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Radioactive nanoparticle

January 01, 1970

A radioactive nanoparticle is a nanoparticle that contains radioactive materials. Radioactive nanoparticles have applications in medical diagnostics, medical imaging, toxicokinetics, and environmental health, and are being investigated for applications in nuclear nanomedicine. Radioactive nanoparticles present special challenges in operational health physics and internal dosimetry that are not present for other substances, although existing radiation protection measures and hazard controls for nanoparticles generally apply.

Types and applications edit

Engineered edit

 
SPECT/CT images of injected gold-coated lanthanum/gadolinium phosphate nanoparticles containing the alpha-emitting radionuclide actinium-225 in a mouse. Depending on the surface functionalization, the particles migrate either to the lungs or the liver.[1]

Engineered radioactive nanoparticles are used in medical imaging techniques such as positron emission tomography and single-photon emission computed tomography,[2] and an aerosol of carbon nanoparticles containing technetium-99m are used in a commercially available procedure for ventilation/perfusion scintigraphy of the lungs.[3]: 122–125  Engineered radioactive nanoparticles are also used as a radiolabel to detect the presence of the nanoparticles themselves in environmental health and toxicokinetics studies.[3]: 119–122 

Engineered radioactive nanoparticles are being investigated for therapeutic use combining nuclear medicine with nanomedicine, especially for cancer.[3]: 125–130  Neutron capture therapy is one such potential application.[2][4] In addition, nanoparticles can help to sequester the toxic daughter nuclides of alpha emitters when used in radiotherapy.[1]

Nuclear imaging is non-invasive and has high sensitivity, and nanoparticles are useful as a platform for combining multiple copies of targeting vectors and effectors in order to selectively deliver radioisotopes to a specific region of interest.[5] Other benefits of nanoparticles for diagnostic and therapeutic use include increased blood and tumor retention time, as well as the possibility of using their unique physical and chemical properties in treatment.[citation needed] However, the nanoparticles must be engineered to avoid being recognized by the mononuclear phagocyte system and transported to the liver or spleen, often through manipulating their surface functionalization.[4][5]

Targeting techniques include functionalizing radioactive nanoparticles with antibodies to target them to a specific tissue, and using magnetic nanoparticles that are attracted to a magnet placed over the tumor site.[4] Technetium-99m, indium-111, and iodine-131 are common radioisotopes used for these purposes,[3]: 119–130 [4] with many others used as well.[6][7] Radioactive nanoparticles can be produced by either synthesizing the nanoparticles directly from the radioactive materials, or by irradiating non-radioactive particles with neutrons or accelerated ions, sometimes in situ.[3]: 119 [8]

Natural and incidental edit

As with all nanoparticles, radioactive nanoparticles can also be naturally occurring or incidentally produced as a byproduct of industrial processes. The main source of naturally occurring nanomaterials containing radionuclides is the decay of radon gas, whose immediate decay products are non-gaseous elements that precipitate into nanoscale particles along with atmospheric dust and vapors. Minor natural sources include primordial radionuclides present in the nanoscale portion of volcanic ash, and primordial and cosmogenic nuclides taken up by plants which are later burned. Radioactive nanoparticles may be incidentally produced by procedures in the nuclear industry such as nuclear reprocessing and the cutting of contaminated objects.[3]: 16–20 

Health and safety edit

Radioactive nanoparticles combine the hazards of radioactive materials with the hazards of nanomaterials.[3]: 2–6  Inhalation exposure is the most common route of exposure to airborne particles in the workplace. Animal studies on some classes of nanoparticles indicate pulmonary effects including inflammation, granulomas, and pulmonary fibrosis, which were of similar or greater potency when compared with other known fibrogenic materials such as silica, asbestos, and ultrafine carbon black. Some studies in cells or animals have shown genotoxic or carcinogenic effects, or systemic cardiovascular effects from pulmonary exposure.[9][10] The hazards of ionizing radiation depend on whether the exposure is acute or chronic, and includes effects like radiation-induced cancer and teratogenesis.[11][12] In some cases, the inherent physicochemical toxicity of the nanoparticle itself may lead to lower exposure limits than those associated with the radioactivity alone, which is not the case with most radioactive materials.[3]: 2–6 

Radioactive nanoparticles present special challenges in operational health physics and internal dosimetry that are not present for other substances, as the nanoparticles' toxicokinetics depend on their physical and chemical properties including size, shape, and surface chemistry. For example, inhaled nanoparticles will deposit in different locations in the lungs, and will be metabolized and transported through the body differently, than vapors or larger particles.[3]: 2–6  There may also be hazards from associated processes such as strong magnetic fields and cryogens used in imaging equipment, and handling of lab animals in experimental studies.[13] Effective risk assessment and communication is important, as both nanotechnology and radiation have unique considerations with public perception.[14]

Hazard controls edit

 
A fume hood is an engineering control typically used to protect workers using nanoparticles.

In general, most elements of a standard radiation protection program are applicable to radioactive nanomaterials, and many hazard controls for nanomaterials will be effective with the radioactive versions. The hierarchy of hazard controls encompasses a succession of five categories of control methods to reduce the risk of illness or injury. The two most effective are elimination and substitution, for example reducing dust exposure by eliminating a sonication process or substituting a nanomaterial slurry or suspension in a liquid solvent instead of a dry powder. Substitutions should consider both the radioactivity and physicochemical hazards of all the options, and also take into account that radioactive nanomaterials are easier to detect than non-radioactive substances.[3]: 2–6, 35–41 

Engineering controls should be the primary form of protection, including local exhaust systems such as fume hoods, gloveboxes, biosafety cabinets, and vented balance enclosures; radiation shielding; and access control systems.[3]: 41–48  The need for negative room pressure to prevent contamination of outside areas can conflict with the customary use of positive pressure when pharmaceuticals are being handled, although this can be overcome through use of a cascade pressure system, or by handling nanomaterials in enclosures.[13]

Administrative controls include procedures to limit radiation doses, and contamination control procedures including encouraging good work practices and monitoring for contamination. Personal protective equipment is the least effective and should be used in conjunction with other hazard controls. In general, personal protective equipment intended for radioactive materials should be effective with radioactive nanomaterials, including impervious laboratory coats, goggles, safety gloves, and in some cases respirators, although the greater potential penetration through clothing and mobility in air of nanoparticles should be taken into account.[3]: 48–63 

See also edit

References edit

  1. ^ a b McLaughlin, Mark F.; Woodward, Jonathan; Boll, Rose A.; Wall, Jonathan S.; Rondinone, Adam J.; Kennel, Stephen J.; Mirzadeh, Saed; Robertson, J. David (2013-01-18). "Gold Coated Lanthanide Phosphate Nanoparticles for Targeted Alpha Generator Radiotherapy". PLOS ONE. 8 (1): e54531. Bibcode:2013PLoSO...854531M. doi:10.1371/journal.pone.0054531. ISSN 1932-6203. PMC 3548790. PMID 23349921.
  2. ^ a b Prasad, Paras N. (2012-05-11). Introduction to Nanomedicine and Nanobioengineering. John Wiley & Sons. pp. 121–124. ISBN 9781118351079.
  3. ^ a b c d e f g h i j k l "Radiation Safety Aspects of Nanotechnology". National Council on Radiation Protection and Measurements. 2017-03-02. Retrieved 2017-07-07.
  4. ^ a b c d Hamoudeh, Misara; Kamleh, Muhammad Anas; Diab, Roudayna; Fessi, Hatem (2008-09-15). "Radionuclides delivery systems for nuclear imaging and radiotherapy of cancer". Advanced Drug Delivery Reviews. 60 (12): 1329–1346. doi:10.1016/j.addr.2008.04.013. PMID 18562040.
  5. ^ a b Lewis, Michael R.; Kannan, Raghuraman (November 2014). "Development and applications of radioactive nanoparticles for imaging of biological systems". Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology. 6 (6): 628–640. doi:10.1002/wnan.1292. ISSN 1939-0041. PMID 25196269.
  6. ^ Martín, Isabel García; Frigell, Jens; Llop, Jordi; Marradi, Marco (2016-03-22). "Radiolabelling of NPs Using Radiometals: 99mTc, 68Ga, 67Ga, 89Zr, and 64Cu". In Llop, Jordi; Gomez-Vallejo, Vanessa; Gibson, Peter Neil (eds.). Isotopes in Nanoparticles. Pan Stanford. pp. 183–229. doi:10.1201/b19950-9. ISBN 9789814669085.
  7. ^ Llop, Jordi; Gómez-Vallejo, Vanessa; Martín, Isabel García; Marradi, Marco (2016-03-22). "Radiolabelling of Nanoparticles Using Radiohalogens, 13N, and 11C". In Llop, Jordi; Gomez-Vallejo, Vanessa; Gibson, Peter Neil (eds.). Isotopes in Nanoparticles. Pan Stanford. pp. 231–260. doi:10.1201/b19950-10. ISBN 9789814669085.
  8. ^ Abbas, Kamel; Simonelli, Federica; Holzwarth, Uwe; Gibson, Peter (2009). "Overview on the production of radioactive nanoparticles for bioscience applications at the JRC Cyclotron – European Commission". Journal of Labelled Compounds and Radiopharmaceuticals. 52: S231–S255. doi:10.1002/jlcr.1643. Retrieved 2017-07-11.
  9. ^ "Current Intelligence Bulletin 65: Occupational Exposure to Carbon Nanotubes and Nanofibers". U.S. National Institute for Occupational Safety and Health: v–ix, 33–35. April 2013. doi:10.26616/NIOSHPUB2013145. Retrieved 2017-04-26.
  10. ^ "Current Intelligence Bulletin 63: Occupational Exposure to Titanium Dioxide". U.S. National Institute for Occupational Safety and Health: v–vii, 73–78. April 2011. doi:10.26616/NIOSHPUB2011160. Retrieved 2017-04-27.
  11. ^ "Radiation Health Effects". U.S. Environmental Protection Agency. 2017-05-23. Retrieved 2017-07-17.
  12. ^ "Radiation and Its Health Effects". U.S. Nuclear Regulatory Commission. 2014-10-17. Retrieved 2017-07-17.
  13. ^ a b Reese, Torsten; Gómez-Vallejo, Vanessa; Ferreira, Paola; Llop, Jordi (2016-03-22). "Health and Safety Considerations for Radiolabelled Nanoparticles". In Llop, Jordi; Gomez-Vallejo, Vanessa; Gibson, Peter Neil (eds.). Isotopes in Nanoparticles. Pan Stanford. pp. 493–512. doi:10.1201/b19950-19. ISBN 9789814669085.
  14. ^ Hoover, Mark D.; Myers, David S.; Cash, Leigh J.; Guilmette, Raymond A.; Kreyling, Wolfgang G.; Oberdörster, Günter; Smith, Rachel; Cassata, James R.; Boecker, Bruce B. (2015). "Application of an Informatics-Based Decision-Making Framework and Process to the Assessment of Radiation Safety in Nanotechnology". Health Physics. 108 (2): 179–194. doi:10.1097/hp.0000000000000250. PMID 25551501. S2CID 42732844.

January 01, 1970
radioactive, nanoparticle, radioactive, nanoparticle, nanoparticle, that, contains, radioactive, materials, have, applications, medical, diagnostics, medical, imaging, toxicokinetics, environmental, health, being, investigated, applications, nuclear, nanomedic. A radioactive nanoparticle is a nanoparticle that contains radioactive materials Radioactive nanoparticles have applications in medical diagnostics medical imaging toxicokinetics and environmental health and are being investigated for applications in nuclear nanomedicine Radioactive nanoparticles present special challenges in operational health physics and internal dosimetry that are not present for other substances although existing radiation protection measures and hazard controls for nanoparticles generally apply Contents 1 Types and applications 1 1 Engineered 1 2 Natural and incidental 2 Health and safety 2 1 Hazard controls 3 See also 4 ReferencesTypes and applications editEngineered edit nbsp SPECT CT images of injected gold coated lanthanum gadolinium phosphate nanoparticles containing the alpha emitting radionuclide actinium 225 in a mouse Depending on the surface functionalization the particles migrate either to the lungs or the liver 1 Engineered radioactive nanoparticles are used in medical imaging techniques such as positron emission tomography and single photon emission computed tomography 2 and an aerosol of carbon nanoparticles containing technetium 99m are used in a commercially available procedure for ventilation perfusion scintigraphy of the lungs 3 122 125 Engineered radioactive nanoparticles are also used as a radiolabel to detect the presence of the nanoparticles themselves in environmental health and toxicokinetics studies 3 119 122 Engineered radioactive nanoparticles are being investigated for therapeutic use combining nuclear medicine with nanomedicine especially for cancer 3 125 130 Neutron capture therapy is one such potential application 2 4 In addition nanoparticles can help to sequester the toxic daughter nuclides of alpha emitters when used in radiotherapy 1 Nuclear imaging is non invasive and has high sensitivity and nanoparticles are useful as a platform for combining multiple copies of targeting vectors and effectors in order to selectively deliver radioisotopes to a specific region of interest 5 Other benefits of nanoparticles for diagnostic and therapeutic use include increased blood and tumor retention time as well as the possibility of using their unique physical and chemical properties in treatment citation needed However the nanoparticles must be engineered to avoid being recognized by the mononuclear phagocyte system and transported to the liver or spleen often through manipulating their surface functionalization 4 5 Targeting techniques include functionalizing radioactive nanoparticles with antibodies to target them to a specific tissue and using magnetic nanoparticles that are attracted to a magnet placed over the tumor site 4 Technetium 99m indium 111 and iodine 131 are common radioisotopes used for these purposes 3 119 130 4 with many others used as well 6 7 Radioactive nanoparticles can be produced by either synthesizing the nanoparticles directly from the radioactive materials or by irradiating non radioactive particles with neutrons or accelerated ions sometimes in situ 3 119 8 Natural and incidental edit As with all nanoparticles radioactive nanoparticles can also be naturally occurring or incidentally produced as a byproduct of industrial processes The main source of naturally occurring nanomaterials containing radionuclides is the decay of radon gas whose immediate decay products are non gaseous elements that precipitate into nanoscale particles along with atmospheric dust and vapors Minor natural sources include primordial radionuclides present in the nanoscale portion of volcanic ash and primordial and cosmogenic nuclides taken up by plants which are later burned Radioactive nanoparticles may be incidentally produced by procedures in the nuclear industry such as nuclear reprocessing and the cutting of contaminated objects 3 16 20 Health and safety editRadioactive nanoparticles combine the hazards of radioactive materials with the hazards of nanomaterials 3 2 6 Inhalation exposure is the most common route of exposure to airborne particles in the workplace Animal studies on some classes of nanoparticles indicate pulmonary effects including inflammation granulomas and pulmonary fibrosis which were of similar or greater potency when compared with other known fibrogenic materials such as silica asbestos and ultrafine carbon black Some studies in cells or animals have shown genotoxic or carcinogenic effects or systemic cardiovascular effects from pulmonary exposure 9 10 The hazards of ionizing radiation depend on whether the exposure is acute or chronic and includes effects like radiation induced cancer and teratogenesis 11 12 In some cases the inherent physicochemical toxicity of the nanoparticle itself may lead to lower exposure limits than those associated with the radioactivity alone which is not the case with most radioactive materials 3 2 6 Radioactive nanoparticles present special challenges in operational health physics and internal dosimetry that are not present for other substances as the nanoparticles toxicokinetics depend on their physical and chemical properties including size shape and surface chemistry For example inhaled nanoparticles will deposit in different locations in the lungs and will be metabolized and transported through the body differently than vapors or larger particles 3 2 6 There may also be hazards from associated processes such as strong magnetic fields and cryogens used in imaging equipment and handling of lab animals in experimental studies 13 Effective risk assessment and communication is important as both nanotechnology and radiation have unique considerations with public perception 14 Hazard controls edit nbsp A fume hood is an engineering control typically used to protect workers using nanoparticles In general most elements of a standard radiation protection program are applicable to radioactive nanomaterials and many hazard controls for nanomaterials will be effective with the radioactive versions The hierarchy of hazard controls encompasses a succession of five categories of control methods to reduce the risk of illness or injury The two most effective are elimination and substitution for example reducing dust exposure by eliminating a sonication process or substituting a nanomaterial slurry or suspension in a liquid solvent instead of a dry powder Substitutions should consider both the radioactivity and physicochemical hazards of all the options and also take into account that radioactive nanomaterials are easier to detect than non radioactive substances 3 2 6 35 41 Engineering controls should be the primary form of protection including local exhaust systems such as fume hoods gloveboxes biosafety cabinets and vented balance enclosures radiation shielding and access control systems 3 41 48 The need for negative room pressure to prevent contamination of outside areas can conflict with the customary use of positive pressure when pharmaceuticals are being handled although this can be overcome through use of a cascade pressure system or by handling nanomaterials in enclosures 13 Administrative controls include procedures to limit radiation doses and contamination control procedures including encouraging good work practices and monitoring for contamination Personal protective equipment is the least effective and should be used in conjunction with other hazard controls In general personal protective equipment intended for radioactive materials should be effective with radioactive nanomaterials including impervious laboratory coats goggles safety gloves and in some cases respirators although the greater potential penetration through clothing and mobility in air of nanoparticles should be taken into account 3 48 63 See also editHealth and safety hazards of nanomaterials Radiation protectionReferences edit a b McLaughlin Mark F Woodward Jonathan Boll Rose A Wall Jonathan S Rondinone Adam J Kennel Stephen J Mirzadeh Saed Robertson J David 2013 01 18 Gold Coated Lanthanide Phosphate Nanoparticles for Targeted Alpha Generator Radiotherapy PLOS ONE 8 1 e54531 Bibcode 2013PLoSO 854531M doi 10 1371 journal pone 0054531 ISSN 1932 6203 PMC 3548790 PMID 23349921 a b Prasad Paras N 2012 05 11 Introduction to Nanomedicine and Nanobioengineering John Wiley amp Sons pp 121 124 ISBN 9781118351079 a b c d e f g h i j k l Radiation Safety Aspects of Nanotechnology National Council on Radiation Protection and Measurements 2017 03 02 Retrieved 2017 07 07 a b c d Hamoudeh Misara Kamleh Muhammad Anas Diab Roudayna Fessi Hatem 2008 09 15 Radionuclides delivery systems for nuclear imaging and radiotherapy of cancer Advanced Drug Delivery Reviews 60 12 1329 1346 doi 10 1016 j addr 2008 04 013 PMID 18562040 a b Lewis Michael R Kannan Raghuraman November 2014 Development and applications of radioactive nanoparticles for imaging of biological systems Wiley Interdisciplinary Reviews Nanomedicine and Nanobiotechnology 6 6 628 640 doi 10 1002 wnan 1292 ISSN 1939 0041 PMID 25196269 Martin Isabel Garcia Frigell Jens Llop Jordi Marradi Marco 2016 03 22 Radiolabelling of NPs Using Radiometals 99mTc 68Ga 67Ga 89Zr and 64Cu In Llop Jordi Gomez Vallejo Vanessa Gibson Peter Neil eds Isotopes in Nanoparticles Pan Stanford pp 183 229 doi 10 1201 b19950 9 ISBN 9789814669085 Llop Jordi Gomez Vallejo Vanessa Martin Isabel Garcia Marradi Marco 2016 03 22 Radiolabelling of Nanoparticles Using Radiohalogens 13N and 11C In Llop Jordi Gomez Vallejo Vanessa Gibson Peter Neil eds Isotopes in Nanoparticles Pan Stanford pp 231 260 doi 10 1201 b19950 10 ISBN 9789814669085 Abbas Kamel Simonelli Federica Holzwarth Uwe Gibson Peter 2009 Overview on the production of radioactive nanoparticles for bioscience applications at the JRC Cyclotron European Commission Journal of Labelled Compounds and Radiopharmaceuticals 52 S231 S255 doi 10 1002 jlcr 1643 Retrieved 2017 07 11 Current Intelligence Bulletin 65 Occupational Exposure to Carbon Nanotubes and Nanofibers U S National Institute for Occupational Safety and Health v ix 33 35 April 2013 doi 10 26616 NIOSHPUB2013145 Retrieved 2017 04 26 Current Intelligence Bulletin 63 Occupational Exposure to Titanium Dioxide U S National Institute for Occupational Safety and Health v vii 73 78 April 2011 doi 10 26616 NIOSHPUB2011160 Retrieved 2017 04 27 Radiation Health Effects U S Environmental Protection Agency 2017 05 23 Retrieved 2017 07 17 Radiation and Its Health Effects U S Nuclear Regulatory Commission 2014 10 17 Retrieved 2017 07 17 a b Reese Torsten Gomez Vallejo Vanessa Ferreira Paola Llop Jordi 2016 03 22 Health and Safety Considerations for Radiolabelled Nanoparticles In Llop Jordi Gomez Vallejo Vanessa Gibson Peter Neil eds Isotopes in Nanoparticles Pan Stanford pp 493 512 doi 10 1201 b19950 19 ISBN 9789814669085 Hoover Mark D Myers David S Cash Leigh J Guilmette Raymond A Kreyling Wolfgang G Oberdorster Gunter Smith Rachel Cassata James R Boecker Bruce B 2015 Application of an Informatics Based Decision Making Framework and Process to the Assessment of Radiation Safety in Nanotechnology Health Physics 108 2 179 194 doi 10 1097 hp 0000000000000250 PMID 25551501 S2CID 42732844 Retrieved from https en wikipedia org w index php title Radioactive nanoparticle amp oldid 1136423844, wikipedia, wiki, book, books, library,

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