Fluorine-18 Fluorodeoxyglucose Isolation Using Graphene Oxide for Alternative Radiopharmaceutical Spillage Decontamination in PET Scan

• Main Authors: Abdullah, N.H (Author), Hadzuan, F.H.M (Author), Ibrahim, F. (Author), Muhamad, M. (Author), Nawi, N.M (Author), Noor, A.M (Author), Razab, M.K.A.A (Author), Sunaiwi, R. (Author), Zin, F.A.M (Author)
• Format: Article
• Language: English
• Published: MDPI 2022
• Subjects: adsorption; chemical composition; decontamination; drug; medicine; nuclear medicine; pollutant removal; radioactive spillage; radioactivity; radiopharmaceutical; sorption; waste management
• Online Access: View Fulltext in Publisher

 Radiopharmaceuticals (RPC) used for diagnostic and therapeutic purposes in nuclear medicine may contaminate surface areas due to spillage during its preparation or accident during RPC transfer from laboratory to the treatment room. Fluorine-18 Fluorodeoxyglucose (18F-FDG) is the most common RPC for positron emission tomography (PET) scan in nuclear medicine due to its ideal annihilation converted energy at 511 keV and short half-life at 109.8 min. Ineffective medical waste management of18F-FDG may pose a risk to the environment or cause unnecessary radiation doses to the personnel and public. Depending on the incident rate of these events, simple decontamination methods such as the use of chemicals and swabs might not be cost-effective and sustainable in the environment. This study aims to propose an alternative method to decontaminate18F-FDG by using graphene oxide (GO). GO was synthesised using the Hummers method while the physical morphology was analysed using a field emission scanning electron microscope (FESEM).18F-FDG adsorption efficiency rate using GO nanolayers was analysed based on the kinetic study of the GO:18F-FDG mixtures. The chemical adsorbability of the material was analysed via UV–vis spectrophotometer to interlink the microstructures of GO with the sorption affinity interaction. Resultantly, the adsorption rate was effective at a slow decay rate and the optical adsorption of GO with18F-FDG was dominated by the π → π∗plasmon peak, which was near 230 nm. By elucidating the underlining GO special features, an alternative technique to isolate18F-FDG for the decontamination process was successfully proven. © 2022 by the authors. Licensee MDPI, Basel, Switzerland.