Grigoriev Institute for Medical Radiology explained

Grigoriev Institute for Medical Radiology
Established:30 July 1920
Chairman:Mykola Krasnoselskyi
Staff:470
Owner:National Academy of Medical Science of Ukraine (NAMS)
City:Kharkiv
Country:Ukraine
Address:82 Pushkinska St., Kharkiv, 61024, Ukraine

Grigoriev Institute for Medical Radiology (GIMR) is a medical radiology and oncology research institution in Kharkiv, Ukraine, founded in 1920. GIMR works in the areas of radiation oncology, radiology, radiotherapy, clinical radiobiology, radiation dosimetry in medicine and radiation safety of patients and medical personnel. The main campus is located at 82 Pushkinska St., Kharkiv, Ukraine.

History

The Institute was founded on July 30, 1920 by the Decree of the Council of People's Commissars of the Ukrainian SSR as the All-Ukrainian X-ray Academy.[1]

In 1925, it was renamed to the Ukrainian X-ray and Radiological Institute, which was reorganized on December 15, 1955 by order No. 591 of the Ministry of Healthcare of Ukraine into the Kharkov Scientific Research Institute of Medical Radiology with the main scientific focus called "Scientific Foundations of Medical Radiology".According to the Decree of the Cabinet of Ministers of Ukraine No. 1232 from 7 August 2000, the Institute was transferred to the Academy of Medical Sciences of Ukraine and renamed as State Organization “Grigoriev Institute for Medical Radiology of the National Academy of Medical Science of Ukraine” (Order of the Academy of Medical Sciences of Ukraine No. 51 from September 29, 2000).

Mission

For the last 20 years, the institute acts as the chief clinical research body in Ukraine in areas of radiation and clinical oncology,[2] radiotherapy, nuclear medicine, treatment of radiation injuries,[3] clinical radiobiology[4] and radiation protection[5] [6] of patients and medical personnel.

Research

All scientific and practical activities of the GIMR are aimed at the development and implementation into the healthcare applications of novel solutions in clinical oncology, radiation diagnostics, radiotherapy, radiation pathology, dosimetry[7] and hygiene of medical irradiations.[8]

National and international collaborations

Scientific interactions with Western and international scientific institutions include a long term cooperation with the International Atomic Energy Agency (Vienna, Austria), the Center of Radiation, Chemical and Environmental Hazards of the Public Health England (former Health Protection Agency, earlier the National Radiological Protection Board, the UK)[9] and various institutions in EU countries via collaboration within the CEC-EU funded research programs.[10]

See also

Notes and References

  1. Web site: Grigoriev Institute for Medical Radiology of National Academy of Medical Sciences of Ukraine Enterprise Catalogue "Ukraine Today". www.rada.com.ua. 2019-08-18.
  2. La Russa. M.. Zapardiel. I.. Halaska. M. J.. Zalewski. K.. Laky. R.. Dursun. P.. Lindquist. D.. Sukhin. V.. Polterauer. S.. August 2018. Conservative management of endometrial cancer: a survey amongst European clinicians. Archives of Gynecology and Obstetrics. 298. 2. 373–380. 10.1007/s00404-018-4820-7. 29943129. 0932-0067.
  3. Vinnikov. Volodymyr. Belyakov. Oleg. 2019-03-27. Radiation Protection Dosimetry. 10.1093/rpd/ncz038. 30916766. 0144-8420. Clinical Applications of Biomarkers of Radiation Exposure: Limitations and Possible Solutions Through Coordinated Research.
  4. Badie. Christophe. Cruz-Garcia. Lourdes. Polozov. Stanislav. Radiation Protection Dosimetry. 10.1093/rpd/ncz053. 31137037. Rapid Gene Expression Based Dose Estimation for Radiological Emergencies. 2019. free.
  5. Cherniavskiy. Igor Yu. Vinnikov. Volodymyr A.. July 2019. The assessment of radiation hazardous areas considering the spectral analysis of the neutron component of a tactical neutron bomb detonation. Applied Radiation and Isotopes. 149. 152–158. 10.1016/j.apradiso.2019.04.032. 31063964.
  6. Edwards. A.. Voisin. P.. Sorokine-Durm. I.. Maznik. N.. Vinnikov. V.. Mikhalevich. L.. Moquet. J.. Lloyd. D.. Delbos. M.. 2004. Biological estimates of dose to inhabitants of Belarus and Ukraine following the Chernobyl accident. Radiation Protection Dosimetry. 111. 2. 211–219. 10.1093/rpd/nch039. 0144-8420. 15266074.
  7. Vinnikov. Volodymyr A.. Ainsbury. Elizabeth A.. Maznyk. Nataliya A.. Lloyd. David C.. Rothkamm. Kai. 2010-07-14. Limitations Associated with Analysis of Cytogenetic Data for Biological Dosimetry. Radiation Research. 174. 4. 403–14. 10.1667/RR2228.1. 20726714. 0033-7587. 2010RadR..174..403V.
  8. Stadnyk. L.. Shalopa. O.. Nosyk. O.. July 2015. Collective effective dose from diagnostic radiology in Ukraine. Radiation Protection Dosimetry. 165. 1–4. 146–149. 10.1093/rpd/ncv121. 1742-3406. 25848100.
  9. O’Brien. Gráinne. Cruz-Garcia. Lourdes. Majewski. Matthäus. Grepl. Jakub. Abend. Michael. Port. Matthias. Tichý. Aleš. Sirak. Igor. Malkova. Andrea. December 2018. FDXR is a biomarker of radiation exposure in vivo. Scientific Reports. 8. 1. 684. 10.1038/s41598-017-19043-w. 29330481. 5766591. 2045-2322. 2018NatSR...8..684O.
  10. Oestreicher. Ursula. Samaga. Daniel. Ainsbury. Elizabeth. Antunes. Ana Catarina. Baeyens. Ans. Barrios. Leonardo. Beinke. Christina. Beukes. Philip. Blakely. William F.. 2017-01-02. RENEB intercomparisons applying the conventional Dicentric Chromosome Assay (DCA). International Journal of Radiation Biology. 93. 1. 20–29. 10.1080/09553002.2016.1233370. 0955-3002. free. 1854/LU-8507326. free.