Photoacoustically guided wavefront shaping for enhanced optical focusing in scattering media

Lai, Puxiang; Wang, Lidai; Tay, Jian Wei

doi:10.1038/nphoton.2014.322

Cited by 280 publications

(248 citation statements)

References 37 publications

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“…As discussed earlier, in photoacoustic effect, transient photon energy-no matter it is ballistic or diffusive-is absorbed by tissue molecules and converted into much less scattering ultrasonic waves, which can be detected using a single or a series of transducers. The detected signal can be generally expressed by [48]:…”

Section: Photoacoustically-guided Wavefront Shaping (Paws)mentioning

confidence: 99%

“…For example, it has been demonstrated that subacoustic diffraction-limited optical focusing is possible when the detected PA signals (which are broadband) are spectrally filtered and then used as the feedback [26,45]. From the perspective of generation nonlinearity, Lai et al developed a dual-pulse excitation approach (Figure 3a), firing two consecutive, yet identical, optical pulses to generate two individual PA signals-the difference between them create a nonlinear PA response that can be used as a nonlinear feedback [48]. The hypothesis was built upon a so-called Grueneisen effect [49].…”

Section: Photoacoustically-guided Wavefront Shaping (Paws)mentioning

confidence: 99%

“…However, recently, researchers began to notice that the seemingly random scattering events and the resultant speckles are actually deterministic within a certain temporal window [37,38], and it is possible to reverse [39][40][41] or compensate for [42] the scattering-induced phase scrambling. To do so, researchers have developed several wavefront shaping (sometimes also referred to wavefront engineering) techniques, such as iterative wavefront optimization [23][24][25][26]28,[42][43][44][45][46][47][48][49][50][51], measuring the transmission matrix of the scattering medium [21,22,[52][53][54][55][56], and optical time reversal via phase conjugation [39,40,[57][58][59][60][61][62][63][64][65]. Nevertheless, the goals of these implementations are identical, i.e., to make light wavelets traveling along different optical paths interfere coherently at a region of interest (ROI) and form a bright optical spot (focus) out of the much darker background.…”

Section: Introductionmentioning

confidence: 99%

“…For that purpose, researchers have proposed injected or embedded probes, such as small optical sensors [66,67], fluorescence particles [68,69], and nonlinear beads [57], ultrasound mediation [40,58,61,70,71], as well as absorption perturbation [22,25,46,48,[72][73][74][75][76]. Among them, PA signal has been proved very attractive [22,25,28,47,48,53,55,73,74,76], as it is noninvasive, relatively deeply-penetrating, and it can pinpoint the focal spot accurately (the acoustic and optical foci overlap). Furthermore, with linear [22,25,28,53,73,74] or nonlinear [48] PA signals as the guide star, acousticand optical-diffraction limited optical focal spot can be achieved, respectively, benefiting from the nature of PA signal generation.…”

Section: Introductionmentioning

confidence: 99%

“…Among them, PA signal has been proved very attractive [22,25,28,47,48,53,55,73,74,76], as it is noninvasive, relatively deeply-penetrating, and it can pinpoint the focal spot accurately (the acoustic and optical foci overlap). Furthermore, with linear [22,25,28,53,73,74] or nonlinear [48] PA signals as the guide star, acousticand optical-diffraction limited optical focal spot can be achieved, respectively, benefiting from the nature of PA signal generation. In turn, during the process of such PA-guided wavefront optimization, the in situ optical fluence is gradually increased, and so is the strength of PA signals.…”

Section: Introductionmentioning

confidence: 99%

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Wavefront Shaping and Its Application to Enhance Photoacoustic Imaging

Lai

2017

Applied Sciences

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Abstract:Since its introduction to the field in mid-1990s, photoacoustic imaging has become a fast-developing biomedical imaging modality with many promising potentials. By converting absorbed diffused light energy into not-so-diffused ultrasonic waves, the reconstruction of the ultrasonic waves from the targeted area in photoacoustic imaging leads to a high-contrast sensing of optical absorption with ultrasonic resolution in deep tissue, overcoming the optical diffusion limit from the signal detection perspective. The generation of photoacoustic signals, however, is still throttled by the attenuation of photon flux due to the strong diffusion effect of light in tissue. Recently, optical wavefront shaping has demonstrated that multiply scattered light could be manipulated so as to refocus inside a complex medium, opening up new hope to tackle the fundamental limitation. In this paper, the principle and recent development of photoacoustic imaging and optical wavefront shaping are briefly introduced. Then we describe how photoacoustic signals can be used as a guide star for in-tissue optical focusing, and how such focusing can be exploited for further enhancing photoacoustic imaging in terms of sensitivity and penetration depth. Finally, the existing challenges and further directions towards in vivo applications are discussed.

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Section: Photoacoustically-guided Wavefront Shaping (Paws)mentioning

confidence: 99%

Section: Photoacoustically-guided Wavefront Shaping (Paws)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Wavefront Shaping and Its Application to Enhance Photoacoustic Imaging

Lai

2017

Applied Sciences

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Planar Diffractive Lenses: Fundamentals, Functionalities, and Applications

et al. 2018

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Traditional objective lenses in modern microscopy, based on the refraction of light, are restricted by the Rayleigh diffraction limit. The existing methods to overcome this limit can be categorized into near-field (e.g., scanning near-field optical microscopy, superlens, microsphere lens) and far-field (e.g., stimulated emission depletion microscopy, photoactivated localization microscopy, stochastic optical reconstruction microscopy) approaches. However, they either operate in the challenging near-field mode or there is the need to label samples in biology. Recently, through manipulation of the diffraction of light with binary masks or gradient metasurfaces, some miniaturized and planar lenses have been reported with intriguing functionalities such as ultrahigh numerical aperture, large depth of focus, and subdiffraction-limit focusing in far-field, which provides a viable solution for the label-free superresolution imaging. Here, the recent advances in planar diffractive lenses (PDLs) are reviewed from a united theoretical account on diffraction-based focusing optics, and the underlying physics of nanofocusing via constructive or destructive interference is revealed. Various approaches of realizing PDLs are introduced in terms of their unique performances and interpreted by using optical aberration theory. Furthermore, a detailed tutorial about applying these planar lenses in nanoimaging is provided, followed by an outlook regarding future development toward practical applications.

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Optically Selective Neuron Stimulation with a Wavefront Shaping‐Empowered Multimode Fiber

Zhong

Qiu

et al. 2021

Advanced Photonics Research

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Selective stimulation of neuron cells at high spatiotemporal resolution in deep brain is a major goal in neuroscience. [1][2][3] Research indicates that neurons can sense, transduce, and respond to various external stimuli such as electric, magnetic, heat, and mechanical stimuli. [4,5] Unmodified neurons may be stimulated directly to evoke action potentials with external fields, such as deep brain stimulation (DBS), [4] but such techniques lacked specificity and selectivity to individual neurons. To address that, in the so-called "optogenetics," chosen neurons can be selectively inserted with wellcharacterized light sensitive proteins (e.g., opsins) and enabled to respond to light stimulation, while other cells remain silent. [6,7] It enables precise neural manipulation with specific time sequence. [4,5,8] Such advancement of spatial resolution and specificity has made optogenetics a powerful tool in neuroscience, especially in exploring the connection between behavior and neural circuits and in treating brain diseases.However, it usually requires invasive procedures to deliver photons into deep brain regions as skull and brain tissue have strong scattering effects to visible and nearinfrared light which is often used in optogenetics. Practically, one may insert a thin optical fiber into a specific deep brain region for neuron activation, which allows for free moving animal manipulations in vivo. The output light from the fiber, no matter it is single-mode fiber (SMF) or multimode fiber (MMF), is divergent and characterized by a large illumination spot or random speckled pattern at a short distance away from the distal fiber end, which fails to meet the spatial variant of the neurons in the field of view (FOV). Although some groups reported that multitargets from a large FOV could be controlled and monitored via a tapered optical fiber, [9] single-fiber-

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Photoacoustically guided wavefront shaping for enhanced optical focusing in scattering media

Cited by 280 publications

References 37 publications

Wavefront Shaping and Its Application to Enhance Photoacoustic Imaging

Wavefront Shaping and Its Application to Enhance Photoacoustic Imaging

Planar Diffractive Lenses: Fundamentals, Functionalities, and Applications

Optically Selective Neuron Stimulation with a Wavefront Shaping‐Empowered Multimode Fiber

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