http://www.imechanica.org/node/2788 Comments for "Postdoctoral position at RPI in modeling respiratory motion during cancer radiation therapy" en http://www.imechanica.org/node/2788#comment-11329 <p> This is good enough for all who have an radiation therapy treatment wherein example here that the tumor-bearing move organs during the radiation therapy. It is actually delevered radiation and can be have quite significant. This therapy could help a lot of cancer patient and have the complete treatment as long as the patient have consistent therapy.&nbsp;<a href="http://doctorfinders.com/doctor.php?Provider=tdzuik"> austin radiation oncologist</a> </p> <p> &nbsp; </p> <p> &nbsp; </p> <br class="clear" /> Mon, 22 Jun 2009 12:05:40 -0400 roebe comment 11329 at http://www.imechanica.org http://www.imechanica.org/node/2788 <p> <strong><span>Brief description:</span></strong><strong><span> </span></strong><span>There is an<br /> opening for a postdoctoral research position in the Advanced Computational<br /> Research Laboratory at RPI, Troy, NY to work on an ongoing R01 reesearch project sponsored by the National Institutes of Health on the modeling of respiratory motion from patient-specific 4D CT images.</span><span> </span><span>In external beam radiation treatment, a lethal radiation dose is delivered through precisely conformed<br /> external radiation to the tumor while sparing the adjacent healthy tissues.<br /> However, the current paradigm is based on an assumption that both tumor<br /> location and shape are known and remain unchanged during the course of<br /> radiation delivery. Such a favorable rigid-body relationship does not exist in<br /> anatomical sites such as the thoracic cavity and the abdomen, owing<br /> predominantly to respiratory motions.</span><span> </span><span>When the tumor-bearing normal organs move during radiation therapy, discrepancies between planned and actually delivered radiation doses can be quite<br /> significant. As a result, although higher radiation doses have shown better<br /> local tumor control, organ motions have unfortunately required less aggressive<br /> treatment strategies having relatively large dose margin to tolerate potential<br /> targeting errors. To overcome this problem we are developing physics-based, 4D<br /> motion-simulating virtual-human models to study complex radiation interactions<br /> in tissues and dose distribution patterns for various radiation delivery<br /> strategies using advanced Monte Carlo simulations.<br /> <span>&nbsp;</span><span>&nbsp;</span></span> </p> <p class="MsoNormal"> <strong><span>Qualifications:</span></strong><span> <span>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; </span></span> </p> <ol> <li class="MsoNormal"><span>PhD in Computational/Applied Mechanics or<br /> related field</span></li> <li class="MsoNormal"><span>Sound background in continuum Mechanics</span></li> <li class="MsoNormal"><span>Knowledge in Biomechanics</span></li> <li class="MsoNormal"><span>Sound background in nonlinear finite<br /> element analysis. </span></li> <li class="MsoNormal"><span>Experience in large scale computational<br /> code development in C++ necessary</span></li> <li class="MsoNormal"><span>Experience in code development on<br /> massively parallel systems highly desirable</span></li> </ol> <p class="MsoNormal"> <span>RPI is home to CCNI,&nbsp; the most powerful university-based supercomputing facility in the world<br /> (7th in the top 500 list)</span> </p> <br class="clear" /> http://www.imechanica.org/node/2788#comments job Sat, 01 Mar 2008 01:04:24 -0500 Suvranu De 2788 at http://www.imechanica.org