Quantitative Determination of (R)-3-Hydroxybutyl (R)-3-Hydroxybutyrate (Ketone Ester) and Its Metabolites Beta-hydroxybutyrate, 1-3-Butanediol, and Acetoacetate in Human Plasma Using LC-MS.

Ketone ester ((R)-3-hydroxybutyl (R)-3-hydroxybutyrate) has gained popularity as an exogenous means to achieve ketosis. Regarding its potential as a therapeutic prodrug, it will be necessary to study its pharmacokinetic profile and its proximal metabolites (beta-hydroxybutyrate, 1,3-butanediol, and acetoacetate) in humans. Here we develop and validate two LC-MS methods for quantifying KE and its metabolites in human plasma. The first assay uses a C18 column to quantitate ketone ester, beta-hydroxybutyrate, and 1,3-butanediol, and the second assay uses a hydrophilic interaction liquid chromatography (HILIC) column for the quantitation of acetoacetate. The method was partially validated for intra- and inter-day accuracy and precision based on the ICH M10 guidelines. For both the assays, the intra- and inter-run accuracy was ±15% of the nominal concentration, and the precision (%CV) was <15% for all 4 molecules being quantified. The matrix effect for all molecules was evaluated and ranged from -62.1 to 44.4% (combined for all molecules), while the extraction recovery ranged from 65.1 to 119% (combined for all molecules). Furthermore, the metabolism of ketone ester in human plasma and human serum albumin was studied using the method. Non-saturable metabolism of ketone ester was seen in human plasma at concentrations as high as 5 mM, and human serum albumin contributed to the metabolism of ketone ester. Together, these assays can be used to track the entire kinetics of ketone ester and its proximal metabolites. The reverse-phase method was used to study the metabolic profile of KE in human plasma and the plasma protein binding of 1,3-BD.

The Caco-2 Model: Modifications and enhancements to improve efficiency and predictive performance.

The Caco-2 cell model has been widely used to assess the permeability of drug candidates. It has provided a high throughput in vitro platform, functionally resembling the enterocytes. Since the oral route is the most preferred for drug administration, the Caco-2 cell model acts as a very important tool to elucidate the oral "druggability" of a molecule by providing a fairly reliable estimate of its permeability through the intestinal membrane. Despite its shortcomings (the lack of a mucus layer, long cultivation period, inter-lab variability, and differences in expression of enzymes, transporters, and tight junction complexes) it remains heavily used due to its reliability, predictive performance, and wide acceptance. Various modifications have been made: co-culturing with other intestinal cells, applying biosimilar mucus, reducing culturing time, combining Caco-2 monolayer with the dissolution apparatus, enhancing protein expression, and redesigning the sampling apparatus. These modifications are intended to overcome some of the shortcomings of the Caco-2 model in order to make its use easier, quicker, economical, and more representative of the intestine. The aim of this review is to discuss such modifications to enhance this model's utility, predictive performance, and reproducibility.