L. Leocani
Vita-Salute San Raffaele University Experimental Neurophysiology UnitAuthor Of 2 Presentations
PS15.03 - Optical coherence tomography in aquaporin-4-IgG positive neuromyelitis optica spectrum disorders: a collaborative multi-center study
- F. Oertel
- S. Specovius
- H. Zimmermann
- C. Chien
- S. Motamedi
- L. Cook
- M. Lana-Peixoto
- M. Fontenelle
- H. Kim
- J. Hyun
- J. Palace
- A. Roca-Fernandez
- F. Ashtari
- R. Kafieh
- L. Pandit
- A. D'Cunha
- O. Aktas
- M. Ringelstein
- E. May
- C. Tongco
- L. Leocani
- M. Pisa
- M. Radaelli
- E. Martinez-Lapiscina
- H. Stiebel-Kalish
- S. Siritho
- J. De Seze
- T. Senger
- J. Havla
- R. Marignier
- E. Nerrant
- A. Cobo Calvo
- D. Bichuetti
- I. Tavares
- N. Asgari
- K. Soelberg
- A. Altintas
- U. Tanriverdi
- A. Jacob
- S. Huda
- Z. Rimler
- Y. Mao-Draayer
- I. Soto De Castillo
- A. Green
- M. Yeaman
- T. Smith
- A. Brandt
- F. Paul
Abstract
Background
Optic neuritis (ON) is a frequent manifestation in aquaporin-4 antibody (AQP4-IgG) seropositive neuromyelitis optica spectrum disorders (NMOSD). Due to limited samples, existing optical coherence tomography (OCT) studies are inconsistent regarding retinal changes in eyes with a history of ON (NMO-ON) and without a history of ON (NMO-NON), and their functional relevance.
Objectives
The CROCTINO (Collaborative Retrospective Study on retinal OCT in Neuromyelitis Optica) project aims to reveal correlates of retinal pathology and to generate hypotheses for prospective OCT studies in NMOSD. The objective of this study was to analyze retinal changes of AQP4-IgG seropositive NMO-ON and NMO-NON eyes in an international cross-sectional OCT dataset.
Methods
Of 656 subjects, we enrolled 283 AQP4-IgG seropositive NMOSD patients and 72 healthy controls (HC) from 22 international expert centers. OCT data was acquired with Spectralis SD-OCT, Cirrus HD-OCT and Topcon 3D OCT-1. Mean thickness for the combined ganglion cell and inner plexiform layer (GCIP) and inner nuclear layer (INL) were calculated from macular volume scans. Clinical, functional and laboratory testing were performed at discretion of each center.
Results
We compared NMO-ON eyes (N = 260), NMO-NON eyes (N = 241) and HC eyes (N = 136). GCIP was reduced in NMO-ON (57.4 ± 12.2 µm) compared with NMO-NON (75.9 ± 7.7 µm; p < 0.001) and HC (81.4 ± 5.7 µm; p < 0.001). NMO-NON had thinner GCIP (p < 0.001) compared with HC. INL was thicker in NMO-ON (40.3 ± 3.9 µm) compared with NMO-NON (38.6 ± 3.9µm; p < 0.001), but not HC (39.4 ± 2.6 µm). Microcystic macular edema were visible in 6.6 % of NMOSD eyes.
Conclusions
AQP4-IgG seropositive NMOSD is characterized by a functionally relevant loss of retinal neuroaxonal content and a - probably inflammatory - increase of INL after ON. Our study further supports the existence of attack-independent damage in the visual system of patients with AQP4-IgG seropositive NMOSD.
PS15.05 - Retinal neuro-axonal loss reflects disability accrual in progressive multiple sclerosis independently from disease activity
Abstract
Background
The visual pathway has emerged as an elective platform to study the interaction between demyelination and neurodegeneration in multiple sclerosis (MS)
Objectives
We specifically assessed neural damage at this level in progressive MS (PMS), also exploring the evolution over time of functional (trough visual evoked potentials - VEPs) and structural (trough optical coherence tomography - OCT) parameters, as well as their relations with disease course and clinical disability.
Methods
We performed a prospective longitudinal study enrolling 350 PMS patients (228 secondary progressive MS - SPMS, 122 primary progressive MS - PPMS) who underwent a cross-sectional evaluation comprehensive of Expanded Disability Statur Scale (EDSS) assessment, high (HCVA)- and low-contrast (LCLA) visual acuity test, full-field (ff-VEPs) as well as multifocal (mf-VEPs) VEPs, and OCT. We performed a follow-up assessment (mean interval 2.0±0.9 years) in 147 patients (52 PPMS and 95 SPMS); a parallel collection of clinical records (including reports MRI scans, performed as per clinical practice) has been also obtained.
Results
Independently from previous optic neuritis (ON), we found visual conduction to be slower among SPMS compared to PPMS patients, particularly for mf-VEPs: mean latency 168.9 ms (95% CI 166.2-171.1) vs 163.8 ms (95% CI 160.7-166.9) respectively, p=0.019. Retinal Nerve Fiber Layer (RNFL) was also found to be thinner among SPMS in comparison to PPMS patients: mean 83.4 μm (95% CI 81.4-85.4) vs 87.0 μm (95% CI 84.4-89.6), p=0.040, with similar results for Ganglion Cell-Inner Plexiform Layer (GCIPL). Considering the evolution over time of functional and structural parameters, we found no significant differences comparing PPMS and SPMS patients. Reclassifying our cohort according to EDSS status (“stable” vs “worsened”) we found a significant between-groups difference in terms of RNFL evolution: mean annualized percent change -0.163 %/year (95% CI -0.467 - -0.141) vs -0.854 %/year (95% CI -1.188 - -0.521) respectively, p=0.003. Similar findings were obtained for GCIPL change. In both cases, these observations were independent from the evidence of MRI activity during follow-up.
Conclusions
our results suggest the presence of a greater functional and structural involvement of the visual system among SPMS compared to PPMS patients, independently from previous ON history; follow-up data suggest however neurodegeneration accrual over time to be similar between these two clinical subgroups. The longitudinal relation between RNFL - GCIPL thinning and EDSS worsening, even in the absence of overt MRI activity and/or clinical relapses, suggests OCT to represent a useful tool to monitor disease progression and to assess neuroprotection in PMS.