Mechanisms of Gadographene-Mediated Proton Spin Relaxation

Hung, Andy H.; Duch, Matthew C.; Parigi, Giacomo; Rotz, Matthew W.; Manus, Lisa M.; Mastarone, Daniel J.; Dam, Kevin T.; Gits, Colton C.; MacRenaris, Keith W.; Luchinat, Claudio; Hersam, Mark C.; Meade, Thomas J.

doi:10.1021/jp406909b

Cited by 25 publications

(44 citation statements)

References 93 publications

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“…54–56 The analysis of relaxivity profiles provides a means of extracting valuable mechanistic information, including dynamic parameters such as τ r and τ m . 31,57–59 …”

Section: Resultsmentioning

confidence: 99%

High Relaxivity Gd(III)–DNA Gold Nanostars: Investigation of Shape Effects on Proton Relaxation

Rotz¹,

Culver²,

et al. 2015

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Gadolinium(III) nanoconjugate contrast agents (CAs) have distinct advantages over their small-molecule counterparts in magnetic resonance imaging. In addition to increased Gd(III) payload, a significant improvement in proton relaxation efficiency, or relaxivity (r1), is often observed. In this work, we describe the synthesis and characterization of a nanoconjugate CA created by covalent attachment of Gd(III) to thiolated DNA (Gd(III)–DNA), followed by surface conjugation onto gold nanostars (DNA–Gd@stars). These conjugates exhibit remarkable r1 with values up to 98 mM−1 s−1. Additionally, DNA–Gd@stars show efficient Gd(III) delivery and biocompatibility in vitro and generate significant contrast enhancement when imaged at 7 T. Using nuclear magnetic relaxation dispersion analysis, we attribute the high performance of the DNA–Gd@stars to an increased contribution of second-sphere relaxivity compared to that of spherical CA equivalents (DNA–Gd@spheres). Importantly, the surface of the gold nanostar contains Gd(III)–DNA in regions of positive, negative, and neutral curvature. We hypothesize that the proton relaxation enhancement observed results from the presence of a unique hydrophilic environment produced by Gd(III)–DNA in these regions, which allows second-sphere water molecules to remain adjacent to Gd(III) ions for up to 10 times longer than diffusion. These results establish that particle shape and second-sphere relaxivity are important considerations in the design of Gd(III) nanoconjugate CAs.

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“…54–56 The analysis of relaxivity profiles provides a means of extracting valuable mechanistic information, including dynamic parameters such as τ r and τ m . 31,57–59 …”

Section: Resultsmentioning

confidence: 99%

High Relaxivity Gd(III)–DNA Gold Nanostars: Investigation of Shape Effects on Proton Relaxation

Rotz¹,

Culver²,

et al. 2015

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“…24–27 It is of interest that BSA-coated graphene poses the same hazard potential as one-dimensional SWCNTs, in spite of the differences in shape, size, aspect ratio, and metal content. 5,17 Although we lack a clear understanding of the earliest mechanism of biological injury by graphene, this report demonstrates that the graphene surface, similar to SWCNTs and MWCNTs, is capable of triggering lysosomal injury and participating in a final common AOP that culminates in pulmonary fibrosis.…”

Section: Discussionmentioning

confidence: 99%

Use of a Pro-Fibrogenic Mechanism-Based Predictive Toxicological Approach for Tiered Testing and Decision Analysis of Carbonaceous Nanomaterials

et al. 2015

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Engineered carbonaceous nanomaterials (ECNs), including single-wall carbon nanotubes (SWCNTs), multi-wall carbon nanotubes (MWCNTs), graphene and graphene oxide (GO), are potentially hazardous to the lung. With incremental experience in the use of predictive toxicological approaches, seeking to relate ECN physicochemical properties to adverse outcome pathways (AOPs), it is logical to explore the existence of a common AOP that allows comparative analysis of broad ECN categories. We established an ECN library comprised of three different types of SWCNTs, graphene and graphene oxide (two sizes) for comparative analysis according to a cell-based AOP that also plays a role in the pathogenesis of pulmonary fibrosis. SWCNTs synthesized by Hipco, arc discharge and Co-Mo catalyst (CoMoCAT®) methods were obtained in their as-prepared (AP) state, following which they were further purified (PD) or coated with Pluronic (PF108) or bovine serum albumin (BSA) to improve dispersal and colloidal stability. Graphene oxide (GO) was prepared as two sizes, GO-small (S) and GO-large (L), while the graphene samples were coated with BSA and PF108 to enable dispersion in aqueous solution. In vitro screening showed that AP- and PD-SWCNTs, irrespective of the method of synthesis, as well as graphene (BSA) and GO (S and L) could trigger interleukin 1β (IL-1β) and transforming growth factor (TGF-β1) production in myeloid (THP-1) and epithelial (BEAS-2B) cell lines, respectively. Oropharyngeal aspiration in mice confirmed that AP-Hipco tubes, graphene (BSA), GO-S and GO-L could induce IL-1β and TGF-β1 production in the lung in parallel with lung fibrosis. Notably, GO-L was the most pro-fibrogenic material based on rapid kinetics of pulmonary injury. In contrast, PF108-dispersed SWCNTs and -graphene failed to exert fibrogenic effects. Collectively, these data indicate that the dispersal state and surface reactivity of ECNs play key roles in triggering a pro-fibrogenic AOP, which could prove helpful for hazard ranking and a proposed tiered testing approach for large ECN categories.

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“…11,12 In particular, ultra-short single-walled carbon nanotubes (US-tubes) and graphene-based MRI CAs have been shown to dramatically increase the efficacy of Gd 3+ ions in reducing the relaxation time of excited proton nuclear spins, resulting in better image contrast. [13][14][15] Gd 3+ -ion-containing US-tubes (Gadonanotubes or GNTs) and related materials are especially promising MRI CA candidates due to their high relaxivity and ability to traverse the cellular membrane. 4 This ability to function as an intracellular label leads to many potential imaging applications which are not possible with conventional macrocyclic gadolinium chelates which are limited to the vasculature.…”

Section: Introductionmentioning

confidence: 99%

Surfactant-free Gd³⁺-ion-containing carbon nanotube MRI contrast agents for stem cell labeling

et al. 2015

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There is an ever increasing interest in developing new stem cell therapies. However, imaging and tracking stem cells in vivo after transplantation remains a serious challenge. In this work, we report new, functionalized and high-performance Gd(3+)-ion-containing ultra-short carbon nanotube (US-tube) MRI contrast agent (CA) materials which are highly-water-dispersible (ca. 35 mg ml(-1)) without the need of a surfactant. The new materials have extremely high T1-weighted relaxivities of 90 (mM s)(-1) per Gd(3+) ion at 1.5 T at room temperature and have been used to safely label porcine bone-marrow-derived mesenchymal stem cells for MR imaging. The labeled cells display excellent image contrast in phantom imaging experiments, and TEM images of the labeled cells, in general, reveal small clusters of the CA material located within the cytoplasm with 10(9) Gd(3+) ions per cell.

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Mechanisms of Gadographene-Mediated Proton Spin Relaxation

Cited by 25 publications

References 93 publications

High Relaxivity Gd(III)–DNA Gold Nanostars: Investigation of Shape Effects on Proton Relaxation

High Relaxivity Gd(III)–DNA Gold Nanostars: Investigation of Shape Effects on Proton Relaxation

Use of a Pro-Fibrogenic Mechanism-Based Predictive Toxicological Approach for Tiered Testing and Decision Analysis of Carbonaceous Nanomaterials

Surfactant-free Gd³⁺-ion-containing carbon nanotube MRI contrast agents for stem cell labeling

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Mechanisms of Gadographene-Mediated Proton Spin Relaxation

Cited by 25 publications

References 93 publications

High Relaxivity Gd(III)–DNA Gold Nanostars: Investigation of Shape Effects on Proton Relaxation

High Relaxivity Gd(III)–DNA Gold Nanostars: Investigation of Shape Effects on Proton Relaxation

Use of a Pro-Fibrogenic Mechanism-Based Predictive Toxicological Approach for Tiered Testing and Decision Analysis of Carbonaceous Nanomaterials

Surfactant-free Gd3+-ion-containing carbon nanotube MRI contrast agents for stem cell labeling

Contact Info

Product

Resources

About

Surfactant-free Gd³⁺-ion-containing carbon nanotube MRI contrast agents for stem cell labeling