Harmonic phase angles used for nanoparticle sensing

Shi, Yipeng; Khurshid, Hafsa; Ness, Dylan B; Weaver, John B.

doi:10.1088/1361-6560/aa8a4a

Cited by 8 publications

(15 citation statements)

References 31 publications

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“…Without losing generality, the functional form of the magnetization,

M

, from a magnetic fluid of MNPs in a sinusoidal applied field has been described as

\frac{M}{M_{s}} = f (n, ω τ, \frac{M_{s} V_{c} H}{kT})

where

H

is the amplitude of the applied magnetic field,

ω

is its frequency, n is the number of mNPs, V h is the hydrodynamic volume,

V_{c}

is core volume,

M_{s}

is the saturation magnetization,

T

is the temperature of the microenvironment,

k

is Boltzmann's constant, and

τ

is the relaxation time. The relaxation time here refers to the generalized relaxation time which may include the effects like Brownian relaxation, Neel relaxation, and the interactions between particles.…”

Section: Methodsmentioning

confidence: 99%

“…To quantify changes in either the temperature or the relaxation time, scaling methods are used . The MNP magnetization and its harmonics are functions of the products of variables.…”

Section: Introductionmentioning

confidence: 99%

“…The products lead to uncertainty relationships between pairs of variables that allow changes in an observed variable to be exactly compensated for by a change in the complimentary variable. The functional relationships are quite general and do not depend on a model of the magnetization . For example, the magnetization is a function of the ratio of the amplitude of the applied magnetic field over the temperature so a change in temperature can be compensated by an opposite scaling of the applied field amplitude to produce identical MNP dynamics.…”

Section: Introductionmentioning

confidence: 99%

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Concurrent quantification of magnetic nanoparticles temperature and relaxation time

Shi

Weaver

2019

Medical Physics

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Purpose The harmonic spectrum of the magnetization of magnetic nanoparticles (MNPs) in the presence of an applied magnetic field can be used to characterize the properties of the microenvironment of the MNPs. The change in temperature and relaxation time has been measured by varying the magnetic field amplitudes or frequency to obtain the harmonic spectrum. However, scaling estimates of temperature or relaxation time are poor if both change simultaneously. In this work, we show that scaling over both the amplitude and frequency of the applied magnetic field allows both the temperature and relaxation to be estimated simultaneously. Methods The scaling methods previously used to measure temperature and relaxation times individually have been expanded to two dimensions allowing both parameters to be estimated simultaneously. Samples with different temperature and relaxation times were measured using a magnetic nanoparticle spectrometer to verify this two‐dimensional scaling method. Simulations were also carried out for a range of nanoparticle sizes, and the best particle sizes were estimated for this two‐dimensional method. Results The two‐dimensional scaling method achieved a mean error of 0.83% for relaxation time by considering the temperature variation as well as relaxation time changes. The temperature and viscosity of the MNPs were measured simultaneously with the mean error of 1.03°C and 0.011 mPas. For monodisperse particles with Brownian relaxation, simulation showed that core radius of 16 nm and hydrodynamic radius of 23 nm had best accuracy for the scaling method. Conclusions The two‐dimensional scaling method allows both temperature and relaxation time to be estimated simultaneously. The measurement accuracy can be improved by combining information in ratios and phases of the magnetic harmonics of the magnetization and by choosing the optimal particle sizes.

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“…Without losing generality, the functional form of the magnetization,

M

, from a magnetic fluid of MNPs in a sinusoidal applied field has been described as

\frac{M}{M_{s}} = f (n, ω τ, \frac{M_{s} V_{c} H}{kT})

where

H

is the amplitude of the applied magnetic field,

ω

is its frequency, n is the number of mNPs, V h is the hydrodynamic volume,

V_{c}

is core volume,

M_{s}

is the saturation magnetization,

T

is the temperature of the microenvironment,

k

is Boltzmann's constant, and

τ

Section: Methodsmentioning

confidence: 99%

“…To quantify changes in either the temperature or the relaxation time, scaling methods are used . The MNP magnetization and its harmonics are functions of the products of variables.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Concurrent quantification of magnetic nanoparticles temperature and relaxation time

Shi

Weaver

2019

Medical Physics

Self Cite

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“…The relaxation time can be measured quantitatively from the MSB spectra at frequencies ω m ,

M (ω_{m} τ),

using scaling methods because the magnetization is a function of the unitless variable ωτ . The MSB spectra of the MNPs before binding were used as the reference with the reference relaxation time τ f .…”

Section: Methodsmentioning

confidence: 99%

“…Previous efforts have also used magnetic particle spectroscopy (MPS) to characterize blood clot lysis using MNP hyperthermia and to quantify the amount of iron on the clot Recently, magnetic spectroscopy of MNP Brownian rotation (MSB) has been shown to be a useful tool for the detection and characterization of blood clots and hence it has the potential to characterize thrombus to treat DVT more effectively and reduce the risks . MSB is a form of magnetic particle spectroscopy sensitive to Brownian rotation of MNPs, which allows for quantization of binding and temperature effects . For i n vivo applications, to detect and quantitatively characterize blood clot stiffness, age, and the number of MNPs in the microenvironment of the thrombus.…”

Section: Introductionmentioning

confidence: 99%