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Journal articles on the topic 'Biomagnetic'

Author: Grafiati
Published: 1 April 2023

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1

Embi, Abraham A. "THE HUMAN HAIR FOLLICLE PULSATING BIOMAGNETIC FIELD REACH AS POSSIBLE ADDITIONAL FACTOR IN MIGRAINE HEADACHES A BIOPHYSICS BASED HYPOTHESIS." International Journal of Research -GRANTHAALAYAH 8, no. 5 (June 8, 2020): 221–29. http://dx.doi.org/10.29121/granthaalayah.v8.i5.2020.179.

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This manuscript introduces a hypothesis linking the intrinsic pulsating nature of the biomagnetic fields reach found in the human hair follicle as factor in the etiology of migraine headaches. In the last two decades, researchers have emphasized the efficiency of external pulsed electromagnetic fields in the treatment of migraine headaches. Clinical trials have also demonstrated that external pulsed electromagnetic fields may prevent or decrease the migraine attacks. A hypothesis is presented linking the inherent hair follicle pulsed bioelectomagnetism as a factor in the etiology of migraines. Does the internal pulsed biomagnetic field reach of the hair follicles factor in the genesis of migraine headaches? Supporting the hypothesis are published papers confirming the inherent biomagnetism of the human hair follicle. The introduction of a novel optical microscopy technique using a special Prussian Blue Stain (PBS) mixed with fine iron particles has produced numerous papers confirming the inherent biomagnetism of the human hair. This manuscript expands on those findings by introducing documentation of the hair follicle pulsating biomagnetic field reach. This is demonstrated by using diamagnetic as well as paramagnetic preparations mixed with iron particles. Still microphotographs and video-recordings are presented.
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2

Swithenby, S. J. "Biomagnetism and the biomagnetic inverse problem." Physics in Medicine and Biology 32, no. 1 (January 1, 1987): 3–4. http://dx.doi.org/10.1088/0031-9155/32/1/002.

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3

A., Abraham. "BIOMAGNETISM AS FACTOR IN RED BLOOD CELLS DEFORMATION." International Journal of Research -GRANTHAALAYAH 6, no. 12 (December 31, 2018): 46–57. http://dx.doi.org/10.29121/granthaalayah.v6.i12.2018.1245.

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The purpose of this manuscript is to report in vitro experiments showing the role of pulsed biomagnetic fields tissues cross-talk between Red Blood Cells (RBCs) and human hairs. Both tissues have been reported to express magnetic properties, ie: RBCs diamagnetic and paramagnetic forces and the hair follicle pulsed diamagnetic forces. This biomagnetic cross-talk is reported as a novel factor in RBCs deformation. In the in vitro experimental model herein used, other forces such as keratin biomagnetism, hydrophilic and hydrophobic properties of the hair shaft may also play a role in the deformation. Presently teardrop red blood cells found in blood smears; and oriented in the same direction are attributed to mechanical artifacts introduced during slide preparations. The data presented in this manuscript supports the new principle of biomagnetic cross talk forces as factor in replicating RBCs deformities.as described in Optical Tweezers Trapping.
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4

Embi Bs, Abraham A. "BIOMAGNETISM AS FACTOR IN RED BLOOD CELLS DEFORMATION." International Journal of Research -GRANTHAALAYAH 6, no. 12 (December 31, 2018): 46–57. http://dx.doi.org/10.29121/granthaalayah.v7.i1.2019.1076.

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The purpose of this manuscript is to report in vitro experiments showing the role of pulsed biomagnetic fields tissues cross-talk between Red Blood Cells (RBCs) and human hairs. Both tissues have been reported to express magnetic properties, ie: RBCs diamagnetic and paramagnetic forces and the hair follicle pulsed diamagnetic forces. This biomagnetic cross-talk is reported as a novel factor in RBCs deformation. In the in vitro experimental model herein used, other forces such as keratin biomagnetism, hydrophilic and hydrophobic properties of the hair shaft may also play a role in the deformation. Presently teardrop red blood cells found in blood smears; and oriented in the same direction are attributed to mechanical artifacts introduced during slide preparations. The data presented in this manuscript supports the new principle of biomagnetic cross talk forces as factor in replicating RBCs deformities.as described in Optical Tweezers Trapping.
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5

Embi, Abraham A. "DEMONSTRATION OF THE HUMAN HAIR FOLLICLE MAGNETORECEPTION OF BIOMAGNETISM RADIATED BY THE CONCAVE PART OF THE HUMAN HAND." International Journal of Research -GRANTHAALAYAH 8, no. 5 (June 12, 2020): 348–54. http://dx.doi.org/10.29121/granthaalayah.v8.i5.2020.291.

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Biological material has been documented to produce an external magnetic field that radiates out. There have been several papers documenting the magnetic fields produced by steady currents in the body. The most notable was published in 1980 by Cohen et al. where the human hair follicle was used as sentinel and biophysically evaluated via sophisticated equipment such as a double planar Superconducting Quantum Interference Devices (SQUID). Most recently, in 2019 Cohen’s work was duplicated by Khan,S by also using double-planar gladiometers. Of interest to this manuscript is that since the introduction of anovel optical microscopy method in 2016 by Scherlag BJ et al is that numerous papers have been introduced in the literature now identifying intrinsic biomagnetic properties of the follicle such as penetration through glass barriers. In this manuscript, a concept of biomagnetic fields by the concave part of the human hand transferring energy to hair follicles is introduced, this was accomplished by using a novel optical microscopy method, in other words, the hair follicle is not limited to radiate out biomagnetism; but also, to receive externally radiated biomagnetic fields from a body part. This magneto receptive property is herein introduced.
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6

Rechnitz, Garry A., and Christopher W. Babb. "Biomagnetic neurosensors." Current Opinion in Biotechnology 7, no. 1 (February 1996): 55–59. http://dx.doi.org/10.1016/s0958-1669(96)80095-4.

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7

Leech, Donal, and Garry A. Rechnitz. "Biomagnetic neurosensors." Analytical Chemistry 65, no. 22 (November 15, 1993): 3262–66. http://dx.doi.org/10.1021/ac00070a016.

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8

Yamada, Shokei, and Christopher C. Gallen. "Biomagnetic Technologies." Neurosurgery 33, no. 1 (July 1993): 166–68. http://dx.doi.org/10.1227/00006123-199307000-00031.

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9

Yamada, Shokei, and Christopher C. Gallen. "Biomagnetic Technologies." Neurosurgery 33, no. 1 (July 1, 1993): 166–68. http://dx.doi.org/10.1097/00006123-199307000-00031.

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10

川勝, 真喜, 宏一郎 小林, 義則 内川, and M. Kotani. "Measurement System for Biomagnetic Fields(Special Issue : Research of Biomagnetism)." JAPANES JOURNAL OF MEDICAL INSTRUMENTATION 69, no. 5 (May 1, 1999): 240–45. http://dx.doi.org/10.4286/ikakikaigaku.69.5_240.

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11

A., Abraham. "THE HUMAN HAIR FOLLICLE PULSATING BIOMAGNETIC FIELD REACH AS MEASURED BY CRYSTALS ACCRETION." International Journal of Research -GRANTHAALAYAH 6, no. 7 (July 31, 2018): 290–99. http://dx.doi.org/10.29121/granthaalayah.v6.i7.2018.1309.

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This manuscript introduces the biomagnetic fields reach (BMFs) of the human hair follicles. The introduction of a novel table top optical microscopy technique using a special Prussian Blue Stain solution (PBS) mixed with fine iron particles has produced numerous papers confirming the inherent biomagnetism of the human hair. This technique allowed for the design of sets of incremental stacked glass slides for the purpose of measuring the human hair follicle BMFs reach out. This was demonstrated (measured) by using diamagnetic as well as paramagnetic Potassium Ferrocyanide preparations mixed with fine iron particles. Still microphotographs and video-recordings are presented.
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12

Xu, Ming, Changlin Han, Hui Min Lu, Junhao Xiao, Jingsheng Tang, and Zongtan Zhou. "The Design of the Biomagnetic Field Sensor without Magnetic Shielding." International Journal of Humanoid Robotics 16, no. 04 (August 2019): 1950019. http://dx.doi.org/10.1142/s0219843619500191.

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Due to the extremely weak intensity of the biomagnetic field and the serious interference from the environmental magnetic field, the detection of the biomagnetic field becomes such challenging work. After analyzing the deficiencies in the current biomagnetic field sensors, this paper proposes and realizes a high-sensitivity magnetic field sensor, based on the giant magneto-impedance (GMI) effect. Taking advantage of the miniaturized magnetic probe, the multistage multiple amplification and the multiband interference suppression, our sensor mainly makes three achievements: the pT level magnetic resolution, the ability to detect the muscle magnetic field without the magnetic shielding and the resistibility to a small-range wobbling in the state of working, which makes it possible to detect the biomagnetic field by wearable sensors under natural conditions.
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13

Owen, Valerie M. "USA — Biomagnetic neurosensors." Biosensors and Bioelectronics 11, no. 9 (January 1996): vii. http://dx.doi.org/10.1016/0956-5663(96)89449-8.

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14

Babb, Christopher W., David R. Coon, and Garry A. Rechnitz. "Biomagnetic Neurosensors. 3. Noninvasive Sensors Using Magnetic Stimulation and Biomagnetic Detection." Analytical Chemistry 67, no. 4 (February 1995): 763–69. http://dx.doi.org/10.1021/ac00100a012.

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15

Embi Bs, Abraham A. "HAIR AND BLOOD ENDOGENOUS LOW LEVEL BIOMAGNETIC FIELDS CROSS-TALK EFFECTS ON FIBRIN INHIBITION AND ROULEAU FORMATION." International Journal of Research -GRANTHAALAYAH 6, no. 11 (November 30, 2018): 200–208. http://dx.doi.org/10.29121/granthaalayah.v6.i11.2018.1118.

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This manuscript introduces a microscopic tabletop technique that demonstrates endogenous biomagnetic fields tissue crosstalk; namely the human hair and human blood. This interaction induces red blood cells (RBCs) agglutination and Rouleaux Formations. Man made exogenous static magnets as well as pulsating low-level magnetic fields have been applied to small animals and shown to affect blood parameters. Those experiments showed an increase in blood coagulation time attributed to the treatment. Ever since the development of a tabletop technique (introduced in 2016) numerous papers have demonstrated the intrinsic pulsating low-level biomagnetic fields emitted by the human hair shaft and follicle. Several published hypothesis involving body parts biomagnetic interactions have been published; they range from diseases such as cancer to the role of iron levels in blood biomagnetically interacting with arterial tissue and atherosclerosis.
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16

TSUKADA, Keiji. "Biomagnetic Measurement using SQUIDs." TEION KOGAKU (Journal of the Cryogenic Society of Japan) 38, no. 9 (2003): 461–68. http://dx.doi.org/10.2221/jcsj.38.461.

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17

Anninos, P. A., G. Anogianakis, K. Lehnertz, Ch Pantev, and M. Hoke. "Biomagnetic Measurements Using Squids." International Journal of Neuroscience 37, no. 3-4 (January 1987): 149–68. http://dx.doi.org/10.3109/00207458708987144.

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18

KOBAYASHI, Tetsuo. "Towards Biomagnetic Field Measurements." Journal of the Institute of Electrical Engineers of Japan 136, no. 1 (2016): 8–9. http://dx.doi.org/10.1541/ieejjournal.136.8.

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19

Trahms, Lutz, Frank Ludwig, and Dietmar Drung. "Biomagnetic instruments go portable." Physics World 10, no. 2 (February 1997): 16. http://dx.doi.org/10.1088/2058-7058/10/2/17.

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20

Herman, Christine. "Biomagnetic Separation Attracting Users." Genetic Engineering & Biotechnology News 32, no. 13 (July 2012): 22–24. http://dx.doi.org/10.1089/gen.32.13.12.

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21

Rudy, Yoram. "Bioelectric and Biomagnetic Imaging." Academic Radiology 2 (September 1995): S143—S144. http://dx.doi.org/10.1016/s1076-6332(12)80059-6.

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22

Saotome, Hideo, Kazuyasu Kitsuta, Seiji Hayano, and Yoshifuru Saito. "Inverse Problems in Biomagnetic Fields." IEEJ Transactions on Fundamentals and Materials 112, no. 4 (1992): 279–86. http://dx.doi.org/10.1541/ieejfms1990.112.4_279.

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23

Moshage, W., S. Achenbach, K. Göhl, A. Weikl, K. Bachmann, P. Wegener, S. Schneider, and W. Härer. "Biomagnetic localization of ventricular arrhythmias." Radiology 180, no. 3 (September 1991): 685–92. http://dx.doi.org/10.1148/radiology.180.3.1714612.

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24

Hoenig, H. E. "Squid arrays for biomagnetic diagnosis." Physica Scripta T35 (January 1, 1991): 177–78. http://dx.doi.org/10.1088/0031-8949/1991/t35/038.

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25

Paulson, D. N., R. L. Fagaly, R. M. Toussaint, and R. Fischer. "Biomagnetic susceptometer with SQUID instrumentation." IEEE Transactions on Magnetics 27, no. 2 (March 1991): 3249–52. http://dx.doi.org/10.1109/20.133904.

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26

Pizzella, Vittorio, Stefania Della Penna, Cosimo Del Gratta, and Gian Luca Romani. "SQUID systems for biomagnetic imaging." Superconductor Science and Technology 14, no. 7 (June 22, 2001): R79—R114. http://dx.doi.org/10.1088/0953-2048/14/7/201.

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27

Matsunaga, Tadashi, and Haruko Takeyama. "Biomagnetic nanoparticle formation and application." Supramolecular Science 5, no. 3-4 (July 1998): 391–94. http://dx.doi.org/10.1016/s0968-5677(98)00037-6.

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28

Anastasiadis, P., Ph Anninos, and E. Sivridis. "Biomagnetic activity in breast lesions." Breast 3, no. 3 (September 1994): 177–80. http://dx.doi.org/10.1016/0960-9776(94)90072-8.

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29

Bradshaw, L. A., A. Myers, W. O. Richards, W. Drake, and J. P. Wikswo. "Vector projection of biomagnetic fields." Medical & Biological Engineering & Computing 43, no. 1 (February 2005): 85–93. http://dx.doi.org/10.1007/bf02345127.

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30

Spathopoulos, J., G. Galazios, V. Liberis, and P. Anastasiadis. "Biomagnetic findings in breast lesions." International Journal of Gynecology & Obstetrics 70 (2000): E16. http://dx.doi.org/10.1016/s0020-7292(00)82372-3.

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31

Schneider, S., K. Abraham-Fuchs, H. Seifert, and H. E. Hoenig. "Current trends in biomagnetic instrumentation." Applied Superconductivity 1, no. 10-12 (October 1993): 1791–812. http://dx.doi.org/10.1016/0964-1807(93)90329-z.

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32

Nenonen, Jukka, and Toivo Katila. "Mathematical modelling for biomagnetic localization." International Journal of Cardiac Imaging 7, no. 3-4 (September 1991): 177–84. http://dx.doi.org/10.1007/bf01797750.

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33

Katila, Toivo, Matti Leiniö, Juha Montonen, and Juku Nenonen. "Sensitivity Limits in Biomagnetic Measurements." Acta Oto-Laryngologica 111, sup491 (January 1991): 36–42. http://dx.doi.org/10.3109/00016489109136779.

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34

Watson, J., and D. Ellwood. "Biomagnetic separation and extraction process." IEEE Transactions on Magnetics 23, no. 5 (September 1987): 3751–52. http://dx.doi.org/10.1109/tmag.1987.1065215.

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35

Nenonen, Jukka, Juha Montonen, and Toiro Katila. "Thermal noise in biomagnetic measurements." Review of Scientific Instruments 67, no. 6 (June 1996): 2397–405. http://dx.doi.org/10.1063/1.1147514.

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36

Fenici, R. R., and G. Melillo. "Biomagnetic study of cardiac arrhythmias." Clinical Physics and Physiological Measurement 12, A (January 1, 1991): 5–10. http://dx.doi.org/10.1088/0143-0815/12/a/001.

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37

Della Penna, S., C. Delgratta, C. Granata, A. Pasquarelli, V. Pizzella, R. Rossi, M. Russo, K. Torquatiand, and S. N. Erné. "Biomagnetic systems for clinical use." Philosophical Magazine B 80, no. 5 (May 2000): 937–48. http://dx.doi.org/10.1080/01418630008221960.

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38

Della Penna, C. Del Gratta, C. Gran, S. "Biomagnetic systems for clinical use." Philosophical Magazine B 80, no. 5 (May 1, 2000): 937–48. http://dx.doi.org/10.1080/014186300254899.

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39

Ishak, B. "Biomagnetics: principles and applications of biomagnetic stimulation and imaging, edited by Shoogo Ueno and Masaki Sekino." Contemporary Physics 58, no. 2 (February 17, 2017): 200–201. http://dx.doi.org/10.1080/00107514.2017.1291730.

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40

Primin, Mykhailo, and Igor Nedayvoda. "Magnetometric Investigations of Biomagnetic Signals: Magnetocardiography." Cybernetics and Computer Technologies, no. 1 (June 30, 2022): 28–41. http://dx.doi.org/10.34229/2707-451x.22.1.4.

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Introduction. Superconducting magnetometers based on SQUIDs (SQUID- Superconducting QUantum Interference Device) are currently used to register weak magnetic fields generated in various human organs and measured outside the body (in the environment). The creation of information technology, which is a set of methods and software tools combined into a technological chain that ensures registration, storage, pre-processing, analysis of measurement data and automatic diagnostic output, is an essential science-intensive component that determines the possibilities and success of the applied use of non-contact diagnostic systems of the human heart The purpose. Article presents new algorithms for spatial analysis of cardiomagnetic signal measurement results. The algorithms are based on the inverse problem solution, when the magnetic field source is matched to the spatial distribution of the magnetic signal and the parameters and spatial configuration of the source are determined. A model of the cardiomagnetic source was used in the form of a system of current density vectors, which are distributed in a plane that is parallel to the measurement plane and crosses the volume of the heart. Results. The inverse problem is solved using the apparatus of two-dimensional integral Fourier transformations. The data transformation algorithm allows to correctly take into account the design of the magnetic flux transformer (the dimensions of the pickup coils, their spatial location and the electrical connection scheme). Algorithm modifications have been developed for most of the known (implemented in existing magnetocardiographs) designs of magnetic flux transformers of the first and second order gradientometers. The operation of the algorithm is modeled on real data of magnetometric investigations of the human heart. Investigations have shown that the application of the proposed algorithms allows obtaining new information about the spatial configuration of the magnetic signal source in the human heart, which can be used in the future for the diagnosis of human heart diseases. Keywords: magnetocardiography, inverse problem of magnetostatics, Fourier transform, SQUID gradientometer.
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41

Matsuura, Kanta, and Yoichi Okabe. "Reconstruction of Sparse Biomagnetic-Source Distribution." IEEJ Transactions on Electronics, Information and Systems 116, no. 2 (1996): 223–29. http://dx.doi.org/10.1541/ieejeiss1987.116.2_223.

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42

Kazami, Kunio, Jun Kawai, Gen Uehara, and Hisashi Kado. "Series SQUID Array for Biomagnetic Measurement." IEEJ Transactions on Electronics, Information and Systems 116, no. 2 (1996): 252–58. http://dx.doi.org/10.1541/ieejeiss1987.116.2_252.

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43

ISHIKAWA, Noboru, Kenichi HARAKAWA, and Hisashi KADO. "Magnetically Shielded Room for Biomagnetic Measurement." TEION KOGAKU (Journal of Cryogenics and Superconductivity Society of Japan) 28, no. 5 (1993): 237–43. http://dx.doi.org/10.2221/jcsj.28.237.

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44

David, B., D. Grundler, S. Krey, V. Doormann, R. Eckart, J. P. Krumme, G. Rabe, and O. Doessel. "High- SQUID magnetometers for biomagnetic measurements." Superconductor Science and Technology 9, no. 4A (April 1, 1996): A96—A99. http://dx.doi.org/10.1088/0953-2048/9/4a/025.

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45

Alvarez, R. E. "Biomagnetic Fourier imaging (current density reconstruction)." IEEE Transactions on Medical Imaging 9, no. 3 (1990): 299–304. http://dx.doi.org/10.1109/42.57767.

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46

Bommel, F. R., R. Rockelein, and L. Urankar. "Boundary element solution of biomagnetic problems." IEEE Transactions on Magnetics 29, no. 2 (March 1993): 1395–98. http://dx.doi.org/10.1109/20.250663.

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47

Matsunaga, T., N. Tsujimura, and S. Kamiya. "Genetic Analysis of Biomagnetic Crystal Formation." Le Journal de Physique IV 07, no. C1 (March 1997): C1–651—C1–654. http://dx.doi.org/10.1051/jp4:19971268.

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48

Kirschvink, Joseph L. "Radio waves zap the biomagnetic compass." Nature 509, no. 7500 (May 7, 2014): 296–97. http://dx.doi.org/10.1038/nature13334.

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49

NENONEN, JUKKA, and TOIVO KATILA. "Noninvasive Functional Localization by Biomagnetic Methods." Journal of Clinical Engineering 16, no. 5 (September 1991): 423–34. http://dx.doi.org/10.1097/00004669-199109000-00014.

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50

Flynn, E. R., and H. C. Bryant. "A biomagnetic system forin vivocancer imaging." Physics in Medicine and Biology 50, no. 6 (March 3, 2005): 1273–93. http://dx.doi.org/10.1088/0031-9155/50/6/016.

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