Simultaneous in vivo imaging of diffuse optical reflectance, optoacoustic pressure, and ultrasonic scattering

Subochev, Pavel; Orlova, Anna; Mikhailova, I. P.; Shilyagina, Natalia Yu.; Turchin, Ilya V.

doi:10.1364/boe.7.003951

Cited by 20 publications

(11 citation statements)

References 22 publications

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“…Raster-scan optoacoustic angiography was performed using the previously developed system [ 35 , 37 ]. A lateral/axial OA resolution of 50 μm/35 μm was provided by a focal spot of 35 MHz polyvinylidene fluoride detector with a 30 MHz bandwidth, F = 6.8 mm focal distance, and 0.6 numerical aperture.…”

Section: Methodsmentioning

confidence: 99%

Raster-scan optoacoustic angiography of blood vessel development in colon cancer models

et al. 2019

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Raster-scan optoacoustic angiography at 532 nm wavelength with 50 μm lateral resolution at 2 mm diagnostic depth was used for quantitative characterization of neoangiogenesis in colon cancer models. Two tumor models of human colon adenocarcinoma (HT-29) and murine colon carcinoma (CT26) different in their histology and vascularization were compared. Tumors of both origins showed an inhomogeneous distribution of areas with high and low vascularization. Rapidly growing CT26 tumor demonstrated a higher rate of vessel growth from the periphery to the center. Peculiarities of the vascularity of tumor models revealed by optoacoustic imaging were confirmed by fluorescent microscopy with FITC-dextran and morphological analysis. The obtained results may be important for the investigation of tumor development and for improvement of colon cancer treatment strategies.

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Section: Methodsmentioning

confidence: 99%

Raster-scan optoacoustic angiography of blood vessel development in colon cancer models

et al. 2019

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“…Reflection-mode OA angiography of the mouse head (7.5 × 7.5 mm 2 field of view) was performed with 25 µm lateral scanning steps provided by two computer-driven stages M-664 (PI, Germany). Optically-generated probing acoustic pulses excited in the PVDF detector due to the absorption of backscattered laser radiation were utilized for complementary ultrasonic imaging of the same 7.5 × 7.5 mm 2 area [28]. To perform cerebral OA angiography at the wavelength of 1064 nm, a four-week-old nu/nu mouse and 3-day-old rat with intact skull and scalp were used (Fig.…”

Section: In Vivo Experiments and Data Processingmentioning

confidence: 99%

Toward whole-brain in vivo optoacoustic angiography of rodents: modeling and experimental observations

Subochev¹,

Smolina²,

Сергеева³

et al. 2020

Biomed. Opt. Express

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Cerebrovascular imaging of rodents is one of the trending applications of optoacoustics aimed at studying brain activity and pathology. Imaging of deep brain structures is often hindered by sub-optimal arrangement of the light delivery and acoustic detection systems. In our work we revisit the physics behind opto-acoustic signal generation for theoretical evaluation of optimal laser wavelengths to perform cerebrovascular optoacoustic angiography of rodents beyond the penetration barriers imposed by light diffusion in highly scattering and absorbing brain tissues. A comprehensive model based on diffusion approximation was developed to simulate optoacoustic signal generation using optical and acoustic parameters closely mimicking a typical murine brain. The model revealed three characteristic wavelength ranges in the visible and near-infrared spectra optimally suited for imaging cerebral vasculature of different size and depth. The theoretical conclusions are confirmed by numerical simulations while in vivo imaging experiments further validated the ability to accurately resolve brain vasculature at depths ranging between 0.7 and 7 mm.

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“…The OA imaging setup ( Figure 3) employed the concept of dark-field acoustic resolution photoacoustic microscopy (AR-PAM) [20], where the scanning OA head is represented by a conical fiber-optic illumination system (CeramOptec, Germany) combined with a spherically focused acoustic detector made of a polyvinylidene difluoride (PVDF) piezo film with a 25 μm thickness (IAP RAS, Russia) [21]. The ultrasound antenna with a numerical aperture of 0.6 and a receiving band of 35 MHz provided a spatial resolution of 40 μm at a probing depth of up to 3 mm.…”

Section: Optoacoustic (Oa) Imaging Setupmentioning

confidence: 99%

Towards Bimodal Optical Monitoring of Photodynamic Therapy with Targeted Nanoconstructs: A Phantom Study

et al. 2019

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Increase of the efficiency of photodynamic therapy (PDT) requires the development of advanced protocols employing both novel photosensitizer (PS) carriers and aids for online monitoring. Nanoconstructs may be comprised of a photosensitizer, chemotherapy drugs, or inhibitors of molecular pathways that support cancer growth. In this paper, we analyze the efficiency of a bimodal approach involving fluorescence and optoacoustic imaging in monitoring drug distribution and photobleaching. The study evaluates typical sensitivities of these techniques to the presence of the two key moieties of a nanoconstruct: benzoporphyrin derivatives (BPD) serving as a PS, and IRDye800 acting as a contrast agent. Both imaging modalities employ dual-wavelength probing at the wavelengths corresponding to absorption peaks of BPD and IRDye800, which enables their separate detection. In an experiment on a tissue-mimicking phantom with inclusions containing separate BPD and IRDye800 solutions, fluorescence imaging demonstrated higher contrast as compared to optoacoustic imaging for both components, though strong light scattering in the surrounding media restricted accurate localization of the markers. It was also sensitive to photobleaching, which is a measure of PDT efficiency. Optoacoustic imaging demonstrated sufficient sensitivity to both components, though less than that of fluorescence imaging, however, it enabled depth-resolved detection of an absorber and estimation of its relative content. Employment of the bimodal approach in monitoring of PS photobleaching adds to its potential in intraprocedural PDT monitoring.

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Simultaneous in vivo imaging of diffuse optical reflectance, optoacoustic pressure, and ultrasonic scattering

Cited by 20 publications

References 22 publications

Raster-scan optoacoustic angiography of blood vessel development in colon cancer models

Raster-scan optoacoustic angiography of blood vessel development in colon cancer models

Toward whole-brain in vivo optoacoustic angiography of rodents: modeling and experimental observations

Towards Bimodal Optical Monitoring of Photodynamic Therapy with Targeted Nanoconstructs: A Phantom Study

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