The effect of vitamin B supplementation on neuronal injury in people living with HIV – a randomised controlled trial

Effective antiretroviral therapy has radically changed the course of the HIV pandemic. However, despite efficient therapy, milder forms of neurocognitive symptoms are still present in people living with HIV. Plasma homocysteine is a marker of vitamin B deficiency and has been associated with cognitive impairment. People living with HIV have higher homocysteine concentrations than HIV-negative controls, and we have previously found an association between plasma homocysteine concentration and CSF concentration of neurofilament light protein, a sensitive marker for ongoing neuronal injury in HIV. This prompted us to perform this randomised controlled trial, to evaluate the effect of vitamin B supplementation on neuronal injury in a cohort of people living with HIV on stable antiretroviral therapy. At the Department of Infectious Diseases at Sahlgrenska University Hospital in Gothenburg, Sweden, 124 virally suppressed people living with HIV were screened to determine eligibility for this study. Sixty-one fulfilled the inclusion criteria by having plasma homocysteine levels at or above 12 μmol/L. They were randomised (1:1) to either active treatment (with cyanocobalamin 0.5 mg, folic acid 0.8 mg, and pyridoxine 3.0 mg) q.d. or to a control arm with a cross-over to active treatment after 12 months. Cognitive function was measured repeatedly during the trial, which ran for 24 months. We found a significant correlation between plasma neurofilament light protein and plasma homocysteine at screening (n = 124, r = 0.35, p < 0.0001). Plasma homocysteine levels decreased by 35% from a geometric mean of 15.7 μmol/L (95% CI 14.7–16.7) to 10.3 μmol/L (95% CI 9.3–11.3) in the active treatment arm between baseline and month 12. No significant change was detected in the control arm during the same time period (geometric mean 15.2 [95% CI 14.3–16.2] vs geometric mean 16.5 μmol/L [95% CI 14.7–18.6]). A significant difference in change in plasma homocysteine levels was seen between arms at 12 months (-40% [95% CI -48 – -30%], p < 0.001). However, no difference between arms was seen in either plasma neurofilament light protein levels (-6.5% [ -20–9%], p = 0.39), or cognitive measures (-0.08 [-0.33–0.17], p = 0.53). Our results do not support a vitamin B-dependent cause of the correlation between neurofilament light protein and homocysteine. Additional studies are needed to further elucidate this matter

The effect of vitamin B supplementation on neuronal injury in people living with HIV: a randomized controlled trial

Effective antiretroviral therapy has radically changed the course of the HIV pandemic. However, despite efficient therapy, milder forms of neurocognitive symptoms are still present in people living with HIV. Plasma homocysteine is a marker of vitamin B deficiency and has been associated with cognitive impairment. People living with HIV have higher homocysteine concentrations than HIV-negative controls, and we have previously found an association between plasma homocysteine concentration and CSF concentration of neurofilament light protein, a sensitive marker for ongoing neuronal injury in HIV. This prompted us to perform this randomized controlled trial, to evaluate the effect of vitamin B supplementation on neuronal injury in a cohort of people living with HIV on stable antiretroviral therapy. At the Department of Infectious Diseases at Sahlgrenska University Hospital in Gothenburg, Sweden, 124 virally suppressed people living with HIV were screened to determine eligibility for this study. Sixty-one fulfilled the inclusion criteria by having plasma homocysteine levels at or above 12 mu mol/l. They were randomized (1:1) to either active treatment (with cyanocobalamin 0.5 mg, folic acid 0.8 mg and pyridoxine 3.0 mg) q.d. or to a control arm with a cross over to active treatment after 12 months. Cognitive function was measured repeatedly during the trial, which ran for 24 months. We found a significant correlation between plasma neurofilament light protein and plasma homocysteine at screening (n = 124, r = 0.35, P < 0.0001). Plasma homocysteine levels decreased by 35% from a geometric mean of 15.7 mu mol/l (95% confidence interval 14.7-16.7) to 10.3 mu mol/l (95% confidence interval 9.3-11.3) in the active treatment arm between baseline and Month 12. No significant change was detected in the control arm during the same time period [geometric mean 15.2 (95% confidence interval 14.3-16.2) versus geometric mean 16.5 mu mol/l (95% confidence interval 14.7-18.6)]. A significant difference in change in plasma homocysteine levels was seen between arms at 12 months [-40% (95% confidence interval -48 to -30%), P < 0.001]. However, no difference between arms was seen in either plasma neurofilament light protein levels [-6.5% (-20 to 9%), P = 0.39], or cognitive measures [-0.08 (-0.33 to 0.17), P = 0.53]. Our results do not support a vitamin B-dependent cause of the correlation between neurofilament light protein and homocysteine. Additional studies are needed to further elucidate this matter. Tyrberg et al. report the results of a randomized controlled trial investigating the effect of vitamin B supplementation on neuronal injury in people living with HIV with effective antiretroviral therapy. Supplementation decreased levels of homocysteine but not neuronal injury measured by neurofilament light protein

Higher plasma drug levels in elderly people living with HIV treated with darunavir

Background The proportion of elderly people living with HIV-1 (PLHIV) is rising. In older patients, comorbidities and concomitant medications are more frequent, increasing the risk of potential drug-drug interactions (PDDIs). Data on the pharmacokinetics of ART in individuals aged < 65 years of age are scarce. We compared plasma drug levels of ART, PDDIs, and sideeffects in PLHIV aged < 65 years of age, with controls > 49 years of age. Methods Patients < 65 years of age and controls > 49 years of age, all of whom were on stable treatment with atazanavir (ATV), darunavir (DRV), or efavirenz (EFV) were included cross-sectionally. Plasma drug levels of ART were analyzed, comorbidities, concomitant medication, adherence, and side-effects recorded, and PDDIs analyzed using drug interactions databases. Results Between 2013 and 2015, we included 100 individuals ≥ 65 years of age (study group) and 99 controls (<49 years of age). Steady-state DRV concentrations were significantly higher in the study group than in the control group (p = 0.047). In the ATV group there was a trend towards a significant difference (p = 0.056). No significant differences were found in the EFV arm. The DRV arm had a higher frequency of reported side-effects than the ATV and EFV arms in the study group (36.7% vs. 0% and 23.8% respectively (p = 0.014), with significant differences between DRV vs. ATV, and EFV vs. ATV). Conclusions Higher steady-state plasma levels of DRV and ATV (but not EFV) were found in PLHIV aged < 65 years of age, compared to controls >49 years of age