Deep tissue photoacoustic computed tomography with a fast and compact laser system

Wang, Depeng; Wang, Yuehang; Wang, Weiran; Luo, Dandan; Chitgupi, Upendra; Geng, Jumin; Zhou, Yang; Wang, Lidai; Lovell, Jonathan F.; Xia, Jun

doi:10.1364/boe.8.000112

Cited by 57 publications

(51 citation statements)

References 49 publications

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“…[146][147][148] Recently, using hemoglobin contrast, different organs (brain, heart, liver, and kidneys) of mouse were imaged using PAT at 1064 nm. 149 The imaging system used a compact high-energy 1064-nm diode-pumped Nd:YAG laser [ Fig. 5(a)] with the following specifications: 3.2 ðLÞ × 14.0 ðWÞ × 6.5 ðHÞ cm, weight ∼1.6 kg, M 2 -factor (beam quality factor) ∼3, pulse energy ∼80 mJ, and pulse repetition rate 1 to 50 Hz, from Montfort Laser GmbH, Austria.…”

Section: Whole-body Imagingmentioning

confidence: 99%

“…12(a). 149 The system uses a compact 1064-nm laser (described in Sec. 4.2) and a bifurcated fiber bundle with circular input (1-cm diameter) and two line outputs (5-cm length) to deliver light to the arm/palm.…”

Section: Human Arm Imagingmentioning

confidence: 99%

“…169 Although the above studies have used NIR-II agents, NIR-II window has shown its potential for PAI without an exogenous agent: in vivo small animal brain imaging and whole body of small animals using blood contrast at 1064 nm. 149,150 In vivo human imaging at 1064 nm was successfully demonstrated by imaging human palm/arm, 149 and breast 36 without a contrast agent. The cross section of the monkey brain cortex with a skull thickness of ∼2 mm was imaged at 1064 nm with energy density of 50 mJ∕cm 2 .…”

Section: High-resolution Photoacoustic Imaging In Near-infrared-ii Wimentioning

confidence: 99%

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Photoacoustic imaging in the second near-infrared window: a review

2019

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Photoacoustic (PA) imaging is an emerging medical imaging modality that combines optical excitation and ultrasound detection. Because ultrasound scatters much less than light in biological tissues, PA generates high-resolution images at centimeters depth. In recent years, wavelengths in the second near-infrared (NIR-II) window (1000 to 1700 nm) have been increasingly explored due to its potential for preclinical and clinical applications. In contrast to the conventional PA imaging in the visible (400 to 700 nm) and the first NIR-I (700 to 1000 nm) window, PA imaging in the NIR-II window offers numerous advantages, including high spatial resolution, deeper penetration depth, reduced optical absorption, and tissue scattering. Moreover, the second window allows a fivefold higher light excitation energy density compared to the visible window for enhancing the imaging depth significantly. We highlight the importance of the second window for PA imaging and discuss the various NIR-II PA imaging systems and contrast agents with strong absorption in the NIR-II spectral region. Numerous applications of NIR-II PA imaging, including whole-body animal imaging and human imaging, are also discussed.

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Section: Whole-body Imagingmentioning

confidence: 99%

Section: Human Arm Imagingmentioning

confidence: 99%

Section: High-resolution Photoacoustic Imaging In Near-infrared-ii Wimentioning

confidence: 99%

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Photoacoustic imaging in the second near-infrared window: a review

2019

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“…65 Currently, pulsed laser diodes are commercially available with a hundreds-watt-level power output at near-infrared (NIR) wavelengths, and continuous-wave (CW) LEDs can cover the full visible (VIS) spectrum. [66][67][68][69][70][71][72][73][74][75][76][77] They could play a broad role in super¯cial vascular PAI, especially where the laser energy requirements are relatively modest. Although the relatively weak power represents a main disadvantage for e±cient photoacoustic e®ect, there is still substantial scope to mitigate this for deeper imaging depth by time and frequency methods.…”

Section: Introductionmentioning

confidence: 99%

Low-cost photoacoustic imaging systems based on laser diode and light-emitting diode excitation

Yao

Ding

Liu

et al. 2017

J. Innov. Opt. Health Sci.

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Photoacoustic imaging, an emerging biomedical imaging modality, holds great promise for preclinical and clinical researches. It combines the high optical contrast and high ultrasound resolution by converting laser excitation into ultrasonic emission. In order to generate photoacoustic signal e±-ciently, bulky Q-switched solid-state laser systems are most commonly used as excitation sources and hence limit its commercialization. As an alternative, the miniaturized semiconductor laser system has the advantages of being inexpensive, compact, and robust, which makes a signi¯cant e®ect on production-forming design. It is also desirable to obtain a wavelength in a wide range from visible to nearinfrared spectrum for multispectral applications. Focussing on practical aspect, this paper reviews the state-of-the-art developments of low-cost photoacoustic system with laser diode and light-emitting diode excitation source and highlights a few representative installations in the past decade.

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“…Both types of systems are commonly used in the PAT field. 13–14 For pulsed-PAT, we used a two-photon dye (AF-350) as the upconverting medium, because it responds to ~800 nm nanosecond to femtosecond laser pulses and possesses two-photon excited emission with high efficiency in the visible region. 15–16 For CW-PAT, we used lanthanide-doped upconverting nanoparticles (UCNPs), because their upconverting luminescence efficiencies are much higher under CW irradiation due to the long fluorescence lifetime of lanthanide ions (~ microsecond).…”

mentioning

confidence: 99%

Nonlinear Photoacoustic Imaging by in Situ Multiphoton Upconversion and Energy Transfer

et al. 2017

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In recent years, photoacoustic tomography (PAT) is increasingly used in biomedical research, as it allows for direct visualization of optical absorption in deep tissue. In addition to vascular and hemodynamic imaging using endogenous contrasts, PAT is also capable of imaging neural and molecular dynamics with extrinsic contrasts. While near-infrared (NIR)-absorbing contrasts are preferred for deep tissue imaging, compared to visible-light-absorbing contrasts, they are much harder to design and synthesize with good environmental stability. We introduce here a new PAT mode which utilizes nonlinear multiphoton upconversion of NIR light in situ to visible light, thus exciting locally a dye that can generate strong photoacoustic signal. This approach allows to take advantage of a large library of visible-light-absorbing dyes that can enable functional imaging, such as imaging of voltage, oxygen, pH, and ion channel activities. Two types of upconversion materials are utilized in this work: 1) a two-photon absorbing and emitting dye that is efficiently excited by NIR nanosecond laser pulses to enable pulsed laser-based PAT (pulsed-PAT); and 2) rare-earth containing inorganic nanocrystals that absorb continuous-wave (CW) NIR light by sequential multiphoton absorption through real intermediate states to enable intensity-modulated CW laser-based PAT (CW-PAT). Since both cases produce highly localized nonlinear photoacoustic signal, which has very weak scattering in tissue, we can achieve high contrast 3-D volume imaging of deep tissues. In this study, we validated the principle of our approach in different PAT modes and successfully detected enhanced photoacoustic signals from a visible-light-absorbing dye embedded deep in tissue. With vast variety of functionalized organic dyes operating in the visible range, our mode of nonlinear photoacoustic imaging will find great applications in preclinical and clinical researches.

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Deep tissue photoacoustic computed tomography with a fast and compact laser system

Cited by 57 publications

References 49 publications

Photoacoustic imaging in the second near-infrared window: a review

Photoacoustic imaging in the second near-infrared window: a review

Low-cost photoacoustic imaging systems based on laser diode and light-emitting diode excitation

Nonlinear Photoacoustic Imaging by in Situ Multiphoton Upconversion and Energy Transfer

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