The Worldwide Alzheimer's Disease Neuroimaging Initiative: ADNI-3 updates and global perspectives.

The Worldwide Alzheimer's Disease Neuroimaging Initiative (WW-ADNI) is a collaborative effort to investigate imaging and biofluid markers that can inform Alzheimer's disease treatment trials. It is a public-private partnership that spans North America, Argentina, Australia, Canada, China, Japan, Korea, Mexico, and Taiwan. In 2004, ADNI researchers began a naturalistic, longitudinal study that continues today around the globe. Through several successive phases (ADNI-1, ADNI-GO, ADNI-2, and ADNI-3), the study has fueled amyloid and tau phenotyping and refined neuroimaging methodologies. WW-ADNI researchers have successfully standardized analyses and openly share data without embargo, providing a rich data set for other investigators. On August 26, 2020, the Alzheimer's Association convened WW-ADNI researchers who shared updates from ADNI-3 and their vision for ADNI-4.

Effects of Rifamycin Coadministration on Bedaquiline Desmethylation in Healthy Adult Volunteers.

There is an urgent need to identify safe and effective combination treatments for multidrug-resistant (MDR) Mycobacterium tuberculosis infection (TB). Bedaquiline, a new diarylquinoline, is approved for the treatment of MDR pulmonary TB in combination with other drugs, which could include rifabutin, which is also used to treat drug-resistant TB. Both rifabutin and bedaquiline are metabolized via cytochrome P450 3A4, and rifabutin is an inducer of this enzyme. Bedaquiline is metabolized into its primary N-monodesmethyl metabolite, M2, and further desmethylated into an N-didesmethyl metabolite, M3. Both metabolites are cytotoxic and induce phospholipidosis. The effect of rifabutin on the generation and disposition of the 2 metabolites was investigated in healthy adult volunteers coadministered bedaquiline and either rifabutin or rifampin. Subjects received single oral doses (400 mg) of bedaquiline on days 1 and 29. Oral rifabutin (300 mg) or rifampin (600 mg) were given daily on days 20-41. In the rifabutin group maximum M2 concentrations (Cmax ) increased significantly (P < .001) from 47.59 to 79.53 ng/mL, and clearance slowed slightly (P = .01). This resulted in significantly (P < .001) increased overall exposure (area under the concentration-time curve [AUC0-τ ]). Peak concentrations of M3 increased approximately 3-fold with little decline thereafter. In rifampin recipients M2 Cmax doubled (48.44 to 101.52 ng/mL), but M2 clearance and time to Cmax significantly (P < .001) increased, and AUC0-∞ and mean residence time significantly decreased (P < .001). Peak M3 concentrations increased 4-fold and rapidly declined. Although both rifamycins accelerate desmethylation of bedaquiline and M2, differences in clearance resulted in sustained elevations of both metabolites during rifabutin, but not rifampin, treatment.

Impact of Rifabutin or Rifampin on Bedaquiline Safety, Tolerability, and Pharmacokinetics Assessed in a Randomized Clinical Trial with Healthy Adult Volunteers.

Bedaquiline is a diarylquinoline that specifically inhibits mycobacterial ATP synthase. Bedaquiline has been used to effectively treat tuberculosis (TB) caused by drug-susceptible and drug-resistant Mycobacterium tuberculosis Rifamycins are a cornerstone of combination drug regimens for the treatment of TB. This phase 1, open-label, randomized, controlled trial evaluated the effect of steady-state dosing of rifabutin or rifampin on the safety, tolerability, and pharmacokinetics of bedaquiline given as a single dose. Thirty-three healthy subjects were enrolled to receive a 400-mg single oral dose of bedaquiline at two time points, on study days 1 and 29. Subjects were randomly assigned to once daily oral doses of rifabutin (300 mg/day, n = 17) or rifampin (600 mg/day, n = 16) during period 2 from days 20 to 41. Serial blood sampling for bedaquiline measurement occurred on days 1 and 29 through 336 h after bedaquiline administration. The day 29 bedaquiline pharmacokinetic parameter estimates were compared to the corresponding day 1 estimates for each rifamycin group. Steady-state rifampin reduced bedaquiline AUC0-336 approximately 45%, from 47.69 h·µg/ml in period 1 to 26.33 h·µg/ml in period 2. Bedaquiline apparent clearance accelerated 24% in rifampin-treated subjects from 6.59 liters/h in period 1 to 8.19 liters/h in period 2. Steady-state rifabutin resulted in little quantitative impact on bedaquiline exposure but was associated with grade 3 and 4 adverse events before and after the day 29 bedaquiline dose. Dosage adjustments may therefore be necessary to ensure that bedaquiline plasma concentrations reach therapeutic levels safely when combining bedaquiline and rifamycins in TB treatment regimens. (This single-site, randomized, open-label, prospective study in healthy adult volunteers was registered at Clinicaltrials.gov under registration no. NCT01341184.).