Single laser pulse generates dual photoacoustic signals for differential contrast photoacoustic imaging

Gao, Fei; Feng, Xiaohua; Zhang, Ruochong; Liu, Siyu; Ding, Ran; Kishor, Rahul; Zheng, Yuanjin

doi:10.1038/s41598-017-00725-4

Cited by 78 publications

(44 citation statements)

References 39 publications

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“…The pressure amplitude at the end of the laser pulse did not depend exclusively on the maximum of the first derivative as also observed by Gao et al 36. The findings of the onset and offset signal for constant pulse peak power (Fig.…”

Section: Discussionsupporting

confidence: 83%

Optoacoustic effect is responsible for laser-induced cochlear responses

Kallweit

Baumhoff

Krueger

et al. 2016

Sci Rep

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Optical stimulation of the cochlea with laser light has been suggested as an alternative to conventional treatment of sensorineural hearing loss with cochlear implants. The underlying mechanisms are controversially discussed: The stimulation can either be based on a direct excitation of neurons, or it is a result of an optoacoustic pressure wave acting on the basilar membrane. Animal studies comparing the intra-cochlear optical stimulation of hearing and deafened guinea pigs have indicated that the stimulation requires intact hair cells. Therefore, optoacoustic stimulation seems to be the underlying mechanism. The present study investigates optoacoustic characteristics using pulsed laser stimulation for in vivo experiments on hearing guinea pigs and pressure measurements in water. As a result, in vivo as well as pressure measurements showed corresponding signal shapes. The amplitude of the signal for both measurements depended on the absorption coefficient and on the maximum of the first time-derivative of laser pulse power (velocity of heat deposition). In conclusion, the pressure measurements directly demonstrated that laser light generates acoustic waves, with amplitudes suitable for stimulating the (partially) intact cochlea. These findings corroborate optoacoustic as the basic mechanism of optical intra-cochlear stimulation.

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Section: Discussionsupporting

confidence: 83%

Optoacoustic effect is responsible for laser-induced cochlear responses

Kallweit

Baumhoff

Krueger

et al. 2016

Sci Rep

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“…The abovementioned studies refer to linear PA imaging; in recent years, the application of multiple laser‐pulse irradiation to achieve nonlinear signal enhancement has attracted increasing research interest. Nonlinear PA imaging involves continuous excitation of biological tissue by employing a dual‐pulse laser with a short time delay, which can provide even more significant contrast and resolution than the commonly studied linear PA imaging by reversibly switching the absorption property, or enhancing the thermally related Gruneisen parameter (thermal expansion coefficient) . Some preliminary work about the contrast agents for nonlinear PA imaging has been reported recently .…”

Section: Nonlinear Pa‐imaging Contrast Agentsmentioning

confidence: 99%

Photoacoustic Imaging: Contrast Agents and Their Biomedical Applications

et al. 2018

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Photoacoustic (PA) imaging as a fast‐developing imaging technique has great potential in biomedical and clinical applications. It is a noninvasive imaging modality that depends on the light‐absorption coefficient of the imaged tissue and the injected PA‐imaging contrast agents. Furthermore, PA imaging provides superb contrast, super spatial resolution, and high penetrability and sensitivity to tissue functional characteristics by detecting the acoustic wave to construct PA images. In recent years, a series of PA‐imaging contrast agents are developed to improve the PA‐imaging performance in biomedical applications. Here, recent progress of PA contrast agents and their biomedical applications are outlined. PA contrast agents are classified according to their components and function, and gold nanocrystals, gold‐nanocrystal assembly, transition‐metal chalcogenides/MXene‐based nanomaterials, carbon‐based nanomaterials, other inorganic imaging agents, small organic molecules, semiconducting polymer nanoparticles, and nonlinear PA‐imaging contrast agents are discussed. The applications of PA contrast agents as biosensors (in the sensing of metal ions, pH, enzymes, temperature, hypoxia, reactive oxygen species, and reactive nitrogen species) and in bioimaging (lymph nodes, vasculature, tumors, and brain tissue) are discussed in detail. Finally, an outlook on the future research and investigation of PA‐imaging contrast agents and their significance in biomedical research is presented.

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“…[1][2][3][4][5][6][7][8][9] PA imaging is based on absorption of photons by biomolecules to thermoelastically induce ultrasonic waves. [12][13][14][15][16][17] The spectral dependence of optical absorption enables PA image contrast provided by speci¯c tissue chromophores to be selectively enhanced by tuning the laser excitation wavelength, which can provide in vivo¯ne morphology of tissue and label-free functional information such as blood oxygenation and blood°ow. PA imaging also enables multiscale high-resolution imaging of biological structures, ranging in size from organelles to organs using the same contrast.…”

Section: Introductionmentioning

confidence: 99%

Optically-excited simultaneous photoacoustic and ultrasound imaging based on a flexible gold-PDMS film

Cui

Zhang

Shi

2020

J. Innov. Opt. Health Sci.

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We constructed a flexible gold-polydimethylsiloxane (gold-PDMS) nanocomposites film with controllable thickness and light transmittance, to realize optically-excited simultaneous photoacoustic (PA) and ultrasound (US) imaging under a single laser pulse irradiation. Benefiting from the excellent thermoelastic properties, the gold-PDMS film absorbs part of the incident laser energy and produces a high-intensity US, which is used to realize US imaging. Meanwhile, the partly transmitted light is used to excite samples for PA imaging. By controlling the thickness of the gold-PDMS, we can control the center frequency in the US imaging. We experimentally analyzed the frequency of the produced US signal by the gold-PDMS film and compared it with the finite element analysis (FEA) method, where the experiments agree with the FEA results. This method is demonstrated by the experiments on phantoms and a mouse model. Our work provides a cost-effective methodology for simultaneous PA and US imaging.

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Single laser pulse generates dual photoacoustic signals for differential contrast photoacoustic imaging

Cited by 78 publications

References 39 publications

Optoacoustic effect is responsible for laser-induced cochlear responses

Optoacoustic effect is responsible for laser-induced cochlear responses

Photoacoustic Imaging: Contrast Agents and Their Biomedical Applications

Optically-excited simultaneous photoacoustic and ultrasound imaging based on a flexible gold-PDMS film

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