Assessment of tissue-engineered islet graft viability by fluorine magnetic resonance spectroscopy

Introduction: Despite significant progress in the last decade, islet transplantation remains an experimental therapy for a limited number of patients with type 1 diabetes. Tissue-engineered approaches may provide promising alternatives to the current clinical protocol and would benefit greatly from concurrent development of graft quality assessment techniques. This study was designed to evaluate whether viability of tissue-engineered islet grafts can be assessed using fluorine magnetic resonance spectroscopy (¹⁹F-MRS), by the noninvasive measurement of oxygen partial pressure (pO₂) and the subsequent calculation of islet oxygen consumption rate (OCR). Methods: Scaffolds composed of porcine plasma were seeded with human islets and perfluorodecalin. Each graft was covered with the same volume of culture media in a Petri dish. Four scaffolds were seeded with various numbers (08000) of islet equivalents (IE) aliquoted from the same preparation. After randomizing run order, grafts were examined by ¹⁹F-MRS at 37°C using a 5T spectrometer and a single-loop surface coil placed underneath. A standard inversion recovery sequence was used to obtain characteristic ¹⁹F spin-lattice relaxation times (T1), which were converted to steady-state average pO₂ estimates using a previously determined linear calibration (R² = 1.000). Each condition was assessed using replicate ¹⁹F-MRS measurements (n = 68). Results: Grafts exhibited IE dose-dependent increases in T1 and decreases in pO₂ estimates. From the difference between scaffold pO₂ estimates and ambient pO ₂, the islet preparation OCR was calculated to be 95 ± 12 (mean ± standard error of the mean) nmol/(min · mg DNA) using theoretical modeling. This value compared well with OCR values measured using established methods for human islet preparations. Conclusions: ¹⁹F-MRS can be used for noninvasive pre- and possibly posttransplant assessment of tissue-engineered islet graft viability by estimating the amount of viable, oxygen-consuming tissue in a scaffold.