Age-Related Sex-Specific Changes in Brain Metabolism and Morphology

Kakimoto, Akihiro; Ito, Shigeru; Okada, Hiroyuki; Nishizawa, Sadahiko; Minoshima, Shinsei; Ouchi, Yasuomi

doi:10.2967/jnumed.115.166439

Cited by 67 publications

(63 citation statements)

References 33 publications

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“…Fourth, older adult men experience more accelerated gray matter atrophy in the core NREM slow wave generating region of the medial prefrontal cortex (Kakimoto et al, 2016; Murphy et al, 2009), which is the same cortical region in which atrophy predicts the severity of SWA decline in the elderly in general (Figure 5) (Mander et al, 2013). Moreover, older adult males suffer greater reductions in metabolic activity in the medial prefrontal regions similar to the medial prefrontal SWA-source generating regions, implicating a functional impairment that may even precede the greater medial prefrontal gray matter atrophy observed in men (Kakimoto et al, 2016).…”

Section: What Are the Neurobiological Mechanisms Of Age-related Sleepmentioning

confidence: 99%

“…Moreover, older adult males suffer greater reductions in metabolic activity in the medial prefrontal regions similar to the medial prefrontal SWA-source generating regions, implicating a functional impairment that may even precede the greater medial prefrontal gray matter atrophy observed in men (Kakimoto et al, 2016). Independently or collectively, these regionally and functionally specific possibilities all lead to falsifiable predictions regarding the mechanisms of gender differences in sleep deterioration in later life.…”

Section: What Are the Neurobiological Mechanisms Of Age-related Sleepmentioning

confidence: 99%

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Sleep and Human Aging

Mander

Winer

Walker

2017

Neuron

804

619

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Older adults do not sleep as well as younger adults. Why? What alterations in sleep quantity and quality occur as we age, and are there functional consequences? What are the underlying neural mechanisms that explain age-related sleep disruption? This review tackles these questions. First, we describe canonical changes in human sleep quantity and quality in cognitively normal older adults. Second, we explore the underlying neurobiological mechanisms that may account for these human sleep alterations. Third, we consider the functional consequences of age-related sleep disruption, focusing on memory impairment as an exemplar. We conclude with a discussion of a still-debated question: do older adults simply need less sleep, or rather, are they unable to generate the sleep that they still need?

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Section: What Are the Neurobiological Mechanisms Of Age-related Sleepmentioning

confidence: 99%

Section: What Are the Neurobiological Mechanisms Of Age-related Sleepmentioning

confidence: 99%

Sleep and Human Aging

Mander

Winer

Walker

2017

Neuron

804

619

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“…In normal subjects, [ 18 F]FDG PET is able to detect a progressive and diffuse reduction of regional consumption of glucose that parallels advancing atrophy (mainly in the frontal, temporal and parietal areas) and age. Even in the absence of cortical atrophy, a progressive reduction of metabolism in the mesial frontal region can be detected, with possible gender differences (Kakimoto et al, 2016). Note the low uptake in the primary visual cortex, which suggests a diagnosis of DLB.…”

Section: @ C I C E D I Z I O N I I N T E R N a Z I O N A L Imentioning

confidence: 99%

Magnetic resonance imaging and positron emission tomography in the diagnosis of neurodegenerative dementias

Sole¹,

Malaspina²,

A³

2016

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SummaryNeuroimaging, both with magnetic resonance imaging (MRI) and positron emission tomography (PET), has gained a pivotal role in the diagnosis of primary neurodegenerative diseases. These two techniques are used as biomarkers of both pathology and progression of Alzheimer's disease (AD) and to differentiate AD from other neurodegenerative diseases. MRI is able to identify structural changes including patterns of atrophy characterizing neurodegenerative diseases, and to distinguish these from other causes of cognitive impairment, e.g. infarcts, space-occupying lesions and hydrocephalus. PET is widely used to identify regional patterns of glucose utilization, since distinct patterns of distribution of cerebral glucose metabolism are related to different subtypes of neurodegenerative dementia. The use of PET in mild cognitive impairment, though controversial, is deemed helpful for predicting conversion to dementia and the dementia clinical subtype. Recently, new radiopharmaceuticals for the in vivo imaging of amyloid burden have been licensed and more tracers are being developed for the assessment of tauopathies and inflammatory processes, which may underlie the onset of the amyloid cascade. At present, the cerebral amyloid burden, imaged with PET, may help to exclude the presence of AD as well as forecast its possible onset. Finally PET imaging may be particularly useful in ongoing clinical trials for the development of dementia treatments. In the near future, the use of the above methods, in accordance with specific guidelines, along with the use of effective treatments will likely lead to more timely and successful treatment of neurodegenerative dementias.

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“…For instance, a large [ 18 F]-FDG PET study consisting of 493 men and 470 women spanning 5 decades (32 – 87 years) showed lower metabolism in parietal cortex for men compared to women, while lower metabolism was observed in ventrolateral prefrontal cortex for women compared to men [215]. In a multi-institutional study of nonischemic heart failure, three radiotracers, [ 15 O]-H 2 O, [ 11 C]-palmitate and [ 11 C]-glucose, were used to evaluate myocardial blood flow and metabolism [216].…”

Section: Preclinical Imagingmentioning

confidence: 99%

Tactics for preclinical validation of receptor-binding radiotracers

Lever

Fan

Lever

2017

Nuclear Medicine and Biology

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Introduction Aspects of radiopharmaceutical development are illustrated through preclinical studies of [125I]-(E)-1-(2-(2,3-dihydrobenzofuran-5-yl)ethyl)-4-(iodoallyl)piperazine ([125I]-E-IA- BF-PE-PIPZE), a radioligand for sigma-1 (σ1) receptors, coupled with examples from the recent literature. Findings are compared to those previously observed for [125I]-(E)-1-(2-(2,3-dimethoxy-5-yl)ethyl)-4-(iodoallyl)piperazine ([125I]-E-IA-DM-PE-PIPZE). Methods Syntheses of E-IA-BF-PE-PIPZE and [125I]-E-IA-BF-PE-PIPZE were accomplished by standard methods. In vitro receptor binding studies and autoradiography were performed, and binding potential was predicted. Measurements of lipophilicity and protein binding were obtained. In vivo studies were conducted in mice to evaluate radioligand stability, as well as specific binding to σ1 sites in brain, brain regions and peripheral organs in the presence and absence of potential blockers. Results E-IA-BF-PE-PIPZE exhibited high affinity and selectivity for σ1 receptors (Ki = 0.43 ± 0.03 nM, σ2 / σ1 = 173). [125I]-E-IA-BF-PE-PIPZE was prepared in good yield and purity, with high specific activity. Radioligand binding provided dissociation (koff) and association (kon) rate constants, along with a measured Kd of 0.24 ± 0.01 nM and Bmax of 472 ± 13 fmol / mg protein. The radioligand proved suitable for quantitative autoradiography in vitro using brain sections. Moderate lipophilicity, Log D7.4 2.69 ± 0.28, was determined, and protein binding was 71 ± 0.3%. In vivo, high initial whole brain uptake, > 6% injected dose / g, cleared slowly over 24 h. Specific binding represented 75% to 93% of total binding from 15 min to 24 h. Findings were confirmed and extended by regional brain biodistribution. Radiometabolites were not observed in brain (1%). Conclusions Substitution of dihydrobenzofuranylethyl for dimethoxyphenethyl increased radioligand affinity for σ1 receptors by 16-fold. While high specific binding to σ1 receptors was observed for both radioligands in vivo, [125I]-E-IA-BF-PE-PIPZE displayed much slower clearance kinetics than [125I]-E-IA-DM-PE-PIPZE. Thus, minor structural modifications of σ1 receptor radioligands lead to major differences in binding properties in vitro and in vivo.

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Age-Related Sex-Specific Changes in Brain Metabolism and Morphology

Cited by 67 publications

References 33 publications

Sleep and Human Aging

Sleep and Human Aging

Magnetic resonance imaging and positron emission tomography in the diagnosis of neurodegenerative dementias

Tactics for preclinical validation of receptor-binding radiotracers

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