Erratum: WITHDRAWN: SQUID-detected ultra-low field MRI (Journal of Magnetic Resonance (2013) 229 (127–141)(S1090780713000499)(10.1016/j.jmr.2013.02.009));SQUID-detected ultra-low field MRI

Journal of Magnetic Resonance

Volumn 229, Issue , 2013, Pages 127-141

  Espy, Michelle ^a   Matlashov, Andrei ^a   Volegov, Petr ^a  

^a LOS ALAMOS NATIONAL LABORATORY   (United States)

Author keywords

Magnetic Resonance Imaging (MRI); SQUID detection; ULF MRI; Ultra low fields (ULFs)

Indexed keywords

BRAIN MAPPING; DEMONSTRATIONS; MAGNETIC FIELDS; MAGNETOENCEPHALOGRAPHY; MOLLUSCS; POLARIZATION; QUANTUM INTERFERENCE DEVICES; SHELLFISH; SQUIDS; TISSUE; TISSUE ENGINEERING;

FUNDAMENTAL LIMITATIONS; HIGH MAGNETIC FIELDS; LARMOR FREQUENCIES; MAGNETIC RESONANCE IMAGING (MRI); NON-INVASIVE IMAGING; PROOF OF CONCEPT; ULTRA-LOW FIELD; ULTRA-LOW-FIELD MRIS;

MAGNETIC RESONANCE IMAGING;

EID: 84875230587     PISSN: 10907807     EISSN: 10960856     Source Type: Journal    
DOI: 10.1016/j.jmr.2016.09.008     Document Type: Erratum

References (67)

1. W. Myers, D. Slichter, M. Hatridge, S. Busch, M. Mößle, R. McDermott, A. Trabesinger, and J. Clarke Calculated signal-to-noise ratio of MRI detected with SQUIDs and Faraday detectors in fields from 10 μT to 1.5 T J. Magn. Reson. 186 2006 182 192
2. A. Macovski, and S. Conolly Novel approaches to low cost MRI Magn. Reson. Med. 30 1993 221 230
3. H.C. Seton, J.M.S. Hutchinson, and D.M. Bussel A 4.2 K receiver coil and SQUID amplifier used to improve the SNR of low-field magnetic resonance images of the human arm Meas. Sci. Technol. 8 1997 198 207
4. J. Clarke, M. Hatridge, and M. Mößle SQUID-detected magnetic resonance imaging in microtesla fields Annu. Rev. Biomed. Eng. 9 2007 389 413
5. P.E. Magnelind, J.J. Gomez, A.N. Matlashov, T. Owens, J.H. Sandin, P.L. Volegov, and M.A. Espy Co-Registration of Interleaved MEG and ULF MRI Using a 7 Channel Low-Tc SQUID System Trans. Appl. Supercond. 21 3, pt.1 2011 456 460
6. V.S. Zotev, A.N. Matlashov, P.L. Volegov, I.M. Savukov, M.A. Espy, J.C. Mosher, J.J. Gomez, and R.H. Kraus Microtesla MRI of the human brain combined with MEG J. Mag. Reson. 194 2008 115 120
7. P.T. Vesanen, J.O. Nieminen, K.C.J. Zevenhoven, J. Dabek, L.T. Parkkonen, A.V. Zhdanov, J. Luomahaara, J. Hassel, J. Penttila, J. Simola, A.I. Ahonen, J.P. Makela, R.J. Ilmoniemi. Hybrid ultra-low-field MRI and magnetoencephalography system based on a commercial wholehead neuromagnetometer. to appear Magn. Reson. Med. < http://onlinelibrary.wiley.com/doi/10.1002/ mrm.24413/pdf >.
8. S.-K. Lee, M. Mossle, W. Myers, N. Kelso, A.H. Trabesinger, A. Pines, and J. Clarke SQUID-Detected MRI at 132 μT with T1- Weighted Contrast Established at 10 μT-300 mT Magn. Reson. Med. 53 2005 9 14
9. V.S. Zotev, A.N. Matlashov, I.M. Savukov, T. Owens, P.L. Volegov, J.J. Gomez, and M.A. Espy SQUID-Based Microtesla MRI for In Vivo Relaxometry of the Human Brain IEEE Trans. Appl. Supercond. 19 3; pt.1 2009 823 826
10. S. Hartwig, J. Voigt, H-J. Scheer, H-H. Albrecht, M. Burghoff, and L. Trahms Nuclear magnetic relaxation in water revisited J. Chem. Phys. 135 2011 054201
11. J.K. Alford, B.K. Rutt, T.J. Scholl, W.B. Handler, and B.A. Chronik Delta relaxation enhanced mr: improving activation- specificity of molecular probes through R1 dispersion imaging Magn. Reson. Med. 61 2009 796 802
12. P.E. Magnelind, I.M. Savukov, Y.T. Araya, M.A. Espy, A.N. Matlashov, P. Nath, P.L. Volegov, and V.S. Zotev Superparamagnetic nanoparticle contrast agents in ultra-low field MRI, presented at the 50th ENC, March 29- April 3 2009 Pacific Grove California
13. S. Ungersma, N. Matter, J. Hardy, R. Venook, A. Macovski, S. Conolly, and G. Scott Magnetic resonance imaging with T1 dispersion contrast Mag. Res. Med. 55 2006 1362 1371
14. R. Kraus, P. Volegov, A. Matlachov, and M. Espy Toward direct neural current imaging by resonant mechanisms at ultra-low field Neuroimage 39 2008 310 317
15. M. Mößle, S-I. Han, W.R. Myers, S-K. Lee, N. Kelso, M. Hatridge, A. Pines, and J. Clarke SQUID-Detected Microtesla MRI in the Presence of Metal J. Magn. Reson. 179 2006 146 151
16. A.N. Matlachov, P.L. Volegov, M.A. Espy, J.S. George, and R.H. Kraus Jr. SQUID detected NMR in microtesla magnetic fields J. Magn. Reson. 170 2004 1 7
17. B. Eom, K. Penanen, P.K. Day, I. Hahn, and M.S. Cohen Development of Cryogen-Free Ultra-Low Field MRI Instrument United States Proc. Intl. Soc. Mag. Reson. Med. 17 2009
18. P.L. Volegov, J.C. Mosher, M.A. Espy, and R.H. Kraus Jr. On concomitant gradients in ultra-low field MRI J Magn. Reson. 175 2005 103 113
19. J.O. Nieminen, and R.J. Ilmoniemi Solving the problem of concomitant gradients in ultra-low-field MRI J Magn. Reson. 207 2010 213 219
20. A.N. Matlashov, E. Burmistrov, P.E. Magnelind, L. Schultz, A.V. Urbaitis, P.L. Volegov, J. Yoder, and M.A. Espy SQUID-based Systems for Co-registration of Ultra-Low Field Nuclear Magnetic Resonance Images and Magnetoencephalography Physica C: Supercond. 482 2012 19 26
21. W.R. Myers, Potential applications of microtesla magnetic resonance imaging detected using a superconducting quantum interference device, Ph.D. thesis (2006) http://escholarship.org/uc/item/19x7q88x#page-9.
22. D.L. Lurie, S. Aime, S. Baroni, N.A. Booth, L.M. Broche, C.-H. Choi, G.R. Davies, S. Ismail, D. O'hogain, and K.J. Pine Fast field cycling magnetic resonance imaging Comptes Rendus Phys. 11 2010 136 148
23. H.W. Fischer, P.A. Rinck, Y. Van Haverbeke, and R.N. Muller Nuclear relaxation of human brain gray and white matter: analysis of field dependence and implications for MRI Magn. Reson. Med. 16 1990 317 334
24. R. McDermott, A.H. Trabesinger, M. Mück, E.L. Hahn, A. Pines, and J. Clarke Liquid-state nmr and scalar couplings in microtesla magnetic fields Science 22 295 2002 2247
25. M. Burghoff, S. Hartwig, and L. Trahms Nuclear magnetic resonance in the nanotesla range Appl. Phys. Lett. 87 2005 054103
26. J.R. Sims, J.B. Schillig, C.A. Swenson, D.L. Gardner, A.N. Matlashov, and C.N. Ammerman Low-noise pulsed pre-polarization magnet systems for ultra-low field NMR IEEE Trans. Appl. Supercond. 20 3 2010 752 755
27. J.O. Nieminen, P.T. Vesanen, K.C.J. Zevenhoven, J. Dabek, J. Hassel, J. Luomahaara, J.S. Penttila, and R.J. Ilmoniemi Avoiding eddy-current problems in ultra-low-field MRI with self-shielded polarizing coils J. Magn. Reson. 212 2011 154 160
28. P. Vesanen, J. Nieminen, C. Zevenhoven, J. Dabek, J. Simola, J. Sarvas, and R. Ilmoniemi The spatial and temporal distortion of magnetic fields applied inside a magnetically shielded room IEEE Trans. Magn. 48 1 2012 53 61
29. J.P. Reilly Peripheral nerve stimulation by induced electric currents: exposure to time-varying magnetic fields Med. Biol. Eng. Comput. 27 1989 101 110
30. M.S. Cohen, M.R. Weisskopf, R.R. Rzedian, and H.L. Kantor Sensory stimulation by time-varying magnetic fields Magn. Reson. Med. 14 2 1990 409 414
31. T.F. Budinger, H. Fischer, D. Hentschel, H.E. Reinfelder, and F. Schmitt Physiological effects of fast oscillating magnetic field gradients J. Comput. Assist. Tomogr. 15 6 1991 909 914
32. Guidance for Industry: Guidance for the Submission Of Premarket Notifications for Magnetic Resonance Diagnostic Devices, Document issued on: November 14, 1998, < http://www.fda.gov/downloads/MedicalDevices/ DeviceRegulationandGuidance/GuidanceDocuments/ucm073818.pdf >.
33. Criteria for Significant Risk Investigations of Magnetic Resonance Diagnostic Devices July 14, 2003 < http://www.fda.gov/downloads/ MedicalDevices/DeviceRegulationandGuidance/GuidanceDocuments/ucm072688.pdf >.
34. Supracon A G < http://www.supracon.com >.
35. M. Espy, S. Baguisa, D. Dunkerley, P. Magnelind, A. Matlashov, T. Owens, H. Sandin, I. Savukov, L. Schultz, A. Urbaitis, and P. Volegov Progress on detection of liquid explosives using ultra-low field MRI IEEE Trans. Appl. Supercond. 21 3 pt. 1 2011 530 533
36. J. Luomahaara, P.T. Vesanen, J. Penttila, J.O. Nieminen, J. Dabek, J. Simola, M. Kiviranta, L. Gronberg, C.J. Zevenhoven, R.J. Ilmoniemi, and J. Hassel All-planar SQUIDs and pickup coils for combined MEG and MRI Supercond. Sci. Technol. 24 2011 075020
37. J.O. Nieminen, M. Burghoff, L. Trahms, R.J. Ilmoniemi Polarization encoding as a novel approach to MRI, J. Magn. Reson., 202 (2) (2010) 211-216.
38. D. Regan Human Brain Electrophysiology: Evoked Potentials And Evoked Magnetic Fields in Science and Medicine 1989 Elsevier Science Publishing New York
39. M. Hamalainen, R. Hari, R.J. Ilmoniemi, J. Knuutila, and O.V. Lounasmaa Magnetoencephalography-theory, instrumentation, and applications to noninvasive studies of the working human brain Rev. Mod. Phys. 65 2 1993 413 497
40. F.H. Lopes da Silva, H.J. Wieringa, and M.J. Peters Source localization of EEG versus MEG: Empirical comparison using visually evoked responses and theoretical considerations Brain Topograp. 4 2 1991 133 142
41. M. Funke, T. Constantino, C. Van Orman, and E. Rodin Magnetoencephalography and magnetic source imaging in epilepsy Clin EEG Neurosci. 40 4 2009 271 280
42. H. Xia, A. Ben-Amar Baranga, D. Hoffman, and M.V. Romalis Magneoencephalography with an atomic magnetometer Appl. Phys. Lett. 89 2006 211104
43. P. Adjamian, G.R. Barnes, A. Hillebrand, I.E. Holliday, K.D. Singh, P.L. Furlong, E. Harrington, C.W. Barclay, and P.J.G. Route Co-registration of MEG with MRI using bite-bar fiducials and surfacematching Clin. Neurophys. 115 2004 691
44. V. Poghosyan, and A.A. Ionnides Precise mapping of early visual responses in space and time Neuroimage 35 2 2007 759 770
45. A.N. Matlachov, P.L. Volegov, M. Espy, R. Stolz, L. Fritzsch, V. Zakosarenko, H.-G. Meyer, and R.H. Kraus Jr. Instrumentation for simultaneous detection of low field NMR and biomagnetic signals IEEE Trans. Appl. Supercond. 15 2 2005 676 679
46. P. Volegov, A.N. Matlachov, M.A. Espy, J.S. George, and R.H. Kraus Jr. Simultaneous magnetoencephalography and SQUID detected nuclear MR in microtesla magnetic fields Magn. Reson. Med. 52 3 2004 467 470
47. K.P. Pruessmann, M. Weiger, M.B. Scheidegger, and P. Boesiger SENSE: sensitivity encoding for fast MRI Magn. Reson. Med. 42 5 1999 952 962
48. V.S. Zotev, P.L. Volegov, A.N. Matlashov, M.A. Espy, J.C. Mosher, and R.H. Kraus Jr. Parallel MRI at microtesla fields J. Magn. Reson. 192 2008 197 208
49. J. Nieminen, Ultra-low-field MRI: techniques and instrumentation for hybrid MEG-MRI, Aalto University publication series doctoral dissertations (2012) < lib.tkk.fi/Diss/2012/isbn9789526046457/isbn9789526046457.pdf >.
50. S-G. Kim and P. Bandettini, BOLD fmRI: A Guide to Functional Imaging for Neuroscientists, in: S. H. Faro, F. B. Mohamed, (Eds.), Principles of Functional MRI, Springer, < http://dx.doi.org/10.1007/978-1-4419-1329-6 >, Library of Congress Control Number: 2010929273, (Chapter 1).
51. M.L. Scholvinck, A. Maier, F.Q. Ye, J.H. Duyn, and D.A. Leopold Neural basis of global resting-state fMRI activity PNAS 107 22 2010 10238
52. C. Kayser and N. K. Logothetis, The Electrophysiological background of the fMRI Signal, fMRI: basics and clinical applications, in: S. Ulmer, O. Jansen, (Eds.), Springer, http://dx.doi.org/10.1007/978-3-540-68132-8, Library of Congress Control Number: 2009931051, (Chapter 4).
53. S.-G. Kim Quantification of relative cerebral blood flow change by flow-sensitive alternating inversion recovery (FAIR) technique: application to functional mapping Magn. Reson. Med. 34 1995 293 301
54. K.K. Kwong, D.A. Chesler, R.M. Weisskoff, K.M. Donahue, T.L. Davis, L. Ostergaard, T.A. Campbell, and B.R. Rosen MR perfusion studies with T1-weighted echo planar imaging Magn. Reson. Med. 34 1995 878 887
55. C. Schwarzbauer, S. Morrissey, and A. Haase Quantitative magnetic resonance imaging of perfusion using magnetic labeling of water proton spins within the detection slice Magn. Reson. Med. 35 1996 540 546
56. P. Magnelind, J. George, J. Gomez, A. Matlashov, A. Urbaitis, P. Volegov, M. Espy, Towards functional magnetic resonance imaging at ultra-low fields, presented at the Superconductivity Centennial Conference in The Hague, The Netherlands (2011).
57. J. Bodurka, and P.A. Bandettini Toward direct mapping of neuronal activity: MRI detection of ultraweak transient magnetic fields changes Magn. Reson. Med. 47 2002 1052 1058
58. J. Bodurka, A. Jesmanowicz, J.S. Hyde, H. Xu, L. Estkowski, and S.J. Li Current-induced magnetic resonance imaging J Magn. Reson. 137 1999 265 271
59. J. Xiong, P.T. Fox, and J.H. Gao Directly mapping magnetic field effects of neuronal activity by magnetic resonance imaging Hum Brain Mapp 20 2003 41 49
60. M. Parkes, F.P. de Lange, P. Fries, I. Toni, and D.G. Norris Inability to directly detect magnetic field changes associated with neuronal activity Magn. Reson. Med. 57 2007 411 416
61. O. Gilad, A. Ghosh, D. Oh, and D.S. Holder A method for recording resistance changes non-invasively during neuronal depolarization with a view to imaging brain activity with electrical impedance tomography J. Neurosci. Methods 180 2009 87 96
62. O. Gilad, and D.S. Holder Impedance changes recorded with scalp electrodes during visual evoked responses: implications for Electrical Impedance Tomography of fast neural activity NeuroImage 47 2009 514 522
63. S. Busch, M. Hatridge, M. Mößle, W. Myers, T. Wong, M. Mück, K. Chew, K. Kuchinsky, J. Simko, and J. Clarke Measurements of T1-relaxation in ex vivo prostate tissue at 132 μt Magn. Reson. Med. 67 2012 1138 1145
64. S.H. Koenig, and R.D. Brown Determinants of proton relaxation rates in tissue Magn. Reson. Med. 1 1984 437 447
65. M. Espy, M. Flynn, J. Gomez, C. Hanson, R. Kraus, P. Magnelind, K. Maskaly, A. Matlashov, S. Newman, M. Peters, H. Sandin, I. Savukov, L. Schultz, A. Urbaitis, P. Volegov, and V. Zotev Applications of Ultra-Low Field Magnetic Resonance for Imaging and Materials Studies IEEE Trans. Appl. Supercond. 19 3; pt.1 2009 835 838
66. M. Espy, M. Flynn, J. Gomez, C. Hanson, R. Kraus, P. Magnelind, K. Maskaly, A. Matlashov, S. Newman, T. Owens, M. Peters, H. Sandin, I. Savukov, L. Schultz, A. Urbaitis, P. Volegov, and V. Zotev Ultra-low field MRI for the detection of liquid explosives Supercond. Sci. Technol. 23 2010 034023
67. T. Takeda, M. Okamoto, T. Miyazaki, N. Morita, K. Katagiri, Magnetoencephalography, ISBN: 978-953-307-255-5 Helium Circulation System (HCS) for the MEG, < http://www.intechopen.com/books/magnetoencephalography/helium- circulation-system-hcs-for-the-meg >.