HIV and tuberculosis coinfection : drug interaction

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Overview

Worldwide, tuberculosis is the most common opportunistic infection among people with HIV infection. In addition to its frequency, tuberculosis is also associated with substantial morbidity and mortality. Despite the complexities of treating two infections requiring multidrug therapy at the same time, antiretroviral therapy can be life-saving among patients with tuberculosis and advanced HIV disease. Observational studies in a variety of settings have shown that use of antiretroviral therapy during tuberculosis treatment results in marked decreases in the risk of death or other opportunistic infections among persons with tuberculosis and advanced HIV disease.[1][2]

Concomitant use of treatment for tuberculosis and antiretroviral therapy is complicated by the adherence challenge of polypharmacy, overlapping side effect profiles of antituberculosis drugs and antiretroviral drugs, immune reconstitution inflammatory syndrome, and drug-drug interactions.[3] The key interactions, and the focus of this chapter, are those between the rifamycin antibiotics and four classes of antiretroviral drugs: Protease inhibitors, Nucleoside reverse transcriptase inhibitors (NRTI), CCR5-inhibitors, and integrase inhibitor [3]

Only two of the currently available antiretroviral drug classes, the nucleoside analogues (other than zidovudine[4]) and enfuvirtide (a parenteral entry inhibitor) do not have significant interactions with the rifamycins.

The Role of Rifamycins in Tuberculosis Treatment

Despite the complexity of these drug interactions, the key role of the rifamycins in the success of tuberculosis treatment mandates that the drug-drug interactions between the rifamycins and antiretroviral drugs be managed, not avoided by using tuberculosis treatment regimens that do not include a rifamycin or by withholding antiretroviral therapy until completion of anti-tuberculosis therapy among patients with advanced immunodeficiency.

In randomized trials, regimens without rifampin or in which rifampin was only used for the first two months of therapy resulted in higher rates of tuberculosis treatment failure and relapse.[5][6] The sub-optimal performance of the regimen of two months of rifampin (with isoniazid, pyrazinamide, and ethambutol) followed by 6 months of isoniazid + ethambutol was particularly notable among participants with HIV co-infection.[5] Therefore, patients with HIV-related tuberculosis should be treated with a regimen including a rifamycin for the full course of tuberculosis treatment, unless the isolate is resistant to the rifamycins or the patient has a severe side effect that is clearly due to the rifamycins.

Furthermore, patients with advanced HIV disease (CD4 cell count < 100 cells/mm3) have an increased risk of acquired rifamycin resistance if treated with a rifamycin-containing regimen administered once or twice-weekly.[1][7] The rifamycin-based regimen should be administered daily (5-7 days per week) for at least the first 2 months of treatment among patients with advanced HIV disease.[8][9]

Predicting Drug Interactions Involving Rifamycins

The rifamycin class upregulate (induce) the synthesis of several classes of drug transporting and drug metabolizing enzymes. With increased synthesis, there is increased total activity of the enzyme (or enzyme system), thereby decreasing the serum half-life and serum concentrations of drugs that are metabolized by that system. The most common locus of rifamycin interactions is the cytochrome P450 enzyme system, particularly the CYP3A4 and CYP2C8/9 isozymes. To a lesser extent, rifampin induces the activity of the CYP2C19 and CYPD6 isozymes. The rifamycins vary in their potential as CYP450 inducers, with rifampin being most potent, rifapentine intermediate, and rifabutin being much less active. Rifampin also upregulates the synthesis of cytosolic drug-metabolizing enzymes, including glucuronosyl transferase, an enzyme involved in the metabolism of zidovudine and raltegravir.[10]

Rifampin and Antiretroviral Therapy

The most important drug-drug interactions in the treatment of HIV-related tuberculosis are those between rifampin and the NNRTIs, efavirenz and nevirapine.

Rifampin is the only rifamycin available in most of the world and initial antiretroviral regimens in areas with high rates of tuberculosis consist of efavirenz or nevirapine (in combination with nucleoside analogues). Furthermore, because of its potency and durability on randomized clinical trials, efavirenz-based therapy is a preferred option for initial antiretroviral therapy in developed countries.

Rifampin and Efavirenz

Rifampin causes a measurable, though modest, decrease in efavirenz concentrations.[11][12] Increasing the dose of efavirenz from 600 mg daily to 800 mg daily compensates for the effect of rifampin[11][12] but it does not appear that this dose increase is necessary to achieve excellent virological outcomes of therapy. Trough concentrations of efavirenz, the best predictor of its virological activity, remain well above the concentration necessary to suppress HIV in vitro among patients on concomitant rifampin.[12]

Trough concentrations of efavirenz, the best predictor of its virological activity, remain well above the concentration necessary to suppress HIV in vitro among patients on concomitant rifampin.[13] A testament to the potency of efavirenz against HIV is that the standard dose of efavirenz results in very high rates of complete viral suppression despite 10-fold interpatient differences in trough concentrations. Therefore, it is unlikely that the 20% decrease in serum concentrations resulting from rifampin will have a clinically-significant effect on antiretroviral activity. In several cohort studies, antiretroviral therapy of standard-dose efavirenz + 2 nucleosides was well-tolerated and highly efficacious in achieving complete viral suppression among patients receiving concomitant rifampin-based tuberculosis treatment.[14][15] Furthermore, there was no apparent benefit from a higher dose of efavirenz (800 mg daily) in one randomized trial [12], and a small observational study documented high serum concentrations and neurotoxicity among 7 of 9 patients receiving the 800 mg dose with rifampin.[16] Therefore, this combination – efavirenz-based antiretroviral therapy and rifampin-based tuberculosis treatment, at their standard doses – is the preferred treatment for HIV-related tuberculosis. Some experts recommend the 800 mg dose of efavirenz for patients weighing > 60 kg.

Alternatives to Efavirenz-Based Antiretroviral Therapy

Alternatives to efavirenz-based antiretroviral therapy are needed for patients with HIV-related tuberculosis:efavirenz cannot be used during pregnancy (at least during the first trimester), some patients are intolerant to efavirenz, and some are infected with NNRTI-resistant strains of HIV.

Rifampin and Nevirapine

Rifampin decreases serum concentrations of nevirapine by 20-55%.[17][18] The common toxicities of nevirapine – skin rash and hepatitis – overlap common toxicities of some first-line anti-tuberculosis therapy. Furthermore, nevirapine-based regimens are not recommended for patients with higher CD4 cell counts (> 350 cells/mm3 for men, > 250 cells/mm3 for women) because of increased risk of severe hypersensitivity reactions. Therefore, there are concerns about the efficacy and safety of using nevirapine-based antiretroviral therapy during rifampin-based tuberculosis treatment.

At present, there have been no studies comparing efavirenz vs. nevirapine-based antiretroviral therapy among patients being treated for tuberculosis. Trough serum concentrations of nevirapine among patients on concomitant rifampin often exceed the concentration necessary to suppress HIV in vitro.[17][19] Several cohort studies have shown high rates of viral suppression among patients receiving nevirapine-based antiretroviral therapy.[17]

The risk of hepatitis among such patients was also comparable to patients receiving first-line tuberculosis treatment without antiretroviral therapy. Despite the interaction with rifampin, nevirapine-based antiretroviral therapy appears to be reasonably effective and well-tolerated among patients being treated for tuberculosis.

These studies are neither adequately powered nor reported in sufficient detail to fully answer the concerns about the efficacy and safety of nevirapine-based antiretroviral therapy during tuberculosis treatment. However, the collected experience is sufficient to make nevirapine an alternative for patients unable to take efavirenz and who do not have access to rifabutin. Some investigators have suggested using an increased dose of nevirapine among patients on rifampin.[18] However, a recent randomized trial comparing standard dose nevirapine (200 mg twice-daily) to a higher dose (300 mg twice daily) among patients on rifampin demonstrated an increased risk of nevirapine hypersensitivity among patients randomized to the higher dose of nevirapine.[20] Therefore, the standard dose of nevirapine should be used among patients on rifampin (200 mg daily for 2 weeks, followed by 200 mg twice-daily).

Other Antiretroviral Regimens for Use With Rifampin

For patients who are infected with NNRTI-resistant HIV, neither efavirenz nor nevirapine will be effective. Unfortunately, there is little clinical experience with alternatives to NNRTI-based therapy among patients being treated with rifampin. Standard doses of protease inhibitors cannot be given with rifampin; the > 90% decreases in trough concentrations of the protease inhibitors would surely make them ineffective.[21][22][23]

Most protease inhibitors are given with low-dose ritonavir (100-200 mg per dose of the other protease inhibitor). However, low-dose ritonavir does not overcome the effects of rifampin; serum concentrations of indinavir, lopinavir, and atazanavir were decreased by > 90% when given with the standard ritonavir boosting dose (100 mg) in the presence of rifampin [22][23][24], and a once-daily regimen of ritonavir-boosted saquinavir (saquinavir 1600 mg + ritonavir 200 mg) resulted in inadequate concentrations of saquinavir.[25][26] Therefore, standard protease inhibitor regimens, whether boosted or not, cannot be given with rifampin.

The dramatic effects of rifampin on serum concentrations of other protease-inhibitors can be overcome with high-doses of ritonavir (400 mg twice-daily, “super-boosted protease inhibitors”) or by doubling the dose of the co-formulated form of lopinavir/ritonavir. [22] However, high rates of hepatoxicity occurred among healthy volunteers treated with rifampin and ritonavir-boosted saquinavir (saquinavir 1000 mg + ritonavir 100 mg twice-daily)[27] and those treated with rifampin and lopinavir/ritonavir (either as lopinavir 400 mg + 400 mg ritonavir twice-daily or as lopinavir 800 mg + ritonavir 200 mg twice-daily) [22]

Whether patients with HIV-related tuberculosis will have the same high rates of hepatotoxicity when treated with super-boosted protease inhibitors or double-dose lopinavir/ritonavir has not been adequately studied. Among patients receiving rifampin-based tuberculosis treatment, the combination of ritonavir-boosted saquinavir (400 mg of each, twice daily) was not well-tolerated.[28] The initial positive experience with super-boosted lopinavir among young children (see below) suggests that these regimens may be tolerable and effective among at least some patients with HIV-related tuberculosis. However, these regimens should only be used with close clinical and laboratory monitoring for possible hepatoxicity, when there is a pressing need to start antiretroviral therapy.

Regimens composed entirely of nucleoside analogues are less active than combinations of two classes of antiretroviral drugs (e.g., NNRTI + nucleosides).[29] A regimen of zidovudine, lamivudine, and the nucleotide agent, tenofovir, has been reported to be active among patients on rifampin-based tuberculosis treatment.[30] However, this regimen has not been compared to standard initial antiretroviral therapy (e.g., efavirenz + 2 nucleosides). Finally, a quadruple regimen of zidovudine, lamivudine, abacavir, and tenofovir has been reported to be as active as an efavirenz-based regimen in an initial small trial.[31] While these regimens of nucleosides and nucleotides cannot be recommended as preferred therapy among patients receiving rifampin, their lack of predicted clinically-significant interactions with rifampin make them an acceptable alternative, for patients unable to take NNRTIs or those with NNRTI-resistant HIV.[30][32]

Rifampin has substantial interactions with the recently-approved CCR5-receptor antagonist, maraviroc. An increased dose of maraviroc has been recommended to allow concomitant use of rifampin and maraviroc, but there is no reported clinical experience with this combination. Rifampin decreases the trough concentrations of raltegravir, the recently-approved integrase inhibitor, by ~ 60%. Because the antiviral activity of raltegravir 200 mg twice daily was very similar to the activity of the licensed dose (400 mg twice-daily), the current recommendation is to use the standard dose of raltegravir in a patient receiving concomitant rifampin. However, this combination should be used with caution – there is very little clinical experience with using concomitant raltegravir and rifampin. Finally, rifampin is predicted to substantially decrease the concentrations of etravirine (a second-generation NNRTI currently available through an expanded access program).[33] Additional drug-interaction studies will be needed to further evaluate whether these new agents can be used among patients receiving rifampin-based tuberculosis treatment.

Rifabutin and Antiretroviral Drugs

Rifabutin is as effective for tuberculosis treatment as rifampin,[34][35] but has much less effect on drugs metabolized through the CYP3A system.[36] However, rifabutin is either not available or is very expensive in countries with high rates of HIV-related tuberculosis. Furthermore, some antiretroviral drugs have a substantial effect on rifabutin concentrations, necessitating somewhat complex dosing guidelines for rifabutin in the setting of antiretroviral therapy. In addition to their complexity, there is another potential problem of using rifabutin for tuberculosis treatment. If a patient whose rifabutin dose was decreased in response to antiretroviral therapy then stops taking the interacting drug (e.g., ritonavir), the resulting rifabutin concentrations are likely to be sub-therapeutic. These factors, in addition to the limited availability of the drug, limit the use of rifabutin in the treatment of HIV-related tuberculosis.

Rifabutin and Protease Inhibitors

Rifabutin has little, if any effect on the serum concentrations of protease-inhibitors (other than unboosted saquinavir).[21] Cohort studies have shown favorable virological and immunological outcomes of protease-inhibitor-based antiretroviral therapy in the setting of rifabutin-based tuberculosis treatment. [1][37] Though no comparative studies have been done, the combination of rifabutin (if available) with protease-inhibitor based antiretroviral therapy is the preferred form of therapy for patients unable to take NNRTI-based antiretroviral therapy. As above, there are concerns about the safety of super-boosted protease-inhibitors and the efficacy of nucleoside-only regimens in the setting of rifampin-based tuberculosis treatment.

The protease-inhibitors, particularly if pharmacologically boosted with ritonavir, markedly increase serum concentrations and toxicity of rifabutin. Therefore, the dose of rifabutin should be decreased when used with protease-inhibitors. As above, the decreased dose of rifabutin would be sub-therapeutic if the patient stopped taking the protease-inhibitor without adjusting the rifabutin dose. Therefore, adherence to the protease-inhibitor should be assessed with each dose of directly observed tuberculosis treatment; one convenient way to do so is to give a supervised dose of protease-inhibitor at the same time as the directly observed dose of tuberculosis treatment.

Special Populations

Pregnant Women

A number of issues complicate the treatment of the HIV-infected woman who is pregnant and has active tuberculosis. Efavirenz is contraindicated during at least the first 1-2 trimesters. Furthermore, pregnant women have an increased risk of severe toxicity from didanosine and stavudine,[38] and women with CD4 cell counts > 250 cells/mm3 have an increased risk of nevirapine-related hepatitis.[39] Therefore, the choice of antiretroviral agents is limited among pregnant women.

Pregnancy alters the distribution and metabolism of a number of drugs, including antiretroviral drugs. Still very little information is available, whether the metabolism of anti-tuberculosis drugs is altered during pregnancy. Notably, the serum concentrations of protease-inhibitors are decreased during the latter stages of pregnancy.[40][41] There are no published data on drug-drug interactions between anti-tuberculosis and antiretroviral drugs among pregnant women. However, it is likely that the effects of rifampin on protease inhibitors are exacerbated during pregnancy.

  • Nevirapine-based therapy :
    • could be used among women on rifampin-based tuberculosis treatment, with the caveat that there be a good monitoring system for symptoms and laboratory tests for hepatotoxicity.
  • Efavirenz-based therapy :
    • may be an option during the later stages of pregnancy.
  • The quadruple nucleoside/nucleotide regimen :
    • zidovudine, lamivudine, abacavir, and tenofovir is an alternative, though additional experience is required, particularly during pregnancy.
  • Protease-inhibitor-based antiretroviral therapy :
    • The preferred option Where rifabutin is available.

Finally, despite their sub-optimal activity, triple nucleoside or nucleoside/nucleotide regimens are an alternative during pregnancy.

Children

HIV-infected children in high-burden countries have very high rates of tuberculosis, often with severe, life-threatening manifestations (e.g., disseminated disease, meningitis). Such children may also have advanced and rapidly-progressive HIV disease, so there are pressing reasons to assure potent treatment for both tuberculosis and AIDS. In addition to the complexities raised by the drug interactions discussed above, children with HIV-related tuberculosis raise other challenges. There are very limited data on the absorption, metabolism, and elimination of anti-tuberculosis drugs among children, particularly among very young children (< 2 years of age).

Some antiretroviral agents are not yet available in suspension formulations, and there are limited pharmacokinetic data for all antiretroviral drugs among young children. The use of single-dose nevirapine selects for NNRTI-resistant strains among those infants who are infected despite perinatal prophylaxis, and such children have inferior outcomes if subsequently treated with nevirapine-based combination antiretroviral therapy.[42] Therefore, there is understandable reluctance to use NNRTI-based therapy among perinatally-infected infants who were exposed to single-dose nevirapine. As above, the inability to use NNRTI-based antiretroviral therapy limits options for antiretroviral therapy among children receiving rifampin-based tuberculosis treatment.

There are emerging, though unpublished, pharmacokinetic data and clinical experience with using protease-inhibitor-based antiretroviral therapy among young children with HIV-related tuberculosis. Children treated with super-boosted lopinavir while on rifampin-based tuberculosis treatment had serum concentrations of lopinavir comparable to those of children treated with standard dose lopinavir/ritonavir in the absence of rifampin. Furthermore, a cohort study found similar virological and immunological outcomes of antiretroviral therapy among children treated with super-boosted lopinavir and rifampin-based tuberculosis treatment compared with children treated with standard dose lopinavir/ritonavir. Therefore, super-boosted lopinavir plus appropriate nucleoside agents is the preferred antiretroviral regimen among children on rifampin-based tuberculosis treatment.

The triple nucleoside regimen of zidovudine, lamivudine, and abacavir has been suggested for young children who are taking rifampin-based tuberculosis treatment.[43] However, there is limited published clinical experience with this regimen among young children, with or without concomitant tuberculosis. Furthermore, young children often have very high HIV RNA levels, suggesting the need for highly-potent antiretroviral regimens. While awaiting additional studies, the triple-nucleoside regimen is an alternative for young children receiving rifampin-based tuberculosis treatment.

In an initial pharmacokinetic study, efavirenz concentrations were not significantly different among children on rifampin, compared to children without tuberculosis. However, efavirenz concentrations were sub-optimal in both groups, raising concerns about the adequacy of current efavirenz dosing recommendations among children.[44] However, Efavirenz-based antiretroviral therapy is highly-active among older children,[45] and can be used with rifampin-based tuberculosis treatment.[46]

Patients with Multidrug-Resistant Tuberculosis

Outbreaks of multidrug-resistant tuberculosis among HIV-infected patients have been documented since the 1980s. Recently an outbreak of highly-lethal multidrug-resistant tuberculosis was discovered in South Africa, primarily involving HIV-infected patients.[47] Prompt initiation of antiretroviral therapy may be one way to decrease the alarmingly high death rate among HIV-infected patients with multidrug-resistant tuberculosis.

Most of the drugs used to treat multidrug-resistant tuberculosis (the second-line drugs: fluoroquinolone antibiotics, ethionamide, cycloserine, kanamycin, amikacin, capreomycin, para-amino salicylate) were developed and approved nearly 40 years ago. They were developed prior to the development of modern laboratory techniques to determine pathways of drug metabolism. Furthermore, there are no published studies of possible drug-drug interactions between second-line antituberculosis drugs and antiretroviral drugs. Based on the existing, albeit incomplete, knowledge of the metabolism of the second-line drugs, only ethionamide has a significant possibility of an interaction with antiretroviral drugs (ethionamide is thought to be metabolized by the CYP450 system, though it is not known which of the CYP isozymes are responsible).[21] Whether doses of ethionamide and/or certain antiretroviral drugs should be modified during the co-treatment of multidrug-resistant tuberculosis and HIV disease is completely unknown.

Limitations of these Guidelines

CDC mentioned the limitations of the information available for writing these guidelines.

  • First, drug-drug interaction studies are often done among healthy volunteers. While such studies reliably predict the nature of a drug-drug interaction (e.g., that rifampin decreases the serum concentrations of efavirenz) , they seldom provide the optimal management of that interaction among patients with HIV-related tuberculosis.
  • Second, rates of drug metabolism often differ markedly between individuals, and part of that variance may be due to genetic polymorphisms in drug-metabolizing enzymes. Therefore, drug interactions and their relevance may not be the same in different populations.
  • Third, in the attempt to provide the most up-to-date information we include studies that have been presented at international conferences, but that have not yet completed the peer review process and been published.
  • Fourth, it is very difficult to predict the outcome of complex drug interactions, such as those that might occur when three drugs with CYP3A activity are used together (e.g.,rifabutin, atazanavir and efavirenz).
  • Finally, in the Special Populations section, we highlighted the lack of pharmacokinetic data on two key populations of patients with HIV-related tuberculosis – pregnant women and children.

Related Chapters

Reference

  1. 1.0 1.1 1.2 Burman W, Benator D, Vernon A, Khan A, Jones B, Silva C, Lahart C, Weis S, King B, Mangura B, Weiner M, El-Sadr W (2006). "Acquired rifamycin resistance with twice-weekly treatment of HIV-related tuberculosis". Am. J. Respir. Crit. Care Med. 173 (3): 350–6. doi:10.1164/rccm.200503-417OC. PMID 16109981. Retrieved 2012-04-03. Unknown parameter |month= ignored (help)
  2. Hung CC, Chen MY, Hsiao CF, Hsieh SM, Sheng WH, Chang SC (2003). "Improved outcomes of HIV-1-infected adults with tuberculosis in the era of highly active antiretroviral therapy". AIDS. 17 (18): 2615–22. doi:10.1097/01.aids.0000088220.77946.19. PMID 14685055. Retrieved 2012-04-03. Unknown parameter |month= ignored (help)
  3. 3.0 3.1 Burman WJ (2005). "Issues in the management of HIV-related tuberculosis". Clin. Chest Med. 26 (2): 283–94, vi–vii. doi:10.1016/j.ccm.2005.02.002. PMID 15837111. Retrieved 2012-04-03. Unknown parameter |month= ignored (help)
  4. Burger DM, Meenhorst PL, Koks CH, Beijnen JH (1993). "Pharmacokinetic interaction between rifampin and zidovudine". Antimicrob. Agents Chemother. 37 (7): 1426–31. PMC 187988. PMID 8363370. Retrieved 2012-04-03. Unknown parameter |month= ignored (help)
  5. 5.0 5.1 Jindani A, Nunn AJ, Enarson DA (2004). "Two 8-month regimens of chemotherapy for treatment of newly diagnosed pulmonary tuberculosis: international multicentre randomised trial". Lancet. 364 (9441): 1244–51. doi:10.1016/S0140-6736(04)17141-9. PMID 15464185. Retrieved 2012-04-03.
  6. Okwera A, Whalen C, Byekwaso F, Vjecha M, Johnson J, Huebner R, Mugerwa R, Ellner J (1994). "Randomised trial of thiacetazone and rifampicin-containing regimens for pulmonary tuberculosis in HIV-infected Ugandans. The Makerere University-Case Western University Research Collaboration". Lancet. 344 (8933): 1323–8. PMID 7526098. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  7. Nettles RE, Mazo D, Alwood K, Gachuhi R, Maltas G, Wendel K, Cronin W, Hooper N, Bishai W, Sterling TR (2004). "Risk factors for relapse and acquired rifamycin resistance after directly observed tuberculosis treatment: a comparison by HIV serostatus and rifamycin use". Clin. Infect. Dis. 38 (5): 731–6. doi:10.1086/381675. PMID 14986259. Retrieved 2012-04-03. Unknown parameter |month= ignored (help)
  8. "Acquired rifamycin resistance in persons with advanced HIV disease being treated for active tuberculosis with intermittent rifamycin-based regimens". MMWR Morb. Mortal. Wkly. Rep. 51 (10): 214–5. 2002. PMID 11922192. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  9. Blumberg HM, Burman WJ, Chaisson RE, Daley CL, Etkind SC, Friedman LN, Fujiwara P, Grzemska M, Hopewell PC, Iseman MD, Jasmer RM, Koppaka V, Menzies RI, O'Brien RJ, Reves RR, Reichman LB, Simone PM, Starke JR, Vernon AA (2003). "American Thoracic Society/Centers for Disease Control and Prevention/Infectious Diseases Society of America: treatment of tuberculosis". Am. J. Respir. Crit. Care Med. 167 (4): 603–62. doi:10.1164/rccm.167.4.603. PMID 12588714. Retrieved 2012-04-03. Unknown parameter |month= ignored (help)
  10. Gallicano KD, Sahai J, Shukla VK, Seguin I, Pakuts A, Kwok D, Foster BC, Cameron DW (1999). "Induction of zidovudine glucuronidation and amination pathways by rifampicin in HIV-infected patients". Br J Clin Pharmacol. 48 (2): 168–79. PMC 2014298. PMID 10417493. Retrieved 2012-04-03. Unknown parameter |month= ignored (help)
  11. 11.0 11.1 López-Cortés LF, Ruiz-Valderas R, Viciana P, Alarcón-González A, Gómez-Mateos J, León-Jimenez E, Sarasanacenta M, López-Pua Y, Pachón J (2002). "Pharmacokinetic interactions between efavirenz and rifampicin in HIV-infected patients with tuberculosis". Clin Pharmacokinet. 41 (9): 681–90. PMID 12126459. Retrieved 2012-04-04.
  12. 12.0 12.1 12.2 12.3 Manosuthi W, Kiertiburanakul S, Sungkanuparph S, Ruxrungtham K, Vibhagool A, Rattanasiri S, Thakkinstian A (2006). "Efavirenz 600 mg/day versus efavirenz 800 mg/day in HIV-infected patients with tuberculosis receiving rifampicin: 48 weeks results". AIDS. 20 (1): 131–2. PMID 16327334. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  13. Manosuthi W, Sungkanuparph S, Thakkinstian A, Vibhagool A, Kiertiburanakul S, Rattanasiri S, Prasithsirikul W, Sankote J, Mahanontharit A, Ruxrungtham K (2005). "Efavirenz levels and 24-week efficacy in HIV-infected patients with tuberculosis receiving highly active antiretroviral therapy and rifampicin". AIDS. 19 (14): 1481–6. PMID 16135901. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  14. Sungkanuparph S, Manosuthi W, Kiertiburanakul S, Vibhagool A (2006). "Initiation of antiretroviral therapy in advanced AIDS with active tuberculosis: clinical experiences from Thailand". J. Infect. 52 (3): 188–94. doi:10.1016/j.jinf.2005.05.010. PMID 15992932. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  15. Patel A, Patel K, Patel J, Shah N, Patel B, Rani S (2004). "Safety and antiretroviral effectiveness of concomitant use of rifampicin and efavirenz for antiretroviral-naive patients in India who are coinfected with tuberculosis and HIV-1". J. Acquir. Immune Defic. Syndr. 37 (1): 1166–9. PMID 15319677. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  16. Brennan-Benson P, Lyus R, Harrison T, Pakianathan M, Macallan D (2005). "Pharmacokinetic interactions between efavirenz and rifampicin in the treatment of HIV and tuberculosis: one size does not fit all". AIDS. 19 (14): 1541–3. PMID 16135909. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  17. 17.0 17.1 17.2 Ribera E, Pou L, Lopez RM, Crespo M, Falco V, Ocaña I, Ruiz I, Pahissa A (2001). "Pharmacokinetic interaction between nevirapine and rifampicin in HIV-infected patients with tuberculosis". J. Acquir. Immune Defic. Syndr. 28 (5): 450–3. PMID 11744833. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  18. 18.0 18.1 Ramachandran G, Hemanthkumar AK, Rajasekaran S, Padmapriyadarsini C, Narendran G, Sukumar B, Sathishnarayan S, Raja K, Kumaraswami V, Swaminathan S (2006). "Increasing nevirapine dose can overcome reduced bioavailability due to rifampicin coadministration". J. Acquir. Immune Defic. Syndr. 42 (1): 36–41. doi:10.1097/01.qai.0000214808.75594.73. PMID 16639340. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  19. Autar RS, Wit FW, Sankote J, Mahanontharit A, Anekthananon T, Mootsikapun P, Sujaikaew K, Cooper DA, Lange JM, Phanuphak P, Ruxrungtham K, Burger DM (2005). "Nevirapine plasma concentrations and concomitant use of rifampin in patients coinfected with HIV-1 and tuberculosis". Antivir. Ther. (Lond.). 10 (8): 937–43. PMID 16430199. |access-date= requires |url= (help)
  20. Avihingsanon A, Manosuthi W, Kantipong P, Chuchotaworn C, Moolphate S, Sakornjun W, Gorowara M, Yamada N, Yanai H, Mitarai S, Ishikawa N, Cooper DA, Phanuphak P, Burger D, Ruxrungtham K (2008). "Pharmacokinetics and 48-week efficacy of nevirapine: 400 mg versus 600 mg per day in HIV-tuberculosis coinfection receiving rifampicin". Antivir. Ther. (Lond.). 13 (4): 529–36. PMID 18672531. |access-date= requires |url= (help)
  21. 21.0 21.1 21.2 Burman WJ, Gallicano K, Peloquin C (1999). "Therapeutic implications of drug interactions in the treatment of human immunodeficiency virus-related tuberculosis". Clin. Infect. Dis. 28 (3): 419–29, quiz 430. doi:10.1086/515174. PMID 10194057. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  22. 22.0 22.1 22.2 22.3 la Porte CJ, Colbers EP, Bertz R, Voncken DS, Wikstrom K, Boeree MJ, Koopmans PP, Hekster YA, Burger DM (2004). "Pharmacokinetics of adjusted-dose lopinavir-ritonavir combined with rifampin in healthy volunteers". Antimicrob. Agents Chemother. 48 (5): 1553–60. PMC 400571. PMID 15105105. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  23. 23.0 23.1 Burger DM, Agarwala S, Child M, Been-Tiktak A, Wang Y, Bertz R (2006). "Effect of rifampin on steady-state pharmacokinetics of atazanavir with ritonavir in healthy volunteers". Antimicrob. Agents Chemother. 50 (10): 3336–42. doi:10.1128/AAC.00461-06. PMC 1610067. PMID 17005814. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  24. Justesen US, Andersen AB, Klitgaard NA, Brøsen K, Gerstoft J, Pedersen C (2004). "Pharmacokinetic interaction between rifampin and the combination of indinavir and low-dose ritonavir in HIV-infected patients". Clin. Infect. Dis. 38 (3): 426–9. doi:10.1086/380794. PMID 14727216. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  25. Ribera E, Azuaje C, Lopez RM, Domingo P, Curran A, Feijoo M, Pou L, Sánchez P, Sambeat MA, Colomer J, Lopez-Colomes JL, Crespo M, Falcó V, Ocaña I, Pahissa A (2007). "Pharmacokinetic interaction between rifampicin and the once-daily combination of saquinavir and low-dose ritonavir in HIV-infected patients with tuberculosis". J. Antimicrob. Chemother. 59 (4): 690–7. doi:10.1093/jac/dkl552. PMID 17307771. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  26. Ribera E, Azuaje C, Lopez RM, Domingo P, Soriano A, Pou L, Sánchez P, Mallolas J, Sambea MA, Falco V, Ocaña I, Lopez-Colomes JL, Gatell JM, Pahissa A (2005). "Once-daily regimen of saquinavir, ritonavir, didanosine, and lamivudine in HIV-infected patients with standard tuberculosis therapy (TBQD Study)". J. Acquir. Immune Defic. Syndr. 40 (3): 317–23. PMID 16249706. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  27. "Drug-induced hepatitis with saquinavir/ritonavir + rifampin". AIDS Clin Care. 17 (3): 32. 2005. PMID 15828118. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  28. Rolla VC, da Silva Vieira MA, Pereira Pinto D, Lourenço MC, de Jesus Cda S, Gonçalves Morgado M, Ferreira Filho M, Werneck-Barroso E (2006). "Safety, efficacy and pharmacokinetics of ritonavir 400mg/saquinavir 400mg twice daily plus rifampicin combined therapy in HIV patients with tuberculosis". Clin Drug Investig. 26 (8): 469–79. PMID 17163279. Retrieved 2012-04-04.
  29. Gulick RM, Ribaudo HJ, Shikuma CM, Lustgarten S, Squires KE, Meyer WA, Acosta EP, Schackman BR, Pilcher CD, Murphy RL, Maher WE, Witt MD, Reichman RC, Snyder S, Klingman KL, Kuritzkes DR (2004). "Triple-nucleoside regimens versus efavirenz-containing regimens for the initial treatment of HIV-1 infection". N. Engl. J. Med. 350 (18): 1850–61. doi:10.1056/NEJMoa031772. PMID 15115831. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  30. 30.0 30.1 "Virological response to a triple nucleoside/nucleotide analogue regimen over 48 weeks in HIV-1-infected adults in Africa". AIDS. 20 (10): 1391–9. 2006. doi:10.1097/01.aids.0000233572.59522.45. PMID 16791013. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  31. Moyle G, Higgs C, Teague A, Mandalia S, Nelson M, Johnson M, Fisher M, Gazzard B (2006). "An open-label, randomized comparative pilot study of a single-class quadruple therapy regimen versus a 2-class triple therapy regimen for individuals initiating antiretroviral therapy". Antivir. Ther. (Lond.). 11 (1): 73–8. PMID 16518962. |access-date= requires |url= (help)
  32. Srikantiah P, Walusimbi MN, Kayanja HK, Mayanja-Kizza H, Mugerwa RD, Lin R, Charlebois ED, Boom WH, Whalen CC, Havlir DV (2007). "Early virological response of zidovudine/lamivudine/abacavir for patients co-infected with HIV and tuberculosis in Uganda". AIDS. 21 (14): 1972–4. doi:10.1097/QAD.0b013e32823ecf6e. PMID 17721107. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  33. Kakuda TN, Schöller-Gyüre M, Hoetelmans RM (2011). "Pharmacokinetic interactions between etravirine and non-antiretroviral drugs". Clin Pharmacokinet. 50 (1): 25–39. doi:10.2165/11534740-000000000-00000. PMID 21142266. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  34. Schwander S, Rüsch-Gerdes S, Mateega A, Lutalo T, Tugume S, Kityo C, Rubaramira R, Mugyenyi P, Okwera A, Mugerwa R (1995). "A pilot study of antituberculosis combinations comparing rifabutin with rifampicin in the treatment of HIV-1 associated tuberculosis. A single-blind randomized evaluation in Ugandan patients with HIV-1 infection and pulmonary tuberculosis". Tuber. Lung Dis. 76 (3): 210–8. PMID 7548903. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  35. Gonzalez-Montaner LJ, Natal S, Yongchaiyud P, Olliaro P (1994). "Rifabutin for the treatment of newly-diagnosed pulmonary tuberculosis: a multinational, randomized, comparative study versus Rifampicin. Rifabutin Study Group". Tuber. Lung Dis. 75 (5): 341–7. PMID 7841427. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  36. Perucca E, Grimaldi R, Frigo GM, Sardi A, Mönig H, Ohnhaus EE (1988). "Comparative effects of rifabutin and rifampicin on hepatic microsomal enzyme activity in normal subjects". Eur. J. Clin. Pharmacol. 34 (6): 595–9. PMID 2901960. |access-date= requires |url= (help)
  37. Narita M, Stambaugh JJ, Hollender ES, Jones D, Pitchenik AE, Ashkin D (2000). "Use of rifabutin with protease inhibitors for human immunodeficiency virus-infected patients with tuberculosis". Clin. Infect. Dis. 30 (5): 779–83. doi:10.1086/313771. PMID 10816148. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  38. Sarner L, Fakoya A (2002). "Acute onset lactic acidosis and pancreatitis in the third trimester of pregnancy in HIV-1 positive women taking antiretroviral medication". Sex Transm Infect. 78 (1): 58–9. PMC 1763698. PMID 11872862. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  39. Leith J, Piliero P, Storfer S, Mayers D, Hinzmann R (2005). "Appropriate use of nevirapine for long-term therapy". J. Infect. Dis. 192 (3): 545–6, author reply 546. doi:10.1086/431606. PMID 15995971. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  40. Nellen JF, Schillevoort I, Wit FW, Bergshoeff AS, Godfried MH, Boer K, Lange JM, Burger DM, Prins JM (2004). "Nelfinavir plasma concentrations are low during pregnancy". Clin. Infect. Dis. 39 (5): 736–40. doi:10.1086/422719. PMID 15356791. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  41. Stek AM, Mirochnick M, Capparelli E, Best BM, Hu C, Burchett SK, Elgie C, Holland DT, Smith E, Tuomala R, Cotter A, Read JS (2006). "Reduced lopinavir exposure during pregnancy". AIDS. 20 (15): 1931–9. doi:10.1097/01.aids.0000247114.43714.90. PMID 16988514. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  42. Lockman S, Shapiro RL, Smeaton LM, Wester C, Thior I, Stevens L, Chand F, Makhema J, Moffat C, Asmelash A, Ndase P, Arimi P, van Widenfelt E, Mazhani L, Novitsky V, Lagakos S, Essex M (2007). "Response to antiretroviral therapy after a single, peripartum dose of nevirapine". N. Engl. J. Med. 356 (2): 135–47. doi:10.1056/NEJMoa062876. PMID 17215531. Retrieved 2012-04-04. Unknown parameter |month= ignored (help)
  43. Abadía-Barrero CE, Castro A (2006). "Experiences of stigma and access to HAART in children and adolescents living with HIV/AIDS in Brazil". Soc Sci Med. 62 (5): 1219–28. doi:10.1016/j.socscimed.2005.07.006. PMID 16099573. Retrieved 2012-04-05. Unknown parameter |month= ignored (help)
  44. Ren Y, Nuttall JJ, Egbers C, Eley BS, Meyers TM, Smith PJ, Maartens G, McIlleron HM (2007). "High prevalence of subtherapeutic plasma concentrations of efavirenz in children". J. Acquir. Immune Defic. Syndr. 45 (2): 133–6. doi:10.1097/QAI.0b013e31805c9d52. PMID 17417100. Retrieved 2012-04-05. Unknown parameter |month= ignored (help)
  45. McKinney RE, Rodman J, Hu C, Britto P, Hughes M, Smith ME, Serchuck LK, Kraimer J, Ortiz AA, Flynn P, Yogev R, Spector S, Draper L, Tran P, Scites M, Dickover R, Weinberg A, Cunningham C, Abrams E, Blum MR, Chittick GE, Reynolds L, Rathore M (2007). "Long-term safety and efficacy of a once-daily regimen of emtricitabine, didanosine, and efavirenz in HIV-infected, therapy-naive children and adolescents: Pediatric AIDS Clinical Trials Group Protocol P1021". Pediatrics. 120 (2): e416–23. doi:10.1542/peds.2006-0925. PMID 17646352. Retrieved 2012-04-05. Unknown parameter |month= ignored (help)
  46. Funk MB, Notheis G, Schuster T, Elanjkal Z, von Hentig N, Stürmer M, Linde R, Dunsch D, Königs C, Wintergerst U, Kreuz W (2005). "Effect of first line therapy including efavirenz and two nucleoside reverse transcriptase inhibitors in HIV-infected children". Eur. J. Med. Res. 10 (12): 503–8. PMID 16356864. Unknown parameter |month= ignored (help); |access-date= requires |url= (help)
  47. Gandhi NR, Moll A, Sturm AW, Pawinski R, Govender T, Lalloo U, Zeller K, Andrews J, Friedland G (2006). "Extensively drug-resistant tuberculosis as a cause of death in patients co-infected with tuberculosis and HIV in a rural area of South Africa". Lancet. 368 (9547): 1575–80. doi:10.1016/S0140-6736(06)69573-1. PMID 17084757. Retrieved 2012-04-05. Unknown parameter |month= ignored (help)

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