This workshop was organized so that experts from different sector

This workshop was organized so that experts from different sectors (academia, industry, government, non-profit) could discuss their understanding of what makes an endocrine-active substance

an endocrine disrupter. A goal of the workshop www.selleckchem.com/products/Trichostatin-A.html was to stimulate an informed debate in which scientific results could be presented, interpreted and discussed relevant to their application in legislation. The Science of Endocrine Disrupters and Relevance to Human Health. Dr. Jan-Åke Gustafsson*, Karolinska Institute, Sweden. This presentation defined hormones as signaling molecules that communicate with cells throughout the body. Hormones are responsible for homeostasis and are also particularly important during embryonic development, puberty and reproduction.

Hormones act by binding FXR agonist to hormone receptors located in the nucleus of their target cells (for thyroid hormone and sex steroids). This hormone-receptor complex then regulates the transcription of genes (Fig. 1a). Endocrine disrupters may interfere with the functioning of hormonal systems in at least three possible ways: 1) By mimicking the action of a naturally-produced hormone, producing similar but exaggerated chemical reactions in the body (Fig. 1b); 2) By blocking hormone receptors, preventing or diminishing the action of normal hormones (Fig. 1b) and 3) By affecting the synthesis, transport, metabolism and/or excretion of hormones, thus altering the concentrations of natural hormones. In some species of wildlife and in laboratory animals, endocrine disrupters have been reported to

have harmful effects on reproduction, growth and development. In humans, increases in some diseases and disorders may be related to disturbance of the endocrine system. There are many disorders of the foetal, pubertal and adult reproductive system, in both males and females, which are believed to involve endocrine disruption in their pathogenesis (Diamanti-Kandarakis et al., 2009). Two of these, breast cancer and testicular cancer, have Glutamate dehydrogenase increased dramatically: an 81% rise in breast cancer between 1971 and 1991 in the UK and a 46% rise in testicular cancer between 1995 and 2006 in the US state of Texas for example. In both of these groups, the largest increases in cancer incidence were not in the oldest age brackets, as would be expected if longer life spans led to more cancer, but instead in the 55–64 and 20–50 year old groups, respectively. It is possible that these increases are due, at least in part, to the increase in endocrine-active chemicals in the environment. Support for the idea that chemical exposure is linked to testicular cancer comes from a study in Northern Europe showing that Denmark has a higher incidence of testicular cancer than Finland.

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