Biofunctional magnetic nanoparticles
(MNPs) have been widely applied
in biomedical engineering. MNPs are used as a contrast medium in magnetic
imaging. Current methods of magnetic imaging, such as magnetic particle
imaging and magnetic relaxometry, use small amounts of MNPs at target
points far from the surface of the patient’s body; these methods
always consume considerable power to produce magnetic fields of high
uniformity or gradient excitations. Some drawbacks, such as a limited
imaging region, imaging system shielding, and complex algorithms based
on assumptions of MNP properties or environmental factors, also limit
the application of MNP methods in clinics. Therefore, this work proposes
an interdisciplinary methodology of ultrasound-induced magnetic imaging
that lacks these drawbacks. In the proposed imaging method, magnet
sets were designed with uniform magnetic fields to magnetize MNPs.
Besides, magnetized MNPs are subjected to ultrasound vibrations; the
motion of the MNPs induces weak induction voltages at the imaging
pickup coils. The highly sensitive scanning superconducting quantum
interference device biosusceptometry with three sets of ultrasound
focus chips was developed to construct magnetic tomography at three
depths. A phantom test showed favorable consistency between the visual
photos and the magnetic images of alpha-fetoprotein antibody (anti-AFP)
MNP distribution on gauzes. In animal tests, rats with liver tumors
were imaged at the pre-injection and post-injection of anti-AFP MNPs.
The consistent results of magnetic images and ultrasound images implied
that the proposed method has high clinical potential.