Clickable polymer ligand-functionalized iron oxide nanocubes: A promising nanoplatform for 'local hot spots' magnetically triggered drug release Articles uri icon

authors

  • MAI, BINH T.
  • CONTEH, JOHN S.
  • GAVILAN RUBIO, HELENA
  • GIROLAMO, ALESSANDRO DI
  • PELLEGRINO, TERESA

publication date

  • November 2022

start page

  • 48476

end page

  • 48488

issue

  • 43

volume

  • 14

International Standard Serial Number (ISSN)

  • 1944-8244

Electronic International Standard Serial Number (EISSN)

  • 1944-8252

abstract

  • Exploiting the local heat on the surface of magnetic nanoparticles (MNPs) upon exposure to an alternating magnetic field (AMF) to cleave thermal labile bonds represents an interesting approach in the context of remotely triggered drug delivery. Here, taking advantages of a simple and scalable two-step ligand exchange reaction, we have prepared iron oxide nanocubes (IONCs) functionalized with a novel multifunctional polymer ligand having multiple catechol moieties, furfuryl pendants, and polyethylene glycol (PEG) side chains. Catechol groups ensure a strong binding of the polymer ligands to the IONCs surface, while the PEG chains provide good colloidal stability to the polymer-coated IONCs. More importantly, furfuryl pendants on the polymer enable to click the molecules of interest (either maleimide-fluorescein or maleimide-doxorubicin) via a thermal labile Diels–Alder adduct. The resulting IONCs functionalized with a fluorescein/doxorubicin-conjugated polymer ligand exhibit good colloidal stability in buffer saline and serum solution along with outstanding heating performance in aqueous solution or even in viscous media (81% glycerol/water) when exposed to the AMF of clinical use. The release of conjugated bioactive molecules such as fluorescein and doxorubicin could be boosted by applying AMF conditions of clinical use (16 kAm-1 and 110 kHz). It is remarkable that the magnetic hyperthermia-mediated release of the dye/drug falls in the concentration range 1.0-5.0 μM at an IONCs dose as low as 0.5 gFe/L and at no macroscopical temperature change. This local release effect makes this magnetic nanoplatform a potential tool for drug delivery with remote magnetic hyperthermia actuation and with a dose-independent action of MNPs.

subjects

  • Chemistry
  • Industrial Engineering
  • Materials science and engineering
  • Mechanical Engineering

keywords

  • multifunctional polymer; heat-mediated release; magnetic hyperthermia; iron oxide nanoparticles; drug release; hot-spot effect