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Combination of accelerator mass spectrometry (AMS) with positron emission tomography (PET) in human microdosing studies M. Simpson1, G. Lappin2, C. Wagner3, O.Langer3, I. Morris4 1University of York, York, UK 2Xceleron Inc, Gaithersburg, MD, USA 3Medical University of Vienna, Vienna, Austria 4Hull York Medical School, York, UK
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Overview Accelerator Mass Spectrometry Positron Emission Tomography
Combining AMS/PET Clinical Design AMS/PET Data Summary Conclusions/Applications
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Accelerator Mass Spectrometry
Isotope ratio technique Originally developed for radiocarbon dating Extremely sensitive Typically used with 12C/14C
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Accelerator Mass Spectrometry
Injection magnet Ion source Linear accelerator High energy allows separation of rare 14C from other isotopes 99.8% 1.1% 10-11% 12C Analysing magnet 13C 14C
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Positron Emission Tomography
PET Non-invasive nuclear imaging technique Tissue distribution Drug labelled with positron emitting radionuclide (e.g. 11C or 18F)
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Positron Emission Tomography
11C B + β+ + v + energy (97keV) PET Camera β+ 11C PET Camera 6
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AMS & PET AMS PET Combination IN THE SAME SUBJECTS Prolonged PK data
Limitation – no distribution information PET PK in tissue Limitation – short term PK only Combination Long term PK (AMS) Brain PK (PET) IN THE SAME SUBJECTS
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Clinical Design Administration of verapamil Calcium channel inhibitor
P-glycoprotein substrate, crosses blood-brain-barrier Well documented safety and PK profile IV dual labelled (R/S)-[14C], (R)-[11C] verapamil (50 µg) Position of dual label (11C and 14C) Chiral centre
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Clinical Design (2) Period 1 Period 2
IV Verapamil = 50 µg(R/S)-[14C] (4.1kBq), (R)-[11C] (407 MBq) PET scan/arterial plasma collection (0-60 minutes) Venous plasma collection (0-24 hours) MRI scan IV dual-labelled verapamil (50 μg) 7 healthy male volunteers Oral verapamil (80 mg)
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Aims To establish a protocol for microdosing studies
R-verapamil in brain by PET R- and S-verapamil in plasma by AMS Assess PK linearity between therapeutic dose and microdose
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Quantification of R- and S-verapamil by HPLC-AMS
Separation of R- & S-verapamil by 2D C18-chiral HPLC R-verapamil S-verapamil
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Microdose + therapeutic dose
Plasma Data Summary R-verapamil Microdose + therapeutic dose Microdose
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Microdose + therapeuticdose
Plasma PK Data Summary Parameter Enantiomer Microdose Microdose + therapeuticdose t1/2 (h) R 6.3 ±1.9 6.9 ±1.6 S 7.2 ±2.5 7.1 ±2.2 Cmax (pg/mL) 210.1 ±79.2 243.8 ±77.7 96.3 ±28.6 103.5 ±33.6 AUC(0-24) (hpg/mL) 579.8 ±107.4 794.0 ±265.1 272.6 ±70.7 313.8 ±59.7 AUC(0-inf) (hpg/mL) 624.5 ±131.6 843.2 ±281.1 308.6 ±79.3 343.3 ±58.9 CL (L/h) 61.0 ±12.6 46.9 ±10.9 89.7 ±24.2 78.2 ±14.7 V (L) 528.2 ±95.1 465.7 ±133.0 912.9 ±341.9 789.0 ±272.8 Vss (L) 397.9 ±89.8 319.9 ±68.7 682.0 ±167.0 600.6 ±187.6
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PET Data Summary PET micro dose PET therapeutic dose MRI SUV 2.8
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Whole brain grey matter
PET Data Summary Total 11C 11C-R-verapamil Arterial plasma Whole brain grey matter
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PET Data Summary Parameter Microdose Microdose + therapeutic dose
K1 (mLmL-1min-1) 0.030±0.003 (10) 0.031±0.005 (8) k2 (min-1) 0.099±0.006 (49) 0.095±0.008 (40) k3 (min-1) k4 (min-1) 0.100±0.001 (90) 0.092±0.029 (26) 0.101±0.000 (96) 0.159±0.063 (42) DV (mLmL-1) 0.66±0.12 (4) 0.56±0.11 (2) DV (Logan) (mLmL-1) 0.66±0.11 (2) 0.57±0.11 (1)
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Conclusions Principle of AMS/PET combination demonstrated
Long term plasma PK obtained along with tissue distribution information Verapamil shown to be dose linear Plasma (by AMS) Brain (by PET) S-verapamil shows preferential clearance Proof of concept for combination studies Applications in brain, tumour, cardiac therapy
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Acknowledgements PET team - Medical University of Vienna
University of York Xceleron Ltd
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