Predicting future human and environmental health challenges: the Health and Environmental Sciences Institute's scientific mapping exercise.

To predict important strategic issues in product safety during the next 10 years, the Health and Environmental Sciences Institute (HESI) of the International Life Sciences Institute initiated a mapping exercise to evaluate which issues are likely to be of societal, scientific, and regulatory importance to regulatory authorities, the HESI membership, and the scientific community at large. Scientists representing government, academia, and industry participated in the exercise. Societal issues identified include sensitive populations, alternative therapies, public education on the precautionary principle, obesity, and aging world populations. Scientific issues identified include cancer testing, children's health, mixtures and co-exposures, sensitive populations, idiosyncratic reactions, "omics" or bioinformatics, and environmental toxicology. Regulatory issues identified include national and regional legislation on chemical safety, exposure inputs, new technologies, transitioning new science into regulations and guidelines, conservative default factors, data quality, and sensitive populations. Because some issues were identified as important in all three areas (e.g. sensitive populations), a comprehensive approach to assessment and management is needed to ensure consideration of societal, scientific, and regulatory implications. The resulting HESI Combined Challenges Map is not intended to offer a universal description of challenges in safety assessment, nor is it intended to address, advocate, or manage the prioritized issues. Rather, the map focuses on and predicts issues likely to be central to the strategic agendas of individual companies and regulatory authorities in the developed world. Many of these issues will become increasingly important in the future in rapidly developing economies, such as India and China. The scientific mapping exercise has particular value to the toxicology community because it represents the contributions of key scientists from around the world from government, academia, and industry.

Six-month continuous intraputamenal infusion toxicity study of recombinant methionyl human glial cell line-derived neurotrophic factor (r-metHuGDNF in rhesus monkeys.

Recombinant human glial cell line-derived neurotrophic factor (r-metHuGDNF) is a potent neuronal growth and survival factor that has been considered for clinical use in the treatment of Parkinson's disease (PD). Here we present results of a 6-month toxicology study in rhesus monkeys conducted to support clinical evaluation of chronic intraputamenal infusion of r-metHuGDNF for PD. Monkeys (6-9/sex/group) were treated with 0 (vehicle), 15, 30, or 100 microg/day r-metHuGDNF by continuous unilateral intraputamenal infusion (150 microl/day flow rate) for 6 months; a subset of animals (2-3/sex/group) underwent a subsequent 3-month treatment-free recovery period. Notable observations included reduced food consumption and body weight at 100 microg/day and meningeal thickening underlying the medulla oblongata and/or overlying various spinal cord segments at 30 and 100 microg/day. In addition, multifocal cerebellar Purkinje cell loss (with associated atrophy of the molecular layer and, in some cases, granule cell loss) was observed in 4 monkeys in the 100-microg/day group. This cerebellar finding has not been observed in previous nonclinical studies evaluating r-metHuGDNF. The small number of affected animals precludes definitive conclusions regarding the pathogenesis of the cerebellar lesion, but the data support an association with r-metHuGDNF treatment.

Six-month continuous intraputamenal infusion toxicity study of recombinant methionyl human glial cell line-derived neurotrophic factor (r-metHuGDNF) in rhesus monkeys.

Recombinant human glial cell line-derived neurotrophic factor (r-metHuGDNF) is a potent neuronal growth and survival factor that has been considered for clinical use in the treatment of Parkinson's disease (PD). Here we present results of a 6-month toxicology study in rhesus monkeys conducted to support clinical evaluation of chronic intraputamenal infusion of r-metHuGDNF for PD. Monkeys (6-9/sex/group) were treated with 0 (vehicle), 15, 30, or 100 micro g/day r-metHuGDNF by continuous unilateral intraputamenal infusion (150 micro l/day flow rate) for 6 months; a subset of animals (2-3/sex/group) underwent a subsequent 3-month treatment-free recovery period. Notable observations included reduced food consumption and body weight at 100 micro g/day and meningeal thickening underlying the medulla oblongata and/or overlying various spinal cord segments at 30 and 100 micro g/day. In addition, multifocal cerebellar Purkinje cell loss (with associated atrophy of the molecular layer and, in some cases, granule cell loss) was observed in 4 monkeys in the 100-micro g/day group. This cerebellar finding has not been observed in previous nonclinical studies evaluating r-metHuGDNF. The small number of affected animals precludes definitive conclusions regarding the pathogenesis of the cerebellar lesion, but the data support an association with r-metHuGDNF treatment.

5-Hydroxytryptamine (5HT) receptors in the heart valves of cynomolgus monkeys and Sprague-Dawley rats.

5-Hydroxytryptamine-2B receptor (5HT2BR) stimulation is known to cause fibroblast mitogenesis, and the mitogenic effect has been proposed to trigger valvular heart disease in humans. In this study, we used real-time polymerase chain reaction (TaqMan) to quantify transcript levels of 5HT2B, 5HT2C, and 5HT1B receptors and immunohistochemistry (IHC) to detect the tissue localization of these receptors in the normal heart valves of cynomolgus (CM) monkeys and Sprague-Dawley (S-D) rats. In both species, positive immunostaining was noted for 5HT1B and 5HT2B receptors in mitral, tricuspid, aortic, and pulmonary valves, and the cell types showing positive staining were interstitial cells and endothelial cells lining the valve leaflet. In CM monkeys, 5HT2CR was expressed only in the endothelial cells lining the leaflet, whereas S-D valves were negative for this receptor. IHC results were correlated with 5HT2B and 5HT1B receptor transcripts for all four valves. However, 5HT2C receptor transcripts were lower than 5HT2B or 5HT1B in all CM monkey valves, whereas 5HT2C transcripts were below the level of detection in any of the S-D rat valves. Our data showed the expression of 5HT2B, 5HT1B, and 5HT2C receptors in the normal heart valves of CM monkeys and S-D rats, and IHC and TaqMan techniques may be used to study the potential mechanism of compounds with 5HT2BR agonist activity.

Vascular effects of GI262570X (PPAR-gamma agonist) in the brown adipose tissue of Han Wistar rats: a review of 1-month, 13-week, 27-week and 2-year oral toxicity studies.

We describe and discuss microscopic findings in the brown adipose tissue (BAT) blood vessels of Han Wistar rats treated with GI262570X, a peroxisome proliferator-activated receptor-gamma agonist (PPAR-gamma agonist) by oral gavage for 28 days, 13 weeks, 27 weeks, and 2 years. Review of these studies revealed a consistent vascular change, consisting of multifocal fatty infiltration in the BAT of treated rats. A similar vascular change was not seen in other vessels or organs. Microscopically, fatty infiltration was characterized primarily by round, clear vacuoles within the tunica media and/or tunica adventitia of small and medium-sized arteries and arterioles. Occasionally, these vacuoles had peripherally located nuclei and morphologically resembled adipocytes, suggesting a well-characterized PPAR effect (ie, differentiation of stem cells or preadipocytes into mature adipocytes). However, administration of GI262570X up to 2 years failed to induce more severe or progressive lesions in the blood vessels of rat BAT and, in particular, did not result in induction of any atherosclerotic-like lesions or foam cell infiltration. At the longer exposure, there was an apparent reduction of severity and/or incidence, indicating a possible adaptive response. These results suggest that the possibility of generating atherosclerotic-like lesions through prolonged treatment of GI262570X (PPAR-gamma agonist) is highly unlikely in rats.

Endocardial myxomatous change in Harlan Sprague-Dawley rats (Hsd:S-D) and CD-1 mice: its microscopic resemblance to drug-induced valvulopathy in humans.

A full assessment of all heart valves in rats and mice is often impractical and is usually not performed in routine toxicity studies, largely due to an inevitable inconsistency of histological sampling. The majority of reported heart valve changes involve the examination of a single, semirandom section through the heart and the valvulopathy occurring with age or induced by xenobiotics may have been generally underestimated in mice and rats. Here we describe the incidence and microscopic features of endocardial myxomatous change (EMC) in Hsd:S-D rats and CD-1 mice. EMC was common and widespread in both CD-1 mice and Hsd:S-D rats (188 of 220 rats and 96 of 215 mice were affected by EMC). Microscopically, EMC consisted of focal or segmental thickening of valves, primarily due to the presence of fibromyxoid tissue in the subendocardium. Occasionally, fibrin or thrombi deposits and collection of neutrophils or mononuclear cells were observed. These microscopic features were similar to those seen in valvular disease in humans induced by fenfluramine-phentermine (fen-phen), ergot alkaloids (ergotamine, methysergide), and carcinoid syndrome. The mitral valve in rats and pulmonary valve in mice were most frequently affected. An association between murine progressive cardiomyopathy (MPC) and EMC was noted only in rats, suggesting that there may be a possible relationship between MPC and EMC. However, additional research is needed to confirm a relationship between EMC and MPC in rats and/or mice.