Hyoryong Lee scite author profile

Therapeutic drug delivery microrobots capable of accurate targeting using an electromagnetic actuation (EMA) system are being developed. However, these drug delivery microrobots include a large number of magnetic nanoparticles (MNPs) for accurate EMA targeting, which causes side effects, such as problems with membrane integrity and normal cell apoptosis. Here, a biocompatible and hydrolyzable PEGDA-based drug delivery helical microrobot capable of MNP retrieval is proposed in which doxorubicin (DOX), an anticancer drug, is encapsulated and MNPs are conjugated by a disulfide bond. After being accurately delivered to the lesion of cancer cells through magnetic field manipulation, the fabricated microrobot provides rapid MNP separation and retrieval from the microrobot because of the use of dithiothreitol (DTT), a reducing agent, as an environment similar to the surrounding cancer cells and near-infrared (NIR) as an external stimulus. The characteristics of the fabricated microrobot are analyzed, and fundamental tests for active electromagnetic field manipulation, separation/retrieval of MNPs from the microrobot, and its hydrolysis are discussed. The therapeutic performance of the fabricated microrobot is verified through an in vitro test using tumor cells. Consequently, by use of an integrated system of microscope, eight-coil EMA, and NIR it is shown that the proposed microrobot can be moved to the target site by electromagnetic manipulation. The MNPs conjugated to the microrobot can be separated and retrieved, and the therapeutic effect on tumor cells by the encapsulated drug can be seen.

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Magnetic nano-particles retrievable biodegradable hydrogel microrobot

Kim

Lee

Kwon

et al. 2019

Sensors and Actuators B: Chemical

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Bilayer Hydrogel Sheet‐Type Intraocular Microrobot for Drug Delivery and Magnetic Nanoparticles Retrieval

Kim

Lee

Kwon

et al. 2020

Adv Healthcare Materials

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By virtue of minimum invasiveness and driving ability using a magnetic field, drug delivery with the aid of a microrobot has an inherent potential for targeted treatment for the eye. The use of microrobots, however, has the limitation of leaving magnetic nanoparticles (MNPs) in the eye that can cause side effects. In this study, a bilayer hydrogel microrobot capable of retrieving MNPs after drug delivery is proposed that overcomes the limitations of existing microrobots. The bilayer hydrogel microrobot is composed of an MNPs layer and a therapeutic layer. Upon applying an alternating magnetic field (AMF) at the target point, the therapeutic layer is dissolved to deliver drug particles, and then the MNPs layer can be retrieved using a magnetic field. The targeting and MNPs retrieval tests validate the drug delivery and MNPs retrieval ability of the microrobot. The ex vivo bovine vitreous and in vitro cell tests demonstrate the potential for the vitreous migration of the microrobot and the therapeutic effect against retinoblastoma Y79 cancer cells. This bilayer hydrogel sheet‐type intraocular microrobot provides a new drug delivery paradigm that overcomes the limitations of microrobot by maintaining the advantages of conventional microrobots in delivering drugs to the eye and retrieving MNPs after drug delivery.

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Preliminary study on alginate/NIPAM hydrogel-based soft microrobot for controlled drug delivery using electromagnetic actuation and near-infrared stimulus

Lee

Choi

Lee

et al. 2018

Biomed Microdevices

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Active delivery of multi-layer drug-loaded microneedle patches using magnetically driven capsule

Lee

Kwon

Park

2020

Medical Engineering & Physics

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Hyoryong Lee

Magnetically Actuated Drug Delivery Helical Microrobot with Magnetic Nanoparticle Retrieval Ability

Magnetic nano-particles retrievable biodegradable hydrogel microrobot

Bilayer Hydrogel Sheet‐Type Intraocular Microrobot for Drug Delivery and Magnetic Nanoparticles Retrieval

Preliminary study on alginate/NIPAM hydrogel-based soft microrobot for controlled drug delivery using electromagnetic actuation and near-infrared stimulus

Active delivery of multi-layer drug-loaded microneedle patches using magnetically driven capsule

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