With the rapid development of micro/nanomanufacturing technology, a variety of multifunctional micro/nanorobots have emerged. In particular, magnetic actuation-based micro/nanorobots have attracted much interest due to their advantages of untethered contact, remote control, noninvasiveness, and high tissue-penetrating capability. Various magnetic micro/nanorobots have been designed and applied in biomedicine, which indicates the great potential of clinical transformation. This article reviews the new advancements of engineering magnetic micro/nanorobots for versatile biomedical applications, ranging from targeted delivery, minimally invasive surgery, cellular and intracellular measurement, and intelligent sensing to detoxification and antibacterial applications. The controllability, visualization, and biosafety aspects of magnetically manipulated micro/nanorobots are summarized. In particular, the challenges being faced are discussed to outlook future prospective development.
Fast and effective thrombolysis using tissue plasminogen activator (tPA) is limited by the poor delivery efficiency of thrombolytic drugs, which is induced by an interrupted bloodstream and delayed recanalization. Existing magnetic micro/nanodrug‐loaded robots used for targeted thrombotic therapy are limited by the complexity of the clinical verification of nanodrugs and the limited space of magnetic actuation systems. Herein, a general drug delivery strategy based on mass transportation theory for thrombolysis is presented, and an open space C‐shaped magnetic actuation system with laser location and ultrasound imaging navigation for in vivo evaluation is developed. tPA can be guided through an interrupted bloodstream to the thrombi by the locomotion of magnetic nanoparticle swarms (MNSs), thereby improving the thrombolysis efficacy. Notably, this strategy is able to quickly establish a life channel to achieve time‐critical recanalization, which is typically inaccessible using native tPA. Both in vitro and in vivo thrombolysis experiments demonstrate that the thrombus lysis efficacy significantly increases after the application of the MNS under a rotating magnetic field. This study provides an anticipated C‐shaped magnetic actuation system for in vivo validation and also presents a clinically feasible drug delivery strategy for targeted thrombolytic therapy with minimal systemic tPA exposure.
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