Triple-Configurational Magnetic Robot for Targeted Drug Delivery and Sustained Release

Chen, Weinan; Chen, Xi; Yang, Minghan; Li, Shishi; Fan, Xinjian; Zhang, Hao; Xie, Hui

doi:10.1021/acsami.1c14610

Cited by 25 publications

(25 citation statements)

References 43 publications

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“…Our drug delivery system could sustainedly release the drug into the complete medium for 15–20 min completely. The sustained-release microrobots are supposed to reduce the side-effect to normal cells and enhance the drug lethality in tumor cells ( Chen et al, 2021 ). The selected inhibition of the magnetic-driven hydrogel microrobot drug delivery system was simulated in vitro ( Figure 5A ).…”

Section: Resultsmentioning

confidence: 99%

Magnetic-Driven Hydrogel Microrobots Selectively Enhance Synthetic Lethality in MTAP-Deleted Osteosarcoma

Liu

Zhang

et al. 2022

Front. Bioeng. Biotechnol.

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Background: Drugs based on synthetic lethality have advantages such as inhibiting tumor growth and affecting normal tissue in vivo. However, specific targets for osteosarcoma have not been acknowledged yet. In this study, a non-targeted but controllable drug delivery system has been applied to selectively enhance synthetic lethality in osteosarcoma in vitro, using the magnetic-driven hydrogel microrobots.Methods: In this study, EPZ015666, a PRMT5 inhibitor, was selected as the synthetic lethality drug. Then, the drug was carried by hydrogel microrobots containing Fe3O4. Morphological characteristics of the microrobots were detected using electron microscopy. In vitro drug effect was detected by the CCK-8 assay kit, Western blotting, etc. Swimming of microrobots was observed by a timing microscope. Selective inhibition was verified by cultured tumors in an increasing magnetic field.Results: Genomic mutation of MTAP deletion occurred commonly in pan-cancer in the TCGA database (nearly 10.00%) and in osteosarcoma in the TARGET database (23.86%). HOS and its derivatives, 143B and HOS/MNNG, were detected by MTAP deletion according to the CCLE database and RT-PCR. EPZ015666, the PRMT5 inhibitor, could reduce the SDMA modification and inhibition of tumor growth of 143B and HOS/MNNG. The hydrogel microrobot drug delivery system was synthesized, and the drug was stained by rhodamine. The microrobots were powered actively by a magnetic field. A simulation of the selected inhibition of microrobots was performed and lower cell viability of tumor cells was detected by adding a high dose of microrobots.Conclusion: Our magnetic-driven drug delivery system could carry synthetic lethality drugs. Meanwhile, the selective inhibition of this system could be easily controlled by programming the strength of the magnetic field.

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Section: Resultsmentioning

confidence: 99%

Magnetic-Driven Hydrogel Microrobots Selectively Enhance Synthetic Lethality in MTAP-Deleted Osteosarcoma

Liu

Zhang

et al. 2022

Front. Bioeng. Biotechnol.

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“…Micro-/nanorobots capable of converting various energies into effective locomotion in low-Reynolds number fluids have attracted increasing interest due to their great potential in the biomedical area. − In recent years, significant developments of micro-/nanorobots with diverse propulsion mechanisms (e.g., chemical, − light, − acoustic, − and magnetic propulsion − ) have been achieved and magnetic micro-/nanorobots have gained particular attention. To date, various magnetic micro-/nanorobots have been proposed to efficiently deliver anticancer drugs to targeted tumor spots − owing to their potential to enhance the therapeutic efficacy.…”

Section: Introductionmentioning

confidence: 99%

Magnetic Biohybrid Microrobot Multimers Based on Chlorella Cells for Enhanced Targeted Drug Delivery

Gong

Celi

Zhang

et al. 2022

ACS Appl. Mater. Interfaces

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Magnetic micro-/nanorobots have been regarded as a promising platform for targeted drug delivery, and tremendous strategies have been developed in recent years. However, realizing precise and efficient drug delivery in vivo still remains challenging, in which the versatile integration of good biocompatibility and reconfiguration is the main obstacle for micro-/nanorobots. Herein, we proposed a novel strategy of magnetic biohybrid microrobot multimers (BMMs) based on Chlorella (Ch.) and demonstrated their great potential for targeted drug delivery. The spherical Ch. cells around 3–5 μm were magnetized with Fe3O4 to fabricate biohybrid microrobots and then loaded with doxorubicin (DOX). Using magnetic dipolar interactions, the microrobot units could reconfigure into chain-like BMMs as tiny dimers, trimers, and so forth via attraction-induced self-assembly and disassemble reversibly via repulsion. The BMMs exhibited diverse swimming modes including rolling and tumbling with high maneuverability, and the rolling dimer’s velocity could reach 107.6 μm/s (∼18 body length/s) under a 70 Gs precessing magnetic field. Furthermore, the BMMs exhibited low cell toxicity, high DOX loading capacity, and pH-triggered drug release, which were verified by chemotherapy experiments toward HeLa cancer cells. Due to the remarkable versatility and facile fabrication, the BMMs demonstrate great potential for targeted anticancer therapy.

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“…Recently, artificial micro- and nanomotors have attracted substantial attention because of their versatile actuation modes, potential to navigate in hard-to-reach and confined environments, and immense application prospects in biomedicine, including minimally invasive surgery, − targeted drug delivery, and biomedical diagnostics. − However, generally, the size of single micro- and nanomotors is much smaller than that of MIP, making it impossible to repair MIPs using single micro- and nanomotors. Consequently, multiple micro- and nanomotors such as micro/nanoswarms are required.…”

Section: Introductionmentioning

confidence: 99%

Wheel-like Magnetic-Driven Microswarm with a Band-Aid Imitation for Patching Up Microscale Intestinal Perforation

Yue

Chang

Liu

et al. 2022

ACS Appl. Mater. Interfaces

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Microscale intestinal perforation can cause considerable mortality and is very difficult to treat using conventional methods owing to the numerous challenges associated with microscale operations, which require the development of new body-friendly and effective treatment methods. Swarming micro- and nanomotors have shown great potential in biomedical applications in complex and hard-to-reach environments. Herein, we present a wheel-like magnetic-driven microswarm (WLM) with a band-aid imitation to patch microscale intestinal perforations by pasting on the perforation point in mucus-filled environments. A method called “packing under rolling” was applied to make the formed microswarms denser and rounder. Microswarms with variable aspect ratios can be fabricated by tuning the frequency and strength of the external magnetic field. Actuation and navigation in a confined complex environment, locomotion on three-dimensional surfaces, and multiple switchable motion modes have been realized by combining AC and DC magnetic fields. Moreover, we demonstrated WLM controllable navigation, movement, and microscale perforation patching in the chicken intestines ex vivo. The proposed strategy will contribute to the treatment of microscale intestinal perforation and may be applicable to novel, precise topical medication and microsurgery.

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Triple-Configurational Magnetic Robot for Targeted Drug Delivery and Sustained Release

Cited by 25 publications

References 43 publications

Magnetic-Driven Hydrogel Microrobots Selectively Enhance Synthetic Lethality in MTAP-Deleted Osteosarcoma

Magnetic-Driven Hydrogel Microrobots Selectively Enhance Synthetic Lethality in MTAP-Deleted Osteosarcoma

Magnetic Biohybrid Microrobot Multimers Based on Chlorella Cells for Enhanced Targeted Drug Delivery

Wheel-like Magnetic-Driven Microswarm with a Band-Aid Imitation for Patching Up Microscale Intestinal Perforation

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