Abstract
Background4-[18F] fluorobenzyl dexetimide (F-DEX) is the first non-subtype selective fluorine-18 labelled tracer for muscarinic receptors (mAChR) used in humans. A recent first-in-human study found high regional brain uptake with low variation in normal subjects. Disturbance of mAChR has been reported in Alzheimer’s and Parkinson’s disease, schizophrenia and depression and various cardiac diseases. The following work assesses the biodistribution, organ tracer kinetics and radiation dose associated with F-DEX.MethodDose calculations were based on activity uptake derived from multiple time point whole body PET CT imaging and the organ-specific dosimetric S-factors derived from the ICRP 133 standard man and woman mathematical phantoms. Effective doses were calculated using the latest ICRP tissue weighting factors.ResultsSerial images and time activity curves demonstrate high brain and left ventricular myocardial uptake (5% and 0.65% of injected activity, respectively) with greater retention in brain than myocardium. The mean effective dose was in concordance with other 18F labelled tracers at 19.70 ± 2.27 μSv/MBq. The largest absorbed doses were in the liver (52.91 ± 1.46 μGy/MBq) and heart wall (43.94 ± 12.88 μGy/MBq) for standard man and the liver (61.66 ± 13.61 μGy/MBq) and lungs (40.93 ± 3.11 μGy/MBq) for standard woman. The absorbed dose to all organs, most notably, the red bone marrow (20.03 ± 2.89 μGy/MBq) was sufficiently low to ensure no toxicity after numerous follow-up procedures.ConclusionsThe radiation dose associated with an administration of F-DEX is comparable to that of other 18F labelled tracers such as FDG (19.0 μSv/MBq) and lower than tracers used for SPECT imaging of muscarinic receptors (I-DEX 28.5 μSv/MBq). Clinical use would likely result in an effective dose less than 4 mSv for the ICRP 133 standard phantoms after dose optimisation allowing justification for numerous follow-up procedures. Recent results from first in-human studies and a comparatively low radiation dose make F-DEX an attractive option for future applications of imaging muscarinic receptors in the brain. Further investigation of the potential of F-DEX for imaging parasympathetic innervation of the heart may be warranted.
Highlights
The first in-human study of 4-[18F] fluorobenzyl dexetimide (F-DEX) has recently shown it to have potential as a robust tool for detecting variations in muscarinic acetylcholine receptors in the brain using hybrid positron emission tomography and computed tomography (PET Hybrid positron emission tomography and computed tomography (CT)) [1]
The mean effective dose was in concordance with other 18F labelled tracers at 19.70 ± 2.27 μSv/MBq
The radiation dose associated with an administration of F-DEX is comparable to that of other 18F labelled tracers such as FDG (19.0 μSv/MBq) and lower than tracers used for single photon emission computed tomography (SPECT) imaging of muscarinic receptors ( I-DEX 28.5 μSv/MBq)
Summary
The first in-human study of 4-[18F] fluorobenzyl dexetimide (F-DEX) has recently shown it to have potential as a robust tool for detecting variations in muscarinic acetylcholine receptors (mAChR) in the brain using hybrid positron emission tomography and computed tomography (PET CT) [1]. It has been shown that a decline in cholinergic function correlates strongly with the symptoms of Alzheimer’s disease [2], and acetyl cholinesterase inhibitors remain the principle symptomatic treatment for this condition. Current research into mAChR agonists aims to develop more effective symptomatic therapy with less systemic side-effects. Observing temporal changes of brain function with PET results in the accrual of relatively high, though still low level, radiation doses. This emphasises the necessity for accurate dosimetry of such tracers prior to clinical or research use
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