Your search keyword '"in vivo mouse brain imaging"' showing total 3 results

1. Submillimeter-Resolution PET for High-Sensitivity Mouse Brain Imaging.

Author

Kang HG, Tashima H, Wakizaka H, Nishikido F, Higuchi M, Takahashi M, and Yamaya T

Subjects

Mice, Animals, Phantoms, Imaging, Neuroimaging, Equipment Design, Positron-Emission Tomography, Fluorodeoxyglucose F18

Abstract

PET is a powerful molecular imaging technique that can provide functional information on living objects. However, the spatial resolution of PET imaging has been limited to around 1 mm, which makes it difficult to visualize mouse brain function in detail. Here, we report an ultrahigh-resolution small-animal PET scanner we developed that can provide a resolution approaching 0.6 mm to visualize mouse brain function with unprecedented detail. Methods: The ultrahigh-resolution small-animal PET scanner has an inner diameter of 52.5 mm and axial coverage of 51.5 mm. The scanner consists of 4 rings, each of which has 16 depth-of-interaction detectors. Each depth-of-interaction detector consists of a 3-layer staggered lutetium yttrium orthosilicate crystal array with a pitch of 1 mm and a 4 × 4 silicon photomultiplier array. The physical performance was evaluated in accordance with the National Electrical Manufacturers Association NU4 protocol. Spatial resolution was evaluated with phantoms of various resolutions. In vivo glucose metabolism imaging of the mouse brain was performed. Results: Peak absolute sensitivity was 2.84% with an energy window of 400-600 keV. The 0.55-mm rod structure of a resolution phantom was resolved using an iterative algorithm. In vivo mouse brain imaging with 18 F-FDG clearly identified the cortex, thalamus, and hypothalamus, which were barely distinguishable in a commercial preclinical PET scanner that we used for comparison. Conclusion: The ultrahigh-resolution small-animal PET scanner is a promising molecular imaging tool for neuroscience research using rodent models., (© 2023 by the Society of Nuclear Medicine and Molecular Imaging.)

Published

2023

2. In vivo brain imaging with multimodal optical coherence microscopy in a mouse model of thromboembolic photochemical stroke.

Author

Dolezyczek H, Tamborski S, Majka P, Sampson D, Wojtkowski M, Wilczyński G, Szkulmowski M, and Malinowska M

Abstract

We used a new multimodal imaging system that combines optical coherence microscopy and brightfield microscopy. Using this in vivo brain monitoring approach and cranial window implantation, we three-dimensionally visualized the vascular network during thrombosis, with high temporal (18 s) and spatial (axial, 2.5    μ m ; lateral, 2.2    μ m ) resolution. We used a modified mouse model of photochemical thromboembolic stroke in order to more accurately parallel human stroke. Specifically, we applied green laser illumination to focally occlude a branch of the middle cerebral artery. Despite the recanalization of the superficial arteries at 24 h after stroke, no blood flow was detected in the small vessels within deeper regions. Moreover, after 24 h of stroke progression, scattering signal enhancement was observed within the stroke region. We also evaluated the infarct extent and shape histologically. In summary, we present a novel approach for real-time mouse brain monitoring and ischemic variability analysis. This multimodal imaging method permits the analysis of thrombosis progression and reperfusion. Additionally and importantly, the system could be used to study the effect of poststroke drug treatments on blood flow in small arteries and capillaries of the brain., (© The Authors. Published by SPIE under a Creative Commons Attribution 4.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.)

Published

2020

3. In vivo brain imaging with multimodal optical coherence microscopy in a mouse model of thromboembolic photochemical stroke

Author

Szymon Tamborski, Monika Malinowska, Danuta M. Sampson, Maciej Wojtkowski, Maciej Szkulmowski, Grzegorz M. Wilczynski, Piotr Majka, and H. Dolezyczek

Subjects

Paper, cranial window, optical coherence microscopy, cerebral blood flow, Neuroscience (miscellaneous), Thromboembolic stroke, Photochemistry, 01 natural sciences, 010309 optics, 03 medical and health sciences, 0302 clinical medicine, Neuroimaging, medicine.artery, 0103 physical sciences, photochemical thromboembolic stroke, Medicine, Radiology, Nuclear Medicine and imaging, angiography, Stroke, Radiological and Ultrasound Technology, medicine.diagnostic_test, business.industry, Blood flow, in vivo mouse brain imaging, medicine.disease, Research Papers, Cerebral blood flow, Middle cerebral artery, Angiography, business, 030217 neurology & neurosurgery, Preclinical imaging

Abstract

We used a new multimodal imaging system that combines optical coherence microscopy and brightfield microscopy. Using this in vivo brain monitoring approach and cranial window implantation, we three-dimensionally visualized the vascular network during thrombosis, with high temporal (18 s) and spatial (axial, 2.5 μm; lateral, 2.2 μm) resolution. We used a modified mouse model of photochemical thromboembolic stroke in order to more accurately parallel human stroke. Specifically, we applied green laser illumination to focally occlude a branch of the middle cerebral artery. Despite the recanalization of the superficial arteries at 24 h after stroke, no blood flow was detected in the small vessels within deeper regions. Moreover, after 24 h of stroke progression, scattering signal enhancement was observed within the stroke region. We also evaluated the infarct extent and shape histologically. In summary, we present a novel approach for real-time mouse brain monitoring and ischemic variability analysis. This multimodal imaging method permits the analysis of thrombosis progression and reperfusion. Additionally and importantly, the system could be used to study the effect of poststroke drug treatments on blood flow in small arteries and capillaries of the brain.