The landscape of biomedical research in neuroscience has changed dramatically in recent years as a result of spectacular progress in dynamic microscopy. In this context Adaptive Optics allows in-depth imaging by correcting aberrations induced by the biological sample, the key issue being then the ability to perform an accurate and reliable wavefront sensing (WFS). We present here a limitation of modal sensorless WFS in the case of a heterogeneous medium. We then build a new method called Axially-Locked Modal Sensorless (ALMS) that exploits these heterogeneities to overcome this limitation. The new method is simulated and compared to standard modal sensorless. The simulation results show a more accurate wavefront estimation even in the case of a strongly aberrated biological media.
J. Teixeira, D. Champelovier, J-M. Conan, L. Mugnier, S. Meimon, N. Balla, S. Reichinnek, T. Tressard, R. Cossart, S. Monneret, H. Rigneault, and A. Malvache, "New sensorless wavefront estimation approach for two-photon scanning microscopy," Proc. SPIE 10073, Adaptive Optics and Wavefront Control for Biological Systems III, 1007317 (Presented at SPIE BiOS: January 30, 2017; Published: 21 February 2017); https://doi.org/10.1117/12.2250323.
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