Immunological effects of iron oxide nanoparticles and iron-based complex drug formulations: Therapeutic benefits, toxicity, mechanistic insights, and translational considerations

Shah, Avani; Dobrovolskaia, Marina A.

doi:10.1016/j.nano.2018.01.014

Cited by 106 publications

(64 citation statements)

References 167 publications

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“…MIONs can mediate toxicity through several mechanisms that all have to be taken into account when evaluating their safety. Most intracellular toxicity is caused by generation of reactive oxygen species whereas in vivo disturbances of blood clotting, iron homeostasis and macrophage function, as well as organ toxicities, are additional considerations (Ilinskaya and Dobrovolskaia, 2013 ; Wu et al, 2014 ; Wei et al, 2016 ; Shah and Dobrovolskaia, 2018 ). A more detailed discussion of MION toxicity can be found in specialized review articles (Reddy et al, 2012 ; Liu et al, 2013 ; Arami et al, 2015 ).…”

Section: Dosing and Toxicity Of Magnetic Iron Oxide Nanoparticlesmentioning

confidence: 99%

Biologically Targeted Magnetic Hyperthermia: Potential and Limitations

et al. 2018

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Hyperthermia, the mild elevation of temperature to 40–43°C, can induce cancer cell death and enhance the effects of radiotherapy and chemotherapy. However, achievement of its full potential as a clinically relevant treatment modality has been restricted by its inability to effectively and preferentially heat malignant cells. The limited spatial resolution may be circumvented by the intravenous administration of cancer-targeting magnetic nanoparticles that accumulate in the tumor, followed by the application of an alternating magnetic field to raise the temperature of the nanoparticles located in the tumor tissue. This targeted approach enables preferential heating of malignant cancer cells whilst sparing the surrounding normal tissue, potentially improving the effectiveness and safety of hyperthermia. Despite promising results in preclinical studies, there are numerous challenges that must be addressed before this technique can progress to the clinic. This review discusses these challenges and highlights the current understanding of targeted magnetic hyperthermia.

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Section: Dosing and Toxicity Of Magnetic Iron Oxide Nanoparticlesmentioning

confidence: 99%

Biologically Targeted Magnetic Hyperthermia: Potential and Limitations

et al. 2018

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“…In general, MNPs do not cause notable toxicity in different immune cell types, with high cell viability percentages often observed [86]. MNP toxicity usually occurs mainly when high doses and prolonged exposure times are used [87,88] or in the presence of certain coatings [89]. Besides, there are several studies demonstrating the low toxicity of MNPs in both human and murine T and NK cell lines and in primary T and NK cells [75,78,80,[89][90][91][92][93][94][95][96][97][98][99].…”

Section: The Interaction Between Mnps and Lymphoid Cellsmentioning

confidence: 99%

Improving Tumor Retention of Effector Cells in Adoptive Cell Transfer Therapies by Magnetic Targeting

2020

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Adoptive cell transfer therapy is a promising anti-tumor immunotherapy in which effector immune cells are transferred to patients to treat tumors. However, one of its main limitations is the inefficient trafficking of inoculated effector cells to the tumor site and the small percentage of effector cells that remain activated when reaching the tumor. Multiple strategies have been attempted to improve the entry of effector cells into the tumor environment, often based on tumor types. It would be, however, interesting to develop a more general approach, to improve and facilitate the migration of specific activated effector lymphoid cells to any tumor type. We and others have recently demonstrated the potential for adoptive cell transfer therapy of the combined use of magnetic nanoparticle-loaded lymphoid effector cells together with the application of an external magnetic field to promote the accumulation and retention of lymphoid cells in specific body locations. The aim of this review is to summarize and highlight the recent findings in the field of magnetic accumulation and retention of effector cells in tumors after adoptive transfer, and to discuss the possibility of using this approach for tumor targeting with chimeric antigen receptor (CAR) T-cells.

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“…34 Production of reactive oxygen species can be induced by nano-materials as nanomaterials are able to reach mitochondria and hence may induce inammatory response in activated macrophages. 35 Microarray analysis revealed that gene responsible for oxidative stress and inammatory responses undergo for reprogramming in IONPs treated mouse macrophages. 36 We therefore speculate that IONPs-induced ROS activates NF-kB, which subsequently leads to release of pro-inammatory cytokines.…”

Section: Measurement Of Serum Cytokinesmentioning

confidence: 99%