Dirk Wildemeersch1, Pieter-Jan Sabbe2, Mark G Dowsett3, Victoria Flexer2, Paul Thompson4, David Walker3, Pam A Thomas3, Annemie Adriaens2. 1. Gynecological Outpatient Clinic and IUD Training Centre, Ghent 9000, Belgium. Electronic address: d.wildemeersch@skynet.be. 2. Department of Analytical Chemistry, Ghent University, Krijgslaan 281-S12, Ghent 9000, Belgium. 3. Department of Physics, University of Warwick, Coventry CV4 7AL, United Kingdom. 4. XMaS, The UK-CRG, European Synchrotron Radiation Facility, 6 rue Jules Horowitz, BP220, 38043 Grenoble, Cedex, France; Department of Physics, University of Liverpool, Liverpool L69 7ZX, United Kingdom.
Abstract
OBJECTIVE: To assess the site-specific corrosive behavior of the frameless intrauterine device (IUD) following long-term exposure to the uterine environment. STUDY DESIGN: A qualitative and morphological study using X-ray diffraction (XRD) and scanning electron microscopy (SEM). RESULTS: Three GyneFix® IUDs that were in site up to 150 months were examined. In utero corroded copper sleeves were divided into 10 different groups based on their shape (U or O), orientation (inside or outside) and in utero residence time. XRD indicated the presence of solely cuprite (Cu2O) as corrosion product on both the inside and the outside of the copper sleeves, regardless of their shape. These results were confirmed by backscattered electron micrographs recorded on the inside, the outside and the cross-section of the IUD sleeve. SEM results suggest that shape and orientation slightly affect the corrosion rate. CONCLUSION: The apparent copper loss from both sides of GyneFix copper tubes proves that both sides are a potential copper source and therefore justifies the design of GyneFix IUD. This could be beneficial for women as the IUD could be reduced in size and therefore better tolerated. The impact on bleeding could also be minimized. IMPLICATION STATEMENT: Release of copper ions from both sides of the copper tubes of the frameless GyneFix® IUD allows the IUD to be reduced in size, contributing to better toleration. The impact on menstrual bleeding is also minimized by a smaller size of the foreign body.
OBJECTIVE: To assess the site-specific corrosive behavior of the frameless intrauterine device (IUD) following long-term exposure to the uterine environment. STUDY DESIGN: A qualitative and morphological study using X-ray diffraction (XRD) and scanning electron microscopy (SEM). RESULTS: Three GyneFix® IUDs that were in site up to 150 months were examined. In utero corroded copper sleeves were divided into 10 different groups based on their shape (U or O), orientation (inside or outside) and in utero residence time. XRD indicated the presence of solely cuprite (Cu2O) as corrosion product on both the inside and the outside of the copper sleeves, regardless of their shape. These results were confirmed by backscattered electron micrographs recorded on the inside, the outside and the cross-section of the IUD sleeve. SEM results suggest that shape and orientation slightly affect the corrosion rate. CONCLUSION: The apparent copper loss from both sides of GyneFix copper tubes proves that both sides are a potential copper source and therefore justifies the design of GyneFix IUD. This could be beneficial for women as the IUD could be reduced in size and therefore better tolerated. The impact on bleeding could also be minimized. IMPLICATION STATEMENT: Release of copper ions from both sides of the copper tubes of the frameless GyneFix® IUD allows the IUD to be reduced in size, contributing to better toleration. The impact on menstrual bleeding is also minimized by a smaller size of the foreign body.
Authors: Oier Bikondoa; Laurence Bouchenoire; Simon D Brown; Paul B J Thompson; Didier Wermeille; Chris A Lucas; Malcolm J Cooper; Thomas P A Hase Journal: Philos Trans A Math Phys Eng Sci Date: 2019-06-17 Impact factor: 4.226