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3D Printer Put to Work in Developing Cancer-Measuring Transducer http://ift.tt/2nh4G4c According to the American Cancer Society, in 2017 alone, an estimated 1,688,780 new cancer cases will be diagnosed in the US, and I’m guessing that number is pretty high for other countries as well. So it’s always good to hear about new research and projects centered around early diagnosis and cancer treatment. Medical device contractor the ITL Group (Integrated Technologies Ltd.) recently teamed up with King’s College London (KCL) to develop a cancer imaging project, which will assist with the planning and monitoring of cancer treatment through better initial identification, and sizing, of cancer tumors in the body. The project is funded by the European Commission’s Horizon 2020 framework, the biggest EU Research and Innovation program ever, with nearly €80 billion of funding available over a total of seven years (2014 to 2020). It is seen as a means to create jobs and drive economic growth, and has provided funding for multiple projects that use 3D printing, such as the MESO-BRAIN Initiative’s work with emulating accurate brain activity, and the collaborative Bionic Aircraft research project. The cancer imaging project brings together a consortium of 20 companies, including among them ITL Group, KCL, Philips, and Siemens, to combine engineering developments with Magnetic Resonance Imaging (MRI) in order to make Magnetic Resonance Force (MRF) Imaging for new cancer diagnostics applications, which could potentially give doctors a non-invasive way to both diagnose and measure cancerous tumors. ITL Group joined as a medical device design, development and manufacturing partner in 2015; once early project elements were completed this year, it became an active consortium participant. The consortium has been tasked with producing three prototypes: one each for brain, breast, and liver cancer patients. KCL came up with the initial hardware design: an advanced vibration transducer that measures cell traction forces and interstitial fluid pressure. ITL Group will continue to develop the original design, taking into account KCL’s thoughts on making the device more aesthetically pleasing and compact, easier to handle, and more efficient. The company plans to make several prototypes, which will be ready for trials and presented to Harvard Medical School this June. ITL has been hard at work, improving upon the original vibration transducers, and continuing to develop the technology that could help doctors determine the best course of treatment for cancer patients. ITL has been using a 3D printer for a trial period during this project, and it’s not the first time we’ve seen 3D printing used to make an impact in MRI research and development, from 3D printed MRIs for patient education, to a 3D printed gas delivery system for pulmonary MRI research. The technology works well with this particular project: since the transducer will be put to work in an MRI scanner, it’s imperative that all of its components are plastic. 3D printing additionally allows for a fast turnaround, offering another benefit to progress in development.
ITL has worked on a great deal of commercial projects over the past 40 years, and partnered with many of the top universities in the UK. But the grant from Horizon 2020 allows Hollands and the rest of the team the time and resources to experiment more freely, in order to really “push the design to its limits.”
[Source: ITL Group]
Printing via 3DPrint.com https://3dprint.com March 29, 2017 at 03:57AM
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