FrieseMASchattlingBFuggerL. Mechanisms of neurodegeneration and axonal dysfunction in multiple sclerosis. Nat Rev Neurol2014; 10(4): 225–238.
2.
FrischerJMBramowSDal-BiancoA. The relation between inflammation and neurodegeneration in multiple sclerosis brains. Brain2009; 132(5): 1175–1189.
3.
ReichDSSmithSAGordon-LipkinEM. Damage to the optic radiation in multiple sclerosis is associated with retinal injury and visual disability. Arch Neurol2009; 66(8): 998–1006.
4.
CiccarelliOToosyATHickmanSJ. Optic radiation changes after optic neuritis detected by tractography-based group mapping. Hum Brain Mapp2005; 25(3): 308–316.
5.
GabilondoIMartínez-LapiscinaEHMartínez-HerasE. Trans-synaptic axonal degeneration in the visual pathway in multiple sclerosis. Ann Neurol2014; 75(1): 98–107.
6.
RoccaMAMesarosSPreziosaP. Wallerian and trans-synaptic degeneration contribute to optic radiation damage in multiple sclerosis: A diffusion tensor MRI study. Mult Scler2013; 19: 1610–1617.
7.
BalkLJTwiskJWSteenwijkMD. A dam for retrograde axonal degeneration in multiple sclerosis?J Neurol Neurosurg Psychiatry2014; 85(7): 782–789.
8.
KolbeSBajraszewskiCChapmanC. Diffusion tensor imaging of the optic radiations after optic neuritis. Hum Brain Mapp2012; 33: 2047–2061.
9.
TurCGoodkinOAltmannDR. Longitudinal evidence for anterograde trans-synaptic degeneration after optic neuritis. Brain2016; 139(3): 816–828.
10.
KolbeSCWaltAVan Der ButzkuevenH. Serial diffusion tensor imaging of the optic radiations after acute optic neuritis. J Ophthalmol2016; 2016: 2764538.
11.
KlistornerASriramPVootakuruN. Axonal loss of retinal neurons in multiple sclerosis associated with optic radiation lesions. Neurology2014; 82(24): 2165–2172.
12.
GelfandJMNolanRSchwartzDM. Microcystic macular oedema in multiple sclerosis is associated with disease severity. Brain2012; 135(6): 1786–1793.
