Thalamic energy dysfunction is associated with thalamo-cortical tract damage in multiple sclerosis: A diffusion spectroscopy study

Abstract

Background:

Diffusion-weighted ¹H magnetic resonance spectroscopy (DW-MRS) allows to quantify creatine-phosphocreatine brain diffusivity (ADC(tCr)), whose reduction in multiple sclerosis (MS) has been proposed as a proxy of energy dysfunction.

Objective:

To investigate whether thalamic ADC(tCr) changes are associated with thalamo-cortical tract damage in MS.

Methods:

Twenty patients with MS and 13 healthy controls (HC) were enrolled in a DW-MRS and DW imaging (DWI) study. From DW-MRS, ADC(tCr) and total N-acetyl-aspartate diffusivity (ADC(tNAA)) were extracted in the thalami. Three thalamo-cortical tracts and one non-thalamic control tract were reconstructed from DWI. Fractional anisotropy (FA), mean (MD), axial (AD), and radial diffusivity (RD), reflecting microstructural integrity, were extracted for each tract. Associations between thalamic ADC(tCr) and tract metrics were assessed using linear regression models adjusting for age, sex, thalamic volume, thalamic ADC(tNAA), and tract-specific lesion load.

Results:

Lower thalamic ADC(tCr) was associated with higher MD and RD of thalamo-cortical projections in MS (MD: p = 0.029; RD: p = 0.017), but not in HC (MD: p = 0.625, interaction term between thalamic ADC(tCr) and group = 0.019; RD: p = 0.320, interaction term = 0.05). Thalamic ADC(tCr) was not associated with microstructural changes of the control tract.

Conclusion:

Reduced thalamic ADC(tCr) correlates with thalamo-cortical tract damage in MS, showing that pathologic changes in thalamic energy metabolism are associated with structural degeneration of connected fibers.

Keywords

Multiple sclerosis energy dysfunction diffusion-weighted spectroscopy diffusion tensor imaging tractography neurodegeneration

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References

Ontaneda

Fox

Chataway

Clinical trials in progressive multiple sclerosis: Lessons learned and future perspectives. Lancet Neurol 2015; 14(2): 208–223.

Campbell

Worrall

Mahad

DJ.

The central role of mitochondria in axonal degeneration in multiple sclerosis. Mult Scler 2014; 20(14): 1806–1813.

Trapp

Stys

PK.

Virtual hypoxia and chronic necrosis of demyelinated axons in multiple sclerosis. Lancet Neurol 2009; 8(3): 280–291.

Friese

Schattling

Fugger

Mechanisms of neurodegeneration and axonal dysfunction in multiple sclerosis. Nat Rev Neurol 2014; 10: 225–238.

Palombo

Shemesh

Ronen

, et al. Insights into brain microstructure from in vivo DW-MRS. Neuroimage 2018; 182: 97–116.

Bodini

Branzoli

Poirion

, et al. Dysregulation of energy metabolism in multiple sclerosis measured in vivo with diffusion-weighted spectroscopy. Mult Scler 2018; 24(3): 313–321.

Steen

Wilczak

Hoogduin

, et al. Reduced creatine kinase B activity in multiple sclerosis normal appearing white matter. Plos One 2010; 5(5): e10811.

Kipp

Wagenknecht

Beyer

, et al. Thalamus pathology in multiple sclerosis: From biology to clinical application. Cell Mol Life Sci 2015; 72(6): 1127–1147.

Kolasinski

Stagg

Chance

, et al. A combined post-mortem magnetic resonance imaging and quantitative histological study of multiple sclerosis pathology. Brain 2012; 135(Pt 10): 2938–2951.

10.

Bodini

Khaleeli

Cercignani

, et al. Exploring the relationship between white matter and gray matter damage in early primary progressive multiple sclerosis: An in vivo study with TBSS and VBM. Hum Brain Mapp 2009; 30(9): 2852–2861.

11.

Polman

Reingold

Banwell

, et al. Diagnostic criteria for multiple sclerosis: 2010 Revisions to the McDonald criteria. Ann Neurol 2011; 69(2): 292–302.

12.

Ronen

Valette

Diffusion-weighted magnetic resonance spectroscopy. Emagres 2015; 4: 733–750.

13.

Iglesias

Insausti

Lerma-Usabiaga

, et al. A probabilistic atlas of the human thalamic nuclei combining ex vivo MRI and histology. Neuroimage 2018; 183: 314–326.

14.

Leemans

Jeurissen

Sijbers

, et al. ExploreDTI: A graphical toolbox for processing, analyzing, and visualizing diffusion MR data. Proc Intl Soc Mag Reson Med 2009; 17: 3537.

15.

Tax

CMW

Otte

Viergever

, et al. REKINDLE: Robust extraction of kurtosis INDices with linear estimation. Magn Reson Med 2015; 73(2): 794–808.

16.

Tournier

Calamante

Connelly

Robust determination of the fibre orientation distribution in diffusion MRI: Non-negativity constrained super-resolved spherical deconvolution. Neuroimage 2007; 35(4): 1459–1472.

17.

Wang

Wedeen

VJ.

Diffusion toolkit : A software package for diffusion imaging data processing and tractography. Proc Intl Soc Mag Reson Med 2007; 15: 3720.

18.

Catani

Thiebaut

Schotten

A diffusion tensor imaging tractography atlas for virtual in vivo dissections. Cortex 2008; 44(8): 1105–1132.

19.

Lipp

Parker

Tallantyre

, et al. Tractography in the presence of white matter lesions in multiple sclerosis. Neuroimage 2019; 209: 116471.

20.

Provencher

SW.

Automatic quantitation of localized in vivo 1H spectra with LCModel. NMR Biomed 2001; 14(4): 260–264.

21.

Kauv

Ayache

Creange

, et al. Adenosine triphosphate metabolism measured by phosphorus magnetic resonance spectroscopy: A potential biomarker for multiple sclerosis severity. Eur Neurol 2017; 77(5–6): 316–321.

22.

Hattingen

Magerkurth

Pilatus

, et al. Combined (1)H and (31)P spectroscopy provides new insights into the pathobiochemistry of brain damage in multiple sclerosis. NMR Biomed 2011; 24(5): 536–546.

23.

Wood

Ronen

Techawiboonwong

, et al. Investigating axonal damage in multiple sclerosis by diffusion tensor spectroscopy. J Neurosci 2012; 32(19): 6665–6669.

24.

Hares

Kemp

Rice

, et al. Reduced axonal motor protein expression in non-lesional grey matter in multiple sclerosis. Mult Scler 2014; 20(7): 812–821.

25.

Campbell

Ohno

Turnbull

, et al. Mitochondrial changes within axons in multiple sclerosis: An update. Curr Opin Neurol 2012; 25(3): 221–230.

26.

Sasaki

Metabolic aspects of neuronal degeneration: From a NAD+ point of view. Neurosci Res 2019; 139: 9–20.

27.

Huang-Link

Y-M

Al-Hawasi

Eveman

Retrograde degeneration of visual pathway: Hemimacular thinning of retinal ganglion cell layer in progressive and active multiple sclerosis. J Neurol 2014; 261(12): 2453–2456.

28.

Bodini

Chard

Altmann

, et al. White and gray matter damage in primary progressive MS—The chicken or the egg? Neurology 2016; 86: 170–176.

29.

Brück

Inflammatory demyelination is not central to the pathogenesis of multiple sclerosis. J Neurol 2005; 252(Suppl. 5): 10–15.

30.

Tallantyre

Al-Rawashdeh

, et al. Clinico-pathological evidence that axonal loss underlies disability in progressive multiple sclerosis. Mult Scler 2010; 16(4): 406–411.

31.

Koubiyr

Deloire

Coupe

, et al. Differential gray matter vulnerability in the 1 year following a clinically isolated syndrome. Front Neurol 2018; 9: 824.

32.

Yin

Quan

, et al. Evaluation of patients with relapsing-remitting multiple sclerosis using tract-based spatial statistics analysis: Diffusion kurtosis imaging. BMC Neurol 2018; 18(1): 108.

33.

Pasternak

Shenton

Westin

C-F.

Estimation of extracellular volume from regularized multi-shell diffusion MRI. Med Image Comput Comput Assist Interv 2012; 15(Pt 2): 305–312.

34.

Vallée

Lecarpentier

Guillevin

, et al. Demyelination in multiple sclerosis: Reprogramming energy metabolism and potential PPARγ agonist treatment approaches. Int J Mol Sci 2018; 19: E1212.

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