Literature DB >> 12028637

Is intracellular hyperthermia superior to extracellular hyperthermia in the thermal sense?

Y Rabin1.   

Abstract

More than 20 years ago, it was hypothesized that intracellular hyperthermia is superior to extracellular hyperthermia. It was further hypothesized that even a single biological cell containing magnetic nanoparticles can be treated for hyperthermia by an AC magnetic field, independent of its surrounding cells. Since experimental investigation of the thermal effects of intracellular hyperthermia is not feasible, these hypotheses have been studied theoretically. The current report shows that nano-scale heating effects are negligible. This study further shows that intracellular heat generation is sufficient to create the necessary conditions for hyperthermia only in a large group of cells loaded with nanoparticles, having an overall diameter of at least 1mm. It is argued in this report that there is no reason to believe that intracellular hyperthermia is superior to extracellular hyperthermia in the thermal sense.

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Year:  2002        PMID: 12028637     DOI: 10.1080/02656730110116713

Source DB:  PubMed          Journal:  Int J Hyperthermia        ISSN: 0265-6736            Impact factor:   3.914


  32 in total

1.  Controlled cell death by magnetic hyperthermia: effects of exposure time, field amplitude, and nanoparticle concentration.

Authors:  L Asín; M R Ibarra; A Tres; G F Goya
Journal:  Pharm Res       Date:  2012-02-24       Impact factor: 4.200

2.  FEM numerical model study of heating in magnetic nanoparticles.

Authors:  John A Pearce; Jason R Cook; P Jack Hoopes; Andrew Giustini
Journal:  Proc SPIE Int Soc Opt Eng       Date:  2011-02-22

Review 3.  Cancer therapy with iron oxide nanoparticles: Agents of thermal and immune therapies.

Authors:  Frederik Soetaert; Preethi Korangath; David Serantes; Steven Fiering; Robert Ivkov
Journal:  Adv Drug Deliv Rev       Date:  2020-06-27       Impact factor: 15.470

4.  Spatiotemporal temperature distribution and cancer cell death in response to extracellular hyperthermia induced by gold nanorods.

Authors:  Huang-Chiao Huang; Kaushal Rege; Jeffrey J Heys
Journal:  ACS Nano       Date:  2010-05-25       Impact factor: 15.881

5.  Peptide conjugated magnetic nanoparticles for magnetically mediated energy delivery to lung cancer cells.

Authors:  Anastasia K Hauser; Kimberly W Anderson; J Zach Hilt
Journal:  Nanomedicine (Lond)       Date:  2016-07-07       Impact factor: 5.307

6.  Nanoscale thermal phenomena in the vicinity of magnetic nanoparticles in alternating magnetic fields.

Authors:  Andreina Chiu-Lam; Carlos Rinaldi
Journal:  Adv Funct Mater       Date:  2016-03-31       Impact factor: 18.808

7.  Local heating of discrete droplets using magnetic porous silicon-based photonic crystals.

Authors:  Ji-Ho Park; Austin M Derfus; Ester Segal; Kenneth S Vecchio; Sangeeta N Bhatia; Michael J Sailor
Journal:  J Am Chem Soc       Date:  2006-06-21       Impact factor: 15.419

8.  Numerical Model Study of In Vivo Magnetic Nanoparticle Tumor Heating.

Authors:  John A Pearce; Alicia A Petryk; P Jack Hoopes
Journal:  IEEE Trans Biomed Eng       Date:  2017-03-01       Impact factor: 4.538

9.  Comparison of magnetic nanoparticle and microwave hyperthermia cancer treatment methodology and treatment effect in a rodent breast cancer model.

Authors:  Alicia A Petryk; Andrew J Giustini; Rachel E Gottesman; B Stuart Trembly; P Jack Hoopes
Journal:  Int J Hyperthermia       Date:  2013-12       Impact factor: 3.914

10.  Physical limits to magnetogenetics.

Authors:  Markus Meister
Journal:  Elife       Date:  2016-08-16       Impact factor: 8.140
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