Dealing with PET radiometabolites
Positron emission tomography (PET) offers the study of biochemical, physiological, and pharmacological functions at a cellular and molecular level. The performance of a PET study mostly depends on the used radiotracer of interest. However, the development of a novel PET tracer is very difficult, as...
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Science::Medicine Radiometabolites PET |
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Science::Medicine Radiometabolites PET Ghosh, Krishna Kanta Padmanabhan, Parasuraman Yang, Chang-Tong Mishra, Sachin Halldin, Christer Gulyás, Balázs Dealing with PET radiometabolites |
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Positron emission tomography (PET) offers the study of biochemical, physiological, and pharmacological functions at a cellular and molecular level. The performance of a PET study mostly depends on the used radiotracer of interest. However, the development of a novel PET tracer is very difficult, as it is required to fulfill a lot of important criteria. PET radiotracers usually encounter different chemical modifications including redox reaction, hydrolysis, decarboxylation, and various conjugation processes within living organisms. Due to this biotransformation, different chemical entities are produced, and the amount of the parent radiotracer is declined. Consequently, the signal measured by the PET scanner indicates the entire amount of radioactivity deposited in the tissue; however, it does not offer any indication about the chemical disposition of the parent radiotracer itself. From a radiopharmaceutical perspective, it is necessary to quantify the parent radiotracer's fraction present in the tissue. Hence, the identification of radiometabolites of the radiotracers is vital for PET imaging. There are mainly two reasons for the chemical identification of PET radiometabolites: firstly, to determine the amount of parent radiotracers in plasma, and secondly, to rule out (if a radiometabolite enters the brain) or correct any radiometabolite accumulation in peripheral tissue. Besides, radiometabolite formations of the tracer might be of concern for the PET study, as the radiometabolic products may display considerably contrasting distribution patterns inside the body when compared with the radiotracer itself. Therefore, necessary information is needed about these biochemical transformations to understand the distribution of radioactivity throughout the body. Various published review articles on PET radiometabolites mainly focus on the sample preparation techniques and recently available technology to improve the radiometabolite analysis process. This article essentially summarizes the chemical and structural identity of the radiometabolites of various radiotracers including [11C]PBB3, [11C]flumazenil, [18F]FEPE2I, [11C]PBR28, [11C]MADAM, and (+)[18F]flubatine. Besides, the importance of radiometabolite analysis in PET imaging is also briefly summarized. Moreover, this review also highlights how a slight chemical modification could reduce the formation of radiometabolites, which could interfere with the results of PET imaging. |
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Lee Kong Chian School of Medicine (LKCMedicine) |
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Lee Kong Chian School of Medicine (LKCMedicine) Ghosh, Krishna Kanta Padmanabhan, Parasuraman Yang, Chang-Tong Mishra, Sachin Halldin, Christer Gulyás, Balázs |
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Article |
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Ghosh, Krishna Kanta Padmanabhan, Parasuraman Yang, Chang-Tong Mishra, Sachin Halldin, Christer Gulyás, Balázs |
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Ghosh, Krishna Kanta |
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Dealing with PET radiometabolites |
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Dealing with PET radiometabolites |
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Dealing with PET radiometabolites |
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Dealing with PET radiometabolites |
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Dealing with PET radiometabolites |
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dealing with pet radiometabolites |
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2020 |
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https://hdl.handle.net/10356/145152 |
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sg-ntu-dr.10356-1451522023-03-05T16:46:44Z Dealing with PET radiometabolites Ghosh, Krishna Kanta Padmanabhan, Parasuraman Yang, Chang-Tong Mishra, Sachin Halldin, Christer Gulyás, Balázs Lee Kong Chian School of Medicine (LKCMedicine) Science::Medicine Radiometabolites PET Positron emission tomography (PET) offers the study of biochemical, physiological, and pharmacological functions at a cellular and molecular level. The performance of a PET study mostly depends on the used radiotracer of interest. However, the development of a novel PET tracer is very difficult, as it is required to fulfill a lot of important criteria. PET radiotracers usually encounter different chemical modifications including redox reaction, hydrolysis, decarboxylation, and various conjugation processes within living organisms. Due to this biotransformation, different chemical entities are produced, and the amount of the parent radiotracer is declined. Consequently, the signal measured by the PET scanner indicates the entire amount of radioactivity deposited in the tissue; however, it does not offer any indication about the chemical disposition of the parent radiotracer itself. From a radiopharmaceutical perspective, it is necessary to quantify the parent radiotracer's fraction present in the tissue. Hence, the identification of radiometabolites of the radiotracers is vital for PET imaging. There are mainly two reasons for the chemical identification of PET radiometabolites: firstly, to determine the amount of parent radiotracers in plasma, and secondly, to rule out (if a radiometabolite enters the brain) or correct any radiometabolite accumulation in peripheral tissue. Besides, radiometabolite formations of the tracer might be of concern for the PET study, as the radiometabolic products may display considerably contrasting distribution patterns inside the body when compared with the radiotracer itself. Therefore, necessary information is needed about these biochemical transformations to understand the distribution of radioactivity throughout the body. Various published review articles on PET radiometabolites mainly focus on the sample preparation techniques and recently available technology to improve the radiometabolite analysis process. This article essentially summarizes the chemical and structural identity of the radiometabolites of various radiotracers including [11C]PBB3, [11C]flumazenil, [18F]FEPE2I, [11C]PBR28, [11C]MADAM, and (+)[18F]flubatine. Besides, the importance of radiometabolite analysis in PET imaging is also briefly summarized. Moreover, this review also highlights how a slight chemical modification could reduce the formation of radiometabolites, which could interfere with the results of PET imaging. Nanyang Technological University Published version The authors acknowledge the support from Lee Kong Chian School ofMedicine, Nanyang Technological University, Singapore, Austrian Institute ofTechnology and Medical University of Vienna internal Grant (NAM/15006)and LKCMedicine Imaging Probe Dev. Platform, Singapore. 2020-12-14T06:34:26Z 2020-12-14T06:34:26Z 2020 Journal Article Ghosh, K. K., Padmanabhan, P., Yang, C.-T., Mishra, S., Halldin, C., & Gulyás, B. (2020). Dealing with PET radiometabolites. EJNMMI Research, 10(1), 109-. doi:10.1186/s13550-020-00692-4 2191-219X https://hdl.handle.net/10356/145152 10.1186/s13550-020-00692-4 32997213 1 10 en EJNMMI research © 2020 The Author(s). This article is licensed under a Creative Commons Attribution 4.0 International License,which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visithttp://creativecommons.org/licenses/by/4.0/. application/pdf |