TY - GEN
T1 - Adaptive nonlinear microscopy for whole tissue imaging
AU - Müllenbroich, M. Caroline
AU - McGhee, Ewan J.
AU - Wright, Amanda J.
AU - Anderson, Kurt I.
AU - Mathieson, Keith
PY - 2013/2/22
Y1 - 2013/2/22
N2 - Nonlinear microscopy is capable of imaging biological tissue non-invasively with sub-cellular resolution in three dimensions. For efficient multiphoton signal generation, it is necessary to focus high power, ultra-fast laser pulses into a volume of femtolitres. Aberrations introduced either by the system's optical setup or the sample under investigation cause a broadening of the diffraction limited focal spot which leads to loss of image intensity and resolution. Adaptive optics provides a means to compensate for these aberrations and is capable of restoring resolution and signal strength when imaging at depth. We describe the use of a micro-electro-mechanical systems (MEMS) deformable membrane mirror in a multiphoton adaptive microscope. The aberration correction is determined in a wavefront sensorless approach by rapidly altering the mirror shape with a random search algorithm until the fluorescence or second harmonic signal intensity is improved. We demonstrate the benefits of wavefront correction in a wide-variety of samples, including urea crystals, convallaria and organotypic tissue cultures. We show how the optimization algorithm can be adjusted, for example by including a bleaching compensation, to allow the user to switch between different imaging modalities, producing a versatile approach to aberration correction.
AB - Nonlinear microscopy is capable of imaging biological tissue non-invasively with sub-cellular resolution in three dimensions. For efficient multiphoton signal generation, it is necessary to focus high power, ultra-fast laser pulses into a volume of femtolitres. Aberrations introduced either by the system's optical setup or the sample under investigation cause a broadening of the diffraction limited focal spot which leads to loss of image intensity and resolution. Adaptive optics provides a means to compensate for these aberrations and is capable of restoring resolution and signal strength when imaging at depth. We describe the use of a micro-electro-mechanical systems (MEMS) deformable membrane mirror in a multiphoton adaptive microscope. The aberration correction is determined in a wavefront sensorless approach by rapidly altering the mirror shape with a random search algorithm until the fluorescence or second harmonic signal intensity is improved. We demonstrate the benefits of wavefront correction in a wide-variety of samples, including urea crystals, convallaria and organotypic tissue cultures. We show how the optimization algorithm can be adjusted, for example by including a bleaching compensation, to allow the user to switch between different imaging modalities, producing a versatile approach to aberration correction.
KW - aberration correction
KW - adaptive optics
KW - deformable membrane mirror
KW - nonlinear microscopy
KW - SHG
KW - TPEF
UR - http://www.scopus.com/inward/record.url?scp=84878734434&partnerID=8YFLogxK
U2 - 10.1117/12.2006375
DO - 10.1117/12.2006375
M3 - Conference contribution book
AN - SCOPUS:84878734434
SN - 9780819493576
VL - 8588
T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE
BT - Multiphoton Microscopy in the Biomedical Sciences XIII
CY - Bellingham, Washington
T2 - Multiphoton Microscopy in the Biomedical Sciences XIII
Y2 - 3 February 2013 through 5 February 2013
ER -