Kira Lovas scite author profile

Recent research efforts about iron oxide nanoparticles has focused on the development of iron oxide-based T contrast agents for magnetic resonance imaging (MRI), such as ultrasmall iron oxide nanospheres (USNPs <4 nm) and ultrathin nanowires (NW, diameter <4 nm). In this paper, we report the cellular uptake behaviors of these two types of ultrasmall scale nanostructures on HepG2 cells. Both these two nanostructures were functionalized with tannic acid and their physical and chemical properties were carefully analyzed before cellular tests. Both USNPs and NWs exhibited strong paramagnetic signals, a property suitable for T MRI contrast agents. The distinct shapes also caused much difference in their cellular uptake behaviors. Specifically, the uptake of USNPs was five times higher than that of NWs after 72 hours incubation. The shape-dependent cellular uptake can potentially lead to different blood circulation times, and subsequently different applications of these two types of ultrasmall nanostructures.

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T₁-Enhanced MRI-visible nanoclusters for imaging-guided drug delivery

Sherwood

Rich

Lovas

et al. 2017

Nanoscale

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Iron oxide nanoparticles with extremely low dimensions have recently been explored as positive (T) contrast agent for magnetic resonance imaging (MRI). However, their small sizes lead to fast renal clearance and limit their use in elongated in vivo tracking or therapy monitoring. In this paper, we present a state of art approach to forming nanoclusters by crosslinking ultrasmall iron oxide nanoparticles with bovine serum albumin. This novel design not only maintains the T performance of the ultrasmall nanoparticles, but also significantly increases their blood circulation times from 15 minutes to over two hours. Our breast tumor model study also exhibited enhanced contrast at tumor sites for more than 24 hours. The ability of maintaining the T performance of the ultrasmall nanoparticles is significant, because previous studies have shown complete T loss or signal decrease upon polymer encapsulation. This design also shows great potential in encapsulating model drug molecules, which will greatly benefit the field of imaging-guided drug delivery.

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Surface functionalization of dopamine coated iron oxide nanoparticles for various surface functionalities

Sherwood

Lovas

et al. 2017

Journal of Magnetism and Magnetic Materials

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We present effective conjugation of four small molecules (glutathione, cysteine, lysine, and Tris(hydroxymethyl)aminomethane) onto dopamine-coated iron oxide nanoparticles. Conjugation of these molecules could improve the surface functionality of nanoparticles for more neutral surface charge at physiological pH and potentially reduce non-specific adsorption of proteins to nanoparticles surfaces. The success of conjugation was evaluated with dynamic light scattering by measuring the surface charge changes and Fourier transform infrared spectroscopy for surface chemistry analysis. The stability of dopamine-coated nanoparticles and the ability of conjugated nanoparticles to reduce the formation of protein corona were evaluated by measuring the size and charge of the nanoparticles in biological medium. This facile conjugation method opens up possibilities for attaching various surface functionalities onto iron oxide nanoparticle surfaces for biomedical applications.

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Kira Lovas

Shape-dependent cellular behaviors and relaxivity of iron oxide-based T₁MRI contrast agents

T₁-Enhanced MRI-visible nanoclusters for imaging-guided drug delivery

Surface functionalization of dopamine coated iron oxide nanoparticles for various surface functionalities

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Kira Lovas

Shape-dependent cellular behaviors and relaxivity of iron oxide-based T1MRI contrast agents

T1-Enhanced MRI-visible nanoclusters for imaging-guided drug delivery

Surface functionalization of dopamine coated iron oxide nanoparticles for various surface functionalities

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Product

Resources

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Shape-dependent cellular behaviors and relaxivity of iron oxide-based T₁MRI contrast agents

T₁-Enhanced MRI-visible nanoclusters for imaging-guided drug delivery