UNLABELLED: Arachidonic acid (AA) is found in high concentrations in brain phospholipids and is released as a second messenger during neurotransmission and much more so during neuroinflammation and excitotoxicity. Upregulated brain AA metabolism associated with neuroinflammation has been imaged in rodents using [1-(14)C]AA and with PET in Alzheimer disease patients using [1-(11)C]AA. Radiotracer brain AA uptake is independent of cerebral blood flow, making it an ideal tracer despite altered brain functional activity. However, the 20.4-min radioactive half-life of (11)C-AA and challenges of routinely synthesizing (11)C fatty acids limit their translational utility as PET biomarkers. METHODS: As a first step to develop a clinically useful (18)F-fluoroarachidonic acid ((18)F-FAA) with a long radioactive half-life of 109.8 min, we report here a high-yield stereoselective synthetic method of nonradioactive 20-(19)F-FAA. We tested its in vivo pharmacokinetics by infusing purified nonradioactive (19)F-FAA intravenously for 5 min at 2 doses in unanesthetized mice and measured its plasma and brain distribution using gas chromatography-mass spectrometry. RESULTS: Incorporation coefficients of injected (19)F-FAA into brain phospholipids (ratio of brain (19)F-FAA concentration to plasma input function) were 3- to 29-fold higher for choline glycerophospholipid and phosphatidylinositol than for ethanolamine glycerophospholipid and phosphatidylserine at each of the 2 tested doses. The selectivities and values of incorporation coefficients were comparable to those reported after [1-(14)C]AA (the natural arachidonate) infusion in mice. CONCLUSION: These results suggest that it would be worthwhile to translate our stereoselective synthetic method for (19)F-FAA to synthesize positron-emitting (18)F-FAA for human brain AA metabolism in neuroinflammatory disorders such as Alzheimer disease.
UNLABELLED: Arachidonic acid (AA) is found in high concentrations in brain phospholipids and is released as a second messenger during neurotransmission and much more so during neuroinflammation and excitotoxicity. Upregulated brain AA metabolism associated with neuroinflammation has been imaged in rodents using [1-(14)C]AA and with PET in Alzheimer diseasepatients using [1-(11)C]AA. Radiotracer brain AA uptake is independent of cerebral blood flow, making it an ideal tracer despite altered brain functional activity. However, the 20.4-min radioactive half-life of (11)C-AA and challenges of routinely synthesizing (11)C fatty acids limit their translational utility as PET biomarkers. METHODS: As a first step to develop a clinically useful (18)F-fluoroarachidonic acid ((18)F-FAA) with a long radioactive half-life of 109.8 min, we report here a high-yield stereoselective synthetic method of nonradioactive 20-(19)F-FAA. We tested its in vivo pharmacokinetics by infusing purified nonradioactive (19)F-FAA intravenously for 5 min at 2 doses in unanesthetized mice and measured its plasma and brain distribution using gas chromatography-mass spectrometry. RESULTS: Incorporation coefficients of injected (19)F-FAA into brain phospholipids (ratio of brain (19)F-FAA concentration to plasma input function) were 3- to 29-fold higher for cholineglycerophospholipid and phosphatidylinositol than for ethanolamine glycerophospholipid and phosphatidylserine at each of the 2 tested doses. The selectivities and values of incorporation coefficients were comparable to those reported after [1-(14)C]AA (the natural arachidonate) infusion in mice. CONCLUSION: These results suggest that it would be worthwhile to translate our stereoselective synthetic method for (19)F-FAA to synthesize positron-emitting (18)F-FAA for human brain AA metabolism in neuroinflammatory disorders such as Alzheimer disease.
Authors: Epolia Ramadan; Mireille Basselin; Ameer Y Taha; Yewon Cheon; Lisa Chang; Mei Chen; Stanley I Rapoport Journal: Neuropharmacology Date: 2011-08-03 Impact factor: 5.250
Authors: D H Silverman; G W Small; C Y Chang; C S Lu; M A Kung De Aburto; W Chen; J Czernin; S I Rapoport; P Pietrini; G E Alexander; M B Schapiro; W J Jagust; J M Hoffman; K A Welsh-Bohmer; A Alavi; C M Clark; E Salmon; M J de Leon; R Mielke; J L Cummings; A P Kowell; S S Gambhir; C K Hoh; M E Phelps Journal: JAMA Date: 2001-11-07 Impact factor: 56.272
Authors: Giampiero Giovacchini; Alicja Lerner; Maria T Toczek; Charles Fraser; Kaizong Ma; James C DeMar; Peter Herscovitch; William C Eckelman; Stanley I Rapoport; Richard E Carson Journal: J Nucl Med Date: 2004-09 Impact factor: 10.057
Authors: J B Chawluk; A Alavi; R Dann; H I Hurtig; S Bais; M J Kushner; R A Zimmerman; M Reivich Journal: J Nucl Med Date: 1987-04 Impact factor: 10.057
Authors: R E Gur; S M Resnick; A Alavi; R C Gur; S Caroff; R Dann; F L Silver; A J Saykin; J B Chawluk; M Kushner Journal: Arch Gen Psychiatry Date: 1987-02