UMLS:C0019693 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: UMLS:C0019693 (HIV)
170,526 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Since its introduction in 1987, zidovudine monotherapy has been the treatment of choice for patients with HIV infection. Unfortunately it has been established that the beneficial effects of zidovudine are not sustained due to the development of resistant viral strains. This has led to the strategy of combination therapy, and in 1995 treatment with zidovudine plus didanosine, or zidovudine plus zalcitabine, was demonstrated to be more effective than zidovudine monotherapy in preventing disease progression and reducing mortality in patients with HIV disease. Recent work demonstrates an even greater antiviral effect from triple therapy with 2 nucleosides, zidovudine plus zalcitabine with the addition of saquinavir, a new protease inhibitor drug. The HIV protease enzyme is responsible for the post-translational processing of gag and gag-pol polyprotein precursors, and its inhibition by drugs such as saquinavir, ritonavir, indinavir and VX-478 results in the production of non-infectious virions. As resistance may also develop to the protease inhibitors they may be used in combination, and future strategies may well include quadruple therapy with 2 nucleoside analogues plus 2 protease inhibitors. Administration of protease inhibitors alone or in combination with other drugs does raise a number of important pharmacokinetic issues for patients with HIV disease. Some protease inhibitors (e.g. saquinavir) have kinetic profiles characterised by reduced absorption and a high first pass effect, resulting in poor bioavailability which may be improved by administrating with food. Physiological factors including achlorhydria, malabsorption and hepatic dysfunction may influence the bioavailability of protease inhibitors in HIV disease. Protease inhibitors are very highly bound to plasma proteins (> 98%), predominantly to alpha 1-acid glycoprotein. This may influence their antiviral activity in vitro and may also predispose to plasma protein displacement interactions. Such interactions are usually only of clinical relevance if the metabolism of the displaced drug is also inhibited. This is precisely the situation likely to pertain to the protease inhibitors, as ritonavir may displace other protease inhibitor drugs, such as saquinavir, from plasma proteins and inhibit their metabolism. Protease inhibitors are extensively metabolised by the cytochrome P450 (CYP) enzymes present in the liver and small intestine. In vitro studies suggest that the most influential CYP isoenzyme involved in the metabolism of the protease inhibitors is CYP3A, with the isoforms CYP2C9 and CYP2D6 also contributing. Ritonavir has an elimination half-life (t1/2 beta) of 3 hours, indinavir 2 hours and saquinavir between 7 and 12 hours. Renal elimination is not significant, with less than 5% of ritonavir and saquinavir excreted in the unchanged form. As patients with HIV disease are likely to be taking multiple prolonged drug regimens this may lead to drug interactions as a result of enzyme induction or inhibition. Recognised enzyme inducers of CYP3A, which are likely to be prescribed for patients with HIV disease, include rifampicin (rifampin) [treatment of pulmonary tuberculosis], rifabutin (treatment and prophylaxis of Mycobacterium avium complex), phenobarbital (phenobarbitone), phenytoin and carbamazepine (treatment of seizures secondary to cerebral toxoplasmosis or cerebral lymphoma). These drugs may reduce the plasma concentrations of the protease inhibitors and reduce their antiviral efficacy. If coadministered drugs are substrates for a common CYP enzyme, the elimination of one or both drugs may be impaired. Drugs which are metabolised by CYP3A and are likely to be used in the treatment of patients with HIV disease include the azole antifungals, macrolide antibiotics and dapsone; therefore, protease inhibitors may interact with these drugs. (ABSTRACT TRUNCATED)
...
PMID:Protease inhibitors in patients with HIV disease. Clinically important pharmacokinetic considerations. 908 59

The oxidative metabolism of delavirdine, a non-nucleoside inhibitor of HIV-1 reverse transcriptase, is mediated in part by cytochrome P450 3A. The influence of rifabutin, an inducer of certain human cytochrome P450 isozymes, on the steady-state pharmacokinetics of delavirdine was investigated in 12 HIV-positive patients with CD4 counts ranging from 75 to 671/mm3. Both the control group (n = 5) and the rifabutin group (n = 7) received 400 mg delavirdine mesylate every 8 h for 30 days; subjects in the rifabutin group took a 300 mg, once-daily dose of rifabutin on study days 16-30. Harvested plasma from serial blood samples collected after dosing on days 15, 16, and 30 was assayed for delavirdine and its N-desalkyl metabolite concentrations using a reversed-phase HPLC method. Blood samples obtained on days 16 and 30 were also assayed for rifabutin by HPLC. Delavirdine mesylate alone or in combination with rifabutin was well-tolerated. On day 30, statistically significant differences between groups were observed for all delavirdine pharmacokinetic parameters (P < 0.046). After coadministration of rifabutin and delavirdine mesylate for 2 weeks, oral clearance of delavirdine increased five-fold, resulting in lower steady-state plasma delavirdine concentrations. Rifabutin pharmacokinetic parameters were similar to those previously reported. Concomitant use of delavirdine and rifabutin at the recommended dose for each drug is discouraged. Maintaining therapeutic concentrations of delavirdine in patients on both medications may require dose modification.
...
PMID:Pharmacokinetic study of the interaction between rifabutin and delavirdine mesylate in HIV-1 infected patients. 922 61

To investigate the interaction of fluconazole and zidovudine in HIV-positive non-smoking male patients with AIDS categorized as CDC group IV we studied two groups, each consisting of 10 male, non-smoking, HIV-positive patients with CDC group IV disease, with the patients in the first group additionally suffering from candida esophagitis. In the first group, the pharmacokinetics of 500 mg oral zidovudine were determined both before and after 7 days of treatment with fluconazole 400 mg/d. In the second group, the pharmacokinetics of 200 mg oral fluconazole were determined before and after 14 days of treatment with zidovudine 4 x 250 mg/d. In order to determine the microsomal enzyme activity, the 6-beta-hydroxycortisol/17-hydroxycorticosteroid ratio and antipyrine pharmacokinetic parameters were determined. 6-beta-hydroxycortisol was quantitated by RIA. The 17-hydroxycorticosteroids were determined by a colorimetric method. Zidovudine (ZDV) and zidovudine glucuronide (GZDV), and the fluconazole and antipyrine plasma and urine concentrations were measured by HPLC. Administration of fluconazole resulted in a significant increase in the half-life of zidovudine and antipyrine (0.97 +/- 0.17 h prior to vs. 1.11 +/- 0. 14 h after fluconazole administration and 11.9 +/- 1.9 h prior to vs. 13.7 +/- 3.0 h after fluconazole, respectively) while the 6-beta-hydroxycortisol excretion decreased significantly (472.3 +/- 80.6 microg/24 h before and 340.6 +/- 82.1 microg/24 h after administration of fluconazole). No changes were found in the GZDV plasma kinetics and the ZDV and GZDV urinary excretion. Treatment with ZDV did not have any impact on the half-life of fluconazole. Administration of zidovudine did, however, result in a significant reduction in antipyrine half-life (11.7 +/- 2.0 h before vs. 9.9 +/- 2.3h after ZDV) and a significant increase in 6-beta-hydroxycortisol excretion (438,7 +/- 138.2 microg/24 h before and 684.6 +/- 157.3 microg/24 h after ZDV). Since the antipyrine clearance is altered after administration of ZDV, it is assumed that zidovudine induces cytochrome P450 enzymes. This effect, however, does not alter the pharmacokinetics of fluconazole. High doses of fluconazole can inhibit the plasma elimination of both antipyrine and zidovudine, but the extent of this inhibitory effect is so small that no clinically relevant accumulation is to be expected.
...
PMID:Pharmacokinetic interaction of fluconazole and zidovudine in HIV-positive patients. 930 Sep 34

Saquinavir is an HIV protease inhibitor with no, or limited, effect on the activity of other structurally related human aspartic proteinases. As with other HIV protease inhibitors, saquinavir inhibits the cleavage of the gag-pol protein substrate leading to the release of structurally defective and functionally inactive viral particles. It is active on both HIV-1 and HIV-2, and also has activity on chronically infected cells and HIV strains resistant to reverse transcriptase inhibitors. Synergy of action has been observed with other antiretroviral drugs. Saquinavir is characterised by a low bioavailability which is further reduced in the fasting state. Metabolism is mainly hepatic through cytochrome P450 (CYP) 3A4, but intestinal metabolism through the same system has also been reported. To achieve higher drug plasma concentrations and increase the antiviral effect, a new formulation of saquinavir with a higher bioavailability has recently been introduced. Higher plasma drug concentrations may also be obtained by combining the drug with CYP blockers, such as ritonavir or ketoconazole. Because of its metabolic interference with the CYP system, saquinavir cannot be coadministered with astemizole, terfenadine or cisapride. Rifampicin (rifampin) is also contraindicated because coadministration can lead to decreases in saquinavir concentrations. Interactions have also been reported with other drugs metabolised through the same system, including non-nucleoside reverse transcriptase inhibitors and HIV protease inhibitors. Resistance has been observed after both in vitro and in vivo drug exposure, with a relatively specific mutation profile compared with other protease inhibitors. Saquinavir is generally well tolerated, with mild gastrointestinal symptoms representing the most commonly observed adverse effects. Although characterized by low bioavailability, in phase III trials saquinavir has been shown to have clinical efficacy in terms of survival and progression rate. As with the other protease inhibitors, saquinavir should be used in combination with other antiretroviral drugs. Current therapeutic guidelines, however, recommend the selection of an initial treatment regimen with other protease inhibitors with higher in vivo activity in terms of RNA and CD4 response. The results of ongoing studies will clarify to what extent a new saquinavir formulation, recently introduced, is superior to the previous one in terms of antiviral activity and to provide comparisons with other protease inhibitors. Further studies are also needed to define the best place of saquinavir within treatment strategies based on protease inhibitors, particularly in respect to the optimal sequence for its use with other protease inhibitors, and the dynamics of cross-resistance and its role within regimens based on the combination of protease inhibitors.
...
PMID:Saquinavir. Clinical pharmacology and efficacy. 953 81

Amprenavir (141W94, VX-478, KVX-478) is metabolized primarily by CYP3A4 (cytochrome P450 3A4) in recombinant systems and human liver microsomes (HLM). The effects of ketoconazole, terfenadine, astemizole, rifampicin, methadone, and rifabutin upon amprenavir metabolism were examined in vitro using HLM. Ketoconazole, terfenadine, and astemizole were observed to inhibit amprenavir depletion, consistent with their known specificity for CYP3A4. The HIV protease inhibitors, indinavir, saquinavir, ritonavir, and nelfinavir, were included in incubations containing amprenavir to examine the interactions of HIV protease inhibitors in vitro. The order of amprenavir metabolism inhibition in human liver microsomes was observed to be: ritonavir > indinavir > nelfinavir > saquinavir. The Ki value for amprenavir-mediated inhibition of testosterone hydroxylation in human liver microsomes was found to be approximately 0.5 microM. Studies suggest that amprenavir inhibits CYP3A4 to a greater extent than saquinavir, and to a much lesser extent than ritonavir. Amprenavir, nelfinavir, and indinavir appear to inhibit CYP3A4 to a moderate extent, suggesting a selected number of coadministration restrictions.
...
PMID:Metabolism of amprenavir in liver microsomes: role of CYP3A4 inhibition for drug interactions. 964 46

Therapy of HIV infection is changing rapidly as new drugs are introduced. Many patients with HIV infection require anticonvulsants for therapy or prophylaxis of seizures. Antiretroviral drugs, above all protease inhibitors, and anticonvulsants may cause interactions since they are metabolised through common hepatic pathways and may substantially modulate the activity of numerous cytochrome P450 isoenzymes. We describe known interactions between anticonvulsants and antiretroviral drugs and advise on possible combinations.
...
PMID:[Anti-retroviral therapy and antiepileptics. Case report and discussion]. 971 1

The protease inhibitor ritonavir has demonstrated broad-spectrum ability against HIV 1 and 2. The present study investigated the drug interaction potential of steady-state ritonavir on single dose ethinyl estradiol pharmacokinetics. 23 healthy women (mean age, 34 years) received an oral contraceptive (OC) containing 50 mcg of ethinyl estradiol and 1 mg of ethynodiol on days 1 and 29, while 500 mg of ritonavir was administered every 12 hours on days 15-30. After administration of a single dose of OC, serum ethinyl estradiol concentrations peaked at 4 hours and declined thereafter, with a typical half-life of 17 hours. Administration of the second OC on day 29, after 16 days of continuous ritonavir, resulted in a 32% lower ethinyl estradiol mean maximum concentration (p 0.001) and a 41% lower mean area under curve (p 0.001) compared with OC administration alone. In addition, the mean terminal elimination rate constant increased by 31% (p 0.001) with concomitant ritonavir. The changes in ethinyl estradiol pharmacokinetics were consistent with an increase in clearance from enzymatic induction of glucuronidation and/or cytochrome P450 hydroxylation. Mean steady-state ritonavir concentrations of 6.5 and 13.4 mcg/ml were observed at 0 and 4 hours post-dose, respectively. The interaction observed in this study is likely to be clinically significant, with an increased risk of OC failure. Thus, use of alternate contraceptive measures should be recommended when ritonavir is being administered.
...
PMID:Effect of ritonavir on the pharmacokinetics of ethinyl oestradiol in healthy female volunteers. 972 18

Pharmacokinetic drug interactions with viral protease inhibitors are of potential clinical importance. An in vitro model was applied to the quantitative identification of possible interactions of protease inhibitors with substrates of cytochrome P450-2D6. Biotransformation of desipramine (DMI) to hydroxydesipramine (OH-DMI), an index reaction used to profile activity of human cytochrome P450-2D6, was studied in vitro using human liver microsomes. Quinidine and four viral protease inhibitors currently used to treat human immunodeficiency virus infection were tested as chemical inhibitors in this system. Formation of OH-DMI from DMI was consistent with Michaelis-Menten kinetics, having a mean Km value of 11.7 microM (range: 9.9-15.3 microM). Quinidine, a highly potent and relatively selective inhibitor of P450-2D6, strongly inhibited OH-DMI formation with an apparent competitive mechanism, having a mean inhibition constant of 0.16 microM (range: 0.13-0.18 microM). All four protease inhibitors impaired OH-DMI formation; the pattern was consistent with a mixed competitive-noncompetitive mechanism. Mean inhibition constants (small numbers indicating greater inhibiting potency) were as follows: ritonavir, 4.8 microM; indinavir, 15.6 microM; saquinavir, 24.0 microM; nelfinavir, 51.9 microM. In a clinical pharmacokinetic study, coadministration of ritonavir with DMI inhibited DMI clearance by an average of 59%. The in vitro findings, together with observed plasma ritonavir concentrations, provided a reasonable quantitative forecast of this interaction, whereas estimated unbound plasma or intrahepatic ritonavir concentrations yielded poor quantitative forecasts. Thus the in vitro model correctly identifies ritonavir as a potent and clinically important inhibitor of human P450-2D6. Other protease inhibitors may also inhibit 2D6 activity in humans, but with lower potency than ritonavir.
...
PMID:Inhibition of desipramine hydroxylation (Cytochrome P450-2D6) in vitro by quinidine and by viral protease inhibitors: relation to drug interactions in vivo. 975 74

The anti-HIV protease inhibitors represent a new class of agents for treatment of HIV infection. Saquinavir, ritonavir, indinavir, and nelfinavir are the first drugs approved in this class and significantly reduce HIV RNA copy number with minimal adverse effects. They are all substrates of cytochrome P450 3A4, and are incompletely bioavailable. The drug transporting protein, P-glycoprotein (P-gp), which is highly expressed in the intestinal mucosa, could be responsible for the low oral bioavailability of these and other drugs which are substrates for this transporter. To determine whether these protease inhibitors are modulators of P-gp, we studied them in cell lines which do and do not express P-gp. Saquinavir, ritonavir and nelfinavir significantly inhibited the efflux of [3H]paclitaxel and [3H]vinblastine in P-gp-positive cells, resulting in an increase in intracellular accumulation of these drugs. However, similar concentrations of indinavir did not affect the accumulation of these anticancer agents. In photoaffinity labeling studies, saquinavir and ritonavir displaced [3H]azidopine, a substrate for P-gp, in a dose-dependent manner. These data suggest that saquinavir, ritonavir, and nelfinavir are inhibitors and possibly substrates of P-gp. Because saquinavir has a low bioavailability, its interaction with P-gp may be involved in limiting its absorption.
...
PMID:Interaction of anti-HIV protease inhibitors with the multidrug transporter P-glycoprotein (P-gp) in human cultured cells. 980 61

Ritonavir is 1 of the 4 potent synthetic HIV protease inhibitors, approved by the US Food and Drug Administration (FDA) between 1995 and 1997, that have revolutionised HIV therapy. The extent of oral absorption is high and is not affected by food. Within the clinical concentration range, ritonavir is approximately 98 to 99% bound to plasma proteins, including albumin and alpha 1-acid glycoprotein. Cerebrospinal fluid (CSF) drug concentrations are low in relation to total plasma concentration. However, parallel decreases in the viral burden have been observed in the plasma, CSF and other tissues. Ritonavir is primarily metabolised by cytochrome P450 (CYP) 3A isozymes and, to a lesser extent, by CYP2D6. Four major oxidative metabolites have been identified in humans, but are unlikely to contribute to the antiviral effect. About 34% and 3.5% of a 600 mg dose is excreted as unchanged drug in the faeces and urine, respectively. The clinically relevant t1/2 beta is about 3 to 5 hours. Because of autoinduction, plasma concentrations generally reach steady state 2 weeks after the start of administration. The pharmacokinetics of ritonavir are relatively linear after multiple doses, with apparent oral clearance averaging 7 to 9 L/h. In vitro, ritonavir is a potent inhibitor of CYP3A. In vivo, ritonavir significantly increases the AUC of drugs primarily eliminated by CYP3A metabolism (e.g. clarithromycin, ketoconazole, rifabutin, and other HIV protease inhibitors, including indinavir, saquinavir and nelfinavir) with effects ranging from an increase of 77% to 20-fold in humans. It also inhibits CYP2D6-mediated metabolism, but to a significantly lesser extent (145% increase in desipramine AUC). Since ritonavir is also an inducer of several metabolising enzymes [CYP1A4, glucuronosyl transferase (GT), and possibly CYP2C9 and CYP2C19], the magnitude of drug interactions is difficult to predict, particularly for drugs that are metabolised by multiple enzymes or have low intrinsic clearance by CYP3A. For example, the AUC of CYP3A substrate methadone was slightly decreased and alprazolam was unaffected. Ritonavir is minimally affected by other CYP3A inhibitors, including ketoconazole. Rifampicin (rifampin), a potent CYP3A inducer, decreased the AUC of ritonavir by only 35%. The degree and duration of suppression of HIV replication is significantly correlated with the plasma concentrations. Thus, the large increase in the plasma concentrations of other protease inhibitors when coadministered with ritonavir forms the basis of rational dual protease inhibitor regimens, providing patients with 2 potent drugs at significantly reduced doses and less frequent dosage intervals. Combination treatment of ritonavir with saquinavir and indinavir results in potent and sustained clinical activity. Other important factors with combination regimens include reduced interpatient variability for high clearance agents, and elimination of the food effect on the bioavailibility of indinavir.
...
PMID:Ritonavir. Clinical pharmacokinetics and interactions with other anti-HIV agents. 981 78

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>