Abstract
Using macrophage recruitment in tumors, we develop active, transportable, cancer theragnostic macrophage-based microrobots as vector to deliver therapeutic agents to tumor regions. The macrophage-based microrobots contain docetaxel (DTX)-loaded poly-lactic-co-glycolic-acid (PLGA) nanoparticles (NPs) for chemotherapy and Fe3O4 magnetic NPs (MNPs) for active targeting using an electromagnetic actuation (EMA) system. And, the macrophage-based microrobots are synthesized through the phagocytosis of the drug NPs and MNPs in the macrophages. The anticancer effects of the microrobots on tumor cell lines (CT-26 and 4T1) are evaluated in vitro by cytotoxic assay. In addition, the active tumor targeting by the EMA system and macrophage recruitment, and the chemotherapeutic effect of the microrobots are evaluated using three-dimensional (3D) tumor spheroids. The microrobots exhibited clear cytotoxicity toward tumor cells, with a low survivability rate (<50%). The 3D tumor spheroid assay showed that the microrobots demonstrated hybrid actuation through active tumor targeting by the EMA system and infiltration into the tumor spheroid by macrophage recruitment, resulting in tumor cell death caused by the delivered antitumor drug. Thus, the active, transportable, macrophage-based theragnostic microrobots can be considered to be biocompatible vectors for cancer therapy.
Highlights
Micro/nanoparticle (NP)-based therapy delivers particles containing therapeutic agents to a target area using the enhanced permeability and retention (EPR) effect[1], which has been developed for various biomedical applications, including tumor treatments[1]
The macrophage-based microrobots were designed to have hybrid actuation through active tumor targeting by the electromagnetic actuation (EMA) system and infiltration into the tumor tissue by macrophage recruitment
NPs (
Summary
Micro/nanoparticle (NP)-based therapy delivers particles containing therapeutic agents to a target area using the enhanced permeability and retention (EPR) effect[1], which has been developed for various biomedical applications, including tumor treatments[1] This method has some limitations in cancer therapy because it depends only on the leakage property of tumor vessels, which can be influenced by several factors[2,3,4,5]. The efficacy of drug delivery using particle-based therapy with EPR effects showed an increase of only 20–30% in tumors compared with normal organs[1] To overcome these limitations, cancer therapy using immune cells has been proposed, wherein the immune cells function as vectors or carriers for the delivery of therapeutic agents[6]. PLGA particle size influences the stability of intracellular PLGA particles, the amount of drug loading, and the drug release rate[23]
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