Multispectral imaging of absorption and scattering properties of<i>in vivo</i>exposed rat brain using a digital red-green-blue camera

Yoshida, Keiichiro; Nishidate, Izumi; Ishizuka, Tomohiro; Kawauchi, Satoko; Sato, Shunichi; Sato, Manabu

doi:10.1117/1.jbo.20.5.051026

Cited by 23 publications

(8 citation statements)

References 45 publications

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“…The method is basically the same as that used in our previous study. 19,21 Figure 2 shows the flow diagram of the method. Absorbance spectrum AðλÞ was calculated from diffuse reflectance rðλÞ based on the following equation:…”

Section: Estimation Of Cerebral Absorption (Hemodynamics) and Scattermentioning

confidence: 99%

“…In this study, we performed multispectral imaging of the cortex of the rat brain that was transcranially exposed to an LISW and quantified two-dimensional cerebral hemodynamics and tissue scattering parameters using multiple regression analysis aided by Monte Carlo simulation for the spectral data obtained. 18,19 We assessed morphological changes of vessels and visualized distributions of regional hemoglobin concentration (rC Hb ) and tissue oxygen saturation (StO 2 ) for three time regimes: (i) just after LISW application (before the start of CSD), (ii) during CSD propagation, and (iii) after CSD propagation. Importantly, vascular type-dependent behaviors were observed, and the results were therefore analyzed for each vascular type (arteriolar, venular, and capillaries).…”

Section: Introductionmentioning

confidence: 99%

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Multispectral imaging of cortical vascular and hemodynamic responses to a shock wave: observation of spreading depolarization and oxygen supply-demand mismatch

et al. 2019

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imaging of cortical vascular and hemodynamic responses to a shock wave: observation of spreading depolarization and oxygen supply-demand mismatch," J.Abstract. Blast-induced traumatic brain injury has been a recent major concern in neurotraumatology.However, its pathophysiology and mechanism are not understood partly due to insufficient information on the brain pathophysiology during/immediately after shock wave exposure. We transcranially applied a laserinduced shock wave (LISW, ∼19 Pa · s) to the left frontal region in a rat and performed multispectral imaging of the ipsilateral cortex through a cranial window (n ¼ 4). For the spectral data obtained, we conducted multiple regression analysis aided by Monte Carlo simulation to evaluate vascular diameters, regional hemoglobin concentration (rC Hb ), tissue oxygen saturation (StO 2 ), oxygen extraction fraction, and light-scattering signals as a signature of cortical spreading depolarization (CSD). Immediately after LISW exposure, rC Hb and StO 2 were significantly decreased with distinct venular constriction. CSD was then generated and was accompanied by distinct hyperemia/hyperoxemia. This was followed by oligemia with arteriolar constriction, but it soon recovered (within ∼20 min). However, severe hypoxemia was persistently observed during the post-CSD period (∼1 h). These observations indicate that inadequate oxygen supply and/or excessive oxygen consumption continued even after blood supply was restored in the cortex. Such a hypoxemic state and/or a hypermetabolic state might be associated with brain damage caused by a shock wave.

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Section: Estimation Of Cerebral Absorption (Hemodynamics) and Scattermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multispectral imaging of cortical vascular and hemodynamic responses to a shock wave: observation of spreading depolarization and oxygen supply-demand mismatch

et al. 2019

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“…As for the related cellular morphological changes in response to NIR reflectance signal changes, the microstructure of the cortex will be observed by electron microscopy, which enables estimation of scatterer size and, hence, light-scattering properties in the cortex. For estimation of the related light-scattering properties, we will use simulationbased quantitative analysis of both light absorption and scattering properties in the tissue (Yoshida et al, 2015), for which the recent advanced interferometric NIR spectroscopic technique is also applicable (Borycki, Kholiqov, & Srinivasan, 2017). The stroke model used in this study is for permanent focal ischemia, and we will perform experiments with an ischemia-reperfusion model to reveal the reversibility of the NIR reflectance signal and tissue viability, especially in the peripheral region of the ischemic center (penumbra).…”

Section: Significance and Limitationsmentioning

confidence: 99%

Near‐infrared diffuse reflectance signals for monitoring spreading depolarizations and progression of the lesion in a male rat focal cerebral ischemia model

Kawauchi

Nishidate

Nawashiro

et al. 2017

J of Neuroscience Research

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In ischemic stroke research, a better understanding of the pathophysiology and development of neuroprotection methods are crucial, for which in vivo imaging to monitor spreading depolarizations (SDs) and evolution of tissue damage is desired. Since these events are accompanied by cellular morphological changes, light-scattering signals, which are sensitive to cellular and subcellular morphology, can be used for monitoring them. In this study, we performed transcranial imaging of near-infrared (NIR) diffuse reflectance at ∼800 nm, which sensitively reflects light-scattering change, and examined how NIR reflectance is correlated with simultaneously measured cerebral blood flow (CBF) for a rat middle cerebral artery occlusion (MCAO) model. After MCAO, wavelike NIR reflectance changes indicating occurrence of SDs were generated and propagated around the ischemic core for ∼90 min, during which time NIR reflectance increased not only within the ischemic core but also in the peripheral region. The area with increased reflectance expanded with increase in the number of SD occurrences, the correlation coefficient being 0.7686 (n = 5). The area with increased reflectance had become infarcted at 24 hr after MCAO. The infarct region was found to be associated with hypoperfusion or no-flow response to SD, but hyperemia or hypoperfusion followed by hyperemia response to SD was also observed, and the regional heterogeneity seemed to be connected with the rat cerebrovasculature and hence existence/absence of collateral flow. The results suggest that NIR reflectance signals depicted early evolution of tissue damage, which was not seen by CBF changes, and enabled lesion progression monitoring in the present stroke model.

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“…Specifically, for 2PLSM angiograms, this limitation is exaggerated due to the anatomical features of the vasculature, which runs three-dimensionally (3D) with different sizes of the vessels through tissue whose optical properties vary depending on regional scattering and absorption effects. [22][23][24][25][26] Therefore, application of conventional methods for region of interest-based segmentation to brain cells to adapt images with variable signal-to-noise ratios (SNRs) is not beneficial for accurately extracting a whole network of the vasculature in a consistent manner.…”

Section: Introductionmentioning

confidence: 99%

Three‐dimensional microvascular network reconstruction from in vivo images with adaptation of the regional inhomogeneity in the signal‐to‐noise ratio

et al. 2021

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Objective: Quantification of angiographic images with two-photon laser scanning fluorescence microscopy (2PLSM) relies on proper segmentation of the vascular images. However, the images contain inhomogeneities in the signal-to-noise ratio (SNR) arising from regional effects of light scattering and absorption. The present study developed a semiautomated quantification method for volume images of 2PLSM angiography by adjusting the binarization threshold according to local SNR along the vessel centerlines.Methods: A phantom model made with fluorescent microbeads was used to incorporate a region-dependent binarization threshold. Results:The recommended SNR for imaging was found to be 4.2-10.6 that provide the true size of imaged objects if the binarization threshold was fixed at 50% of SNR.However, angiographic images in the mouse cortex showed variable SNR up to 45 over the depths. To minimize the errors caused by variable SNR and a spatial extent of the imaged objects in an axial direction, the microvascular networks were threedimensionally reconstructed based on the cross-sectional diameters measured along the vessel centerline from the XY-plane images with adapted binarization threshold.The arterial volume was relatively constant over depths of 0-500 µm, and the capillary volume (1.7% relative to the scanned volume) showed the larger volumes than the artery (0.8%) and vein (0.6%). Conclusions:The present methods allow consistent segmentation of microvasculature by adapting the local inhomogeneity in the SNR, which will be useful for quantitative comparison of the microvascular networks, such as under disease conditions where SNR in the 2PLSM images varies over space and time.

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Multispectral imaging of absorption and scattering properties ofin vivoexposed rat brain using a digital red-green-blue camera

Cited by 23 publications

References 45 publications

Multispectral imaging of cortical vascular and hemodynamic responses to a shock wave: observation of spreading depolarization and oxygen supply-demand mismatch

Multispectral imaging of cortical vascular and hemodynamic responses to a shock wave: observation of spreading depolarization and oxygen supply-demand mismatch

Near‐infrared diffuse reflectance signals for monitoring spreading depolarizations and progression of the lesion in a male rat focal cerebral ischemia model

Three‐dimensional microvascular network reconstruction from in vivo images with adaptation of the regional inhomogeneity in the signal‐to‐noise ratio

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