Literature DB >> 19544801

Magnetic nanoparticle temperature estimation.

John B Weaver1, Adam M Rauwerdink, Eric W Hansen.   

Abstract

The authors present a method of measuring the temperature of magnetic nanoparticles that can be adapted to provide in vivo temperature maps. Many of the minimally invasive therapies that promise to reduce health care costs and improve patient outcomes heat tissue to very specific temperatures to be effective. Measurements are required because physiological cooling, primarily blood flow, makes the temperature difficult to predict a priori. The ratio of the fifth and third harmonics of the magnetization generated by magnetic nanoparticles in a sinusoidal field is used to generate a calibration curve and to subsequently estimate the temperature. The calibration curve is obtained by varying the amplitude of the sinusoidal field. The temperature can then be estimated from any subsequent measurement of the ratio. The accuracy was 0.3 degree K between 20 and 50 degrees C using the current apparatus and half-second measurements. The method is independent of nanoparticle concentration and nanoparticle size distribution.

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Mesh:

Year:  2009        PMID: 19544801      PMCID: PMC4109636          DOI: 10.1118/1.3106342

Source DB:  PubMed          Journal:  Med Phys        ISSN: 0094-2405            Impact factor:   4.071


  26 in total

Review 1.  Magnetic resonance temperature imaging for guidance of thermotherapy.

Authors:  B Quesson; J A de Zwart; C T Moonen
Journal:  J Magn Reson Imaging       Date:  2000-10       Impact factor: 4.813

2.  A simulation study on the resolution and sensitivity of magnetic particle imaging.

Authors:  J Weizenecker; J Borgert; B Gleich
Journal:  Phys Med Biol       Date:  2007-10-11       Impact factor: 3.609

3.  Experimental results on fast 2D-encoded magnetic particle imaging.

Authors:  B Gleich; J Weizenecker; J Borgert
Journal:  Phys Med Biol       Date:  2008-02-22       Impact factor: 3.609

4.  Liposomes and local hyperthermia: selective delivery of methotrexate to heated tumors.

Authors:  J N Weinstein; R L Magin; M B Yatvin; D S Zaharko
Journal:  Science       Date:  1979-04-13       Impact factor: 47.728

Review 5.  Minimally invasive techniques for the treatment of intervertebral disk herniation.

Authors:  Hallett H Mathews; Brenda H Long
Journal:  J Am Acad Orthop Surg       Date:  2002 Mar-Apr       Impact factor: 3.020

6.  Hyperthermia enables tumor-specific nanoparticle delivery: effect of particle size.

Authors:  G Kong; R D Braun; M W Dewhirst
Journal:  Cancer Res       Date:  2000-08-15       Impact factor: 12.701

7.  Nanoshell-mediated near-infrared thermal therapy of tumors under magnetic resonance guidance.

Authors:  L R Hirsch; R J Stafford; J A Bankson; S R Sershen; B Rivera; R E Price; J D Hazle; N J Halas; J L West
Journal:  Proc Natl Acad Sci U S A       Date:  2003-11-03       Impact factor: 11.205

8.  Magnetite nanoparticle-loaded anti-HER2 immunoliposomes for combination of antibody therapy with hyperthermia.

Authors:  Akira Ito; Yuko Kuga; Hiroyuki Honda; Hiroyuki Kikkawa; Atsushi Horiuchi; Yuji Watanabe; Takeshi Kobayashi
Journal:  Cancer Lett       Date:  2004-08-30       Impact factor: 8.679

9.  Photo-thermal tumor ablation in mice using near infrared-absorbing nanoparticles.

Authors:  D Patrick O'Neal; Leon R Hirsch; Naomi J Halas; J Donald Payne; Jennifer L West
Journal:  Cancer Lett       Date:  2004-06-25       Impact factor: 8.679

10.  Feasibility of MR-guided focused ultrasound with real-time temperature mapping and continuous sonication for ablation of VX2 carcinoma in rabbit thigh.

Authors:  Jean Palussière; Rares Salomir; Brigitte Le Bail; Rabia Fawaz; Bruno Quesson; Nicolas Grenier; Chrit T W Moonen
Journal:  Magn Reson Med       Date:  2003-01       Impact factor: 4.668
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  42 in total

1.  The use of magnetic nanoparticles in thermal therapy monitoring and screening: Localization and imaging (invited).

Authors:  John B Weaver
Journal:  J Appl Phys       Date:  2012-03-02       Impact factor: 2.546

2.  Harmonic phase angle as a concentration-independent measure of nanoparticle dynamics.

Authors:  Adam M Rauwerdink; John B Weaver
Journal:  Med Phys       Date:  2010-06       Impact factor: 4.071

3.  Measurement of magnetic nanoparticle relaxation time.

Authors:  John B Weaver; Esra Kuehlert
Journal:  Med Phys       Date:  2012-05       Impact factor: 4.071

4.  A Feasibility Study of Nonlinear Spectroscopic Measurement of Magnetic Nanoparticles Targeted to Cancer Cells.

Authors:  Bradley W Ficko; Christian NDong; Paolo Giacometti; Karl E Griswold; Solomon G Diamond
Journal:  IEEE Trans Biomed Eng       Date:  2016-06-23       Impact factor: 4.538

5.  Nanoparticle temperature estimation in combined ac and dc magnetic fields.

Authors:  Adam M Rauwerdink; Eric W Hansen; John B Weaver
Journal:  Phys Med Biol       Date:  2009-09-09       Impact factor: 3.609

6.  Concurrent quantification of multiple nanoparticle bound states.

Authors:  Adam M Rauwerdink; John B Weaver
Journal:  Med Phys       Date:  2011-03       Impact factor: 4.071

7.  Comparisons of characteristic timescales and approximate models for Brownian magnetic nanoparticle rotations.

Authors:  Daniel B Reeves; John B Weaver
Journal:  J Appl Phys       Date:  2015-06-19       Impact factor: 2.546

8.  Modeling the Brownian relaxation of nanoparticle ferrofluids: comparison with experiment.

Authors:  Michael A Martens; Robert J Deissler; Yong Wu; Lisa Bauer; Zhen Yao; Robert Brown; Mark Griswold
Journal:  Med Phys       Date:  2013-02       Impact factor: 4.071

9.  Simulations of magnetic nanoparticle Brownian motion.

Authors:  Daniel B Reeves; John B Weaver
Journal:  J Appl Phys       Date:  2012-12-20       Impact factor: 2.546

10.  Temperature of the magnetic nanoparticle microenvironment: estimation from relaxation times.

Authors:  I M Perreard; D B Reeves; X Zhang; E Kuehlert; E R Forauer; J B Weaver
Journal:  Phys Med Biol       Date:  2014-02-20       Impact factor: 3.609
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