T2 heterogeneity as an in vivo marker of microstructural integrity in medial temporal lobe subfields in ageing and mild cognitive impairment

Wearn, Alfie; Nurdal, Volkan; Saunders-Jennings, Esther; Knight, Michael; Madan, Christopher R.; Fallon, Sean-James; Isotalus, Hanna K.; Kauppinen, Risto A.; Coulthard, Elizabeth

doi:10.1016/j.neuroimage.2021.118214

Cited by 3 publications

(1 citation statement)

References 64 publications

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“…The versatility in adapting pulse sequences for different spatial (6,7) or spectral information (8,9) is an outstanding feature adding the popularity and irreplaceability of MR technique. Among the abundant information from MRI, transverse relaxation time (denoted as T2) is a most basic but critical one because T2 is sensitive to the microstructural and microenvironmental changes (10)(11)(12)(13). For example, in the hemorrhagic stroke, with the development of edema, there will be distinct increase in T2 due to the accumulation of mass free water around the vascular rupture (14).…”

Section: Introductionmentioning

confidence: 99%

Improving the reliability of T₂measurement in magnetic resonance imaging

Yang

2024

Preprint

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Magnetic resonance imaging (MRI) is a versatile technique broadly utilized in research and clinic. Among the information available from MRI measurements, transversal relaxation time (T2) is a basic but critical one to reflect the microstructure and microenvironment at the molecular level. A popular method to estimate T2is employing a series of evolution time (TE) values and, thereafter, fitting with the exponential model (termed as T2fitting). Despite of the popularity in using T2fitting, there is a lack of knowledge how related experimental parameters, such as signal-to-noise (SNR), number of TE utilized, dynamic range of TE, and repetition number of each TE, affect the measurement reproducibility. In this study, we performed Monte Carlo simulations to investigate how SNR, TE number, TE range, and repetition number influence the reliability of T2measurement, which was indexed by coefficient of variations. Good reliability with ≤5.0% variation can be achieved when the normalized noise level is below 2.2%. Optimal TE range for measuring T2is related to the T2under evaluation. TE number and repetition number can be increased to reduce measurement variations.

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Section: Introductionmentioning

confidence: 99%

Improving the reliability of T₂measurement in magnetic resonance imaging

Yang

2024

Preprint

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Morphometry of medial temporal lobe subregions using high‐resolution T2‐weighted MRI in ADNI3: Why, how, and what's next?

Yushkevich,

Ittyerah,

et al. 2024

Alzheimer's & Dementia

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This paper for the 20th anniversary of the Alzheimer's Disease Neuroimaging Initiative (ADNI) provides an overview of magnetic resonance imaging (MRI) of medial temporal lobe (MTL) subregions in ADNI using a dedicated high‐resolution T2‐weighted sequence. A review of the work that supported the inclusion of this imaging modality into ADNI Phase 3 is followed by a brief description of the ADNI MTL imaging and analysis protocols and a summary of studies that have used these data. This review is supplemented by a new study that uses novel surface‐based tools to characterize MTL neurodegeneration across biomarker‐defined AD stages. This analysis reveals a pattern of spreading cortical thinning associated with increasing levels of tau pathology in the presence of elevated amyloid beta, with apparent epicenters in the transentorhinal region and inferior hippocampal subfields. The paper concludes with an outlook for high‐resolution imaging of the MTL in ADNI Phase 4.Highlights As of Phase 3, the Alzheimer's Disease Neuroimaging Initiative (ADNI) magnetic resonance imaging (MRI) protocol includes a high‐resolution T2‐weighted MRI scan optimized for imaging hippocampal subfields and medial temporal lobe (MTL) subregions. These scans are processed by the ADNI core to obtain automatic segmentations of MTL subregions and to derive morphologic measurements. More detailed granular examination of MTL neurodegeneration in response to disease progression is achieved by applying surface‐based modeling techniques. Surface‐based analysis of gray matter loss in MTL subregions reveals increasing and spatially expanding patterns of neurodegeneration with advancing stages of Alzheimer's disease (AD), as defined based on amyloid and tau positron emission tomography biomarkers in accordance with recently proposed criteria. These patterns closely align with post mortem literature on spread of pathological tau in AD, supporting the role of tau pathology in the presence of elevated levels of amyloid beta as the driver of neurodegeneration.

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Age‐related differences in hippocampal subfield volumes across the human lifespan: A meta‐analysis

Homayouni,

Canada,

Saifullah

et al. 2023

Hippocampus

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The human hippocampus (Hc) is critical for memory function across the lifespan. It is comprised of cytoarchitectonically distinct subfields: dentate gyrus (DG), cornu ammonis sectors (CA) 1‐4, and subiculum, each of which may be differentially susceptible to neurodevelopmental and neurodegenerative mechanisms. Identifying age‐related differences in Hc subfield volumes can provide insights into neural mechanisms of memory function across the lifespan. Limited evidence suggests that DG and CA3 volumes differ across development while other regions remain relatively stable, and studies of adulthood implicate a downward trend in all subfield volumes with prominent age effects on CA1. Due to differences in methods and limited sampling for any single study, the magnitude of age effects on Hc subfield volumes and their probable lifespan trajectories remain unclear. Here, we conducted a meta‐analysis on cross‐sectional studies (n = 48,278 participants, ages = 4–94 years) to examine the association between age and Hc subfield volumes in development (n = 11 studies), adulthood (n = 30 studies), and a combined lifespan sample (n = 41 studies) while adjusting estimates for sample sizes. In development, age was positively associated with DG and CA3‐4 volumes, whereas in adulthood a negative association was observed with all subfield volumes. Notably, the observed age effects were not different across subfield volumes within each age group. All subfield volumes showed a nonlinear age pattern across the lifespan with DG and CA3‐4 volumes showing a more distinct age trajectory as compared to the other subfields. Lastly, among all the study‐level variables, only female percentage of the study sample moderated the age effect on CA1 volume: a higher female‐to‐male ratio in the study sample was linked to the greater negative association between age and CA1 volume. These results document that Hc subfield volumes differ as a function of age offering broader implications for constructing theoretical models of lifespan memory development.

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T2 heterogeneity as an in vivo marker of microstructural integrity in medial temporal lobe subfields in ageing and mild cognitive impairment

Cited by 3 publications

References 64 publications

Improving the reliability of T₂measurement in magnetic resonance imaging

Improving the reliability of T₂measurement in magnetic resonance imaging

Morphometry of medial temporal lobe subregions using high‐resolution T2‐weighted MRI in ADNI3: Why, how, and what's next?

Age‐related differences in hippocampal subfield volumes across the human lifespan: A meta‐analysis

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T2 heterogeneity as an in vivo marker of microstructural integrity in medial temporal lobe subfields in ageing and mild cognitive impairment

Cited by 3 publications

References 64 publications

Improving the reliability of T2measurement in magnetic resonance imaging

Improving the reliability of T2measurement in magnetic resonance imaging

Morphometry of medial temporal lobe subregions using high‐resolution T2‐weighted MRI in ADNI3: Why, how, and what's next?

Age‐related differences in hippocampal subfield volumes across the human lifespan: A meta‐analysis

Contact Info

Product

Resources

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Improving the reliability of T₂measurement in magnetic resonance imaging

Improving the reliability of T₂measurement in magnetic resonance imaging