Highly Optimized Iron Oxide Embedded Poly(Lactic Acid) Nanocomposites for Effective Magnetic Hyperthermia and Biosecurity

Iron oxide magnetic nanoparticles (IONPs) have attracted considerable attention for various biomedical applications owing to their ease of synthesis, strong magnetic properties, and biocompatibility. In particular, IONPs can generate heat under an alternating magnetic field, the effects of which hav...

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Bibliographic Details
Published in:International journal of nanomedicine 2022-01, Vol.17, p.31-44
Main Authors: Ryu, Chiseon, Lee, Hwangjae, Kim, Hohyeon, Hwang, Seong, Hadadian, Yaser, Mohanty, Ayeskanta, Park, In-Kyu, Cho, Beongki, Yoon, Jungwon, Lee, Jae Young
Format: Article
Language:English
Subjects:
Biocompatibility
Biomedical engineering
Biosecurity
Cell culture
Efficiency
Ferric Compounds
Ferric oxide
Fever
Heat
Heating
Hyperthermia
Hyperthermia, Induced
inter-particle interactions
Iron
Iron compounds
iron oxide nanoparticle
Lactic acid
Magnetic Fields
Magnetic properties
Nanocomposites
nanomedicine
Nanoparticles
Original Research
Physiological aspects
Polyesters
Polymers
Polyvinyl alcohol
Tissue Distribution
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Summary:Iron oxide magnetic nanoparticles (IONPs) have attracted considerable attention for various biomedical applications owing to their ease of synthesis, strong magnetic properties, and biocompatibility. In particular, IONPs can generate heat under an alternating magnetic field, the effects of which have been extensively studied for magnetic hyperthermia therapy. However, the development of IONPs with high heating efficiency, biocompatibility, and colloidal stability in physiological environments is still required for their safe and effective application in biomedical fields. We synthesized magnetic IONP/polymer nanocomposites (MNCs) by embedding IONPs in a poly(L-lactic acid) (PLA) matrix via nanoemulsion. The IONP contents (Fe: 9-22 [w/w]%) in MNCs were varied to investigate their effects on the magnetic and hyperthermia performances based on their optimal interparticle interactions. Further, we explored the stability, cytocompatibility, biodistribution, and in vivo tissue compatibility of the MNCs. The MNCs showed enhanced heating efficiency with over two-fold increase compared to nonembedded bare IONPs. The relationship between the IONP content and heating performance in MNCs was nonmonotonous. The highest heating performance was obtained from MNC2, which contain 13% Fe (w/w), implying that interparticle interactions in MNCs can be optimized to achieve high heating performance. In addition, the MNCs exhibited good colloidal stability under physiological conditions and maintained their heating efficiency during 48 h of incubation in cell culture medium. Both in vitro and in vivo studies revealed excellent biocompatibility of the MNC. Our nanocomposites, comprising biocompatible IONPs and PLA, display improved heating efficiency, good colloidal stability, and cytocompatibility, and thus will be beneficial for diverse biomedical applications, including magnetic hyperthermia for cancer treatment.
ISSN:1178-2013
1176-9114
1178-2013
DOI:10.2147/IJN.S344257