ライフサイエンスコーパス: photoacoustic

1 Fluorescence live imaging, photothermal, and photoacoustic analysis were utilized to examine nanopart

2 extinction coefficients were measured using photoacoustic and cavity ring-down spectroscopy techniqu

3 n in solid tumors, which enabled noninvasive photoacoustic and fluorescence imaging of H(2)O(2).

4 Applying hybrid photoacoustic and fluorescence microscopy, we simultaneo

5 the body as AuNR@PEG after therapy; enhanced photoacoustic and photo thermal properties; and high pho

6 Uniquely, the nanorods are intrinsically photoacoustic and photothermal, enabling multi-imaging d

7 se limitations, we developed a dual-modality photoacoustic and ultrasonic imaging system to noninvasi

8 The customizable photoacoustic and ultrasound imaging system is intended

9 Here, we present a real-time clinical photoacoustic and ultrasound imaging system which consis

10 minescence (for tumor proliferation status), Photoacoustic and Ultrasound imaging.

11 The NCs additionally possessed photoacoustic and X-ray contrast imaging abilities that

12 ging modalities: near-infrared fluorescence, photoacoustic, and magnetic resonance imaging.

13 l imaging, sensing, stretchable electronics, photoacoustics, and electrochemistry.

14 presented catheter design will benefit other photoacoustic applications such as needle-based intramus

15 articles with high photostability and strong photoacoustic brightness are designed and synthesized, w

16 ective and cell-permeable calcium sensor for photoacoustics (CaSPA), a versatile imaging technique th

17 Here, we present a photoacoustic catheter probe design on the basis of coll

18 with an optical chopper before entering the photoacoustic cell.

19 new photoacoustic microscopic method, termed photoacoustic computed microscopy (PACM) that combines c

20 resolution at depths approaching 10 mm using photoacoustic computed tomography, and we imaged individ

21 Therefore, MNP can serve not only as a photoacoustic contrast agent, but also as a nanoplatform

22 derstanding the targeted design of molecular photoacoustic contrast agents (MPACs) is presented.

23 applications of photoacoustic imaging, novel photoacoustic contrast agents are highly desired for mol

24 biochemical characteristics of the existing photoacoustic contrast agents, highlighting key applicat

25 , engineered from bacterial phytochromes, as photoacoustic contrast agents.

26 biochemical analysis can be performed using photoacoustic contrast nanoagents that have been designe

27 ry to tumours and generate 4.5 times greater photoacoustic contrast.

28 rves also as a photothermal (and potentially photoacoustic) contrast agent, allowing for photothermal

29 he breadth of clinical applications in which photoacoustics could play a valuable role include: nonin

30 l results and numerical models in support of photoacoustic coupling as the mechanism.

31 Simulated photoacoustic data from synthetic, mouse-brain, lung, an

32 signals, and secondly, record ultrasound and photoacoustic data from the same animal.

33 py enhanced in an optical cavity (CERS), and photoacoustic detection in a differential Helmholtz reso

34 Since photoacoustic detection is commonly contact based, a new

35 of the remote speckle sensing technique for photoacoustic detection is demonstrated.

36 This study not only reveals the sensitive photoacoustic detection of RONS but also highlights the

37 xcitation with single-element depth-resolved photoacoustic detection.

38 Photoacoustic Doppler velocimetry provides a major oppor

39 Here we show a new single-wavelength photoacoustic dynamic contrast-enhanced imaging techniqu

40 MSOT is based on the photoacoustic effect and thus not limited by photon scat

41 optoacoustic imaging takes advantage of the photoacoustic effect to generate high-contrast, high-res

42 ion directly stimulates the SGNs or evokes a photoacoustic effect.

43 ate) absorption contributes to enhancing the photoacoustic emission of the curcuminBF2 and bis-styryl

44 We report here the design of the photoacoustic experiments, the spectroscopy of glucose i

45 over 300 h of in-motion measurements using a photoacoustic extinctiometer.

46 Here we address this problem using photoacoustic feedback for wavefront optimization.

47 melanoma cells, we developed dual-wavelength photoacoustic flow cytography coupled with a nanosecond-

48 stream as the basis for new super-resolution photoacoustic flow cytometry in vivo.

49 To this end, we developed single-RBC photoacoustic flowoxigraphy (FOG), which can image oxyge

50 and enable trimodal gut contrast imaging via photoacoustic, fluorescence, and positron emission tomog

51 ng mice, fluorescent (from DiR) and enhanced photoacoustic (from DLPNPs) signals were found in tumor

52 work could provide further understanding of photoacoustic generation and a simple strategy for incre

53 The photoacoustic hypothesis provides an alternative explana

54 Ten photoacoustic images acquired with optical wavelengths s

55 Spectral photoacoustic images were acquired of the placenta of no

56 Coregistered US and photoacoustic images were acquired spanning volumes cont

57 was translated into robust signal changes in photoacoustic images.

58 otential of non-invasive imaging approaches (photoacoustic imaging (PAI) and magnetic resonance imagi

59 Photoacoustic imaging (PAI) combines laser technology wi

60 Photoacoustic imaging (PAI) has the potential for real-t

61 Photoacoustic imaging (PAI) has ushered in a new era of

62 (CyFaP) salt dye and used for high contrast photoacoustic imaging (PAI) in the second near-infrared

63 Photoacoustic imaging (PAI) is an attractive imaging mod

64 Photoacoustic imaging (PAI) is an emerging tool that bri

65 1000-1700 nm) fluorescence imaging (FI) and photoacoustic imaging (PAI) with the ultimate goal of im

66 ging (MRI), magnetic particle imaging (MPI), photoacoustic imaging (PAI), and image-guided drug deliv

67 id-liquid-gas triphase interface system, for photoacoustic imaging (PAI)-guided photothermal therapy

68 , pH sensing nanoprobes and multi-wavelength photoacoustic imaging (PAI).

69 great promise as contrast agents for in vivo photoacoustic imaging (PAI).

70 Se8 nanoplates are successfully utilized for photoacoustic imaging (PAI)/magnetic resonance imaging (

71 o photogenerate singlet oxygen, or to act as photoacoustic imaging agents within the optical window o

72 the probing depths were measured with novel photoacoustic imaging and a Williams periodontal probe.

73 ings" are useful both as contrast agents for photoacoustic imaging and as light-activated drug-delive

74 -based in vivo pH mapping method by coupling photoacoustic imaging and pH-responsive modified nanopar

75 the mesopourous silica shell to enable both photoacoustic imaging and photothermal therapy.

76 cence imaging on the one hand and 808 nm for photoacoustic imaging and PTT with high photothermal con

77 The PMCS allow infrared and photoacoustic imaging and synergetic photothermal therap

78 ng for nanobubble-amplified photothermal and photoacoustic imaging and therapy.

79 The photoacoustic imaging approach also offered 0.01-mm prec

80 Fluorescence and photoacoustic imaging are cost-effective imaging modalit

81 d APC-1 and APC-2 explicitly for ratiometric photoacoustic imaging by using an aza-BODIPY dye scaffol

82 ii) multispectral optoacoustic tomography, a photoacoustic imaging device that directly visualises th

83 Monitoring by photoacoustic imaging during the treatments revealed tha

84 bsorbing small molecule (CyBA) and LED-based photoacoustic imaging equipment.

85 Photoacoustic imaging for in vivo quantification of plac

86 This report is the first to use photoacoustic imaging for probing depth measurements wit

87 Photoacoustic imaging has attracted interest for its cap

88 Photoacoustic imaging has evolved into a clinically tran

89 Photoacoustic imaging has matured over the years and is

90 LED-based photoacoustic imaging has practical value in that it is

91 Molecular photoacoustic imaging has shown great potential in medic

92 Photoacoustic imaging has the potential to fill this gap

93 Photoacoustic imaging holds great promise for the visual

94 Photoacoustic imaging imparts the ability to distinguish

95 ence, bioluminescence, chemiluminescence and photoacoustic imaging in living animals.

96 This also allowed dual-modality photoacoustic imaging in the second near-infrared (NIR)

97 Photoacoustic imaging is an emerging modality for in viv

98 In this review, the current state of photoacoustic imaging is presented, including techniques

99 Spectrally resolved photoacoustic imaging is promising for label-free imagin

100 nstrated a in vivo label free laser-scanning photoacoustic imaging modality featuring high frame rate

101 icles are reported as an efficient agent for photoacoustic imaging of deep brain tumors in living mic

102 Intravascular photoacoustic imaging of lipid-laden atherosclerotic pla

103 ly-encoded probes of choice for simultaneous photoacoustic imaging of several tissues or processes in

104 able toxicity-near-infrared fluorescence and photoacoustic imaging of the tumours and a reduction in

105 accumulation, and superior fluorescence and photoacoustic imaging properties.

106 Recently available photoacoustic imaging provides real-time evaluation of v

107 aging in terms of detection sensitivity with photoacoustic imaging relative to blood oxygenation leve

108 ADSCs were tracked using bioluminescence and photoacoustic imaging serially over 7 days.

109 In vivo fluorescence and photoacoustic imaging studies highlight the ability of t

110 Ts), a contrast agent, in combination with a photoacoustic imaging system to identify the locations o

111 Several photoacoustic imaging systems have been commercialized r

112 ing, nuclear medicine imaging, MRI, and even photoacoustic imaging techniques.

113 ed high-density microwell array and by using photoacoustic imaging to measure the haemoglobin oxygen

114 ap the release of Dox from Dox@PEG-HAuNS and photoacoustic imaging to monitor the tumor temperature a

115 ned contrast-enhanced ultrasound method with photoacoustic imaging to visualize blood flow patterns i

116 brid ultrasound-optical devices ranging from photoacoustic imaging transducers to transparent actuato

117 k establishes the foundation for integrating photoacoustic imaging with modern brain research.

118 scent/magnetic resonance/computed tomography/photoacoustic imaging) and theranostic (concurrent diagn

119 -coupled non-destructive ultrasound testing, photoacoustic imaging, and remote sensing.

120 bacterial phytochrome for use in multiscale photoacoustic imaging, BphP1, with the most red-shifted

121 Photoacoustic imaging, in the form of volumetric multisp

122 ote preclinical and clinical applications of photoacoustic imaging, novel photoacoustic contrast agen

123 (photothermal therapy, PTT) or sound energy (photoacoustic imaging, PAI) has been intensively investi

124 In photoacoustic imaging, the second near-infrared (NIR-II)

125 In photoacoustic imaging, tissue is optically excited to pr

126 nthesis of a targeted, activatable probe for photoacoustic imaging, which is responsive to one of the

127 enes were prepared to achieve a fluorescence/photoacoustic imaging-guided combination photo/gene ther

128 nct product, facilitating identification via photoacoustic imaging.

129 be 1 (HyP-1), a hypoxia-responsive agent for photoacoustic imaging.

130 h larval brain via combined fluorescence and photoacoustic imaging.

131 is critical to catheter-based intravascular photoacoustic imaging.

132 measured by contrast-enhanced ultrasound and photoacoustic imaging.

133 could enable high-speed spectrally resolved photoacoustic imaging.

134 ption, and provide good optical contrast for photoacoustic imaging.

135 rface functionalization for fluorescence and photoacoustic imaging.

136 ygenation during preeclampsia using spectral photoacoustic imaging.

137 eir thermal stability, leading to unreliable photoacoustic imaging.

138 200 nm), making them suitable as tracers for photoacoustic imaging.

139 but also highlights the utility of LED-based photoacoustic imaging.

140 for external ultrasound coupling medium for photoacoustic imaging.

141 Optoacoustic (photoacoustic) imaging has seen marked advances in detec

142 cumferential-Intravascular-Radioluminescence-Photoacoustic-Imaging (CIRPI) system in vivo to enable d

143 the well-designed M-NS can achieve effective photoacoustic-imaging-guided synergistic starvation-enha

144 multiphoton process, rather than thermal- or photoacoustic-induced desorption.

145 An intravascular photoacoustic (IVPA) catheter is considered a promising

146 y a carbon black/polydimethylsiloxane (PDMS)-photoacoustic lens, were introduced to trigger the drug

147 rms ranging from fluorescence, luminescence, photoacoustic, magnetic resonance, and positron emission

148 mass basis, permitting whole-body lymph-node photoacoustic mapping in living mice at a low systemic i

149 This approach enables a photoacoustic measurement at thousands of wavelengths si

150 problem by using dual-comb spectroscopy for photoacoustic measurements.

151 cterized using absorption, fluorescence, and photoacoustic measurements; upon addition of pathophysio

152 In this paper, based on the two-photon photoacoustic mechanism, we demonstrated a in vivo label

153 ve mapping of microvascular blood flow using photoacoustic methods.

154 Here we describe a new photoacoustic microscopic method, termed photoacoustic c

155 Here we demonstrate microtomy-assisted photoacoustic microscopy (mPAM) of mouse brains and othe

156 Optical-resolution photoacoustic microscopy (OR-PAM) is an imaging modality

157 tical biopsy," using high-optical-resolution photoacoustic microscopy (OR-PAM) to quantify the microv

158 Multimodal imaging with photoacoustic microscopy (PAM) and optical coherence tom

159 Joint high-resolution multimodal photoacoustic microscopy (PAM) and optical coherence tom

160 We present fast functional photoacoustic microscopy (PAM) for three-dimensional hig

161 either optical coherence tomography (OCT) or photoacoustic microscopy (PAM) has been independently co

162 Photoacoustic microscopy (PAM) images the ocular vascula

163 Photoacoustic microscopy (PAM) is emerging as a powerful

164 Photoacoustic microscopy (PAM) is uniquely positioned fo

165 ss volumetric spatially invariant resolution photoacoustic microscopy (SIR-PAM).

166 perspectives for PAM in biomedical sciences.Photoacoustic microscopy allows for label-free 3D in viv

167 Here, we show that single-cell photoacoustic microscopy can reach throughputs of approx

168 d over time using confocal microscopy, while photoacoustic microscopy enables dynamic measurement of

169 Using this usCCW, we demonstrate photoacoustic microscopy of cortical vascular network in

170 High-throughput single-cell photoacoustic microscopy of oxygen consumption rates sho

171 t, for the first time, the use of multiscale photoacoustic microscopy to non-invasively monitor the d

172 ardless of the most advanced high-resolution photoacoustic microscopy, sub-femtoliter spatial resolut

173 ion resolution of approximately 140 nm using photoacoustic microscopy.

174 Photoacoustic molecular imaging is an emerging and promi

175 hese findings not only provide a ratiometric photoacoustic molecular imaging probe for the detection

176 To fully utilize this potential, photoacoustic molecular imaging probes have to be develo

177 , but also provides a tool for spectroscopic photoacoustic molecular imaging.

178 ticles as a new class of contrast agents for photoacoustic molecular imaging.

179 s to be an ideal nanoplatform for developing photoacoustic molecular probes.

180 We combined photoacoustic ophthalmoscopy (PAOM) with spectral domain

181 esent a near-infrared virtual intraoperative photoacoustic optical coherence tomography (NIR-VISPAOCT

182 re we extend this technique to ion-selective photoacoustic optodes (ISPAOs) that serve at the same ti

183 as IV injected via tail vein 1-hour prior to photoacoustic (PA) and fluorescence in vivo imaging by e

184 pplied as imaging agents for in vivo bimodal photoacoustic (PA) and magnetic resonance (MR) imaging o

185 gold nanoparticles (AuNPs), possessing both photoacoustic (PA) and photothermal (PT) properties.

186 e potassium nanosensor (NS) aimed at in vivo photoacoustic (PA) chemical imaging of the extracellular

187 s a Raman probe to detect cancer cells and a photoacoustic (PA) contrast agent for imaging-guided can

188 cs for near-infrared fluorescence (NIRF) and photoacoustic (PA) dual-modal imaging-guided synergistic

189 ein biomarkers based on the plasmon-enhanced photoacoustic (PA) effect.

190 Photoacoustic (PA) imaging as a fast-developing imaging

191 Photoacoustic (PA) imaging emerged as an alternative to

192 propose a new technique that combines US and photoacoustic (PA) imaging for concurrent ablation fiber

193 Ns) are investigated as a contrast agent for photoacoustic (PA) imaging in the second near-infrared (

194 er excitation, we performed both optical and photoacoustic (PA) imaging in vitro and in vivo.

195 Photoacoustic (PA) imaging is continuing to be applied f

196 g simultaneous real-time ultrasound (US) and photoacoustic (PA) imaging of human peripheral joints, w

197 mic contrast-enhanced ultrasound (DCEUS) and photoacoustic (PA) imaging serve as promising candidates

198 region leads to a much higher efficiency in photoacoustic (PA) imaging than for non-chain vesicles.

199 Photoacoustic (PA) imaging uses the intrinsic characteri

200 he well-defined Au(25) (SG)(18) nanocluster, photoacoustic (PA) imaging was used to visualize its tra

201 ibe the photophysical properties involved in photoacoustic (PA) measurements and present a detailed a

202 NIR-II photoacoustic (PA) molecular imaging (PMI) is emerging a

203 Different configurations of photoacoustic (PA) setups for the online-measurement of

204 By generating photoacoustic (PA) signals using simultaneous and time-d

205 visible and near-IR (500 to 840 nm) using a photoacoustic (PA) spectrometer and a pulsed supercontin

206 ptical information at ultrasonic resolution, photoacoustic (PA) technique could provide highly sensit

207 agent (denoted as CDPGM) is developed for MR/photoacoustic (PA)/positron emission tomography (PET) mu

208 itron-emission tomography/magnetic resonance/photoacoustic/photothermal multimodal-imaging-guided can

209 D GeQDs-based PTAs were used in fluorescence/photoacoustic/photothermal-imaging-guided hyperpyrexia a

210 theranostic platform for magnetic resonance/photoacoustic/positron emission tomography multimodal im

211 pment of the first near-infrared ratiometric photoacoustic probe for in vivo real-time imaging of rea

212 ic acid can serve as molecular high-contrast photoacoustic probes for single-cell diagnostics and as

213 ch arena owing to a lack of analyte-specific photoacoustic probes.

214 The fluorescent and photoacoustic properties of a fluorophore-tagged condens

215 ing ability to drugs and ions, and intrinsic photoacoustic properties, can serve as an efficient endo

216 rticle (MNP) was developed and showed unique photoacoustic property and natural binding ability with

217 waves of a single frequency, interference of photoacoustic pulses is often overlooked because of thei

218 ermore, non-contact detection of air-coupled photoacoustic pulses optically generated from a 200 nm t

219 Here, we study cancellation of two symmetric photoacoustic pulses radiated in the opposite direction

220 photon emission computed tomography (SPECT), photoacoustic, Raman imaging, etc.) and cargo (chemo/gen

221 he nanohybrids generate transient ultrasharp photoacoustic resonances directly in the bloodstream as

222 egrees C, which is sufficient for generating photoacoustic responses that can drive particles into th

223 describe molecular imaging with an LED-based photoacoustic scanner.

224 To this end, optoacoustic (photoacoustic) sensing and imaging have demonstrated the

225 Communication, we develope a chemoselective photoacoustic sensor (LP-hCy7) composed of the liposome

226 In this work, we describe a cellulose-based photoacoustic sensor for heparin.

227 = 0.01) and increased oxyhemoglobin-weighted photoacoustic signal (n = 9, P < 0.01).

228 esulted in reduced total hemoglobin-weighted photoacoustic signal (n = 9, P = 0.01) and increased oxy

229 The ratiometric photoacoustic signal (PA860/PA690) is noticeably increas

230 eration and a simple strategy for increasing photoacoustic signal amplitudes.

231 To optimize for Ca(2+)-dependent photoacoustic signal changes, we synthesized a selective

232 e mitigated by high-pass filtering to select photoacoustic signal components associated with high het

233 d and synthesized, which results in 5.3-fold photoacoustic signal enhancement in tumor xenografts aft

234 An in vivo murine drug release showed a photoacoustic signal enhancement of up to 649 % after 10

235 Further, the photoacoustic signal from a circulating melanoma cell im

236 CyBA produces increasing photoacoustic signal in response to peroxynitrite (ONOO(

237 OO(-)) and hydrogen peroxide (H(2)O(2)) with photoacoustic signal increases of 3.54 and 4.23-fold at

238 retical and numerical analysis, showing that photoacoustic signal is not only proportional to the opt

239 mally stable and generate 3.5 times stronger photoacoustic signal than their absorption-matched large

240 The photoacoustic signal was also validated against the cumu

241 ser light energy of 80 nJ was used to induce photoacoustic signal, which is approximately half the en

242 ed into an accompanying decrease of the peak photoacoustic signal.

243 release of 40.6 % and a 670-fold increase in photoacoustic signal.

244 xidized to produce a concentration-dependent photoacoustic signal.

245 elucidating its efficiency for optoacoustic (photoacoustic) signal generation and examining the in vi

246 ns, iRFP670 and iRFP720 demonstrate stronger photoacoustic signals at longer wavelengths, and can be

247 a proof-of-concept demonstration, we measure photoacoustic signals from polymer films.

248 t agent can generate up to 30 times stronger photoacoustic signals than the concentration-matched ino

249 rable photothermal and surprisingly a higher photoacoustic signals, compared to a plasmonic gold nano

250 luorescence, chemiluminescence, afterglow or photoacoustic signals, enabling deep-tissue ultrasensiti

251 by activated magnetic resonance/fluorescence/photoacoustic signals.

252 ated in the opposite direction from the same photoacoustic sources near a free surface.

253 n the use of ultrasound-guided spectroscopic photoacoustic (sPA) imaging of molecularly activated pla

254 rescence and red-shift of the absorption and photoacoustic spectra were observed.

255 possess high structural flexibility, narrow photoacoustic spectral profiles and strong resistance to

256 Spectra were measured in situ using a photoacoustic spectrometer and step-scanning a supercont

257 g the signal-to-noise ratio of the dual-comb photoacoustic spectrometer could enable high-speed spect

258 ambda = 500 to 840 nm were collected using a photoacoustic spectrometer coupled to a supercontinuum l

259 particle mass analyzer, cavity ring-down and photoacoustic spectrometers, and a condensation particle

260 A novel photoacoustic spectrophotometer (PAS) for the measuremen

261 An off-resonance broadband photoacoustic spectroscopy (PAS) technique with a superc

262 Quartz-enhanced photoacoustic spectroscopy (QEPAS) is a sensitive gas de

263 The combination of photoacoustic spectroscopy and gas chromatography offers

264 In addition, photoacoustic spectroscopy and X-ray diffraction, with t

265 Cantilever-enhanced photoacoustic spectroscopy coupled with gas chromatograp

266 Here we use three-pulse photoacoustic spectroscopy to investigate the damping of

267 using a novel technique called "all-optical photoacoustic spectroscopy" (AOPAS).

268 ction of nanogram quantity of analytes using photoacoustic spectroscopy, can be readily exploited in

269 Building on conventional pump-probe photoacoustic spectroscopy, we introduce an additional l

270 orce microscopy in conjunction with infrared photoacoustic spectroscopy.

271 online simultaneously with high-sensitivity photoacoustic spectroscopy.

272 ers performing both clinical and preclinical photoacoustic studies.

273 decrease is <2% with the low-power LED-based photoacoustic system and the same radiant exposure time.

274 Non-invasive, non-ionizing photoacoustic techniques were used to visualize nanonap

275 Photoacoustic tomography (PAT) can offer structural, fun

276 Photoacoustic tomography (PAT) is a non-ionizing imaging

277 Photoacoustic tomography (PAT) is an emerging technique

278 Photoacoustic tomography (PAT) of genetically encoded pr

279 quely positioned to provide such benefits is photoacoustic tomography (PAT), a sensitive modality for

280 ircumferential radioluminescence imaging and photoacoustic tomography (PAT).

281 Photoacoustic tomography and blood draws were performed

282 Using spectroscopic photoacoustic tomography at isosbestic wavelengths, we c

283 Although photoacoustic tomography breaks this limit by exciting t

284 study was to assess the potential of in vivo photoacoustic tomography for direct functional measureme

285 Photoacoustic tomography has emerged as a promising alte

286 se studies show that functional connectivity photoacoustic tomography is a promising, noninvasive tec

287 Photoacoustic tomography is a scalable imaging technique

288 Photoacoustic tomography is able to evaluate both vessel

289 ick ex vivo rat brain tissue, we demonstrate photoacoustic tomography of cell membrane voltage respon

290 ith angiography extension and an all optical photoacoustic tomography system, we can resolve in 3D th

291 tion, we developed a functional connectivity photoacoustic tomography system, which allows noninvasiv

292 stigated peak peptide uptake in tumors using photoacoustic tomography.

293 puted tomography, Cerenkov luminescence, and photoacoustic tomography.

294 Here, we used photoacoustic ultrasound for high-spatial resolution ima

295 Intravascular photoacoustic-ultrasound (IVPA-US) imaging is an emergin

296 cation, we report the first demonstration of photoacoustic voltage response imaging in both in vitro

297 ise interpolation governed by the physics of photoacoustic wave propagation and then uses a convoluti

298 d emits an ultrasonic pressure wave called a photoacoustic wave.

299 f the ultrasound transducer to the generated photoacoustic waves with an evolutionary competition amo

300 Optical and photoacoustic Z-scan spectroscopy was used to identify h