Tailored Dual PEGylation of Inorganic Porous Nanocarriers for Extremely Long Blood Circulation in Vivo

Nissinen, Tuomo; Näkki, Simo; Laakso, Hanne; Kučiauskas, Dalius; Kaupinis, Algirdas; Kettunen, Mikko I.; Liimatainen, Timo; Hyvönen, Mervi T.; Valius, Mindaugas; Gröhn, Olli; Lehto, Vesa‐Pekka

doi:10.1021/acsami.6b12481

Cited by 44 publications

(41 citation statements)

References 44 publications

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“…It has been well demonstrated that the density and length of PEG, as well as its mixed heterogeneous layer structure, could affect blood circulation. 5,28 It has also been reported that the increase in molecular weight of PEG can prolong the circulation time of PEG in blood. 29 For example, when the molecular weight increased from 6,000 to 19,000, the half-life time could be increased from 18 minutes to 1 hour in blood.…”

Section: Effects Of Core Size and Peg Layer On The Clearance Rate Of mentioning

confidence: 98%

“…Similar to gold NPs and porous silicon NPs, they are required to undergo surface modification to avoid quick clearance by the immune system prior to arriving at the predesignated organs. 4,5 Recent studies in this field revealed that the blood circulation of IONPs can be controlled by their particle size, morphology, and surface ligands. 6,7 Since spherical IONPs have been widely adopted for biomedical applications, including the commercial Endorem (Guerbet S.A., Roissy Charles de Gaulle Cedex, France), and Sinerem (AMAG Pharmaceuticals, Inc., Cambridge, MA, USA), the effect of core size and surface ligands on circulation time has attracted extensive attention.…”

Section: Introductionmentioning

confidence: 99%

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Effects of core size and PEG coating layer of iron oxide nanoparticles on the distribution and metabolism in mice

Wang¹,

Liu²,

Zhang³

et al. 2018

IJN

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IntroductionIn vivo distribution of polyethylene glycol (PEG)ylated functional nanoparticles is vital for determining their imaging function and therapeutic efficacy in nanomedicine. However, contradictory results have been reported regarding the effect of core size and PEG surface of the nanoparticles on biodistribution.MethodsTo clarify this ambiguous understanding, using iron oxide nanoparticles (IONPs) as a model system, we investigated the effect of core size and PEG molecule weights on in vivo distribution in mice. Three PEGylated IONPs, including 14 nm IONP@PEG2,000, 14 nm IONP@PEG5,000, and 22 nm IONP@PEG5,000, were prepared with a hydrodynamic size of 26, 34, and 81 nm, respectively. The blood pharmacokinetics and tissue distribution were investigated in detail.ResultsThe results indicated that the PEG layer, rather than core size, played a dominant role in determining the half-life time of IONPs. Specifically, increased molecular weight of the PEG layer led to a longer half-life time. These PEGylated IONPs were mainly excreted by liver clearance. While the PEG molecular layer constituted the key factor to determine the clearance ratio, core size affected the clearance rate.ConclusionComplete blood count analysis and histopathology suggested excellent biocompatibility of PEGylated IONPs for future clinical trials.

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Section: Effects Of Core Size and Peg Layer On The Clearance Rate Of mentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Effects of core size and PEG coating layer of iron oxide nanoparticles on the distribution and metabolism in mice

Wang¹,

Liu²,

Zhang³

et al. 2018

IJN

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“…Surface modification which makes magnetic particles stable in physiological conditions is highly researched area since particle aggregation can make treatment ineffective or can cause negative health effects. Myriads of magnetic particle preparation and functionalization procedures were reported, however only two types of particles entered clinical trials, i.e., particles coated with polysaccharides or silica [ 234 , 235 ]. Further, polymeric compounds are highly investigated to hide magnetic particles from the immune system.…”

Section: Magnetic Nanoparticles In the Real Worldmentioning

confidence: 99%

Magnetic Nanoparticles: From Design and Synthesis to Real World Applications

et al. 2017

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The increasing number of scientific publications focusing on magnetic materials indicates growing interest in the broader scientific community. Substantial progress was made in the synthesis of magnetic materials of desired size, morphology, chemical composition, and surface chemistry. Physical and chemical stability of magnetic materials is acquired by the coating. Moreover, surface layers of polymers, silica, biomolecules, etc. can be designed to obtain affinity to target molecules. The combination of the ability to respond to the external magnetic field and the rich possibilities of coatings makes magnetic materials universal tool for magnetic separations of small molecules, biomolecules and cells. In the biomedical field, magnetic particles and magnetic composites are utilized as the drug carriers, as contrast agents for magnetic resonance imaging (MRI), and in magnetic hyperthermia. However, the multifunctional magnetic particles enabling the diagnosis and therapy at the same time are emerging. The presented review article summarizes the findings regarding the design and synthesis of magnetic materials focused on biomedical applications. We highlight the utilization of magnetic materials in separation/preconcentration of various molecules and cells, and their use in diagnosis and therapy.

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“…13–16 Furthermore, polydisperse PEG brushes of varying length have been shown to be more effective than monodisperse PEG layers in reducing protein adsorption, 17, 18 indicating the design may generate long circulating NPs. 19 The improvement was attributed to the increased PEG density and layer thickness because short PEG chains fit in between longer PEG molecules, and steric repulsions between grafted chains increase the overall thickness of the PEG layer. However, some studies have reported the existence of an optimal density of grafted PEG for repelling proteins.…”

mentioning

confidence: 99%

Dense and Dynamic Polyethylene Glycol Shells Cloak Nanoparticles from Uptake by Liver Endothelial Cells for Long Blood Circulation

et al. 2018

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Research into long-circulating nanoparticles has in the past focused on reducing their clearance by macrophages. By engineering a hierarchical polyethylene glycol (PEG) structure on nanoparticle surfaces, we revealed an alternative mechanism to enhance nanoparticle blood circulation. The conjugation of a second PEG layer at a density close to but lower than the mushroom-to-brush transition regime on conventional PEGylated nanoparticles dramatically prolongs their blood circulation via reduced nanoparticle uptake by non-Kupffer cells in the liver, especially liver sinusoidal endothelial cells. Our study also disclosed that the dynamic outer PEG layer reduces protein binding affinity to nanoparticles, although not the total number of adsorbed proteins. These effects of the outer PEG layer diminish in the higher density regime. Therefore, our results suggest that the dynamic topographical structure of nanoparticles is an important factor in governing their fate in vivo. Taken together, this study advances our understanding of nanoparticle blood circulation and provides a facile approach for generating long circulating nanoparticles.

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Tailored Dual PEGylation of Inorganic Porous Nanocarriers for Extremely Long Blood Circulation in Vivo

Cited by 44 publications

References 44 publications

Effects of core size and PEG coating layer of iron oxide nanoparticles on the distribution and metabolism in mice

Effects of core size and PEG coating layer of iron oxide nanoparticles on the distribution and metabolism in mice

Magnetic Nanoparticles: From Design and Synthesis to Real World Applications

Dense and Dynamic Polyethylene Glycol Shells Cloak Nanoparticles from Uptake by Liver Endothelial Cells for Long Blood Circulation

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