Neuronal loss and neurofibrillary degeneration in the hippocampal cortex in late‐onset sporadic Alzheimer's disease

Fukutani, Yuken; Cairns, Nigel J.; Shiozawa, Masaki; Sasaki, Kohsuke; Sudo, Satoru; Isaki, Kiminori; Lantos, Peter L.

doi:10.1046/j.1440-1819.2000.00747.x

Cited by 59 publications

(53 citation statements)

References 17 publications

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“…The reduction in ␣ 1D -AR mRNA cannot be attributed to the cell loss documented in the CA1 in AD (Simic et all., 1997;Bobinski et al, 1998;Fukutani et al, 2000;Price et al, 2001;Rossler et al, 2002) because ␣ 2A -AR mRNA expression was unchanged in the same region, in the same subjects. It is possible that these different ␣-AR subtypes are expressed in different neurons and the neurons expressing ␣ 1D -AR mRNA are lost in AD and DLB.…”

Section: Discussionmentioning

confidence: 89%

“…Perhaps the loss of ␣ 2C -AR mRNA in AD and DLB subjects in the hippocampus contributes to these behavior symptoms. The loss of ␣ 2C -AR mRNA in the GCL or CA3 cannot be attributed to neuronal loss in AD because these regions do not demonstrate any degree of loss (Simic et al, 1997;Bobinski et al, 1998;Fukutani et al, 2000;Price et al, 2001;Rossler et al, 2002), and the expression of ␣ 2A -AR mRNA in the same regions was unchanged in AD and DLB.…”

Section: Discussionmentioning

confidence: 99%

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Compensatory Changes in the Noradrenergic Nervous System in the Locus Ceruleus and Hippocampus of Postmortem Subjects with Alzheimer's Disease and Dementia with Lewy Bodies

Szot¹,

White²,

Greenup³

et al. 2006

J. Neurosci.

219

240

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In Alzheimer's disease (AD), there is a significant loss of locus ceruleus (LC) noradrenergic neurons. However, functional and anatomical evidence indicates that the remaining noradrenergic neurons may be compensating for the loss. Because the noradrenergic system plays an important role in learning and memory, it is important to determine whether compensation occurs in noradrenergic neurons in the LC and hippocampus of subjects with AD or a related dementing disorder, dementia with Lewy bodies (DLB). We observed profound neuronal loss in the LC in AD and DLB subjects with three major changes in the noradrenergic system consistent with compensation: (1) an increase in tyrosine hydroxylase (TH) mRNA expression in the remaining neurons; (2) sprouting of dendrites into peri-LC dendritic zone, as determined by ␣ 2 -adrenoreceptors (ARs) and norepinephrine transporter binding sites; and (3) sprouting of axonal projections to the hippocampus as determined by ␣ 2 -ARs. In AD and DLB subjects, the postsynaptic ␣ 1 -ARs were normal to elevated. Expression of ␣ 1A -and ␣ 2A -AR mRNA in the hippocampus of AD and DLB subjects were not altered, but expression of ␣ 1D -and ␣ 2C -AR mRNA was significantly reduced in the hippocampus of AD and DLB subjects. Therefore, in AD and DLB subjects, there is compensation occurring in the remaining noradrenergic neurons, but there does appear to be a loss of specific AR in the hippocampus. Because changes in these noradrenergic markers in AD versus DLB subjects were similar (except neuronal loss and the increase in TH mRNA were somewhat greater in DLB subjects), the presence of Lewy bodies in addition to plaques and tangles in DLB subjects does not appear to further affect the noradrenergic compensatory changes.

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Section: Discussionmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Compensatory Changes in the Noradrenergic Nervous System in the Locus Ceruleus and Hippocampus of Postmortem Subjects with Alzheimer's Disease and Dementia with Lewy Bodies

Szot¹,

White²,

Greenup³

et al. 2006

J. Neurosci.

219

240

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“…Neurofibrillary tangles, a defining feature of Alzheimer's disease (AD), occur earlier and with much greater frequency in the superficial layers of perirhinal and entorhinal cortex than in most areas of neocortex (Brun and Gustafson, 1976;Ball, 1977;Braak andBraak, 1985, 1991;Arnold et al, 1991;Casanova et al, 1993;Arendt et al, 1998;Braak et al, 2000). Regional differentiation is also well documented for the hippocampus, where tangles are significantly more frequent in CA1 than in CA3 neurons (Braak and Braak, 1991;Bobinski et al, 1996;Corder et al, 2000;Fukutani et al, 2000). Aberrant swellings of the initial segments of axons ("meganeurites"), a feature that occurs with increasing frequency in human brains beginning at about age 50, also show a striking regional selectivity (e.g., layer III but not layer V of the frontal cortex), which matches well with the distribution of tangles (Braak, 1984).…”

mentioning

confidence: 99%

Spatial patterns of mammalian brain aging: Distribution of cathepsin D–immunoreactive cell bodies and dystrophic dendrites in aging dogs resembles that in Alzheimer's disease

Head

Cotman

et al. 2003

J of Comparative Neurology

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Elevated levels of the lysosomal enzyme cathepsin D are found in the early stages of Alzheimer's disease (AD) and co-occur with intraneuronal tangles. The present study tested whether increases in cathepsin D would emerge during aging in another mammalian species. Regional brain patterns of cathepsin D immunostaining were compared in dogs ages 0.35 to 16 years. Accumulations of immunopositive material were evident in neuronal cell bodies in many forebrain sites in middle-age to old dogs (>/=6 years). Three types could be distinguished: (1) dense aggregates with no particular position within the cell body; (2) crescent-shaped "caps" that occupied one pole of the cell body; and (3) very dense "spikes" that extended from the cell body for variable distances into the apical dendrite; these spikes were found in only a few areas, most notably the subiculum and layer V of neocortex. The spikes appeared between ages 2 and 5 years and increased steadily with age thereafter. Spikes were found in the subiculum in the aged human brain but only infrequently; they were, however, present in large numbers in AD brains. These results established that brain aging in dogs is (1) well advanced by middle age, (2) varies markedly across regions, and (3) in at least some of its aspects (dystrophic dendrites) is prominent in areas known to exhibit pathology early in the course of AD. Combined with previous results for rats, these findings indicated that changes in cathepsin D observed in AD, in particular in the temporal lobe, reflect a generalized mammalian pattern of brain aging.

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“…AD is characterized by a well-defined progression of its histopathological hallmarks amyloid plaques and neurofibrillary tangles. Particularly the latter has been shown to be closely associated with cognitive performance and neuron loss within the hippocampus and mesio-temporal lobe (Giannakopoulos et al, 1996;Giannakopoulos et al, 2007;Fukutani et al, 2000). The earliest site of neurofibrillary tangle accumulation in the preclinical state of AD is the trans-entorhinal cortex (BA 35) followed by the entorhinal cortex.…”

Section: Discussionmentioning

confidence: 99%

“…The hippocampus is not a homogeneous structure but consists of several histologically and functionally specialized but nonetheless tightly interconnected subfields: the subiculum (SUB) which is subdivided into the prosubiculum, subiculum proper, pre-and parasubiculum, the cornu ammonis sectors (CA) 1-3 and the dentate gyrus (DG) (Duvernoy et al, 2013). Animal and histopathological studies have shown that different pathological conditions affect subfields differently, e.g., Alzheimer's disease and hypoxia damage CA1, schizophrenia CA2, traumatic brain injury and post-traumatic stress syndrome CA3 and temporal lobe epilepsy damages the dentate gyrus (e.g., West et al, 1994;Fukutani et al, 2000;Bluemcke et al, 1999;Lucassen et al, 2006;Baldwin et al, 1997;Bluemcke et al, 2007). These observations suggest that subfield specific information might allow for a better differentiation of different disease processes and consequently for an earlier diagnosis than total hippocampal volume (Small, 2014).…”

Section: Introductionmentioning

confidence: 99%

P2‐231: Systematic Comparison of Different Techniques to Measure Hippocampal Subfield Volumes in ADNI2

Mueller

Yushkevich

Wang

et al. 2016

Alzheimer's & Dementia

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Objective: Subfield-specific measurements provide superior information in the early stages of neurodegenerative diseases compared to global hippocampal measurements. The overall goal was to systematically compare the performance of five representative manual and automated T1 and T2 based subfield labeling techniques in a subset of the ADNI2 population. Methods: The high resolution T2 weighted hippocampal images (T2-HighRes) and the corresponding T1 images from 106 ADNI2 subjects (41 controls, 57 MCI, 8 AD) were processed as follows. A. T1-based: 1. Freesurfer + Large-Diffeomorphic-Metric-Mapping in combination with shape analysis. 2. FreeSurfer 5.1 subfields using invivo atlas. B. T2-HighRes: 1. Model-based subfield segmentation using ex-vivo atlas (FreeSurfer 6.0). 2. T2-based automated multi-atlas segmentation combined with similarity-weighted voting (ASHS). 3. Manual subfield parcellation. Multiple regression analyses were used to calculate effect sizes (ES) for group, amyloid positivity in controls, and associations with cognitive/memory performance for each approach. Results: Subfield volumetry was better than whole hippocampal volumetry for the detection of the mild atrophy differences between controls and MCI (ES: 0.27 vs 0.11). T2-HighRes approaches outperformed T1 approaches for the detection of early stage atrophy (ES: 0.27 vs.0.10), amyloid positivity (ES: 0.11 vs 0.04), and cognitive associations (ES: 0.22 vs 0.19). Conclusions: T2-HighRes subfield approaches outperformed whole hippocampus and T1 subfield approaches. None of the different T2-HghRes methods tested had a clear advantage over the other methods. Each has strengths and weaknesses that need to be taken into account when deciding which one to use to get the best results from subfield volumetry.

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Neuronal loss and neurofibrillary degeneration in the hippocampal cortex in late‐onset sporadic Alzheimer's disease

Cited by 59 publications

References 17 publications

Compensatory Changes in the Noradrenergic Nervous System in the Locus Ceruleus and Hippocampus of Postmortem Subjects with Alzheimer's Disease and Dementia with Lewy Bodies

Compensatory Changes in the Noradrenergic Nervous System in the Locus Ceruleus and Hippocampus of Postmortem Subjects with Alzheimer's Disease and Dementia with Lewy Bodies

Spatial patterns of mammalian brain aging: Distribution of cathepsin D–immunoreactive cell bodies and dystrophic dendrites in aging dogs resembles that in Alzheimer's disease

P2‐231: Systematic Comparison of Different Techniques to Measure Hippocampal Subfield Volumes in ADNI2

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