TY - GEN
T1 - Optical focusing in scattering media with photoacoustic wavefront shaping (PAWS)
AU - Lai, Puxiang
AU - Tay, Jian Wei
AU - Wang, Lidai
AU - Wang, Lihong V.
PY - 2014
Y1 - 2014
N2 - Controllable light delivery to the region of interest is essential to biomedical optical imaging methods like photoacoustic microscopy. It is, however, challenging beyond superficial depths in biological tissue (∼1 mm beneath human skin) due to the strong scattering of light that scrambles the photon propagation paths. Recently, optical wavefront shaping has been proposed to modulate the incident light wavefront to compensate for the scattering-induced phase distortions, and consequentially, convey light optimally to a desired location behind or inside turbid media. To reach an optimum wavefront, a searching algorithm is usually required to optimize a feedback signal. In this work, we present our latest explorations, which use photoacoustic signals as the feedback to remotely and non-invasively guide the wavefront shaping process. Our method does not require direct optical access to the target region or the invasive embedding of fluorescence probes inside turbid media. Experimentally, we have demonstrated that diffuse light can be converged to the ultrasound focus by maximizing the amplitude of photoacoustic emissions from the intended absorbing site. Moreover, we show that wavefront-shaped light focusing can enhance existing optical imaging modalities like photoacoustic microscopy, in regard to signal-to-noise ratio, imaging depth, and potentially, resolution. © 2014 SPIE.
AB - Controllable light delivery to the region of interest is essential to biomedical optical imaging methods like photoacoustic microscopy. It is, however, challenging beyond superficial depths in biological tissue (∼1 mm beneath human skin) due to the strong scattering of light that scrambles the photon propagation paths. Recently, optical wavefront shaping has been proposed to modulate the incident light wavefront to compensate for the scattering-induced phase distortions, and consequentially, convey light optimally to a desired location behind or inside turbid media. To reach an optimum wavefront, a searching algorithm is usually required to optimize a feedback signal. In this work, we present our latest explorations, which use photoacoustic signals as the feedback to remotely and non-invasively guide the wavefront shaping process. Our method does not require direct optical access to the target region or the invasive embedding of fluorescence probes inside turbid media. Experimentally, we have demonstrated that diffuse light can be converged to the ultrasound focus by maximizing the amplitude of photoacoustic emissions from the intended absorbing site. Moreover, we show that wavefront-shaped light focusing can enhance existing optical imaging modalities like photoacoustic microscopy, in regard to signal-to-noise ratio, imaging depth, and potentially, resolution. © 2014 SPIE.
KW - Grueneisen memory effect
KW - Light scattering
KW - Nonlinear photoacoustic signal
KW - Optical focusing
KW - Optical speckle
KW - Photoacoustic imaging
KW - Spatial light modulator
KW - Wavefront shaping
UR - https://www.scopus.com/pages/publications/84902105516
UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-84902105516&origin=recordpage
U2 - 10.1117/12.2036510
DO - 10.1117/12.2036510
M3 - RGC 32 - Refereed conference paper (with host publication)
SN - 9780819498564
VL - 8943
BT - Progress in Biomedical Optics and Imaging - Proceedings of SPIE
PB - SPIE
T2 - Photons Plus Ultrasound: Imaging and Sensing 2014
Y2 - 2 February 2014 through 5 February 2014
ER -