Radiation-induced damage to the lens of the eye can include the loss of clarity resulting in opacification or clouding several years after exposure. The impact is highly dependent on the type of radiation, how the exposure of the lens was delivered, the genetic susceptibilities of the individual exposed, and the location of the opacity relative to the visual axis of the individual. The preponderance of epidemiological evidence suggests that lens damage could occur at lower doses than previously considered and the NCRP has determined that it is prudent to reduce the recommended annual lens of the eye occupational dose limit from an equivalent dose of 150 mSv to an absorbed dose of 50 mGy. Significant additional research is still needed in the following areas: comprehensive evaluation of the overall effects of ionizing radiation on the eye, dosimetry methodology and dose-sparing optimization techniques, additional high quality epidemiology studies, and a basic understanding of the mechanisms of cataract development.
The National Council on Radiation Protection and Measurements (NCRP) established NCRP Scientific Committee 2-6 to develop a report on the current state of knowledge and guidance for radiation safety programs involved with nanotechnology. Nanotechnology is the understanding and control of matter at the nanoscale, at dimensions between ∼1 and 100 nm, where unique phenomena enable novel applications. While the full report is in preparation, this paper presents and applies an informatics-based decision-making framework and process through which the radiation protection community can anticipate that nano-enabled applications, processes, nanomaterials, and nanoparticles are likely to become present or are already present in radiation-related activities; recognize specific situations where environmental and worker safety, health, well-being, and productivity may be affected by nano-related activities; evaluate how radiation protection practices may need to be altered to improve protection; control information, interpretations, assumptions, and conclusions to implement scientifically sound decisions and actions; and confirm that desired protection outcomes have been achieved. This generally applicable framework and supporting process can be continuously applied to achieve health and safety at the convergence of nanotechnology and radiation-related activities.
Previous National Council on Radiation Protection and Measurements (NCRP) publications have addressed the issues of risk and dose limitation in radiation protection and included guidance on specific organs and the lens of the eye (NCRP 1987, 1989, 1993a, 1993b, 1995a, 1995b, 2000b, 2001b, 2010a, 2010b, 2013). NCRP decided to prepare an updated commentary intended to enhance the previous recommendations provided in these earlier reports. NCRP Scientific Committee 1-23 (SC 1-23) (NCRP 2015) is charged with preparing a commentary that will evaluate recent studies on the radiation dose response for the development of cataracts, and also consider the type and severity of the cataracts as well as the dose rate; provide guidance on whether existing dose limits to the lens of the eye should be changed in the United States; and suggest research needs regarding radiation effects on and dose limits to the lens of the eye. A status of the ongoing work of SC 1-23 was presented at the NCRP 2015 Annual Meeting, “Changing Regulations and Radiation Guidance: What Dose the Future Hold?” The following represents a synopsis of a few main points in the current draft commentary. It is likely that several changes will be forthcoming as SC 1-23 responds to subject matter expert review and develops a final document, expected later in 2015.
Two derivatives of (RS)-1-azabicyclo[2.2.2]oct-3-yl (RS)-alpha-hydroxy-alpha-(4-iodophenyl)-alpha-phenylacetate (1a) and three partially resolved (R)- or (S)-1-azabicyclo[2.2.2]oct-3-yl (RS)-alpha-hydroxy-alpha-(4-iodophenyl)-alpha-phenylacetates labeled with no carrier added iodine-125 (1b, 18, and 19) and iodine-123 (1c and 18a) were synthesized by the Wallach triazene approach. We have found that this approach is necessary to obtain no carrier added labeling and gives far better results than the direct electrophilic iodination. The obtained yields were 7 to 18% when using iodine-123 (yield dependent on the source of iodide) and up to 17% for iodine-123 (yield dependent on the source of iodide) and up to 17% for iodine-125 labeled compounds. Our preliminary distribution studies indicate that 1b localizes in the organs known to have a large concentration of muscarinic receptors and that this localization is due to binding to those receptors.
During vaginal delivery, the fetus is exposed to a variety of stresses including pressure applied to the fetal skull. In order to study the effects of this stress on fetal homeostasis, we monitored the response to external cephalic compression applied to the acutely prepared near-term fetal lamb. In response to cephalic pressure, we noted initial bradycardia followed by sustained tachycardia. Mean arterial pressure and pulse pressure rose during cephalic pressure and gradually returned to baseline levels. Cerebral blood flow fell approximately 95% early in the period of compression. This fall in total cerebral blood flow was accompanied by a redistribution of cerebral flow. During this time, a smaller percentage of cerebral blood flow was found in the cortex and a greater percentage was directed to the brainstem.
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