TY - JOUR
T1 - NEW ARTIFICIAL INTELLIGENCE ANALYSIS for PREDICTION of LONG-TERM VISUAL IMPROVEMENT after EPIRETINAL MEMBRANE SURGERY
AU - Crincoli, Emanuele
AU - Savastano, Maria Cristina
AU - Savastano, Alfonso
AU - Caporossi, Tomaso
AU - Bacherini, Daniela
AU - Miere, Alexandra
AU - Gambini, Gloria
AU - De Vico, Umberto
AU - Baldascino, Antonio
AU - Minnella, Angelo Maria
AU - Scupola, Andrea
AU - Damico, Guglielmo
AU - Molle, Fernando
AU - Bernardinelli, Patrizio
AU - De Filippis, Alessandro
AU - Kilian, Raphael
AU - Rizzo, Clara
AU - Ripa, Matteo
AU - Ferrara, Silvia
AU - Scampoli, Alessandra
AU - Brando, Davide
AU - Molle, Andrea
AU - Souied, Eric H.
AU - Rizzo, Stanislao
PY - 2023
Y1 - 2023
N2 - Purpose:To predict improvement of best-corrected visual acuity (BCVA) 1 year after pars plana vitrectomy for epiretinal membrane (ERM) using artificial intelligence methods on optical coherence tomography B-scan images.Methods:Four hundred and eleven (411) patients with Stage II ERM were divided in a group improvement (IM) (≥15 ETDRS letters of VA recovery) and a group no improvement (N-IM) (<15 letters) according to 1-year VA improvement after 25-G pars plana vitrectomy with internal limiting membrane peeling. Primary outcome was the creation of a deep learning classifier (DLC) based on optical coherence tomography B-scan images for prediction. Secondary outcome was assessment of the influence of various clinical and imaging predictors on BCVA improvement. Inception-ResNet-V2 was trained using standard augmentation techniques. Testing was performed on an external data set. For secondary outcome, B-scan acquisitions were analyzed by graders both before and after fibrillary change processing enhancement.Results:The overall performance of the DLC showed a sensitivity of 87.3% and a specificity of 86.2%. Regression analysis showed a difference in preoperative images prevalence of ectopic inner foveal layer, foveal detachment, ellipsoid zone interruption, cotton wool sign, unprocessed fibrillary changes (odds ratio = 2.75 [confidence interval: 2.49-2.96]), and processed fibrillary changes (odds ratio = 5.42 [confidence interval: 4.81-6.08]), whereas preoperative BCVA and central macular thickness did not differ between groups.Conclusion:The DLC showed high performances in predicting 1-year visual outcome in ERM surgery patients. Fibrillary changes should also be considered as relevant predictors.
AB - Purpose:To predict improvement of best-corrected visual acuity (BCVA) 1 year after pars plana vitrectomy for epiretinal membrane (ERM) using artificial intelligence methods on optical coherence tomography B-scan images.Methods:Four hundred and eleven (411) patients with Stage II ERM were divided in a group improvement (IM) (≥15 ETDRS letters of VA recovery) and a group no improvement (N-IM) (<15 letters) according to 1-year VA improvement after 25-G pars plana vitrectomy with internal limiting membrane peeling. Primary outcome was the creation of a deep learning classifier (DLC) based on optical coherence tomography B-scan images for prediction. Secondary outcome was assessment of the influence of various clinical and imaging predictors on BCVA improvement. Inception-ResNet-V2 was trained using standard augmentation techniques. Testing was performed on an external data set. For secondary outcome, B-scan acquisitions were analyzed by graders both before and after fibrillary change processing enhancement.Results:The overall performance of the DLC showed a sensitivity of 87.3% and a specificity of 86.2%. Regression analysis showed a difference in preoperative images prevalence of ectopic inner foveal layer, foveal detachment, ellipsoid zone interruption, cotton wool sign, unprocessed fibrillary changes (odds ratio = 2.75 [confidence interval: 2.49-2.96]), and processed fibrillary changes (odds ratio = 5.42 [confidence interval: 4.81-6.08]), whereas preoperative BCVA and central macular thickness did not differ between groups.Conclusion:The DLC showed high performances in predicting 1-year visual outcome in ERM surgery patients. Fibrillary changes should also be considered as relevant predictors.
KW - artificial intelligence
KW - deep learning
KW - epiretinal membrane
KW - fibrillary changes
KW - optical coherence tomography
KW - artificial intelligence
KW - deep learning
KW - epiretinal membrane
KW - fibrillary changes
KW - optical coherence tomography
UR - http://hdl.handle.net/10807/232090
U2 - 10.1097/IAE.0000000000003646
DO - 10.1097/IAE.0000000000003646
M3 - Article
SN - 0275-004X
VL - 43
SP - 173
EP - 181
JO - Retina
JF - Retina
ER -