Evaluation of the Pharmacokinetics and Safety of AMG 986 Tablet and Capsule Formulations in Healthy Adult Subjects: A Phase I, Open-Label, Randomized Study.

BACKGROUND AND OBJECTIVE: AMG 986 is a first-in-class, novel apelin receptor small molecule agonist initially developed for the treatment of heart failure. The current phase I study was conducted to evaluate the pharmacokinetics and safety of a single-dose 200-mg capsule formulation of AMG 986 relative to the tablet formulation in 12 healthy subjects. METHODS: In a two-period, two-way crossover design, eligible subjects were randomized 1:1 to tablet/capsule or capsule/tablet treatment sequences; each treatment sequence lasted for approximately 6 days and comprised six subjects. RESULTS: Following a single oral dose of AMG 986, the geometric mean maximum observed concentration (Cmax) values were 9670 ng/mL and 6920 ng/mL and the geometric mean area under the curve from time zero to 120 h (AUC0-120h) values were 68,000 ng*h/mL and 59,900 ng*h/mL for the tablet and capsule, respectively. The geometric least squares means (90% confidence interval [90% CI]) for the ratios of capsule/tablet were 0.88 (90% CI 0.81-0.96) and 0.72 (90% CI 0.57-0.91) for AUC0-120h and Cmax, respectively. AMG 986 had an acceptable safety profile; all adverse events were grade 1 or 2 in severity. CONCLUSION: There was a modest 12% decrease in AUC0-120h and a 28% decrease in Cmax with the AMG 986 capsule versus the tablet. These differences are not considered to be clinically relevant, suggesting the capsule formulation can be used in subsequent clinical studies of AMG 986.

Calculation of effective penetration depth in X-ray diffraction for pharmaceutical solids.

The use of the glancing incidence X-ray diffraction configuration to depth profile surface phase transformations is of interest to pharmaceutical scientists. The Parratt equation has been used to depth profile phase changes in pharmaceutical compacts. However, it was derived to calculate 1/e penetration at glancing incident angles slightly below the critical angle of condensed matter and is, therefore, applicable to surface studies of materials such as single crystalline nanorods and metal thin films. When the depth of interest is 50-200 microm into the surface, which is typical for pharmaceutical solids, the 1/e penetration depth, or skin depth, can be directly calculated from an exponential absorption law without utilizing the Parratt equation. In this work, we developed a more relevant method to define X-ray penetration depth based on the signal detection limits of the X-ray diffractometer. Our definition of effective penetration depth was empirically verified using bilayer compacts of varying known thicknesses of mannitol and lactose.

The Arabidopsis Aux/IAA protein family has diversified in degradation and auxin responsiveness.

Rapid, auxin-responsive degradation of multiple auxin/indole-3-acetic acid (Aux/IAA) proteins is essential for plant growth and development. Domain II residues were previously shown to be required for the degradation of several Arabidopsis thaliana Aux/IAA proteins. We examined the degradation of additional full-length family members and the proteolytic importance of N-terminal residues outside domain II using luciferase (LUC) fusions. Elimination of domain I did not affect degradation. However, substituting an Arg for a conserved Lys between domains I and II specifically impaired basal degradation without compromising the auxin-mediated acceleration of degradation. IAA8, IAA9, and IAA28 contain domain II and a conserved Lys, but they were degraded more slowly than previously characterized family members when expressed as LUC fusions, suggesting that sequences outside domain II influence proteolysis. We analyzed the degradation of IAA31, with a region somewhat similar to domain II but without the conserved Lys, and of IAA20, which lacks domain II and the conserved Lys. Both IAA20:LUC and epitope-tagged IAA20 were long-lived, and their longevity was not influenced by auxin. Epitope-tagged IAA31 was long-lived, like IAA20, but by contrast, it showed accelerated degradation in response to auxin. The existence of long-lived and auxin-insensitive Aux/IAA proteins suggeststhat they may play a novel role in auxin signaling.