The anti-cancer effects of a static magnetic field

ZHANG Xin

doi:10.7693/wl20170701

PHYSICS > 2017 > 46(7): 409-415. > DOI: 10.7693/wl20170701

ZHANG Xin. The anti-cancer effects of a static magnetic field[J]. PHYSICS, 2017, 46(7): 409-415. DOI: 10.7693/wl20170701

Citation:

ZHANG Xin. The anti-cancer effects of a static magnetic field[J]. PHYSICS, 2017, 46(7): 409-415. DOI: 10.7693/wl20170701

Citation:

ZHANG Xin. The anti-cancer effects of a static magnetic field[J]. PHYSICS, 2017, 46(7): 409-415. DOI: 10.7693/wl20170701

PDF (2402 KB)

The anti-cancer effects of a static magnetic field

ZHANG Xin^†

High Magnetic Field Laboratory,Hefei Institutes of Physical Science,Chinese Academy of Sciences,Hefei 230031,China

More Information

Received Date: May 04, 2017
Published Date: July 11, 2017

Graphical Abstract

Abstract

Abstract

In recent years much progress has been made in studies of the effect of a static magnetic field (SMF) on cancer. This article presents current evidence (from the molecular, cellular,animal, and patient levels), as well as some possible mechanisms explaining the effects of SMF on cancer inhibition. Although using SMF in cancer treatment is still at a very preliminary experimental stage, its effectiveness and safety have shown great anti-cancer potential. Therefore, it is necessary to conduct systematic investigations into the relationship between SMF and tumours, and to carry out clinical trials that meet international standards, as well as to unravel the underlying molecular mechanisms.
- static magnetic field,
- cancer cell,
- epidermal growth factor receptor,
- microtubules,
- cell division,
- alternative treatment,
- combined therapy

FullText(HTML)

References (40)

References

[1]	Zhang X. Potential applications of static magnetic fields in cancer treatment. Book chatper in "Biological effects of static magnetic fields". Springer，2017. p.175
[2]	Zhang L et al. Oncotarget，2017，8(8)：13126
[3]	Brito D A，Rieder C L. Cell Motil. Cytoskeleton，2009，66(8)：437
[4]	Liu X，Lei M，Erikson R L. Mol. Cell. Biol.，2006，26(6)：2093
[5]	Tang Y et al. J. Biomol. Screen.，2013，18(9)：1062
[6]	Luo Y et al. Bioelectrochemistry，2016，109：31
[7]	Zhang L et al. Elife，2017，6：e28212
[8]	Jia C et al. Bioelectromagnetics，2007，28(3)：197
[9]	SunWet al. Cell. Physiol. Biochem.，2008，22(5-6)：507
[10]	SunWet al. Int. J. Radiat. Biol.，2013，89(5)：378
[11]	Zhang L et al. Oncotarget，2016，7(27)：41527
[12]	Strieth S et al. Cancer Biol. Ther.，2008，7(6)：814
[13]	Wang Z et al. Bioelectromagnetics，2009，30(6)：446
[14]	Strelczyk D et al. Cancer Biol. Ther.，2009，8(18)：1756
[15]	Gellrich D，Becker S，Strieth S. Cancer Lett.，2014，343(1)：107
[16]	ShortWO et al. Invest. Radiol.，1992，27(10)：836
[17]	Yang P F et al. IEEE Transactions on Magnetics，2009，45(5)：2136
[18]	Tang R J et al. Bioelectromagnetics，2016，37(2)：89
[19]	Nie Y Z et al. BMC Cancer，2013，13：582
[20]	Wang T T et al. Bioelectromagnetics，2011，32(6)：443
[21]	Nie Y Z et al. Plos One，2013，8(11)：e72411
[22]	Ghodbane S et al. Biomed. Res. Int.，2013，2013：602987
[23]	Zhang L et al. Science Bulletin，2015，60(24)：2120
[24]	Gray J R，Frith C H，Parker J D. Bioelectromagnetics，2000，21(8)：575
[25]	Hao Q et al. Bioelectromagnetics，2011，32(3)：191
[26]	Sun R G et al. Gen. Physiol. Biophys.，2012，31(1)：1
[27]	Sabo J et al. Bioelectrochemistry，2002，56(1-2)：227
[28]	Ghibelli L et al. Apoptosis，2006，11(3)：359
[29]	Nakahara T et al. Radiology，2002，224(3)：817
[30]	Sarvestani A S et al. Micron.，2010，41(2)：101
[31]	Teodori L et al. J. Radiat. Res.，2014，55(2)：218
[32]	Politanski P et al. Bioelectromagnetics，2013，34(4)：333
[33]	Sun C T et al. Oncology Letters，2012，4(5)：1130
[34]	周万松.磁性材料及器件，2000，31(4)：32
[35]	Vallbona C，Hazlewood C F，Jurida G. Arch. Phys. Med. Rehabil.，1997，78(11)：1200
[36]	Salvatore J R，Harrington J，Kummet T. Bioelectromagnetics，2003，24(7)：524
[37]	Ronchetto F et al. Bioelectromagnetics，2004，25(8)：563
[38]	Elzinga G，Wong E T. Case Rep. Neurol.，2014，6(1)：109
[39]	Taillibert S，Le Rhun E，Chamberlain M C. Curr. Opin. Neurol.，2015，28(6)：659
[40]	Lok E，Swanson K D，Wong E T. Expert Rev. Med. Devices，2015，12(6)：717

[1]	CHEN Le-Tian, YUAN Hong, SUN Chang-Pu. Brownian motion theory and its application in the study of complex climate systems[J]. PHYSICS, 2022, 51(9): 588-601. DOI: 10.7693/wl20220901
[2]	LIN Yan-Luan. From radiative-convective equilibrium to global climate models——an introduction to the work of the 2021 Nobel laureate in Physics, Syukuro Manabe[J]. PHYSICS, 2022, 51(1): 16-23. DOI: 10.7693/wl20220103
[3]	HU Yong-Yun. The complex climate system and global warming[J]. PHYSICS, 2022, 51(1): 10-15. DOI: 10.7693/wl20220102
[4]	CHEN Xiao-Song, FAN Jing-Fang. Opportunities for complexity science: the Nobel Prize in Physics 2021[J]. PHYSICS, 2022, 51(1): 1-9. DOI: 10.7693/wl20220101
[5]	GAO Peng-Yue, LV Jian, WANG Yan-Chao, MA Yan-Ming. Structure prediction via intelligent global optimization algorithms[J]. PHYSICS, 2017, 46(9): 582-589. DOI: 10.7693/wl20170902
[6]	Double-strand DNA melted by laser micro-flow method[J]. PHYSICS, 2010, 39(06): 423-425.
[7]	Solution methods for preparing Graphene[J]. PHYSICS, 2009, 38(06): 387-394.
[8]	Physical problems in the global climate change[J]. PHYSICS, 2009, 38(02): 71-83.
[9]	An optimized design method for city-street-lamps collocations[J]. PHYSICS, 2007, 36(04): 330-333.
[10]	Multimedia applying in course of methods of mathematical physics[J]. PHYSICS, 2007, 36(02): 153-158.

Cited By

Cited by

Periodical cited type(2)

1.	程伟，罗勇，曹龙，丹利，黄磊，邓祥征. 二氧化碳移除技术研究进展与评述. 气候变化研究进展. 2023(05): 672-682 .
2.	陈乐天，袁红，孙昌璞. 布朗运动理论及其在复杂气候系统研究中的应用. 物理. 2022(09): 588-601 . 本站查看

Other cited types(0)

Get Citation

PDF

XML

Article views (177) PDF downloads (934) Cited by(2)

Turn off MathJax

Article Contents

Abstract

References

The anti-cancer effects of a static magnetic field

Abstract

References

Related Articles

Cited by

Periodical cited type(2)

Other cited types(0)

Catalog

The anti-cancer effects of a static magnetic field

Abstract

References

Related Articles

Cited by

Periodical cited type(2)

Other cited types(0)

Catalog

Export File

Citation

Format

Content