Health Risk Assessment of Ortho-Toluidine Utilising Human Biomonitoring Data of Workers and the General Population.

The aim of this work was to demonstrate how human biomonitoring (HBM) data can be used to assess cancer risks for workers and the general population. Ortho-toluidine, OT (CAS 95-53-4) is an aniline derivative which is an animal and human carcinogen and may cause methemoglobinemia. OT is used as a curing agent in epoxy resins and as intermediate in producing herbicides, dyes, and rubber chemicals. A risk assessment was performed for OT by using existing HBM studies. The urinary mass-balance methodology and generic exposure reconstruction PBPK modelling were both used for the estimation of the external intake levels corresponding to observed urinary levels. The external exposures were subsequently compared to cancer risk levels obtained from the evaluation by the Scientific Committee on Occupational Exposure Limits (SCOEL). It was estimated that workers exposed to OT have a cancer risk of 60 to 90:106 in the worst-case scenario (0.9 mg/L in urine). The exposure levels and cancer risk of OT in the general population were orders of magnitude lower when compared to workers. The difference between the output of urinary mass-balance method and the general PBPK model was approximately 30%. The external exposure levels calculated based on HBM data were below the binding occupational exposure level (0.5 mg/m3) set under the EU Carcinogens and Mutagens Directive.

A new approach to predict human intestinal absorption using porcine intestinal tissue and biorelevant matrices.

A reliable prediction of the oral bioavailability in humans is crucial and of high interest for pharmaceutical and food industry. The predictive value of currently used in silico methods, in vitro cell lines, ex vivo intestinal tissue and/or in vivo animal studies for human intestinal absorption, however, is often insufficient, especially when food-drug interactions are evaluated. Ideally, for this purpose healthy human intestinal tissue is used, but due to its limited availability there is a need for alternatives. The aim of this study was to evaluate the applicability of healthy porcine intestinal tissue mounted in a newly developed InTESTine™ system to predict human intestinal absorption of compounds with different chemical characteristics, and within biorelevant matrices. To that end, first, a representative set of compounds was chosen of which the apparent permeability (Papp) data in both Caco-2 cells and human intestinal tissue mounted in the Ussing chamber system, and absolute human oral bioavailability were reported. Thereafter, Papp values of the subset were determined in both porcine jejunal tissue and our own Caco-2 cells. In addition, the feasibility of this new approach to study regional differences (duodenum, jejunum, and ileum) in permeability of compounds and to study the effects of luminal factors on permeability was also investigated. For the latter, a comparison was made between the compatibility of porcine intestinal tissue, Caco-2 cells, and Caco-2 cells co-cultured with the mucin producing HT29-MTX cells with biorelevant samples as collected from an in vitro dynamic gastrointestinal model (TIM). The results demonstrated that for the paracellularly transported compounds atenolol, cimetidine, mannitol and ranitidine porcine Papp values are within 3-fold difference of human Papp values, whereas the Caco-2 Papp values are beyond 3-fold difference. Overall, the porcine intestinal tissue Papp values are more comparable to human Papp values (9 out of 12 are within 3-fold difference), compared to Caco-2 Papp values (4 out of 12 are within 3-fold difference). In addition, for the selected hydrophilic compounds a significant increase in the permeability was observed from duodenum to ileum. Finally, this study indicated that porcine jejunal tissue segments can be used with undiluted luminal samples to predict human intestinal permeability and the effect of biorelevant matrices on this. In conclusion, viable porcine intestinal tissue mounted in the InTESTine™ system can be applied as a reliable tool for the assessment of intestinal permeability in the absence and presence of biorelevant samples. This would enable an accessible opportunity for a reliable prediction of human intestinal absorption, and the effect of luminal compounds such as digested foods, early in drug development.

Prediction of methotrexate CNS distribution in different species - influence of disease conditions.

Children and adults with malignant diseases have a high risk of prevalence of the tumor in the central nervous system (CNS). As prophylaxis treatment methotrexate is often given. In order to monitor methotrexate exposure in the CNS, cerebrospinal fluid (CSF) concentrations are often measured. However, the question is in how far we can rely on CSF concentrations of methotrexate as appropriate surrogate for brain target site concentrations, especially under disease conditions. In this study, we have investigated the spatial distribution of unbound methotrexate in healthy rat brain by parallel microdialysis, with or without inhibition of Mrp/Oat/Oatp-mediated active transport processes by a co-administration of probenecid. Specifically, we have focused on the relationship between brain extracellular fluid (brainECF) and CSF concentrations. The data were used to develop a systems-based pharmacokinetic (SBPK) brain distribution model for methotrexate. This model was subsequently applied on literature data on methotrexate brain distribution in other healthy and diseased rats (brainECF), healthy dogs (CSF) and diseased children (CSF) and adults (brainECF and CSF). Important differences between brainECF and CSF kinetics were found, but we have found that inhibition of Mrp/Oat/Oatp-mediated active transport processes does not significantly influence the relationship between brainECF and CSF fluid methotrexate concentrations. It is concluded that in parallel obtained data on unbound brainECF, CSF and plasma concentrations, under dynamic conditions, combined with advanced mathematical modeling is a most valid approach to develop SBPK models that allow for revealing the mechanisms underlying the relationship between brainECF and CSF concentrations in health and disease.

2,6,8-trisubstituted 1-deazapurines as adenosine receptor antagonists.

In this study we developed a refined pharmacophore model for antagonists of the human adenosine A1 receptor, based on features of known pyrimidine and purine derivatives. The adoption of these updated criteria assisted us in synthesizing a series of 1-deazapurines with consistently high affinity as inverse agonists for the adenosine A1 receptor. These 1-deazapurines (otherwise known as 3H-imidazo[4,5-b]pyridines) were substituted at their 2- and 6-positions, yielding a series with five of the derivatives displaying Ki values in the subnanomolar range. The most potent of these, compound 10 (LUF 5978), displayed an affinity of 0.55 nM at the human adenosine A1 receptor with >300-fold and 45-fold selectivity toward A2A and A3 receptors, respectively. Compound 14 (LUF 5981, Ki = 0.90 nM) appeared to have the best overall selectivity with respect to adenosine A2A (>200-fold) and A3 (700-fold) receptors.