Distribution of brain sodium long and short relaxation times and concentrations: a multi-echo ultra-high fieldNa MRI study
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Distribution of brain sodium long and short relaxation times and concentrations: a multi-echo ultra-high fieldNa MRI study. / Ridley, Ben; Nagel, Armin M; Bydder, Mark; Maarouf, Adil; Stellmann, Jan-Patrick; Gherib, Soraya; Verneuil, Jeremy; Viout, Patrick; Guye, Maxime; Ranjeva, Jean-Philippe; Zaaraoui, Wafaa.
In: SCI REP-UK, Vol. 8, No. 1, 12.03.2018, p. 4357.Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review
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TY - JOUR
T1 - Distribution of brain sodium long and short relaxation times and concentrations: a multi-echo ultra-high fieldNa MRI study
AU - Ridley, Ben
AU - Nagel, Armin M
AU - Bydder, Mark
AU - Maarouf, Adil
AU - Stellmann, Jan-Patrick
AU - Gherib, Soraya
AU - Verneuil, Jeremy
AU - Viout, Patrick
AU - Guye, Maxime
AU - Ranjeva, Jean-Philippe
AU - Zaaraoui, Wafaa
PY - 2018/3/12
Y1 - 2018/3/12
N2 - Sodium (23Na) MRI proffers the possibility of novel information for neurological research but also particular challenges. Uncertainty can arise in in vivo23Na estimates from signal losses given the rapidity of T2* decay due to biexponential relaxation with both short (T2*short) and long (T2*long) components. We build on previous work by characterising the decay curve directly via multi-echo imaging at 7 T in 13 controls with the requisite number, distribution and range to assess the distribution of both in vivo T2*shortand T2*longand in variation between grey and white matter, and subregions. By modelling the relationship between signal and reference concentration and applying it to in vivo23Na-MRI signal,23Na concentrations and apparent transverse relaxation times of different brain regions were measured for the first time. Relaxation components and concentrations differed substantially between regions of differing tissue composition, suggesting sensitivity of multi-echo23Na-MRI toward features of tissue composition. As such, these results raise the prospect of multi-echo23Na-MRI as an adjunct source of information on biochemical mechanisms in both physiological and pathophysiological states.
AB - Sodium (23Na) MRI proffers the possibility of novel information for neurological research but also particular challenges. Uncertainty can arise in in vivo23Na estimates from signal losses given the rapidity of T2* decay due to biexponential relaxation with both short (T2*short) and long (T2*long) components. We build on previous work by characterising the decay curve directly via multi-echo imaging at 7 T in 13 controls with the requisite number, distribution and range to assess the distribution of both in vivo T2*shortand T2*longand in variation between grey and white matter, and subregions. By modelling the relationship between signal and reference concentration and applying it to in vivo23Na-MRI signal,23Na concentrations and apparent transverse relaxation times of different brain regions were measured for the first time. Relaxation components and concentrations differed substantially between regions of differing tissue composition, suggesting sensitivity of multi-echo23Na-MRI toward features of tissue composition. As such, these results raise the prospect of multi-echo23Na-MRI as an adjunct source of information on biochemical mechanisms in both physiological and pathophysiological states.
KW - Journal Article
U2 - 10.1038/s41598-018-22711-0
DO - 10.1038/s41598-018-22711-0
M3 - SCORING: Journal article
C2 - 29531255
VL - 8
SP - 4357
JO - SCI REP-UK
JF - SCI REP-UK
SN - 2045-2322
IS - 1
ER -