SHINE Medical Technologies
Industry | Medical |
---|---|
Founded | June 2010 |
Founder | Gregory Piefer |
Headquarters | Monona, Wisconsin |
Website | http://shinemed.com |
SHINE Medical Technologies, is a private corporation based in Monona, Wisconsin USA which is building a facility to produce radioactive isotopes for medical applications.[1] SHINE is an acronym for Subcritical Hybrid Intense Neutron Emitter.[2]
Business model
In 2009, the supply of molybdenum-99 (Mo-99), a precursor to technetium-99m used in more than 30 medical imaging procedures, fell short of demand due to maintenance idling of a pair of research reactors, one located in the Netherlands, forcing doctors to use more dangerous isotopes.[3][4] By 2016, the largest global supplier of the isotope, a Canadian research reactor, was scheduled to go idle.[3][4] In 2010, the National Nuclear Security Administration (NNSA), a part of the United States Department of Energy, began funding a number of method development ventures aimed at ensuring that shortages in the United States could be avoided[4] as well as reducing the use of highly enriched uranium and with it lowering the risk of nuclear proliferation.[5]
SHINE was among a handful of early recipients of funds from the NNSA program and received US$13.9 million through it as of 2014.[4] SHINE has also relied on venture capital funding, having secured up to US$125 million from Deerfield Management beginning in October 2014.[4][6]
The 2014 market for medical isotopes was estimated to be about US$600 million per year.[4] Several companies in addition to SHINE are vying for part of this market, and the need for redundancy in production will support a number suppliers beyond the minimum needed to meet current demand.[4]
The company plans to start production scale generation of isotope until 2018, having pushed the proposed start date back several times,[7] it has secured a number of supply agreements predicated on this start date.[4][8]
In addition to supplying Mo-99, SHINE has secured a US$150,000 National Science Foundation grant to develop production methods for Iodine-131, used in the treatment of Graves' disease and certain cancers.[9]
Facilities and technology
Original technology for production of Mo-99 was reactor-based and unavoidably produced significant nuclear waste.[3] SHINE plans to use particle accelerator technology developed at the University of Wisconsin–Madison by company founder Gregory Piefer.[4][9] The method, referred to as "neutron generator technology", uses helium and free neutrons, produced by colliding a beam of deuterium particles with tritium gas, to bombard low-level enriched uranium targets leading to the production of "useful isotopes with minimal waste."[4] In addition to the diagnostically useful Mo-99, the process can also produce Iodine-131, used in medical treatments.[1]
In 2013, SHINE constructed a full-scale prototype particle accelerator at their Monona, Wisconsin facility to be used to demonstrate the technology. Eight accelerators would be used at the Janesville facility.[10]
On June 15, 2015, Argonne National Laboratory demonstrated that SHINE's production, separation and purification process could produce Mo-99 which meets purity specifications of the British Pharmacopoeia.[5]
The NRC approved SHINE's construction permit for a facility in Janesville, Wisconsin in late February 2016. If constructed, the facility would still require NRC licensing to operate.[11] In 2014 the facility was originally slated for opening in 2016, was then delayed to 2017.[12] As of February 2016, construction was planned for 2017 with production potentially beginning in 2019.[11]
References
- 1 2 Gallagher, Kathleen (June 30, 2015). "Shine Medical Technologies receives $150,000 National Science Foundation grant". The Milwaukee Journal Sentinel. Retrieved 2015-07-24.
- ↑ Chemerisov, S. (April 14, 2014). "Development of the mini-SHINE/MIPS experiments" (PDF). Argonne National Laboratory. doi:10.2172/1132249. Retrieved July 17, 2015.
- 1 2 3 Noorden, Richard Van (December 11, 2013). "Radioisotopes: The medical testing crisis". Nature 504 (7479): 202–204. doi:10.1038/504202a. ISSN 0028-0836. PMID 24336269. Retrieved 14 July 2015.
- 1 2 3 4 5 6 7 8 9 10 LaMonica, Martin (December 18, 2014). "Startups Race to Solve Looming Medical Radioisotope Crisis". Xconomy. Retrieved July 23, 2015.
The company has supply agreements in place and plans to build a production plant in Janesville, WI.
- 1 2 Cunningham, Greg (June 15, 2015). "Argonne confirms new commercial method for producing medical isotope". Argonne National Lab. Retrieved July 17, 2015.
- ↑ Engel, Jeff (October 9, 2014). "Deerfield Pouring $125M Into WI Startup Shine Medical Technologies". Xconomy. Retrieved July 23, 2015.
- ↑ Newman, Judy. "Environmental report supports SHINE Medical's plan to build radioisotope plant in Janesville". Wisconsin State Journal. Retrieved July 23, 2015.
- ↑ Gallagher, Kathleen (April 3, 2014). "Shine Medical Technologies signs supply contract with GE Healthcare". Milwaukee Journal Sentinel. Retrieved July 23, 2015.
- 1 2 Gallagher, Kathleen (September 3, 2014). "Shine Medical Technologies raises $2.4 million". Milwaukee Journal Sentinel. Retrieved July 23, 2015.
- ↑ Leute, Jim (February 17, 2013). "Testing 1, 2, 3: SHINE makes progress at demonstration facility". Janesville Gazette. Retrieved July 17, 2015.
- 1 2 Newman, Judy (February 25, 2016). "SHINE Medical wins NRC's OK to build medical isotope plant". Wisconsin State Journal. Retrieved February 25, 2016.
- ↑ "Financing deal for $125 million brings SHINE Janesville plant closer to reality". The Janesville Gazette. October 10, 2014. Retrieved July 23, 2015.(subscription required)
External links
- Official website
- "SHINE Medical Technologies v. 0, ML14356A515". NRC.gov. May 19, 2015.