TriMag Microrobots: 3D-Printed Microrobots for Magnetic Actuation, Imaging, and Hyperthermia
Recommended Citation
Xing L, Cai Y, Zhang Y, Mozel K, Tang Z, Tang T, Mottini V, Nigam S, Smith BR, Lee IY, Nagaraja TN, Wang P, Li X, Gao T, and Li J. TriMag Microrobots: 3D-Printed Microrobots for Magnetic Actuation, Imaging, and Hyperthermia. Adv Mater 2025;e19708.
Document Type
Article
Publication Date
8-11-2025
Publication Title
Adv Mater
Abstract
Microrobots hold immense potential in biomedical applications, including drug delivery, disease diagnostics, and minimally invasive surgeries. However, two key challenges hinder their clinical translation: achieving scalable and precision fabrication, and enabling non-invasive imaging and tracking within deep biological tissues. Magnetic particle imaging (MPI), a cutting-edge imaging modality, addresses these challenges by detecting the magnetization of nanoparticles and visualizing superparamagnetic nanoparticles (SPIONs) with sub-millimeter resolution, free from interference by biological tissues. This capability makes MPI an ideal tool for tracking magnetic microrobots in deep tissue environments. In this study, "TriMag" microrobots are introduced: 3D-printed microrobots with three integrated magnetic functionalities-magnetic actuation, magnetic particle imaging, and magnetic hyperthermia. The TriMag microrobots are fabricated using an innovative method that combines two-photon lithography for 3D printing biocompatible hydrogel structures with in situ chemical reactions to embed the hydrogel scaffold with Fe(3)O(4) nanoparticles for good MPI contrast and CoFe(2)O(4) nanoparticles for efficient magnetothermal heating. This approach enables scalable, precise fabrication of helical magnetic hydrogel microrobots. The resulting TriMag microrobots, with the synergistic effects of Fe(3)O(4) and CoFe(2)O(4) nanoparticles, demonstrate efficient magnetic actuation for controlled movement, precise imaging via MPI for imaging and tracking in biological fluid and organs, including porcine eye and mouse stomach, and magnetothermal heating for tumor ablation in a mouse model. By combining these capabilities, the fabrication and imaging approach provides a robust platform for non-invasive monitoring and manipulation of microrobots for transformative applications in medical treatment and biological research.
PubMed ID
40787971
ePublication
ePub ahead of print
First Page
19708
Last Page
19708
