Bio-integrated μBots with overtone ultrawideband magnetoelectric antennas for wireless telemetry
Mahdieh Shojaei Baghini, Adam Armada-Moreira, Alessio Di Clemente, Dibyajyoti Mukherjee, Afesomeh Ofiare, Jonathon Harwell, Mary Dysko, Luana Benetti, Declan Bolster, Laura Mazon Maldonado, Dayhim Nekoeian, Moreno Maini, Mostafa Elsayed, Rossana Cecchi, Ricardo Ferreira, Jeff Kettle, Sandy Cochran, William Holmes, Carlos Garcia Nunez, Luca Selmi, Nicola Toschi, Michele Giugliano, Hadi HeidariImplantable and wearable devices require antennas that are both miniaturized and efficient, yet conventional designs are constrained by narrow bandwidth and orientation sensitivity. We report overtone ultrawideband magnetoelectric (OUWB-ME) antennas that exploit higher-order acoustic modes in polished silicon substrates to achieve a 22.6-gigahertz −10-decibel bandwidth and overtone capability in the 3- to 4-gigahertz range. Packaged into “μBots,” these magnetoelectric heterostructures bonded with silver nanoparticle inks maintain stable operation under biological loading. In vitro assays confirm the biocompatibility of aluminum nitride and the protective role of parylene encapsulation for iron-gallium. Ex vivo rat and human tissues reshape transmission and reflection spectra, with reproducible frequency windows near 3.3 and 3.9 gigahertz. μBots enable real-time audiovisual telemetry using software-defined radios and exhibit compatibility with 7-tesla magnetic resonance imaging. By combining wideband response, robustness to misalignment, and biocompatible packaging, OUWB-ME μBots provide a scalable platform for wireless bio-integrated communication and telemetry.