Decomposition of high-frequency electrical conductivity into extracellular and intracellular compartments based on two-compartment model using low-to-high multi-b diffusion MRI.

Tytuł:: Decomposition of high-frequency electrical conductivity into extracellular and intracellular compartments based on two-compartment model using low-to-high multi-b diffusion MRI.
Autorzy:: Lee MB; Department of Mathematics, Konkuk University, 05029, Seoul, South Korea.
Kim HJ; Department of Biomedical Engineering, Kyung Hee University, 02447, Seoul, South Korea.
Kwon OI; Department of Mathematics, Konkuk University, 05029, Seoul, South Korea. .
Źródło:: Biomedical engineering online [Biomed Eng Online] 2021 Mar 25; Vol. 20 (1), pp. 29. Date of Electronic Publication: 2021 Mar 25.
Typ publikacji:: Journal Article
Język:: English
Imprint Name(s):: Original Publication: London : BioMed Central, [2002-
MeSH Terms:: Diffusion Magnetic Resonance Imaging*
Electric Conductivity*
Tomography*
Image Processing, Computer-Assisted/*methods
Brain/diagnostic imaging ; Brain/physiology ; Brain Mapping ; Cerebrospinal Fluid ; Electric Impedance ; Humans ; Normal Distribution ; Phantoms, Imaging ; Reproducibility of Results
References:: Biomed Eng Lett. 2018 Apr 25;8(3):273-282. (PMID: 30603211)
Phys Med Biol. 2009 Aug 21;54(16):4863-78. (PMID: 19636081)
Nature. 2015 Mar 19;519(7543):299-300. (PMID: 25788094)
Eur Radiol. 2018 Jan;28(1):348-355. (PMID: 28698943)
Magn Reson Med. 2017 Nov;78(5):2011-2021. (PMID: 28039883)
Magn Reson Med. 2015 Jul;74(1):185-195. (PMID: 25099920)
Radiology. 2008 Dec;249(3):748-52. (PMID: 19011179)
IEEE Trans Med Imaging. 2018 Apr;37(4):966-976. (PMID: 29610075)
Magn Reson Med. 2016 Aug;76(2):530-9. (PMID: 26375762)
Phys Med Biol. 1996 Nov;41(11):2251-69. (PMID: 8938025)
Curr Opin Anaesthesiol. 2013 Apr;26(2):182-5. (PMID: 23385317)
Neuroimage. 2018 Jul 1;174:518-538. (PMID: 29544816)
Magn Reson Med. 2019 Feb;81(2):803-810. (PMID: 30325052)
Exp Neurol. 1965 Apr;11:451-63. (PMID: 14278100)
IEEE Trans Med Imaging. 2005 Sep;24(9):1170-6. (PMID: 16156354)
NMR Biomed. 2019 Apr;32(4):e3841. (PMID: 29193413)
IEEE Trans Med Imaging. 2009 Sep;28(9):1365-74. (PMID: 19369153)
Br J Psychiatry. 2016 Jun;208(6):522-31. (PMID: 27056623)
IEEE Trans Biomed Eng. 1997 Mar;44(3):220-3. (PMID: 9216137)
IEEE Trans Med Imaging. 2014 Mar;33(3):777-93. (PMID: 24595349)
Neuroimage. 2020 Jul 15;215:116835. (PMID: 32289460)
Neuroimage. 2021 Jan 15;225:117466. (PMID: 33075557)
Magn Reson Med. 2010 Mar;63(3):562-9. (PMID: 20187164)
Magn Reson Med. 2016 Apr;75(4):1752-63. (PMID: 25974332)
Magn Reson Med. 2005 Jun;53(6):1432-40. (PMID: 15906300)
Neuropsychopharmacology. 2012 Jan;37(1):102-16. (PMID: 21976043)
Magn Reson Med. 2015 Apr;73(4):1505-13. (PMID: 24777618)
Magn Reson Med. 2011 Aug;66(2):456-66. (PMID: 21773985)
Neuroimage. 2014 Nov 1;101:513-30. (PMID: 24821532)
Proc Natl Acad Sci U S A. 1996 Oct 15;93(21):11443-7. (PMID: 8876154)
PLoS One. 2020 Apr 8;15(4):e0230903. (PMID: 32267858)
Proc Natl Acad Sci U S A. 2001 Sep 25;98(20):11697-701. (PMID: 11573005)
IEEE Trans Med Imaging. 2019 Jul;38(7):1569-1577. (PMID: 30507528)
Brain Topogr. 2019 Sep;32(5):825-858. (PMID: 31054104)
Magn Reson Med. 2017 Jan;77(1):137-150. (PMID: 26762771)
Biomed Eng Online. 2014 Mar 08;13(1):24. (PMID: 24607262)
Eur Radiol. 2019 Apr;29(4):1778-1786. (PMID: 30255252)
Magn Reson Med. 2003 Oct;50(4):727-34. (PMID: 14523958)
Proc Natl Acad Sci U S A. 2006 May 23;103(21):8263-8. (PMID: 16702549)
Neuroimage. 2012 Feb 1;59(3):2241-54. (PMID: 22001791)
Eur Radiol. 2016 Jul;26(7):2317-26. (PMID: 26497503)
Contributed Indexing:: Keywords: High-frequency conductivity decomposition; Low-frequency conductivity tensor; Magnetic resonance electrical property tomography; Multi-b diffusion weighted imaging; Random forest
Entry Date(s):: Date Created: 20210326 Date Completed: 20210402 Latest Revision: 20210402
Update Code:: 20240105
PubMed Central ID:: PMC7993544
DOI:: 10.1186/s12938-021-00869-5
PMID:: 33766044
: Czasopismo naukowe

Pełny tekst

Background: As an object's electrical passive property, the electrical conductivity is proportional to the mobility and concentration of charged carriers that reflect the brain micro-structures. The measured multi-b diffusion-weighted imaging (Mb-DWI) data by controlling the degree of applied diffusion weights can quantify the apparent mobility of water molecules within biological tissues. Without any external electrical stimulation, magnetic resonance electrical properties tomography (MREPT) techniques have successfully recovered the conductivity distribution at a Larmor-frequency.
Methods: This work provides a non-invasive method to decompose the high-frequency conductivity into the extracellular medium conductivity based on a two-compartment model using Mb-DWI. To separate the intra- and extracellular micro-structures from the recovered high-frequency conductivity, we include higher b-values DWI and apply the random decision forests to stably determine the micro-structural diffusion parameters.
Results: To demonstrate the proposed method, we conducted phantom and human experiments by comparing the results of reconstructed conductivity of extracellular medium and the conductivity in the intra-neurite and intra-cell body. The phantom and human experiments verify that the proposed method can recover the extracellular electrical properties from the high-frequency conductivity using a routine protocol sequence of MRI scan.
Conclusion: We have proposed a method to decompose the electrical properties in the extracellular, intra-neurite, and soma compartments from the high-frequency conductivity map, reconstructed by solving the electro-magnetic equation with measured B1 phase signals.

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