Phosphotungstic acid‐enhanced microCT: Optimized protocols for embryonic and early postnatal mice

Lesciotto, Kate M.; Perrine, Susan M. Motch; Kawasaki, Mizuho; Stecko, Timothy D.; Ryan, Timothy M.; Kawasaki, Kazuhiko; Richtsmeier, Joan T.

doi:10.1002/dvdy.136

Cited by 43 publications

(63 citation statements)

References 48 publications

(237 reference statements)

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“…Using these ex vivo imaging modalities, we were able to evaluate the inner ear within the intact whole head in two and three dimensions at these developmental stages. In the embryo, we performed Micro-CT following immersion in phosphotungstic acid (PTA), a radio dense contrast agent (11), allowing distinction of tissues through variable X-ray attenuation that would otherwise appear homogenous on Micro-CT or MRI.…”

Section: Resultsmentioning

confidence: 99%

Multimodal Atlas of the Murine Inner Ear: From Embryo to Adult

et al. 2021

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The inner ear is a complex organ housed within the petrous bone of the skull. Its intimate relationship with the brain enables the transmission of auditory and vestibular signals via cranial nerves. Development of this structure from neural crest begins in utero and continues into early adulthood. However, the anatomy of the murine inner ear has only been well-characterized from early embryogenesis to post-natal day 6. Inner ear and skull base development continue into the post-natal period in mice and early adulthood in humans. Traditional methods used to evaluate the inner ear in animal models, such as histologic sectioning or paint-fill and corrosion, cannot visualize this complex anatomy in situ. Further, as the petrous bone ossifies in the postnatal period, these traditional techniques become increasingly difficult. Advances in modern imaging, including high resolution Micro-CT and MRI, now allow for 3D visualization of the in situ anatomy of organs such as the inner ear. Here, we present a longitudinal atlas of the murine inner ear using high resolution ex vivo Micro-CT and MRI.

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Section: Resultsmentioning

confidence: 99%

Multimodal Atlas of the Murine Inner Ear: From Embryo to Adult

et al. 2021

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“…A drawback of whiceCT may be that the incubation time is prolonged to 18 days, as compared to diceCT protocols for mouse brain imaging that report only 1–2 days incubation to reach homogeneous contrast enhancement 30 – 32 . However, this incubation time is within an acceptable range, since more recent techniques employing PTA-enhanced µCT optimized for embryonic and early postnatal mice require even longer incubation periods in adult mice 34 . The advantage of the whiceCT protocol that outweighs the relatively long incubation time is that the craniofacial structure is conserved.…”

Section: Discussionmentioning

confidence: 99%

“…Alternative protocols have explored the use of selectively perfusable iodine-based contrast-enhanced computed tomography (spiceCT) to administer contrast to the entire mouse body leaving the entire anatomy intact including the craniofacial structure, but this strategy does not manage to provide contrast into the brain 33 . Imaging protocols using other contrast agents such as phosphotungstic acid (PTA) have enabled the visualization of bone and soft tissue from µCT scans with minimal shrinkage 34 , but have not yet been optimized for adult mice, are more costly and require more elaborated sample processing. Finally, the brain ventricles are not visible in any of these approaches, which implies an extra limitation for the neurodegenerative and neurodevelopmental disorders research fields, where the ventricular anatomy or volume are important biomarkers 35 – 38 .…”

Section: Introductionmentioning

confidence: 99%

ViceCT and whiceCT for simultaneous high-resolution visualization of craniofacial, brain and ventricular anatomy from micro-computed tomography

Llambrich

Wouters

Himmelreich

et al. 2020

Sci Rep

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Up to 40% of congenital diseases present disturbances of brain and craniofacial development resulting in simultaneous alterations of both systems. Currently, the best available method to preclinically visualize the brain and the bones simultaneously is to co-register micro-magnetic resonance (µMR) and micro-computed tomography (µCT) scans of the same specimen. However, this requires expertise and access to both imaging techniques, dedicated software and post-processing knowhow. To provide a more affordable, reliable and accessible alternative, recent research has focused on optimizing a contrast-enhanced µCT protocol using iodine as contrast agent that delivers brain and bone images from a single scan. However, the available methods still cannot provide the complete visualization of both the brain and whole craniofacial complex. In this study, we have established an optimized protocol to diffuse the contrast into the brain that allows visualizing the brain parenchyma and the complete craniofacial structure in a single ex vivo µCT scan (whiceCT). In addition, we have developed a new technique that allows visualizing the brain ventricles using a bilateral stereotactic injection of iodine-based contrast (viceCT). Finally, we have tested both techniques in a mouse model of Down syndrome, as it is a neurodevelopmental disorder with craniofacial, brain and ventricle defects. The combined use of viceCT and whiceCT provides a complete visualization of the brain and bones with intact craniofacial structure of an adult mouse ex vivo using a single imaging modality.

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“…16 We specifically developed algorithms for distributed local intensity correction and cross-modal registration while leveraging existing state-of-the-art, open-source tools. 12,13 We applied CloudReg to various datasets including in vivo human brain MRI, 17 ex vivo macaque brain MRI, 18,19 ex vivo in situ mouse brain micro-CT, 20,21 and LSM-imaged cleared mouse and rat brains. 3,4,5 Figure 1 shows an overview of the CloudReg pipeline.…”

Section: Clearing Methods Including Clarity (Clear Lipid-exchanged Anatomically Rigidmentioning

confidence: 99%

CloudReg: Automatic Terabyte-Scale Cross-Modal Brain Volume Registration

Chandrashekhar

Tward

Crowley

et al. 2021

Preprint

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Quantifying terabyte-scale multi-modal human and animal imaging data requires scalable analysis tools. We developed CloudReg, an open-source, automatic, terabyte-scale, cloud-based image analysis pipeline that pre-processes and registers cross-modal volumetric datasets with artifacts via spatially-varying polynomial intensity transform. CloudReg accurately registers the following datasets to their respective atlases: in vivo human and ex vivo macaque brain magnetic resonance imaging, ex vivo mouse brain micro-computed tomography, and cleared murine brain light-sheet microscopy.

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Phosphotungstic acid‐enhanced microCT: Optimized protocols for embryonic and early postnatal mice

Cited by 43 publications

References 48 publications

Multimodal Atlas of the Murine Inner Ear: From Embryo to Adult

Multimodal Atlas of the Murine Inner Ear: From Embryo to Adult

ViceCT and whiceCT for simultaneous high-resolution visualization of craniofacial, brain and ventricular anatomy from micro-computed tomography

CloudReg: Automatic Terabyte-Scale Cross-Modal Brain Volume Registration

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