Imaging of Her2‐targeted magnetic nanoparticles for breast cancer detection: comparison of SQUID‐detected magnetic relaxometry and MRI

Adolphi, Natalie L.; Butler, Kimberly S.; Lovato, Debbie M.; Tessier, Trace E.; Trujillo, Jason E; Hathaway, Helen J.; Fegan, Danielle L.; Monson, Todd C.; Stevens, Tyler E.; Huber, Dale L.; Ramu, Jaivijay; Milne, Michelle L.; Altobelli, Stephen A.; Bryant, H. C.; Larson, Richard S.; Flynn, E.R.

doi:10.1002/cmmi.499

Cited by 90 publications

(57 citation statements)

References 38 publications

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“…This agrees with typical r 2 values of small iron oxide nanoparticles -in the order of 100 (mM s) −1 [6]. However, the difference between the r 2 of particles with and without BSA protein is too small to be applicable in biomedical applications.…”

Section: Resultssupporting

confidence: 85%

Effect of BSA Protein on the Contrast Properties of Magnetite Nanoparticles during MRI

et al. 2017

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The aim of the study was to establish whether there is a significant change in the MRI contrast of magnetite nanoparticles, after BSA protein binding on the surface of particles. The rationale is the applicability of this feature in clinical practice for the tracking of specific proteins which are often associated with various pathologies. Contrast agents could bind to this specific marker, with the change in MRI contrast indicating the presence of pathology. We found that changes in relative contrast acquired at low-field MRI offer potential for the differentiation of magnetite nanoparticles with and without BSA protein. However, the variations in the transverse relaxation time (T2) and transverse relaxivity (r2), acquired at high-field MRI, were too small to be applicable for biomedical applications.

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Section: Resultssupporting

confidence: 85%

Effect of BSA Protein on the Contrast Properties of Magnetite Nanoparticles during MRI

et al. 2017

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“…Previously, we showed that anti-Her2-conjugated NPs specifically bind cells expressing Her2 on the surface [11]. Furthermore, we demonstrated that the magnetic moment signal correlates to the levels of Her2 expressed at the cell surface [1]. To illustrate, Figure 5A shows the results of a 15-min incubation of anti-Her2-conjugated Ocean Nanotech SHP NPs with a series of breast cancer cell lines that express Her2 to varying degrees, with MCF7/Her218 having the highest expression, MDA-MB-231 having reduced expression and Chinese hamster ovary (CHO) cells as a negative control.…”

Section: Cell Incubationsmentioning

confidence: 75%

Magnetic relaxometry as applied to sensitive cancer detection and localization

Haro¹,

Karaulanov²,

Vreeland³

et al. 2015

Biomedical Engineering / Biomedizinische Technik

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Background: Here we describe superparamagnetic relaxometry (SPMR), a technology that utilizes highly sensitive magnetic sensors and superparamagnetic nanoparticles for cancer detection. Using SPMR, we sensitively and specifically detect nanoparticles conjugated to biomarkers for various types of cancer. SPMR offers high contrast in vivo, as there is no superparamagnetic background, and bones and tissue are transparent to the magnetic fields. Methods: In SPMR measurements, a brief magnetizing pulse is used to align superparamagnetic nanoparticles of a discrete size. Following the pulse, an array of superconducting quantum interference detectors (SQUID) sensors detect the decaying magnetization field. NP size is chosen so that, when bound, the induced field decays in seconds. They are functionalized with specific biomarkers and incubated with cancer cells in vitro to determine specificity and cell binding. For in vivo experiments, functionalized

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“…Herein, exchange coupling is neglected and long-range dipolar interaction is taken into consideration. 21,22 For an ensemble of randomly distributed NPs, this energy barrier is thus revised by the mean-field approximation: 23,24 …”

Section: Sarmentioning

confidence: 99%

Magnetic hyperthermia performance of magnetite nanoparticle assemblies under different driving fields

Wang

2017

AIP Advances

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The heating performance of magnetic nanoparticles (MNPs) under an alternating magnetic field (AMF) is dependent on several factors. Optimizing these factors improves the heating efficiency for cancer therapy and meanwhile lowers the MNP treatment dosage. AMF is one of the most easily controllable variables to enhance the efficiency of heat generation. This paper investigated the optimal magnetic field strength and frequency for an assembly of magnetite nanoparticles. For hyperthermia treatment in clinical applications, monodispersed NPs are forming nanoclusters in target regions where a strong magnetically interactive environment is anticipated, which leads to a completely different situation than MNPs in ferrofluids. Herein, the energy barrier model is revisited and Néel relaxation time is tailored for high MNP packing densities. AMF strength and frequency are customized for different magnetite NPs to achieve the highest power generation and the best hyperthermia performance.

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Imaging of Her2‐targeted magnetic nanoparticles for breast cancer detection: comparison of SQUID‐detected magnetic relaxometry and MRI

Cited by 90 publications

References 38 publications

Effect of BSA Protein on the Contrast Properties of Magnetite Nanoparticles during MRI

Effect of BSA Protein on the Contrast Properties of Magnetite Nanoparticles during MRI

Magnetic relaxometry as applied to sensitive cancer detection and localization

Magnetic hyperthermia performance of magnetite nanoparticle assemblies under different driving fields

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