pyrimidinones and Hepatitis-C

The combination of antiretroviral (ARV) therapies introduced at the end of the 1990s profoundly changed the natural history of human immunodeficiency virus (HIV) infection. Liver diseases are one of the three primary causes of 'non-AIDS-related' death in people living with HIV for three reasons: the high prevalence of hepatotropic viral co-infections, the hepatotoxicity of ARV drugs and new emerging liver diseases, including nodular regenerative hyperplasia and hepatitis E virus infection. The impact of HIV infection on the natural history of hepatitis C virus (HCV) or hepatitis B virus (HBV)/HIV co-infection has markedly changed in the past few decades with the progress made in ARV treatment and the improved definition of therapeutic strategies for HCV or HBV. Initially, HIV had a negative impact on hepatotropic infections. Today, HIV does not appear to significantly modify the natural history of HCV and HBV infection. This is associated with fair immune restoration, viral suppression associated with analogues having dual activity against HBV and HIV and with the increasing efficacy of antiviral treatments against HCV. A significant decline is expected in the morbidity and mortality associated with chronic liver infection in co-infected patients. Nevertheless, today, there are three major issues: (i) improving preventive measures including vaccination and risk reduction; (ii) screening patients infected with HBV or HCV and evaluating the impact of chronic infection on the liver and finally; (iii) early screening of hepatocellular carcinoma whose occurrence is higher and that evolves more rapidly in co-infected than in mono-infected patients.

Topics: Adenine; Antiviral Agents; Deoxycytidine; Disease Progression; Drug Therapy, Combination; Emtricitabine; Guanine; Hepatitis B; Hepatitis C; Hepatitis Viruses; HIV Infections; Humans; Interferon-alpha; Lamivudine; Nucleosides; Organophosphonates; Pyrimidinones; Telbivudine; Tenofovir; Thymidine

Most viral diseases, with the exception of those caused by human immunodeficiency virus, are self-limited illnesses that do not require specific antiviral therapy. The currently available antiviral drugs target 3 main groups of viruses: herpes, hepatitis, and influenza viruses. With the exception of the antisense molecule fomivirsen, all antiherpes drugs inhibit viral replication by serving as competitive substrates for viral DNA polymerase. Drugs for the treatment of influenza inhibit the ion channel M(2) protein or the enzyme neuraminidase. Combination therapy with Interferon-α and ribavirin remains the backbone treatment for chronic hepatitis C; the addition of serine protease inhibitors improves the treatment outcome of patients infected with hepatitis C virus genotype 1. Chronic hepatitis B can be treated with interferon or a combination of nucleos(t)ide analogues. Notably, almost all the nucleos(t) ide analogues for the treatment of chronic hepatitis B possess anti-human immunodeficiency virus properties, and they inhibit replication of hepatitis B virus by serving as competitive substrates for its DNA polymerase. Some antiviral drugs possess multiple potential clinical applications, such as ribavirin for the treatment of chronic hepatitis C and respiratory syncytial virus and cidofovir for the treatment of cytomegalovirus and other DNA viruses. Drug resistance is an emerging threat to the clinical utility of antiviral drugs. The major mechanisms for drug resistance are mutations in the viral DNA polymerase gene or in genes that encode for the viral kinases required for the activation of certain drugs such as acyclovir and ganciclovir. Widespread antiviral resistance has limited the clinical utility of M(2) inhibitors for the prevention and treatment of influenza infections. This article provides an overview of clinically available antiviral drugs for the primary care physician, with a special focus on pharmacology, clinical uses, and adverse effects.

Topics: Acyclovir; Adenine; Amantadine; Antiviral Agents; Comorbidity; Drug Therapy, Combination; Foscarnet; Ganciclovir; Guanine; Hepatitis; Hepatitis B, Chronic; Hepatitis C; Herpesviridae Infections; HIV Infections; Humans; Influenza, Human; Interferons; Lamivudine; Nucleosides; Oligopeptides; Organophosphonates; Oseltamivir; Proline; Protease Inhibitors; Pyrimidinones; Ribavirin; Telbivudine; Thymidine; Valacyclovir; Valganciclovir; Valine; Virus Replication; Zanamivir

We conducted an exploratory study to assess the safety tolerability, and anti-fibrotic effects of PRI-724, a CBP/β-catenin inhibitor, in patients with hepatitis C virus (HCV)- and hepatitis B virus (HBV)-induced cirrhosis.. Three patients from phase 1 who received the recommended PRI-724 dose were evaluated to obtain efficacy and safety data in phase 2a. Serious adverse events occurred in three patients, one of which was possibly related to PRI-724. The most common adverse events were diarrhoea and nausea. PRI-724 did not decrease hepatic fibrosis with any statistical significance, either by ordinal scoring or measurement of collagen proportionate area at 12 weeks; however, we observed statistically significant improvements in liver stiffness, Model for End-stage Liver Disease score, and serum albumin level.. AMED, Ohara Pharmaceutical.

Topics: Antiviral Agents; beta Catenin; Bridged Bicyclo Compounds, Heterocyclic; End Stage Liver Disease; Hepacivirus; Hepatitis C; Hepatitis C, Chronic; Herpesvirus 1, Cercopithecine; Humans; Liver Cirrhosis; Pyrimidinones; Severity of Illness Index; Treatment Outcome

Liver disease may alter the pharmacokinetics of antiretrovirals and produce changes in plasma protein binding. The aim was to evaluate the pharmacokinetics of total and unbound lopinavir (LPV) in HIV-infected patients with and without hepatitis C virus (HCV) coinfection. Fifty-six HIV+ patients receiving lopinavir/ritonavir (LPV/r) (group I = 24 controls; II = 23 HIV/HCV-coinfected; III = 9 cirrhotic HIV/HCV-coinfected) were included. Total (n = 56) and unbound (n = 36) LPV pharmacokinetic parameters were determined at steady-state using validated high-performance liquid chromatography with ultraviolet detection and high-performance liquid chromatography-tandem mass spectrometry methods, respectively. Pharmacokinetic parameters (plasma concentration just before drug administration, peak concentrations in plasma, times to maximum plasma concentration, areas under the plasma concentration-time curve from 0 to 12 hours, and CL/F/kg) of both total and unbound LPV were calculated by standard noncompartmental methods and differences among groups evaluated (Kruskal-Wallis test).LPV apparent oral clearance normalized to body weight (median, interquartile range) was 55 (40-68), 59 (44-69), and 71 (53-78) mL/h/kg for groups I, II, and III, respectively (II vs. I, P = 0.52; III vs. I, P = 0.16). The areas under the plasma concentration-time curve from 0 to 12 hours were 110.4 (80.9-135.2), 103.4 (85.5-131.3), and 92.8 (87.4-116.3) microg h/mL for groups I, II, and III, respectively (II vs. I, P = 0.68; III vs. I, P = 0.71). Chronic liver impairment produced a slight, although not significant, decrease in plasma protein binding. The free-fraction of LPV increased ( approximately 21%) from 0.97% (0.80-1.06) in HIV+/HCV- patients to 1.18% (0.89-1.65) in HIV/HCV+ cirrhotic patients. The apparent oral clearance of unbound LPV (CLu/F/kg) in cirrhotic patients did not change significantly, supporting the concept that the clearance of unbound LPV in liver disease is not affected after being inhibited by low-dose ritonavir co-administration.LPV total and unbound pharmacokinetics were not affected by hepatic impairment, suggesting that no adjustment of LPV/r dose is required for HIV/HCV-coinfected patients with and without cirrhosis and moderate impairment of liver function.

Topics: Adult; Area Under Curve; Body Weight; CD4 Lymphocyte Count; Chromatography, High Pressure Liquid; Female; Hepatitis C; HIV Infections; HIV Protease Inhibitors; Humans; Liver Cirrhosis; Liver Function Tests; Lopinavir; Male; Middle Aged; Prospective Studies; Pyrimidinones; Risk Factors; Ritonavir; Spectrophotometry, Ultraviolet; Ultrafiltration; Ultrasonography

To characterise the interactions between tacrolimus and antiretroviral drug combinations in hepatitis C virus-HIV co-infected patients who had received a liver transplant.. An observational, open-label, multiple-dose, two-period, one-sequence design clinical trial in which patients received tacrolimus as an immunosuppressive therapy during the postoperative period and then had an antiretroviral drug regimen added. Tacrolimus pharmacokinetics were evaluated at steady state during these two periods.. Fourteen patients participated in the study and seven participated in the intensified pharmacokinetic protocol. Patients were included if they had undergone liver transplantation for end-stage chronic hepatitis C, absence of opportunistic infection, a CD4 cell count of >150 cells/microL and an undetectable HIV plasma viral load (<50 copies/mL) under highly active antiretroviral therapy. During the posttransplantation period, the tacrolimus dose was adjusted according to blood concentrations. When liver function and the tacrolimus dose were stable, antiretroviral therapy was reintroduced.. When lopinavir/ritonavir were added to the tacrolimus regimen (seven patients), the tacrolimus dose was reduced by 99% to maintain the tacrolimus concentration within the therapeutic range. Only two patients were treated with nelfinavir, which led to a wide variation in inhibition of tacrolimus metabolism. When efavirenz (four patients) or a nucleoside analogue combination (one patient) was added, very little change in tacrolimus dosing was required.. The lopinavir/ritonavir combination markedly inhibited tacrolimus metabolism, whereas the effect of efavirenz was small. Tacrolimus dosing must be optimised according to therapeutic drug monitoring and the antiretroviral drug combination.

Topics: Adult; Aged; Alkynes; Antiretroviral Therapy, Highly Active; Area Under Curve; Benzoxazines; CD4 Lymphocyte Count; Cyclopropanes; Dose-Response Relationship, Drug; Female; Graft Rejection; Half-Life; Hepatitis C; HIV; HIV Infections; Humans; Liver Transplantation; Lopinavir; Male; Middle Aged; Nelfinavir; Pyrimidinones; Ritonavir; Tacrolimus; Viral Load

The effect of hepatic impairment on lopinavir/ritonavir pharmacokinetics was investigated. Twenty-four HIV-1-infected subjects received lopinavir 400 mg/ritonavir 100 mg twice daily prior to and during the study: 6 each with mild or moderate hepatic impairment (and hepatitis C virus coinfected) and 12 with normal hepatic function. Mild and moderate hepatic impairment showed similar effects on lopinavir pharmacokinetics. When the 2 hepatic impairment groups were combined, lopinavir Cmax and AUC12 were increased 20% to 30% compared to the controls. Hepatic impairment increased unbound lopinavir AUC12 by 68% and Cmax by 56%. The effect of hepatic impairment on low-dose ritonavir pharmacokinetics was more pronounced in the moderate impairment group (181% and 221% increase in AUC12 and Cmax, respectively) than in the mild impairment group (39% and 61% increase in AUC12 and Cmax, respectively). While lopinavir/ritonavir dose reduction is not recommended in subjects with mild or moderate hepatic impairment, caution should be exercised in this population.

Topics: Adult; Area Under Curve; Biological Availability; Drug Combinations; Drug Monitoring; Female; Hepatitis C; HIV Infections; HIV Protease Inhibitors; HIV-1; Humans; Liver Diseases; Lopinavir; Male; Middle Aged; Pyrimidinones; Radioligand Assay; Ritonavir

The aim of this study was to evaluate the frequency, characteristics and risk factors of lipid changes associated with lopinavir/ritonavir treatment in antiretroviral-naive patients.. A prospective cohort of 107 antiretroviral-naive HIV-infected patients was followed for 12 months after starting lopinavir/ritonavir-based highly active antiretroviral therapy.. At 12 months, percentages of patients with hypercholesterolaemia and hypertriglyceridaemia were 17.4% and 40%, respectively. Mean increases in total cholesterol and triglycerides were 40.7 and 73.3 mg/dL. There was a significant increase in both low-density and high-density (HDL) cholesterol, and no increase in the total cholesterol/HDL ratio (from 4.16 at baseline to 4.49 after 12 months). Baseline cholesterol > 200 mg/dL and triglycerides > 150 mg/dL were independent risk factors for dyslipidaemia, while hepatitis C coinfection appeared to be protective.. Patients with elevated lipid values at baseline have the greatest risk of developing hypercholesterolaemia and hypertriglyceridaemia after starting lopinavir/ritonavir. Antiretroviral-naive patients coinfected with hepatitis C have a low risk of developing hyperlipidaemia after starting lopinavir/ritonavir.

Topics: Adult; Aged; Antiretroviral Therapy, Highly Active; Cholesterol, HDL; Cholesterol, LDL; Female; Hepatitis C; HIV Infections; HIV Protease Inhibitors; Humans; Hypercholesterolemia; Hyperlipidemias; Hypertriglyceridemia; Lipids; Lopinavir; Male; Middle Aged; Pyrimidinones; Risk Factors; Ritonavir; Triglycerides

Highly active antiretroviral therapy (HAART) initiation in patients coinfected with human immunodeficiency virus type 1 (HIV-1) and hepatitis C virus (HCV) has been associated with transaminase and HCV viral load flares. Previous studies have included highly variable antiretroviral regimens. We compared effects of 2 protease inhibitor-based regimens on alanine aminotransferase (ALT) levels and HCV loads in HCV-HIV-coinfected patients initiating HAART.. Seventy HIV-infected patients with positive baseline results of HCV enzyme-linked immunosorbant assay from a treatment trial comparing lopinavir-ritonavir with nelfinavir were evaluated during a 48-week period. HCV and HIV titers were analyzed at baseline, at weeks 24 and 48 of treatment, and during flares in the ALT level of >5 times the upper limit of normal.. A total of 57 of 70 patients tested positive for HCV RNA at baseline. HCV titers for patients in lopinavir-ritonavir and nelfinavir groups, respectively, were as follows: baseline, 6.07 and 6.22 log IU/mL; week 24 of treatment, 6.68 and 6.48 log IU/mL; and week 48 of treatment, 6.32 and 6.44 log IU/mL. Of patients with a CD4+ cell count of <100 cells/mm3 at baseline, 5 of 11 in the nelfinavir group and 0 of 10 in the lopinavir-ritonavir group had an increase in the HCV load of >0.5 log IU/mL from baseline to week 48. The mean ALT level increased by 45 U/L at 24 weeks and 18 U/L at 48 weeks in the nelfinavir group but decreased by 18 U/L at 24 weeks and 7 U/L at 48 weeks in the lopinavir-ritonavir group. Eight patients in the nelfinavir group and 2 patients in the lopinavir-ritonavir group had grade 3 or 4 flares in the ALT level.. HAART initiation is associated with increased HCV loads and ALT levels. A low baseline CD4+ cell count is associated with persistent increases in the HCV RNA load in nelfinavir-treated patients. These results warrant careful interpretation of abnormalities in the ALT load after HAART initiation in HCV-HIV-coinfected patients to prevent premature discontinuation of treatment.

Topics: Adult; Aged; Aged, 80 and over; Anti-HIV Agents; Antiretroviral Therapy, Highly Active; CD4 Lymphocyte Count; Female; Hepacivirus; Hepatitis C; HIV Infections; Humans; Liver; Lopinavir; Male; Middle Aged; Nelfinavir; Pyrimidinones; Ritonavir; RNA, Viral; Viral Load

Topics: Adult; Amphetamine-Related Disorders; Antineoplastic Combined Chemotherapy Protocols; Hepatitis C; Humans; Imidazoles; Male; Melanoma; Molecular Targeted Therapy; Neoplasm Metastasis; Oximes; Pyridones; Pyrimidinones; Skin Neoplasms

Thirty-three persons became victims of a serial knife stabbing incident. One of the first victims one day later disclosed that he was HIV-infected. Thereafter thirty-one victims initiated HIV post-exposure prophylaxis (PEP), one exposed patient declined. None of the victims evaluated had seroconverted six months later. In most such incidents HIV exposure will be difficult to rule out as reliable information on the HIV serostatus of all serial victims will be lacking. It appears prudent, however, to inform serial stab victims about the potential risk of HIV transmission and to at least consider PEP in such scenarios.

Topics: Anti-HIV Agents; Crime Victims; Disease Transmission, Infectious; Drug Combinations; Hepatitis B; Hepatitis C; HIV Infections; Humans; Lamivudine; Lopinavir; Post-Exposure Prophylaxis; Pyrimidinones; Viral Load; Wounds, Stab; Zidovudine

To assess the influence of hepatitis C virus (HCV) co-infection and the extent of liver fibrosis on lopinavir/ritonavir pharmacokinetics in HIV-infected patients without liver function impairment.. Cross-sectional, comparative study enrolling HIV-infected adults receiving lopinavir/ritonavir (400 mg/100 mg twice daily). HIV/HCV co-infected patients were grouped as having advanced fibrosis (HCV+/FIB+, n=7) or not (HCV+/FIB-, n=8) based on the FIB-4 index. A full concentration-time profile was obtained for each patient, and blood samples were collected before (0), and 1, 2, 4, 6, 8, 10 and 12 hours after a lopinavir/ritonavir dose. Lopinavir and ritonavir concentrations in plasma were determined by high-performance liquid chromatography. Maximum and minimum plasma concentrations (Cmax and Cmin), area under the plasma concentration-time curve from 0 to 12 hours (AUC12), apparent oral clearance at steady state (CLss/F), and apparent volume of distribution after oral administration (Vd/F) were calculated for each individual using a non-compartmental approach.. Twenty-six HCV- and 22 HCV+patients were enrolled. Lopinavir and ritonavir pharmacokinetics were comparable between HCV- and HCV+patients. However, the Vd/F of lopinavir was 125% higher in HCV+/FIB+patients than in HCV-patients (p=0.015) and 107% higher than in HCV+/FIB-(p=0.040) patients. The CLss/F of ritonavir was 40% lower in HCV+/FIB+patients than in HCV-patients (p=0.005) and 44% lower than in HCV+/FIB-patients (p=0.040). Thus, for ritonavir AUC12, Cmax and Cmin in HCV+/FIB+patients were 63%, 86% and 100% higher, respectively, when compared with those parameters in HCV-patients (p=0.005, p=0.012 and p=0.015, respectively), and 80%, 86% and 100% higher, respectively, when compared with levels in HCV+/FIB- patients (p=0.040, p=0.040 and p=0.029, respectively).. Lopinavir exposure is similar in HIV-infected patients with or without HCV co-infection and without liver function impairment. However, ritonavir exposure may be higher in this setting, particularly in individuals with advanced liver fibrosis.

Topics: Area Under Curve; Chromatography, High Pressure Liquid; Hepatitis C; HIV Infections; HIV Protease Inhibitors; Humans; Liver; Liver Function Tests; Lopinavir; Pyrimidinones; Ritonavir

Atazanavir (ATV) and lopinavir (LPV) are widely used HIV-1 protease inhibitors. Like with other protease inhibitors, careful monitoring of potential drug-drug and drug-disease interactions in clinical practice is necessary. The aim of this study was to assess the impact of substance use and hepatitis virus coinfection on plasma ATV and LPV trough concentrations in HIV-positive substance users and nonusers. Individuals established on ATV (300 mg and 100 mg ritonavir daily) or LPV (400 mg and 100 mg ritonavir twice daily)-containing regimens completed two clinical visits (trough and directly observed therapy) during which dosing characteristics, concomitant medication, and substance use were recorded. Trough plasma concentrations (22-26 hours for ATV and 10-14 hours for LPV) were measured using LCMSMS. The influence of substance use was evaluated by Kruskal-Wallis test. Substance use was associated with a marked decrease in trough LPV concentrations during the trough visit (median, 5.536 and 3.791 microg/mL for nonsubstance users and substance users, respectively, P = 0.029). Significantly lower LPV trough levels were also noted among patients with active hepatitis C virus coinfection evaluated as an independent variable (median, 2.253 and 5.927 microg/mL for active and inactive/no hepatitis C virus infection, respectively, P = 0.032). Substance use and hepatitis virus coinfection had limited effects on ATV trough levels. In this cohort, despite the wide interindividual variability of ATV and LPV trough concentrations, significant associations between substance use and active hepatitis C virus infection and low LPV trough concentrations were observed. Further work is needed to assess the optimal dosing regimen when using LPV in HIV-infected substance users.

Topics: Adult; Anti-HIV Agents; Antiretroviral Therapy, Highly Active; Atazanavir Sulfate; Drug Administration Schedule; Drug Monitoring; Female; Hepatitis C; HIV Infections; HIV-1; Humans; Lopinavir; Male; Middle Aged; Oligopeptides; Pyridines; Pyrimidinones; Substance-Related Disorders; United States

To describe a case of exacerbated mania potentially related to an interaction between lopinavir/ritonavir and valproic acid (VPA) and propose a mechanism of action for this interaction.. A 30-year-old man with bipolar disorder and HIV initiated treatment with lopinavir/ritonavir, zidovudine, and lamivudine. Prior to beginning therapy with these antiretrovirals, he was receiving VPA 250 mg 3 times daily, with his most recent VPA concentration measured at 495 micromol/L. Twenty-one days after starting antiretroviral treatment, he became increasingly manic. His VPA concentration at admission was 238 micromol/L, a 48% decrease. The daily VPA dose was increased to 1500 mg, and olanzapine was introduced. The VPA concentration following this dose escalation was 392 micromol/L, and the patient improved clinically.. Fifty percent of VPA is metabolized by glucuronidation, 40% undergoes mitochondrial beta-oxidation, and less than 10% is eliminated by the cytochrome P450 isoenzymes. Ritonavir can induce glucuronidation of several medications including ethinyl estradiol, levothyroxine, and lamotrigine. We believe that ritonavir-mediated induction of VPA glucuronidation resulted in a decrease in VPA concentrations and efficacy. An objective causality assessment suggested that the increased mania was probably related to the decrease in VPA concentration and that a possible interaction exists between lopinavir/ritonavir and VPA.. A potential interaction exists between VPA and all ritonavir-boosted antiretroviral regimens. Clinicians should monitor patients closely for a decreased VPA effect when these medications are given concomitantly.

Topics: Adult; Antiretroviral Therapy, Highly Active; Bipolar Disorder; Dose-Response Relationship, Drug; Drug Interactions; Hepatitis C; HIV Infections; Humans; Lopinavir; Male; Pyrimidinones; Ritonavir; Valproic Acid

Topics: Adult; Aged; Female; Hepacivirus; Hepatitis C; HIV Infections; Humans; Liver; Lopinavir; Male; Middle Aged; Pyrimidinones; Ritonavir

The objective of this study was to find predictive factors of lopinavir/ritonavir (LPV/r) discontinuation for drug-related toxicities in highly pre-treated human immunodeficiency virus (HIV)-infected subjects. The study was an observational study of HIV patients starting LPV/r with HIV RNA > 3log10 copies/mL and a follow-up > or = 6 months. Parameters studied were HIV RNA, CD4+ cell counts, metabolic parameters and drug-related adverse events. Acquired immune deficiency syndrome (AIDS) events and deaths were recorded. The Kaplan-Meier (KM) model was used to estimate time-dependent probability, and the multivariable Cox model to identify predictors of LPV/r discontinuation for adverse events. The study evaluated 416 HIV-infected patients. Seventy-seven patients (18.5%) discontinued LPV/r for toxicities. Adverse events leading to LPV/r discontinuation were gastrointestinal symptoms in 40 cases, hyperlipidaemia in 27 and increase of aspartate aminotransferase (AST)/alanine aminotransferase (ALT) in 10 patients. Nineteen patients (4.6%) developed an AIDS event during observation and 15 (3.6%) died. The KM probability of LPV/r discontinuation for toxicities was 5.3% (range 3.1-7.5%) at month 12 and 15.7% (range 12.1-19.3%) at month 24. Subjects with hepatitis C virus (HCV)-HIV co-infection (odds ratio (OR) 7.40; 95% confidence interval (CI) 3.73-14.66 versus HCV-negative; P = 0.001) and receiving LPV/r plus nucleoside reverse transcriptase inhibitors (NRTIs) and protease inhibitor (PI)/non-nucleoside reverse transcriptase inhibitor (NNRTI) (OR 1.74; 95% CI 1.04-2.91 versus LPV/r plus only NRTIs; P = 0.04) showed a higher risk of LPV/r discontinuation by a Cox analysis, whereas non-intravenous drug abusers (IVDUs) (OR 0.40; 95% CI 0.24-0.67 versus IVDUs; P = 0.001) had a lower risk. The rate of discontinuation for toxicity decreased by 17% for each additional month of LPV/r exposure (OR 0.83; 95% CI 0.80-0.86 for each additional month; P < 0.001). LPV/r was substantially well tolerated. Diarrhoea was the most frequent adverse event leading to discontinuation. HCV-HIV co-infected patients and patients with a short exposure to LPV/r have a higher risk of discontinuing LPV/r and should be strictly monitored.

Topics: Adult; Aged; Antiretroviral Therapy, Highly Active; Cohort Studies; Drug Administration Schedule; Female; Hepatitis C; HIV Infections; HIV Protease Inhibitors; Humans; Lopinavir; Male; Middle Aged; Odds Ratio; Prospective Studies; Pyrimidinones; Risk Factors; Ritonavir

Liver toxicity is a common side effect of antiretroviral therapy, particularly in subjects coinfected with the hepatitis C virus (HCV). The incidence of severe liver toxicity after initiation of treatment with lopinavir (LPV) as well as its possible association with LPV plasma levels were assessed in 120 HIV-infected patients (52% coinfected by HCV). The incidence of severe liver toxicity at 3 months was 1.7% and the cumulative incidence at 12 months was 4%. The development of severe liver toxicity was associated with HCV coinfection but not with LPV plasma levels.

Topics: Adult; Anti-HIV Agents; CD4 Lymphocyte Count; Female; Hepatitis C; HIV Infections; Humans; Incidence; Liver; Lopinavir; Male; Pyrimidinones

Topics: Drug Therapy, Combination; Hepatitis B; Hepatitis C; HIV Infections; HIV Protease Inhibitors; Humans; Lopinavir; Prospective Studies; Pyrimidinones; Ritonavir

Topics: Drug Combinations; Europe; Hepatitis C; HIV Protease Inhibitors; Humans; Liver; London; Lopinavir; Mitochondria, Liver; Pyrimidinones; Ritonavir