(Fig. 1b) for each of the three sampling periods.

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TABLE 3. Pharmacokinetic parameters of clarithromycin and 14-OH-clarithromycin for 11 subjects receiving regimen A^a

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FIG. 1. Composite curves of mean clarithromycin concentrations (a) and 14-OH-clarithromycin concentrations (b) for regimen A subjects during the three pharmacokinetic sampling periods. Regimen A was clarithromycin, 500 mg every 12 h during days 1 to 14 and then the same clarithromycin dose with rifabutin, 300 mg daily during days 15 to 42.

The mean decrease in the clarithromycin AUC_0-12 between days 14 and 42 was 44% (P < 0.003) (Table 3). A significantdecrease was observed when comparing the mean clarithromycin AUC_0-12between days 15 and 42 (P < 0.004) but not between days 14 and15 (P = 0.678). The individual clarithromycin AUC_0-12 estimatesdecreased 23.4 to 83.5% between days 14 and 42 for all exceptone subject; the AUC_0-12 for one subject increased by 49%.The mean increase in the 14-OH-clarithromycin AUC_0-12 betweendays 14 and 42 was 57% (P = 0.004). The increase was also significantbetween days 15 and 42 (P = 0.006) but not between days 14 and15 (P = 0.795).

The mean decrease in the clarithromycin C_max between days 14 and 42 was 41% (P = 0.003), and a significant decrease was seenin the mean C_max estimates between days 15 and 42 (P < 0.008).The mean increase in the C_max of the 14-OH-clarithromycin metabolitebetween days 14 and 42 was 69% (P = 0.001). No statistically significantchanges were seen in the T_max of clarithromycin or the 14-OH-clarithromycinmetabolite among any of the three time points.

Effect of clarithromycin on rifabutin pharmacokinetics. One regimen B subject who received combination therapy prematurely withdrew from the study due to an adverse event, and datafor that subject were not used in the pharmacokinetic analysis.The AUC_0-24, C_max, and T_max values for rifabutin and 25-O-desacetylrifabutin on days 14, 15, and 42 for regimen B subjects are presentedin Table 4. Figure 2 displays the AUCs of rifabutin (Fig. 2a)and 25-O-desacetyl rifabutin (Fig. 2b) for each of the three samplingperiods.

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TABLE 4. Pharmacokinetic parameters of rifabutin and 25-O-desacetyl-rifabutin for 14 subjects receiving regimen B^a

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FIG. 2. Composite curves of mean rifabutin concentrations (a) and 25-O-desacetyl rifabutin concentrations (b) for regimen B subjects during the three pharmacokinetic sampling periods. Regimen B was rifabutin, 300 mg daily during days 1 to 14 and then the same rifabutin dose with clarithromycin, 500 mg every 12 h during days 15 to 42.

The mean increase in the rifabutin AUC_0-24 between days 14 and 42 was 99% (P = 0.001) (Table 4). Most of this changeoccurred between days 14 and 15 (P < 0.001), while the changebetween days 15 and 42 was not significant (P = 0.152). The individualrifabutin AUC_0-24 estimates increased 19 to 266% betweendays 14 and 42 for all except one subject; the AUC_0-24 forone subject decreased by 39%. The mean increase in the 25-O-desacetylrifabutin AUC_0-24 between day 14 and day 42 was 375% (P< 0.001). This increase was also significant between days 14 and15 (P = 0.003) and between days 15 and 42 (P = 0.002).

The mean increase in the rifabutin C_max between days 14 to 42 was 69% (P = 0.011). The changes in C_max between days 14 and15 and between days 15 and 42 were not significant (P $>=$ 0.20)because of the large variability in the C_max estimate at day 15(Table 4). The mean increase in the C_max for the rifabutin metabolitebetween days 14 to 42 was statistically significant (P = 0.034).As also shown in Table 4, the mean percent change in the rifabutinT_max showed a significant increase between days 14 and 42 (P =0.013). The mean percent change in the 25-O-desacetyl rifabutinT_max also increased significantly between days 14 and 42 (P =0.017).

Concomitant medications. Ten subjects (five subjects from each regimen) received an azole antifungal agent (fluconazole, n = 8; ketoconazole, n = 2)for some period of time during their participation in the study.For regimen A, the mean clarithromycin AUCs at day 14 were 37.1and 36.1 µg · h/ml for the subjects receiving azoles (n = 4) andthose not receiving azoles (n = 7), respectively. At day 42, themean clarithromycin AUCs were 17.8 and 15.6 µg · h/ml for theazole recipients (n = 5) and those not receiving azoles (n = 6),respectively. For regimen B, the mean rifabutin AUCs at day 14were 3.8 and 4.4 µg · h/ml for the subjects receiving azoles (n= 4) and those not receiving azoles (n = 10), respectively. Atday 42, the mean rifabutin AUCs for the azole recipients (n =5) and those not receiving azoles (n = 9) were 6.9 and 7.2 µg· h/ml, respectively. For both regimens, these mean study drugAUCs for patients receiving azoles compared to those for patientsnot receiving azoles at both day 14 and day 42 were not significantlydifferent. The regimen A subject with an atypical AUC responsewas receiving fluconazole throughout the study, and the regimenB subject with an atypical AUC response did not receive any azoletherapy. Other concomitant medications included zidovidine (23subjects), ddI (14 subjects), dapsone (11 subjects), ddC (4 subjects),and trimethoprim-sulfamethoxazole (7 subjects).

	DISCUSSION

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In 1992, plans for large randomized clinical trials were developed to optimize MAC prophylaxis by comparing the most promisingnew therapies. One of these trials, trial ACTG 196/CPCRA 009,was designed to compare clarithromycin, rifabutin, and both drugsin combination. The combination arm was included to determineif effectiveness could be increased by preventing clarithromycinresistance, because relapses of MAC bacteremia with macrolide-resistantstrains occurred frequently during a trial of clarithromycin alonefor the treatment of disseminated MAC disease (8). The toleranceof this combination in the target population and the possibilityof bidirectional pharmacokinetic drug interactions were importantissues to be considered in the design and conduct of the ACTG/CPCRAphase III prophylaxis trial. Trial DATRI 001A was designed toaddress these questions directly with a population of subjectswith late-stage HIV infection.

The outcome of this study validated the hypothesis that >67% of the volunteers could tolerate the combination of clarithromycinand rifabutin over a total of 28 days. Only 2 (7%) of the 29 subjectsreceiving combination therapy discontinued the study drugs dueto toxicities, but adverse events were frequently reported. Nineteensubjects (66%) reported GI complaints of nausea, vomiting, and/ordiarrhea during the combination-therapy period. Given the relativelyshort period of evaluation, the combination therapy may be muchless well tolerated over the longer term. Also, while these adverseevents were not serious and may be tolerated during treatmentof disseminated MAC infection, they may be less often toleratedduring prophylaxis.

The single-drug pharmacokinetic profiles are consistent with those from previous studies of HIV-negative and HIV-infectedsubjects receiving single-agent therapy (9, 38, 42). Bothpharmacokinetic interactions demonstrated in this study were extensive,with the mean day 42 clarithromycin AUC_0-12 decreasing by44% and the mean rifabutin AUC_0-24 increasing by 99% (Pvalues for both comparisons, $<=$ 0.003). These two-way pharmacokineticinteractions between clarithromycin and rifabutin are consistentwith the ability of rifabutin to induce clarithromycin metabolismand, conversely, the inhibitory effect of clarithromycin on rifabutinmetabolism. The observed time course for the clarithromycin AUC_0-12reduction, which was not appreciable at day 15 but which was highlysignificant at day 42, is consistent with cytochrome P-450 enzymeinduction by rifabutin. The increase in the 14-OH-clarithromycinAUC_0-12 was also only apparent at day 42, further supportingan enzyme induction mechanism. Rifabutin levels increased significantlyfollowing the administration of a single clarithromycin dose,and most of the change between days 14 and 42 (60%) occurred betweendays 14 and 15. This finding is consistent with clarithromycininhibition of enzyme metabolism. The identity of the responsibleenzymes is in question. While evidence from one in vitro studyindicates that CYP3A4 has a major role (20), other evidenceindicates that rifabutin is not metabolized by CYP3A4 (39).

The mean percent increases in the 25-O-desacetyl-rifabutin metabolite AUC_0-24 observed between days 14 and 42 were greaterthan the mean increases in the rifabutin AUC_0-24 over thesame time periods, suggesting that the enzyme responsible forconversion of rifabutin to the 25-O-desacetyl metabolite is notinhibited. In addition, this finding also suggests that clarithromycininhibits conversion of the parent compound to alternative primarymetabolites and the further metabolism of 25-O-desacetyl-rifabutin(for example, by inhibiting conversion of both the parent and25-O-desacetyl forms to their 31-hydroxy metabolites) (11).

The data indicating decreased clarithromycin levels at day 42 were consistent among all except one of the regimen A subjects;for one subject the clarithromycin AUC_0-12 had increasedby 57% at day 42. The AUC change for this subject cannot be explainedby concomitant medications (i.e., fluconazole use predated studyentry), but additional doses of clarithromycin may have been taken.An increase in rifabutin levels at day 42 was a consistent findingfor all regimen B subjects except one subject for whom the AUCdecreased by 39%. The day 14, day 21, and day 42 trough levelsfor this subject were 0.144 µg/ml 0.341 µg/ml, and undetectable(<0.050 µg/ml), respectively, suggesting decreased compliancewith the study drug regimen prior to the final pharmacokineticsampling session. Both subjects with atypical AUC changes reportedexcellent compliance. These outlying results lessen the magnitudeof the pharmacokinetic interaction estimates and suggest thatthe observed mean changes in AUC_0- are conservativeestimates. The day 42 AUC values for both the drugs and the measuredmetabolites were not significantly different when the AUCs forsubjects receiving regimen A (clarithromycin initiated first)and those receiving regimen B (rifabutin initiated first) werecompared. This indicates that steady-state values had been reachedby day 42 and that the order of addition of these drugs did notaffect their pharmacokinetic disposition at steady state (allP values were $>=$ 0.120); i.e., no period effect was apparent.

There have been several reports of uveitis occurring in patients receiving rifabutin, usually at dosages of $>=$ 450 mg/day andoften in combination with clarithromycin (13, 14, 30, 35,36). Preliminary data from trial ACTG 196/CPCRA 009, a randomizedcomparison of clarithromycin, rifabutin, and the combination forprophylaxis of MAC infection, support a specific association ofuveitis with this drug combination. In the preliminary analysisof 1,178 eligible patients, uveitis occurred in 23 patients initiallyassigned to the combination of clarithromycin (500 mg twice daily)and rifabutin (450 mg daily, which was later reduced to 300 mgdaily) and in 5 patients assigned to rifabutin and 2 patientsassigned to clarithromycin at the same doses (13). No episodesof uveitis were reported for volunteers in the present study,but uveitis has been most commonly reported after receiving atleast 4 weeks of combination therapy and appears to be very infrequentin patients receiving rifabutin at dosages of $<=$ 300 mg/day in combinationwith clarithromycin.

The exact mechanism of this adverse event is unknown (30). The possible relationship between the concentrations of the parentcompound and its metabolite in plasma and adverse reactions, particularlyuveitis and polyarthritis, require further investigation. Previously,uveitis had been reported in subjects receiving $>=$ 1,800 mg of rifabutinalone in a dose-escalating tolerance and pharmacokinetic study(36), suggesting that uveitis may be related to high concentrationsof rifabutin or its metabolites in plasma. If this hypothesisis correct, the increased levels of rifabutin and its 25-O-desacetylmetabolite occurring in the presence of clarithromycin, as documentedby this study, could explain the increased risk of uveitis associatedwith combination therapy. Alternatively, but less likely, uveitismay be due to increases in the levels of other rifabutin metabolitesproduced as a consequence of this pharmacokinetic interactionor enhancement of a toxic rifabutin effect by clarithromycin orits metabolites.

Only a small minority of the patients who receive combination therapy including rifabutin at dosages of less than 600 mg andclarithromycin develop uveitis. Considerable intersubject variabilitywas noted in this study. The increase in the rifabutin AUC_0-24was greater than 150% for 5 of the 14 regimen B subjects, andfor 2 of those the increase was greater than 200%. Increases inthe 25-O-desacetyl rifabutin AUC_0-24 were greater than 600%for three subjects. The patients experiencing the most substantialincreases in rifabutin and 25-O-desacetyl rifabutin AUC_0-24values during combination therapy may be at the highest risk foruveitis.

Antifungal azoles are a class of drugs likely to have significant pharmacokinetic interactions with rifabutin and clarithromycin.A pharmacokinetic interaction between rifabutin and fluconazolehas been reported (40). While rifabutin levels may be significantlyincreased in the presence of fluconazole, a specific relationshipbetween the concomitant use of azoles and rifabutin and an increasedrisk of uveitis in the absence of clarithromycin has not beenestablished. It also remains to be determined if the inhibitoryeffects of azoles and clarithromycin on rifabutin metabolism areadditive. The data for the study volunteers who received azolesdo not appear to differ from those for the remaining subjects,but a formal assessment of any additive effect was not possible.Whether concurrent therapy with fluconazole and other azoles wouldalso alter the plasma concentration-time profile of clarithromycinor its metabolites requires further study, given the frequentuse of systemic antifungal therapy in this population.

The decreased levels of clarithromycin could diminish the expected clinical efficacy of combination therapy, because in vitrostudies supporting the increased activity of this combinationdid not take into account the observed decrease in clarithromycinconcentrations. If the decrease in clarithromycin levels resultsin diminished clinical antimycobacterial activity, the concurrentincrease in the levels of the 14-OH-clarithromycin metabolitewill not provide significant compensatory activity. The mean increasein the metabolite AUC_0-12 was 4.3 mg · h/ml, while the meandecrease in the clarithromycin AUC_0-12 was 19.9 mg · h/ml.Also, the 14-hydroxy metabolite is approximately eightfold lessactive than the parent compound against MAC in vitro (19). Tocompensate for this interaction, the dosage of clarithromycincould be increased when it is used in combination with rifabutin.However, a higher clarithromycin dosage could exacerbate GI intoleranceand may cause a further increase in the concentrations of rifabutinand its metabolites, possibly resulting in a higher incidenceof uveitis. Furthermore, in treatment studies comparing the standarddosage of clarithromycin (500 mg twice daily) with higher dosagesof clarithromycin (either alone or in combination regimens) forthe treatment of disseminated MAC, patients assigned to the higher-dosetreatment arms had poorer survival rates (8, 12). It is impossibleto determine at this time whether the pharmacokinetic interactionbetween clarithromycin and rifabutin would have an effect on thepoorer survival rate. Until this is further defined, clarithromycineither alone or in combination with rifabutin should not be administeredat a dosage of greater than 500 mg twice daily for the treatmentof MAC infection.

This study does not support the use of clarithromycin and rifabutin in combination for MAC prophylaxis. Combination of thesedrugs results in a high frequency of adverse events and bidirectionalpharmacokinetic interactions. The results of the ACTG 196/CPCRA009 study comparing clarithromycin, rifabutin, and the combinationfor MAC prophylaxis indicated that the use of the combinationdid not increase efficacy and caused more toxicity compared tothe use of clarithromycin alone (13). The reduction of plasmaclarithromycin levels due to pharmacokinetic interaction withrifabutin is a possible explanation for the lack of additionalefficacy for this drug combination. In contrast, a large randomizedstudy comparing rifabutin (300 mg/day), azithromycin (1,200 mg/week),and the combination of both demonstrated that the azithromycin-containingregimens were more effective than those containing rifabutin aloneand that the combination regimen was significantly more effectivethan azithromycin alone for the prevention of disseminated MACinfection (16). One explanation for the enhanced effectivenessof azithromycin and rifabutin in combination may be that azithromycindoes not undergo metabolism and therefore rifabutin does not reduceazithromycin levels (1, 29). The investigators cautionedthat use of the azithromycin and rifabutin combination may belimited by its significantly poorer tolerance and increased costand rifabutin's pharmacokinetic interactions with medicationscommonly used concomitantly (16). Considering the results ofthese trials, monotherapy either with clarithromycin or with azithromycinonce weekly is recommended as first choice for MAC prophylaxis(7).

The introduction of protease inhibitors for HIV therapy has led to additional concerns regarding the choice of drugs for MACprophylaxis. Rifabutin increases the metabolism of protease inhibitors(21), protease inhibitors significantly inhibit rifabutin metabolism(6), and with concomitant use, adjustment of the rifabutindosage is necessary to prevent increased adverse events (7,21). While protease inhibitors inhibit the metabolism of clarithromycin,the clinical significance of this interaction is unknown, anddose adjustment is not advised (7, 33). Because azithromycinis not significantly metabolized and is not known to inhibit themetabolism of other drugs, pharmacokinetic interactions with theprotease inhibitors are unlikely (1, 29). The occurrenceof clinically significant pharmacokinetic interactions betweenrifabutin and protease inhibitors further support the use of clarithromycinor azithromycin alone for MAC prophylaxis.

	ACKNOWLEDGMENTS

This study was supported by the Division of AIDS Treatment Research Initiative Program, National Institutes of Allergy andInfectious Diseases, National Institutes of Health, Bethesda,Md (contract NO1-AI-15123).

We thank the volunteers for participating in this study; Carol Braun Trapnell (Food and Drug Administration, Rockville, Md.),P. K. Narang (Pharmacia & Upjohn), and Sheri Crampton (AbbottLaboratories) for helpful review and comments during the conductand analysis of the study; Beverly B. Barber (Denver Disease ControlService and University of Colorado Health Sciences Center, Denver)and Stephanie LaCarruba (Davies Medical Center, San Francisco,Calif.) for clinical support in conducting this study; AngelaShaver (McKesson Bioservices, Rockville, Md.) for managing theinvestigational drug supplies; Suzanne Beckner (Westat, Rockville,Md.); and Jean King, Theresa Straut, and Mary Enama (Social &Scientific Systems, Inc., Rockville, Md.) for assisting in manuscriptpreparation.

	FOOTNOTES

^* Corresponding author. Mailing address: Division of AIDS, NIAID, 6003 Executive Blvd., Room 2B35, Rockville, MD 20852-7620.Phone: (301) 402-2304. Fax: (301) 402-3171. E-mail: rh23v{at}nih.gov.

Study DATRI 001 of the Division of AIDS Treatment Research Initiative.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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1.	Amsden, G. W. 1995. Macrolides versus azalides: a drug interaction update. Ann. Pharmacother. 29:906-917[Abstract].
2.	Barradell, L. B., G. L. Plosker, and D. McTabish. 1993. Clarithromycin, a review of its pharmacological properties and therapeutic use in Mycobacterium avium-intracellulare complex infection in patients with acquired immune deficiency syndrome. Drugs 46:289-312[Medline].
3.	Benson, C. 1994. Disseminated Mycobacterium avium complex disease in patients with AIDS. AIDS Res. Hum. Retroviruses 10:913-916[Medline].
4.	Benson, C. A., and J. J. Ellner. 1993. Mycobacterium avium complex infection and AIDS: advances in theory and practice. Clin. Infect. Dis. 17:7-20[Medline].
5.	Brogden, R. N., and A. Fitton. 1994. Rifabutin: a review of its antimicrobial activity, pharmacokinetic properties and therapeutic efficacy. Drugs 47:983-1009[Medline].
6.	Cato, A., J. H. Cavanaugh, H. Shi, A. Hsu, G. R. Granneman, and J. Leonard. 1996. Assessment of multiple dose of ritonavir on the pharmacokinetics of rifabutin, abstr. Mo.B1199. In XI International Conference on AIDS.
7.	Centers for Disease Control and Prevention. 1997. 1997 USPHS/IDSA guidelines for the prevention of opportunistic infections in persons with human immunodeficiency virus. Morbid. Mortal. Weekly Rep. 46:12-13.
8.	Chaisson, R. E., C. A. Benson, M. P. Dube, L. B. Heifets, J. A. Korvick, S. Elkin, T. Smith, J. C. Craft, F. R. Sattler, and the AIDS Clinical Trials Group Protocol 157 Study Team. 1994. Clarithromycin therapy for bacteremic Mycobacterium avium complex disease. Ann. Intern. Med. 121:905-911[Abstract/Free Full Text].
9.	Chu, S., D. S. Wilson, R. L. Deaton, A. V. Mackenthum, C. N. Eason, and J. H. Cavanaugh. 1993. Single- and multiple-dose pharmacokinetics of clarithromycin, a new macrolide antimicrobial. J. Clin. Pharmacol. 33:719-726[Abstract].
10.	Chu, S. Y., L. T. Sennello, and R. C. Sonders. 1991. Simultaneous determinations of clarithromycin and 14(R)-hydroxyclarithromycin in plasma and urine using high performance liquid chromatography with electrochemical detection. J. Chromatogr. 571:199-208[Medline].
11.	Cocchiara, G., B. M. Strolin, G. P. Vicario, M. Ballabio, B. Gioia, S. Vioglio, and A. Vigevani. 1989. Urinary metabolites of rifabutin, a new antimycobacterium agent, in human volunteers. Xenobiotica 19:769-780[Medline].
12.	Cohn, D., E. Fischer, B. Franchino, G. Peng, J. Hodges, J. Chesnut, C. Child, C. Gilbert, W. El-Sadr, R. Hafner, M. Ropka, L. Heifets, J. Clotfelter, D. Munroe, R. Caldwell, R. Horsburgh, and the CPCRA 027 Protocol Team. 1997. A prospective, randomized trial of four 3-drug regimens for treatment (Rx) of disseminated MAC disease in AIDS (DM): excess mortality associated with high-dose clarithromycin, abstr. 659. In 4th Conference on Retroviruses and Opportunistic Infections.
13.	Cohn, D. L., C. A. Benson, P. Williams, P. T. Nevin, J. Korvick, R. Hafner, D. Bourland, E. Kopek, S. Becker, P. Hojczyk, P. Timmons, and C. Child. 1996. A prospective, randomized, double-blind, comparative study of the safety and efficacy of clarithromycin (CLA) vs rifabutin (RBT) vs the combination for the prevention of mycobacterium avium complex (MAC) bacteremia or disseminated MAC disease (DMAC) in HIV-infected patients (pts) with CD4 counts less than or equal to 100 cells/mm³, abstr. We.B.421. In XI International Conference on AIDS.
14.	Frank, M. O., M. B. Graham, and B. Wispelway. 1994. Rifabutin and uveitis. N. Engl. J. Med. 330:868[Free Full Text].
15.	Gustavson, L. E., K. S. Blahunkg, G. F. Witt, S. I. Harris, and R. N. Palmer. 1993. Evaluation of the pharmacokinetic drug interaction between terfenadine and clarithromycin. Pharm. Res. 10:S311. (Abstract.)
16.	Havlir, D. V., M. P. Dube, F. R. Sattler, D. N. Forthal, C. A. Kemper, M. W. Dunne, D. M. Parenti, J. P. Lavelle, A. C. White, Jr., M. D. Witt, S. A. Bozzette, and J. A. McCutchan for the California Collaborative Treatment Group. 1996. Prophylaxis against disseminated Mycobacterium avium complex with weekly azithromycin, daily rifabutin, or both. N. Engl. J. Med. 335:392-398[Abstract/Free Full Text].
17.	Heifets, L. B. 1996. Clarithromycin against Mycobacterium avium complex infections. Clarithromycin against Mycobacterium avium complex infections. Tubercle Lung Dis. 77:19-26[Medline].
18.	Heifets, L. B., M. D. Iseman, P. J. Lindholm-Levy, and W. Kanes. 1985. Determination of ansamycin MICs for Mycobacterium avium complex in liquid medium by radiometric and conventional methods. Antimicrob. Agents Chemother. 28:570-575[Abstract/Free Full Text].
19.	Heifets, L. B., P. J. Lindholm-Levy, and R. D. Comstock. 1992. Clarithromycin minimal inhibitory and bactericidal concentrations against Mycobacterium avium. Am. Rev. Respir. Dis. 145:856-858[Medline].
20.	Iatsimirskaia, E., S. Tulebaev, E. Storozhuk, I. Utkin, D. Smith, N. Gerber, and T. Koudriakova. 1997. Metabolism of rifabutin in human enterocyte and liver microsomes: kinetic parameters, identification of enzyme systems, and drug interactions with macrolides and antifungal agents. Clin. Pharmacol. Ther. 61:554-562[Medline].
21.	Indinavir Pharmacokinetics Study Group. 1996. Indinavir (MK639) drug interaction studies, abstr Mo.B174. In XI International Conference on AIDS.
22.	Jurima-Romet, M., K. Crawford, T. Cyr, and T. Inaba. 1994. Terfenadine metabolism in human liver. In vitro inhibition by macrolide antibiotics and azole antifungals. Drug Metab. Dispos. 22:849-857[Abstract].
23.	Kent, R. J., M. Bakhtiar, and D. C. Shanson. 1992. The in-vitro bactericidal activities of combinations of antimicrobial agents against clinical isolates of Mycobacterium avium-intracellulare. J. Antimicrob. Chemother. 30:643-650[Abstract/Free Full Text].
24.	Klemens, S. P., M. S. DeStefano, and M. H. Cynamon. 1992. Activity of clarithromycin against Mycobacterium avium complex infection in beige mice. Antimicrob. Agents Chemother. 36:2413-2417[Abstract/Free Full Text].
25.	Lewis, R. C., N. Z. Hatfield, and P. K. Narang. 1991. A sensitive method for quantitation of rifabutin and its desacetyl metabolite in human biological fluids by high-performance liquid chromatography (HPLC). Pharm. Res. 8:1434-1440[Medline].
26.	Mascellino, M. T., E. Iona, L. Fattorini, P. De Gregoris, C. Q. Hu, C. Santoro, and G. Orefici. 1991. In vitro activity of clarithromycin alone or in combination with other antimicrobial agents against Mycobacterium avium-intracellulare. Complex strains isolated from AIDS patients. J. Chemother. 3:357-362[Medline].
27.	Mor, N., J. Vanderkolk, N. Mezo, and L. Heifets. 1994. Effects of clarithromycin and rifabutin alone and in combination on intracellular and extracellular replication of Mycobacterium avium. Antimicrob. Agents Chemother. 38:2738-2742[Abstract/Free Full Text].
28.	Moro, E., M. F. Benedetti, A. Fanfani, and M. G. Jannuzzo. 1989. Autoinduction of rifabutin metabolism in man, abstr. In Fifth International Congress of Toxicology.
29.	Nahata, M. 1996. Drug interactions with azithromycin and the macrolides: an overview. J. Antimicrob. Chemother. 37(Suppl. C):133-142.
30.	Nichols, C. W. 1996. Mycobacterium avium complex infection, rifabutin, and uveitis $---$ is there a connection? Clin. Infect. Dis. 22:S43-S47.
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