TY - JOUR
T1 - Retinal layer segmentation in multiple sclerosis
T2 - a systematic review and meta-analysis
AU - ERN-EYE IMSVISUAL
AU - Petzold, Axel
AU - Balcer, Laura J.
AU - Calabresi, Peter A.
AU - Costello, Fiona
AU - Frohman, Teresa C.
AU - Frohman, Elliot M.
AU - Martinez-Lapiscina, Elena H.
AU - Green, Ari
AU - Kardon, Randy
AU - Outteryck, Olivier
AU - Paul, Friedemann
AU - Schippling, Sven
AU - Vermersch, Patrik
AU - Villoslada, Pablo
AU - Aktas, Orhan
AU - Albrecht, Philipp
AU - Ashworth, Jane
AU - Asgari, Nasrin
AU - Balcer, Laura
AU - Balk, Lisanne
AU - Black, Graeme
AU - Boehringer, Daniel
AU - Behbehani, Raed
AU - Benson, Leslie
AU - Bermel, Robert
AU - Bernard, Jacqueline
AU - Brandt, Alexander
AU - Burton, Jodie
AU - Calabresi, Peter
AU - Calkwood, Jonathan
AU - Cordano, Christian
AU - Costello, Fiona
AU - Courtney, Ardith
AU - Cruz-Herranz, Andrés
AU - Diem, Ricarda
AU - Daly, Avril
AU - Dollfus, Helene
AU - Fasser, Christina
AU - Finke, Carsten
AU - Frederiksen, Jette
AU - Frohman, Elliot
AU - Frohman, Teresa
AU - Garcia-Martin, Elenaw
AU - Suárez, Inés González
AU - Pihl-Jensen, Gorm
AU - Graves, Jennifer
AU - Green, Ari
AU - Havla, Joachim
AU - Hemmer, Bernhard
AU - Petzold, Axel
PY - 2017/10/1
Y1 - 2017/10/1
N2 - Background Structural retinal imaging biomarkers are important for early recognition and monitoring of inflammation and neurodegeneration in multiple sclerosis. With the introduction of spectral domain optical coherence tomography (SD-OCT), supervised automated segmentation of individual retinal layers is possible. We aimed to investigate which retinal layers show atrophy associated with neurodegeneration in multiple sclerosis when measured with SD-OCT. Methods In this systematic review and meta-analysis, we searched for studies in which SD-OCT was used to look at the retina in people with multiple sclerosis with or without optic neuritis in PubMed, Web of Science, and Google Scholar between Nov 22, 1991, and April 19, 2016. Data were taken from cross-sectional cohorts and from one timepoint from longitudinal studies (at least 3 months after onset in studies of optic neuritis). We classified data on eyes into healthy controls, multiple-sclerosis-associated optic neuritis (MSON), and multiple sclerosis without optic neuritis (MSNON). We assessed thickness of the retinal layers and we rated individual layer segmentation performance by random effects meta-analysis for MSON eyes versus control eyes, MSNON eyes versus control eyes, and MSNON eyes versus MSON eyes. We excluded relevant sources of bias by funnel plots. Findings Of 25 497 records identified, 110 articles were eligible and 40 reported data (in total 5776 eyes from patients with multiple sclerosis [1667 MSON eyes and 4109 MSNON eyes] and 1697 eyes from healthy controls) that met published OCT quality control criteria and were suitable for meta-analysis. Compared with control eyes, the peripapillary retinal nerve fibre layer (RNFL) showed thinning in MSON eyes (mean difference −20·10 μm, 95% CI −22·76 to −17·44; p<0·0001) and in MSNON eyes (–7·41 μm, −8·98 to −5·83; p<0·0001). The macula showed RNFL thinning of −6·18 μm (–8·07 to −4·28; p<0·0001) in MSON eyes and −2·15 μm (–3·15 to −1·15; p<0·0001) in MSNON eyes compared with control eyes. Atrophy of the macular ganglion cell layer and inner plexiform layer (GCIPL) was −16·42 μm (–19·23 to −13·60; p<0·0001) for MSON eyes and −6·31 μm (–7·75 to −4·87; p<0·0001) for MSNON eyes compared with control eyes. A small degree of inner nuclear layer (INL) thickening occurred in MSON eyes compared with control eyes (0·77 μm, 0·25 to 1·28; p=0·003). We found no statistical difference in the thickness of the combined outer nuclear layer and outer plexiform layer when we compared MSNON or MSON eyes with control eyes, but we found a small degree of thickening of the combined layer when we compared MSON eyes with MSNON eyes (1·21 μm, 0·24 to 2·19; p=0·01). Interpretation The largest and most robust differences between the eyes of people with multiple sclerosis and control eyes were found in the peripapillary RNFL and macular GCIPL. Inflammatory disease activity might be captured by the INL. Because of the consistency, robustness, and large effect size, we recommend inclusion of the peripapillary RNFL and macular GCIPL for diagnosis, monitoring, and research. Funding None.
AB - Background Structural retinal imaging biomarkers are important for early recognition and monitoring of inflammation and neurodegeneration in multiple sclerosis. With the introduction of spectral domain optical coherence tomography (SD-OCT), supervised automated segmentation of individual retinal layers is possible. We aimed to investigate which retinal layers show atrophy associated with neurodegeneration in multiple sclerosis when measured with SD-OCT. Methods In this systematic review and meta-analysis, we searched for studies in which SD-OCT was used to look at the retina in people with multiple sclerosis with or without optic neuritis in PubMed, Web of Science, and Google Scholar between Nov 22, 1991, and April 19, 2016. Data were taken from cross-sectional cohorts and from one timepoint from longitudinal studies (at least 3 months after onset in studies of optic neuritis). We classified data on eyes into healthy controls, multiple-sclerosis-associated optic neuritis (MSON), and multiple sclerosis without optic neuritis (MSNON). We assessed thickness of the retinal layers and we rated individual layer segmentation performance by random effects meta-analysis for MSON eyes versus control eyes, MSNON eyes versus control eyes, and MSNON eyes versus MSON eyes. We excluded relevant sources of bias by funnel plots. Findings Of 25 497 records identified, 110 articles were eligible and 40 reported data (in total 5776 eyes from patients with multiple sclerosis [1667 MSON eyes and 4109 MSNON eyes] and 1697 eyes from healthy controls) that met published OCT quality control criteria and were suitable for meta-analysis. Compared with control eyes, the peripapillary retinal nerve fibre layer (RNFL) showed thinning in MSON eyes (mean difference −20·10 μm, 95% CI −22·76 to −17·44; p<0·0001) and in MSNON eyes (–7·41 μm, −8·98 to −5·83; p<0·0001). The macula showed RNFL thinning of −6·18 μm (–8·07 to −4·28; p<0·0001) in MSON eyes and −2·15 μm (–3·15 to −1·15; p<0·0001) in MSNON eyes compared with control eyes. Atrophy of the macular ganglion cell layer and inner plexiform layer (GCIPL) was −16·42 μm (–19·23 to −13·60; p<0·0001) for MSON eyes and −6·31 μm (–7·75 to −4·87; p<0·0001) for MSNON eyes compared with control eyes. A small degree of inner nuclear layer (INL) thickening occurred in MSON eyes compared with control eyes (0·77 μm, 0·25 to 1·28; p=0·003). We found no statistical difference in the thickness of the combined outer nuclear layer and outer plexiform layer when we compared MSNON or MSON eyes with control eyes, but we found a small degree of thickening of the combined layer when we compared MSON eyes with MSNON eyes (1·21 μm, 0·24 to 2·19; p=0·01). Interpretation The largest and most robust differences between the eyes of people with multiple sclerosis and control eyes were found in the peripapillary RNFL and macular GCIPL. Inflammatory disease activity might be captured by the INL. Because of the consistency, robustness, and large effect size, we recommend inclusion of the peripapillary RNFL and macular GCIPL for diagnosis, monitoring, and research. Funding None.
UR - http://www.scopus.com/inward/record.url?scp=85029184210&partnerID=8YFLogxK
U2 - https://doi.org/10.1016/S1474-4422(17)30278-8
DO - https://doi.org/10.1016/S1474-4422(17)30278-8
M3 - Article
C2 - 28920886
SN - 1474-4422
VL - 16
SP - 797
EP - 812
JO - The Lancet Neurology
JF - The Lancet Neurology
IS - 10
ER -