Extended field-of-view deep brain imaging using aberration correction in GRIN microendoscopes through 3D printed polymer microlenses

Sattin, Andrea; Antonini, Andrea; Bovetti, Serena; Moretti, Claudio; Forli, Angelo; Succol, Francesca; Rajamanickam, Vijayakumar Palanisamy; Bertoncini, Andrea; Liberale, Carlo; Fellin, Tommaso

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Type

Conference Paper

Authors

Sattin, Andrea
Antonini, Andrea
Bovetti, Serena
Moretti, Claudio
Forli, Angelo
Succol, Francesca
Rajamanickam, Vijayakumar Palanisamy
Bertoncini, Andrea

Liberale, Carlo

Fellin, Tommaso

KAUST Department

Biological and Environmental Sciences and Engineering (BESE) Division
Bioscience Program
Label-Free Optical Microscopy for Biology Lab

Date

2020-05-19

Online Publication Date

2020-05-19

Print Publication Date

2020

Permanent link to this record

http://hdl.handle.net/10754/665495

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Abstract

We report the development and application of a new approach to correct aberrations in GRIN microendoscopes using 3D printed polymer microlenses. Corrected microendoscopes are validated performing functional imaging experiments in the mouse brain in vivo.

Citation

Sattin, A., Antonini, A., Bovetti, S., Moretti, C., Forli, A., Succol, F., … Fellin, T. (2020). Extended Field-of-View Deep Brain Imaging using Aberration Correction in GRIN Microendoscopes through 3D Printed Polymer Microlenses. Biophotonics Congress: Biomedical Optics 2020 (Translational, Microscopy, OCT, OTS, BRAIN). doi:10.1364/brain.2020.btu2c.6

Publisher

The Optical Society

Conference/Event name

Optics and the Brain, BRAIN 2020

ISBN

9781557528209