Correia, CarlosBatista, AnaBarbeiro, SílviaCardoso, JoãoDomingues, José PauloHenriques, RafaelLoureiro, CustódioSantos, Mário J.Serranho, PedroBernardes, RuiMorgado, Miguel2024-11-182024-11-182023http://hdl.handle.net/10400.2/167912023 IEEE. ENBENG, 22-23 Junho de 2023, realizado no Porto, Portugal.We present the initial stages of development of a Finite Element Method-based time-dependent elastic numerical model which seeks to support the employment of our Optical Coherence Elastography system for assessing murine retinal elasticity. The current model is able to reconstruct displacement maps in both homogeneous and heterogeneous domains with errors up to a few hundredths relatively to a known exact displacement map, within 1 millisecond. The results demonstrate the robustness of the numerical algorithm under different elastic domains, and model parametrization with real Optical Coherence Elastography data is already in progress.engOptical coherence elastographyRetinaNumerical modellingFinite element methodTime-dependent elastic numerical model for Optical Coherence Elastography of the murine retinaconference object10.1109/ENBENG58165.2023.10175350