Lanthanide-based (Ln(3+)-based) nanoparticles have great potential for high-field magnetic resonance imaging (MRI) applications. Here, we report NaHoF4 and NaDyF4 nanoparticles with modulated sizes (9-40 nm) and shapes (spherical-like, hexagonal prism, rod-like), suitable for high-field MRI as shown through in vivo studies. We used X-ray diffraction, transmission electron microscope, dynamic light scattering, and MRI techniques to investigate the structure, morphology, hydrodynamic size, and relaxivity of the prepared NaHoF4 and NaDyF4 nanoparticles, showing monodisperse nanoparticles of high crystallinity. In particular, we studied effects of the particle size, shape, surface coating and zeta-potential on transverse (spin-spin relaxivity, r(2)) and longitudinal (spin lattice relaxivity, r(1)) relaxivity at 9.4 T. We found that the NaHoF4 and NaDyF4 nanoparticles have r(2) relaxivities of (274.0 +/- 6.9) x 10(4) and (4767.3 +/- 160.9) x 10(4) mM(NP)(-1) s(-1) per nanoparticle and high r(2)/r(1) ratio of 781 and 410 at a high magnetic field of 9.4 T, respectively, making them attractive as MRI T-2 contrast agents. The growth of the hexagonal structure of the NaHoF4 and NaDyF4 nanoparticles was mainly dominated by the growth competition along the [001] and [100] directions that could be modulated by the amount of oleic acid (OA), 1-octadecene (ODE), NaOH, and NH4F. Moreover, both the larger particle size and thin coating polymer layer of nanoparticles increased the transverse relaxivity. The effects of the parameters, such as rotation correlation time, diffusion, and electronic relation times on the dipolar and Curie components of the inner- and outer-sphere contribution, and thus directly on the relaxivity, are discussed. We found that these parameters can be modulated by the particle size and surface coating. Following the outer-sphere relaxation theory, we used computer simulations of r(1) and r(2) relaxivity as a function of the particle core size, hydrodynamic size, diffusion time, and electronic relation time, which all show an impact on r(1) and r(2), albeit to very different extends, which has enhanced our understanding of the relaxivity mechanisms. According to the computer simulations, r(1) can be controlled by the core size, hydrodynamic size at low magnetic fields of similar to 0.02 T corresponding to proton Larmor frequency of about 1 MHz. The r(1) does not change significantly at the higher frequency and actually drops precipitously. However, on the basis of theoretical simulations, we expect r(2) can be increased in a wide range of Larmor frequencies (0.1-1000 MHz) by increasing the core size, reducing thickness of the coating layer, or increasing the magnetic field. The particle sizes, hydrodynamic sizes, and diffusion times and magnetic fields have larger contribution to the relaxivity than that of other parameters. Five animals were imaged and in vivo MRI showed that the rod-like NaDyF4 (25 nm x 35 nm) nanoparticles, without any targeting ligands, provided visible contrast between brain and breast tumors and normal tissues up to 24 h after injection. Contrast was observed in all animals after injection of nanoparticle solution, which may be attributed to enhanced permeation and retention effects of the rod-shape nanoparticles in tumor. @@@ The experimental and simulation results suggest that the NaHoF4 and NaDyF4 nanoparticles are indeed good candidates for high-field (>3 T) T-2 imaging contrast agents.

• 出版日期2016-5-10
• 单位河北工业大学