Partially fluorinated copolymers as oxygen sensitive 19F MRI agents.

19 F magnetic resonance imaging (MRI) is an promising emerging imaging modality. Specifically, the inherent sensitivity of the spin-lattice relaxation time ( T 1 ) of 19 F nuclei to oxygen partial pressure makes 19 F MRI an attractive non-invasive approach to quantify tissue oxygenation in a spatiotemporal manner. There remain, however, few materials with the adequate sensitivity to be used as oxygen-sensitive 19 F MRI agents. Herein, we report highly fluorinated monomers that provide a platform to realize water-soluble, partially fluorinated copolymers as 19 F MRI agents with the required sensitivity to quantify solution oxygenation at clinically relevant magnetic field strengths. The synthesis of a systematic library of partially fluorinated copolymers enabled a comprehensive evaluation of copolymer structure-property relationships relevant to 19 F MRI. The highest-performing material composition demonstrated a signal-to-noise ratio that corresponded to an apparent 19 F density of 220 mM, which surpasses the threshold of 126 mM 19 F required for visualization on a three Tesla clinical MRI. Furthermore, the T 1 of these high performing materials demonstrated a linear relationship with solution oxygenation, with oxygen sensitivity reaching 240×10 -5 mmHg -1 s -1 . The relationships between material composition and 19 F MRI performance identified herein suggest general structure-property criteria for the further improvement of modular, water-soluble 19 F MRI agents for quantifying oxygenation in environments relevant to medical imaging .