Identification of changes in neuronal function as a consequence of aging and tauopathic neurodegeneration using a novel and sensitive magnetic resonance imaging approach

Fontaine, Sarah N.; Ingram, Alexandria; Cloyd, Ryan; Meier, Shelby E.; Miller, Emily; Lyons, Danielle N.; Nation, Grant K.; Mechas, Elizabeth; Weiss, Blaine E.; Lanzillotta, Chiara; Domenico, Fabio Di; Schmitt, Frederick A.; Powell, David K.; Vandsburger, Moriel; Abisambra, Jose F.

doi:10.1016/j.neurobiolaging.2017.04.007

Cited by 25 publications

(36 citation statements)

References 42 publications

(60 reference statements)

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“…Immunohistochemical and biochemical examinations of postmortem rTg4510 brains confirmed that the progression of NFT formation was drastically increased from 4 months to 6 months of age [12,14,15,17]. Recently, advanced in vivo brain imaging techniques, including manganese-enhanced magnetic resonance imaging (MRI), arterial spin labeling, amide proton transfer imaging, diffusion tenser imaging, and PET, have enabled us to visualize neuronal dysfunction and pathological tau accumulation in living rTg4510 mice [18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 94%

“…Recent advances in positron emission tomography (PET) imaging for tauopathy allow us to noninvasively examine the state of tau protein in living human brains [2][3][4][5][6][7]. Among potential tau PET tracers, 11 C-labeled phenyl/pyridinilbutadienyl-benzothiazoles/benzothiazolium 3 ([ 11 C] PBB3), [ 18 F]AV-1451, and [ 18 F]THKs have been used for pre-clinical studies in human brain imaging [6][7][8]. Among these tracers, PBB3 compound, based on a phenyl/pyridinil-butadienylbenzothiazoles/benzothiazolium (PBB) backbone compound, selectively binds to ␤-pleated sheet structures such as neurofibrillary tangles (NFTs), neuropil threads (NTs), and diffuse plaques, although selective binding to NFTs is much higher than the binding to plaques [2].…”

Section: Introductionmentioning

confidence: 99%

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In Vivo Visualization of Tau Accumulation, Microglial Activation, and Brain Atrophy in a Mouse Model of Tauopathy rTg4510

Ishikawa

Takao

Maeda

et al. 2018

JAD

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Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

In Vivo Visualization of Tau Accumulation, Microglial Activation, and Brain Atrophy in a Mouse Model of Tauopathy rTg4510

Ishikawa

Takao

Maeda

et al. 2018

JAD

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“…MEMRI can detect neuronal dysfunction at an early stage and contributes to early detection of the disease. Fontaine et al used a quantitative R1 value ( R1 = R1 6h -R1 baseline ) and intraperitoneal MnCl 2 injection to detect markedly abnormal elevations in R1 in the hippocampal CA1 and CA3 regions before the onset of cognitive deficits in tau protein transgenic mice (rTg4510) (97). In another AD model (5XFAD mice), MEMRI with SA of Mn 2+ showed increased signal intensity in brain areas associated with spatial cognition in the early stages of the disease (2-5 months of age); this increased intensity was associated with impaired learning and memory in behavioral tests (98).…”

Section: Neurodegenerative Diseases Alzheimer's Disease (Ad)mentioning

confidence: 99%

Manganese-Enhanced Magnetic Resonance Imaging: Application in Central Nervous System Diseases

Yang

2020

Front. Neurol.

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Manganese-enhanced magnetic resonance imaging (MEMRI) relies on the strong paramagnetism of Mn 2+. Mn 2+ is a calcium ion analog and can enter excitable cells through voltage-gated calcium channels. Mn 2+ can be transported along the axons of neurons via microtubule-based fast axonal transport. Based on these properties, MEMRI is used to describe neuroanatomical structures, monitor neural activity, and evaluate axonal transport rates. The application of MEMRI in preclinical animal models of central nervous system (CNS) diseases can provide more information for the study of disease mechanisms. In this article, we provide a brief review of MEMRI use in CNS diseases ranging from neurodegenerative diseases to brain injury and spinal cord injury.

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“…P301S and P301L lines (transgenic for a human 4 repeat tau isoform) [6,[52][53][54], which have become important tools to study the mechanisms of abnormal tau aggregation and deposition in FTD (4 repeat tau) [61] and AD (3 and 4 repeat tau) [25, 33,41]. In the P301L 4 (Thy 1.2, pR5 line) [11,18], P301L (CaMKIIa) [23,43,62] and P301L (tetO) [14] mouse models, tau deposits begin forming before 3 months-of-age in neurons in the entorhinal cortex, hippocampus and later in the cortex, and amygdala; with neuroinflammation and impaired memory functions in hippocampus-and amygdala-dependent tasks manifesting at a later stage [49,50,67]. Brain atrophy and white matter changes indicating neurodegeneration were reported in P301L (CaMKIIa) mouse line around 9 months-of-age [16,23,43,62], which was driven by factors additional to human tau overexpression.…”

Section: Introductionmentioning

confidence: 99%

Tau deposition is associated with imaging patterns of tissue calcification in the P301L mouse model of human tauopathy

Zarb

Kuhn

et al. 2019

Preprint

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Brain calcification is associated with several neurodegenerative proteinopathies. Here, we report a new phenotype of intracranial calcification in transgenic P301L mice overexpressing 4 repeat tau. P301L mice (Thy1.2) of 3, 5, 9 and 18-25 months-of-age and age-matched non-transgenic littermates were assessed using in vivo/ex vivo magnetic resonance imaging (MRI) with a gradient recalled echo sequence and micro computed tomography (μCT). Susceptibility weighted images computed from the gradient recalled echo data revealed regional hypointensities in the hippocampus, cortex, caudate nucleus and thalamus of P301L mice, which in corresponding phase images indicated diamagnetic lesions. Concomitantly, µCT detected hyperdense lesions.Occurrence of diamagnetic susceptibility lesions in the hippocampus, increased with age.Immunochemical staining of brain sections revealed bone protein-positive deposits. Furthermore, intra-neuronal and vessel-associated protein-containing nodules co-localized with phosphorylated-tau (AT8 and AT100) in the hippocampus. Protein-containing nodules were detected also in the thalamus in the absence of phosphorylated-tau deposition. In contrast, osteocalcin-containing nodules were vessel-associated, indicating ossified vessels, in the thalamus in absence of phosphorylated-tau. In summary, MRI and µCT demonstrated imaging pattern of intracranial calcification, concomitant with immunohistochemical evidence of formation of protein deposits containing bone proteins along with phosphorylated-tau in the P301L mouse model of human tauopathy. The P301L mouse model may thus serve as a future model to study the pathogenesis of brain calcifications in tauopathies.3

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Identification of changes in neuronal function as a consequence of aging and tauopathic neurodegeneration using a novel and sensitive magnetic resonance imaging approach

Cited by 25 publications

References 42 publications

In Vivo Visualization of Tau Accumulation, Microglial Activation, and Brain Atrophy in a Mouse Model of Tauopathy rTg4510

In Vivo Visualization of Tau Accumulation, Microglial Activation, and Brain Atrophy in a Mouse Model of Tauopathy rTg4510

Manganese-Enhanced Magnetic Resonance Imaging: Application in Central Nervous System Diseases

Tau deposition is associated with imaging patterns of tissue calcification in the P301L mouse model of human tauopathy

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