Time‐Dependent T 1 –T 2 Switchable Magnetic Resonance Imaging Realized by c(RGDyK) Modified Ultrasmall Fe 3 O 4 Nanoprobes

To achieve the accurate diagnosis of tumor with the magnetic resonance imaging (MRI), nanomaterials‐based contrast agents are developed rapidly. Here, a tumor targeting nanoprobe of c(RGDyK) modified ultrasmall sized iron oxide is reported with high saturation magnetization and high T 1 ‐weighted imaging capability, attributed to a large number of paramagnetic centers on the surface of nanoprobes and rapid water proton exchange rate (inner sphere model), as well as strong superparamagnetism (outer sphere model). These nanoprobes could actively target and gradually accumulate at the tumor site with a time‐dependent T 1 –T 2 contrast enhancement imaging effect. In in vivo MRI experiments, the nanoprobes exhibit the best T 1 contrast enhancement at 30 min after intravenous administration, followed by gradually vanishing and generating T 2 contrast enhancement with increasing time at tumor site. This is likely due to time‐dependent nanoprobes aggregation in tumor, in good agreement with in vitro experiment where aggregated nanoprobes display larger r 2 / r 1 value (19.1) than that of the dispersed nanoprobes (2.8). This dynamic property is completely different from other T 1 ‐T 2 dual‐modal nanoprobes which commonly exhibit the T 1 ‐ and T 2 ‐weighted enhancement effect at the same time. To sum up, these c(RGDyK) modified ultrasmall Fe 3 O 4 nanoprobes have significant potential to improve the diagnostic accuracy and sensitivity in MRI.