Pharmacokinetic Modeling of Non-Linear Brain Distribution of Fluvoxamine in the Rat

Introduction. A pharmacokinetic (PK) model is proposed for estimation of total and free brain concentrations of fluvoxamine. Materials and methods. Rats with arterial and venous cannulas and a microdialysis probe in the frontal cortex received intravenous infusions of 1, 3.7 or 7.3 mg.kg j1 of fluvoxamine. Analysis. With increasing dose a disproportional increase in brain concentrations was observed. Th

Is gut microbiota a relevant and competitive dietary target for cardio-metabolic health? Proceedings of an expert workshop

Background: The gut microbiota is a putative target for dietary interventions for cardio-metabolic health (CMH), including prevention of obesity, type 2 diabetes, and cardiovascular disease. This has generated considerable interest, but the actual feasibility for diet or specific foods to induce measurable, sustained and meaningful benefits for CMH risk by this route remains uncertain. Scope and approach: This report summarises an expert workshop assessing the gut microbiota as a relevant, feasible and competitive target for CMH benefits by dietary interventions. It summarises the expert presentations and overall view of participants on the current status and outlook, considering also implications for the food industry. Key findings and conclusions: Changing the gut microbiota by diet is possible, but an assessment of the impact on CMH risk is still needed, including clarifying advantages above other known dietary routes. The individual gut microbiota composition may in part determine the impact of diet and its effects on health. Therefore, future developments may identify individuals at risk and thus possible modification of the microbiota to achieve benefits in susceptible (sub) populations depending on their initial microbiota composition. Prebiotics currently appear to be the most promising ingredients; however, required doses may be relatively high and the actual role of gut microbiota needs further assessment. Overall, causal evidence linking gut microbiota interventions with CMH benefits are developing in preclinical models but are still lacking in humans. A significant research effort is needed and ongoing to determine whether potential effects can be reliably substantiated

Identification of novel small molecule inhibitors for solute carrier SGLT1 using proteochemometric modeling

Abstract Sodium-dependent glucose co-transporter 1 (SGLT1) is a solute carrier responsible for active glucose absorption. SGLT1 is present in both the renal tubules and small intestine. In contrast, the closely related sodium-dependent glucose co-transporter 2 (SGLT2), a protein that is targeted in the treatment of diabetes type II, is only expressed in the renal tubules. Although dual inhibitors for both SGLT1 and SGLT2 have been developed, no drugs on the market are targeted at decreasing dietary glucose uptake by SGLT1 in the gastrointestinal tract. Here we aim at identifying SGLT1 inhibitors in silico by applying a machine learning approach that does not require structural information, which is absent for SGLT1. We applied proteochemometrics by implementation of compound- and protein-based information into random forest models. We obtained a predictive model with a sensitivity of 0.64 ± 0.06, specificity of 0.93 ± 0.01, positive predictive value of 0.47 ± 0.07, negative predictive value of 0.96 ± 0.01, and Matthews correlation coefficient of 0.49 ± 0.05. Subsequent to model training, we applied our model in virtual screening to identify novel SGLT1 inhibitors. Of the 77 tested compounds, 30 were experimentally confirmed for SGLT1-inhibiting activity in vitro, leading to a hit rate of 39% with activities in the low micromolar range. Moreover, the hit compounds included novel molecules, which is reflected by the low similarity of these compounds with the training set (< 0.3). Conclusively, proteochemometric modeling of SGLT1 is a viable strategy for identifying active small molecules. Therefore, this method may also be applied in detection of novel small molecules for other transporter proteins

Inulin solid dispersion technology to improve the absorption of the BCS Class IV drug TMC240

TMC240 is a very poorly soluble and poorly permeating HIV protease inhibitor. In order to enhance its oral bioavailability, a fast dissolving inulin-based solid dispersion tablet was developed. During the dissolution test in water (0.5% or 1.0% SLS), this tablet released at least 80% of TMC240 within 30min, while a tablet with the same composition, but manufactured as physical mixture, released only 6% after 2h. In a subsequent single-dose study in dogs (200mg of TMC240), plasma concentrations of TMC240 remained below the lower limit of quantification (<1.00ng/mL) in all animals (n=3 per tested formulation), except in one dog receiving the inulin solid dispersion tablet (C(max)=1.8ng/mL, AUC(0-7 h)=3.0ngh/mL). In the latter treatment group, ritonavir co-administration (10mg/kg b.i.d.) increased TMC240 exposure more than 30-fold (mean AUC(0-7 h)=108ngh/mL; F(rel)=3588%). Exposure was also 16-fold higher than after TMC240 administration as PEG400 suspension in the presence of ritonavir (AUC(0-7 h)=6.7ngh/mL). The current data demonstrate that a solid dispersion of TMC240 in an inulin matrix allows considerable improvement in the release of poorly water-soluble TMC240, both in vitro in the presence of a surfactant and in vivo upon oral administration