Gray matter atrophy is primarily related to demyelination of lesions in multiple sclerosis a diffusion tensor imaging MRI study /

Gray matter atrophy is primarily related to demyelination of lesions in multiple sclerosis a diffusion tensor imaging MRI study /

Objective: Cortical pathology, periventricular demyelination and lesion formation in multiple sclerosis (MS) are related (hypothesis 1). Factors in the cerebrospinal fluid close to these compartments could possibly drive the parallel processes. Alternatively, the cortical atrophy could be caused...

Teljes leírás

Elmentve itt :
Bibliográfiai részletek
Szerzők: Tóth Eszter
Szabó Nikoletta
Csete Gergő
Király András
Faragó Péter
Spisák Tamás
Bencsik Krisztina
Vécsei László
Kincses Zsigmond Tamás
Dokumentumtípus: Cikk
Megjelent: 2017
Sorozat:FRONTIERS IN NEUROANATOMY 11
doi:10.3389/fnana.2017.00023

mtmt:3202097
Online Access:http://publicatio.bibl.u-szeged.hu/11720
Leíró adatok
Tartalmi kivonat:Objective: Cortical pathology, periventricular demyelination and lesion formation in multiple sclerosis (MS) are related (hypothesis 1). Factors in the cerebrospinal fluid close to these compartments could possibly drive the parallel processes. Alternatively, the cortical atrophy could be caused by remote axonal transection (hypothesis 2). Since MRI can differentiate between demyelination and axon loss, we used this imaging modality to investigate the correlation between the pattern of diffusion parameter changes in the periventricular- and deep white matter and the grey matter atrophy. Methods: High-resolution T1-weighted, FLAIR and diffusion MRI images were acquired in 52 RRMS patients and 50 healthy, age-matched controls. We used EDSS to estimate the clinical disability. We used Tract Based Spatial Statistics to compare diffusion parameters (fractional anisotropy, mean, axial and radial diffusivity) between groups. We evaluated global brain, white and grey matter atrophy with SIENAX. Averaged, standard diffusion parameters were calculated in four compartment: periventricular lesioned and normal appearing white matter, non-periventricular lesioned and normal appearing white matter. PLS regression was used to identify which diffusion parameter and in which compartment best predicts the brain atrophy and clinical disability. Results: In our diffusion tensor imaging study compared to controls we found extensive alterations of fractional anisotropy, mean and radial diffusivity and smaller changes of axial diffusivity (maximal p-value>0.0002) in patients that suggested demyelination in the lesioned and in the normal appearing white matter. We found significant reduction in total brain, total white and grey matter (patients: 718.764±14.968cm3, 323.237±7.246cm3, 395.527±8.050cm3, controls: 791.772±22.692cm3 355.350±10.929cm3, 436.422±12.011cm3 (mean±SE)), (p<0.015; p<0.0001; p<0.009; respectively) of patients compared to controls. The PLS analysis revealed a combination of demyelination-like diffusion parameters (higher mean and radial diffusivity in patients) in the lesions and in the non-lesioned periventricular white matter, which best predicted the grey matter atrophy (p<0.001). Similarly, EDSS was best predicted by the radial diffusivity of the lesions and the non- lesioned periventricular white matter, but axial diffusivity of the periventricular lesions also contributed significantly (p<0.0001). Interpretation: Our investigation showed that grey matter atrophy and white matter demyelination are related in MS but white matter axonal loss does not significantly contribute to the grey matter pathology.
Terjedelem/Fizikai jellemzők:Terjedelem: 11 p-Azonosító: 23
ISSN:1662-5129

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