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E. Sowell, B. Peterson, P. Thompson, Suzanne Welcome, Amy Henkenius, A. Toga (2003)
Mapping cortical change across the human life spanNature Neuroscience, 6
Stephen Smith (2002)
Fast robust automated brain extractionHuman Brain Mapping, 17
E. Courchesne, H. Chisum, J. Townsend, Angilene Cowles, James Covington, B. Egaas, Mark Harwood, Stuart Hinds, G. Press (2000)
Normal brain development and aging: quantitative analysis at in vivo MR imaging in healthy volunteers.Radiology, 216 3
L. Qiu, J. Germann, S. Spring, C. Alm, D. Vousden, M. Palmert, J. Lerch (2013)
Hippocampal volumes differ across the mouse estrous cycle, can change within 24hours, and associate with cognitive strategiesNeuroImage, 83
S. Mueller, L. Stables, A. Du, N. Schuff, D. Truran, N. Cashdollar, M. Weiner (2007)
Measurement of hippocampal subfields and age-related changes with high resolution MRI at 4TNeurobiology of Aging, 28
Jordan Poppenk, Hallvard Evensmoen, M. Moscovitch, L. Nadel (2013)
Long-axis specialization of the human hippocampusTrends in Cognitive Sciences, 17
M. Folstein, M. Folstein, S. Folstein, S. Folstein, P. McHugh, P. McHugh (1975)
“Mini-mental state”: A practical method for grading the cognitive state of patients for the clinicianJournal of Psychiatric Research, 12
J. Steiger (1980)
Tests for comparing elements of a correlation matrix.Psychological Bulletin, 87
Joshua Breunig, J. Arellano, J. Macklis, P. Rakic (2007)
Everything that glitters isn't gold: a critical review of postnatal neural precursor analyses.Cell stem cell, 1 6
R. Green (1991)
The human hippocampus: An atlas of applied anatomyJournal of Epilepsy, 4
C. Jack, C. Twomey, A. Zinsmeister, F. Sharbrough, R. Petersen, G. Cascino (1989)
Anterior temporal lobes and hippocampal formations: normative volumetric measurements from MR images in young adults.Radiology, 172 2
S. Krogsrud, C. Tamnes, A. Fjell, I. Amlien, Håkon Grydeland, Unni Sulutvedt, P. Due-Tønnessen, A. Bjørnerud, A. Sølsnes, A. Håberg, Jon Skrane, K. Walhovd (2014)
Development of hippocampal subfield volumes from 4 to 22 yearsHuman Brain Mapping, 35
N. Raz, U. Lindenberger, K. Rodrigue, K. Kennedy, D. Head, Adrienne Williamson, Cheryl Dahle, D. Gerstorf, J. Acker (2005)
Regional brain changes in aging healthy adults: general trends, individual differences and modifiers.Cerebral cortex, 15 11
G. Kerchner, D. Berdnik, J. Shen, Jeffrey Bernstein, Michelle Fenesy, G. Deutsch, T. Wyss-Coray, B. Rutt (2014)
APOE ε4 worsens hippocampal CA1 apical neuropil atrophy and episodic memoryNeurology, 82
S. Mueller, M. Weiner (2009)
Selective effect of age, Apo e4, and Alzheimer's disease on hippocampal subfieldsHippocampus, 19
Y. Shing, K. Rodrigue, K. Kennedy, Yana Fandakova, N. Bodammer, M. Werkle-Bergner, U. Lindenberger, N. Raz (2011)
Hippocampal Subfield Volumes: Age, Vascular Risk, and Correlation with Associative MemoryFrontiers in Aging Neuroscience, 3
M. Kassem, J. Lagopoulos, T. Stait-Gardner, W. Price, Tariq Chohan, J. Arnold, S. Hatton, M. Bennett (2013)
Stress-Induced Grey Matter Loss Determined by MRI Is Primarily Due to Loss of Dendrites and Their SynapsesMolecular Neurobiology, 47
N. Ofen (2012)
The development of neural correlates for memory formation, 36
J. Pereira, C. Valls-Pedret, E. Ros, E. Palacios, C. Falcón, N. Bargalló, D. Bartrés-Faz, L. Wahlund, E. Westman, C. Junqué (2014)
Regional vulnerability of hippocampal subfields to aging measured by structural and diffusion MRIHippocampus, 24
(2006)
Hippocampal neuroanatomy
Arne Ekstrom, Adam Bazih, N. Suthana, R. Al-Hakim, K. Ogura, M. Zeineh, A. Burggren, S. Bookheimer (2009)
Advances in high-resolution imaging and computational unfolding of the human hippocampusNeuroImage, 47
N. Raz, A. Daugherty, Andrew Bender, Cheryl Dahle, S. Land (2014)
Volume of the hippocampal subfields in healthy adults: differential associations with age and a pro-inflammatory genetic variantBrain Structure and Function, 220
C. Tamnes, K. Walhovd, A. Engvig, Håkon Grydeland, S. Krogsrud, Ylva Østby, D. Holland, A. Dale, A. Fjell (2014)
Regional Hippocampal Volumes and Development Predict Learning and MemoryDevelopmental Neuroscience, 36
A. Holtmaat, K. Svoboda (2009)
Experience-dependent structural synaptic plasticity in the mammalian brainNature Reviews Neuroscience, 10
N Raz, KM. Kennedy (2009)
Imaging the Aging Brain
C. Petito, W. Pulsinelli (1984)
Delayed Neuronal Recovery and Neuronal Death in Rat Hippocampus following Severe Cerebral Ischemia: Possible Relationship to Abnormalities in Neuronal ProcessesJournal of Cerebral Blood Flow & Metabolism, 4
M. Bobinski, M. Leon, M. Leon, J. Wegiel, S. Desanti, A. Convit, A. Convit, L. Louis, H. Rusinek, H. Wiśniewski (1999)
The histological validation of post mortem magnetic resonance imaging-determined hippocampal volume in Alzheimer's diseaseNeuroscience, 95
R. Insausti, S. Cebada-Sánchez, P. Marcos (2009)
Postnatal development of the human hippocampal formation.Advances in anatomy, embryology, and cell biology, 206
S. Mueller, N. Schuff, S. Raptentsetsang, J. Elman, M. Weiner (2008)
Selective effect of Apo e4 on CA3 and dentate in normal aging and Alzheimer's disease using high resolution MRI at 4 TNeuroImage, 42
R. Joie, Marine Fouquet, F. Mézenge, B. Landeau, Nicolas Villain, K. Mevel, Alice Pélerin, F. Eustache, B. Desgranges, G. Chételat (2010)
Differential effect of age on hippocampal subfields assessed using a new high-resolution 3T MR sequenceNeuroImage, 53
U. Lindenberger, Timo Oertzen, Paolo Ghisletta, C. Hertzog (2011)
Cross-sectional age variance extraction: what's change got to do with it?Psychology and aging, 26 1
E. Sullivan, A. Pfefferbaum, T. Rohlfing, F. Baker, Mayra Padilla, I. Colrain (2011)
Developmental change in regional brain structure over 7 months in early adolescence: Comparison of approaches for longitudinal atlas-based parcellationNeuroImage, 57
E. Carmines, R. Zeller (1979)
Reliability and Validity Assessment
L. Luo, D. O'Leary (2005)
Axon retraction and degeneration in development and disease.Annual review of neuroscience, 28
N. Ofen
Neuroscience and Biobehavioral Reviews the Development of Neural Correlates for Memory Formation
LS. Radloff (1977)
The CES‐D scale: A self‐report depression scale for research in the general population, 153
C. Quintana, S. Bellefqih, J. Laval, J. Guerquin-Kern, T. Wu, J. Avila, I. Ferrer, R. Arranz, C. Patiño (2006)
Study of the localization of iron, ferritin, and hemosiderin in Alzheimer's disease hippocampus by analytical microscopy at the subcellular level.Journal of structural biology, 153 1
Xiaozhen Li, Tie-Qiang Li, Neils Andreasen, M. Wiberg, E. Westman, L. Wahlund (2014)
MICROBLEEDS RELATED WITH BRAIN STRUCTURAL CHANGES AND CSF BIOMARKERS IN ALZHEIMER'S DISEASEAlzheimer's & Dementia, 10
R. Flores, R. Joie, B. Landeau, Audrey Perrotin, F. Mézenge, V. Sayette, F. Eustache, B. Desgranges, G. Chételat (2014)
EFFECTS OF AGE AND ALZHEIMER'S DISEASE ON HIPPOCAMPAL SUBFIELDS: COMPARISON BETWEEN MANUAL AND FREESURFER VOLUMETRYAlzheimer's & Dementia, 10
N. Raz, K. Kennedy (2009)
A Systems Approach to the Aging Brain: Neuroanatomic Changes, Their Modifiers, and Cognitive Correlates
JIH Keuker, T Michaelis, G Biurrun, PGM Luiten, MP Witter, E. Fuchs (2002)
Aging in Nonhuman Primates. Interdisciplinary Topics in Gerontology, 31
N. Raz, Faith Gunning-Dixon, D. Head, K. Rodrigue, Adrienne Williamson, J. Acker (2004)
Aging, sexual dimorphism, and hemispheric asymmetry of the cerebral cortex: replicability of regional differences in volumeNeurobiology of Aging, 25
N. Ho, J. Hooker, Amar Sahay, D. Holt, J. Roffman (2013)
In vivo imaging of adult human hippocampal neurogenesis: progress, pitfalls and promiseMolecular Psychiatry, 18
S. Small, S. Schobel, R. Buxton, M. Witter, C. Barnes (2011)
A pathophysiological framework of hippocampal dysfunction in ageing and diseaseNature Reviews Neuroscience, 12
Paul Yushkevich, J. Pluta, Hongzhi Wang, L. Xie, S. Ding, E. Gertje, L. Mancuso, Daria Kliot, Sandhitsu Das, D. Wolk (2015)
Automated volumetry and regional thickness analysis of hippocampal subfields and medial temporal cortical structures in mild cognitive impairmentHuman Brain Mapping, 36
Joshua Lee, Arne Ekstrom, S. Ghetti (2014)
Volume of hippocampal subfields and episodic memory in childhood and adolescenceNeuroImage, 94
Matthew Jones, T. McHugh (2011)
Updating hippocampal representations: CA2 joins the circuitTrends in Neurosciences, 34
N. Raz, Paolo Ghisletta, K. Rodrigue, K. Kennedy, U. Lindenberger (2010)
Trajectories of brain aging in middle-aged and older adults: Regional and individual differencesNeuroImage, 51
E. Gould (2007)
How widespread is adult neurogenesis in mammals?Nature Reviews Neuroscience, 8
(2014)
volume across MRI field strengths ( 1 . 5 T and 3 T )
EG Carmines, RA. Zeller (1979)
Quantitative Applications in the Social Sciences
N. Gogtay, Thomas Nugent, D. Herman, A. Ordóñez, D. Greenstein, K. Hayashi, L. Clasen, A. Toga, J. Giedd, J. Rapoport, P. Thompson (2006)
Dynamic mapping of normal human hippocampal developmentHippocampus, 16
Bruce Perry, Marsha White, Steve Dorman, Gogtay Md, J. Giedd, Leslie Ba, Kiralee Bs, D. Greenstein, A. Vaituzis, David Bs, Thomas Nugent, Iii Ab, L. Clasen, A. Toga, J. Rapoport, P. Thompson, Johnson Sb, Blum Rw, Tiemeier H, Lenroot Rk, Greenstein Dk, Tran L, Pierson Giedd, Jn Cerebellum, Giedd Jn, Lalonde Fm, Celano Mj, White Sl, Wallace Gl, Lee Nr, Lenroot Magnetic, Shaw P, Addington A, Evans A, Rapoport J (2004)
Dynamic mapping of human cortical development during childhood through early adulthood.Proceedings of the National Academy of Sciences of the United States of America, 101 21
D Amaral, P. Lavenex (2006)
The Hippocampus Book Oxford Neuroscience Series
L. Wisse, G. Biessels, S. Heringa, H. Kuijf, Dineke Koek, P. Luijten, M. Geerlings (2014)
Hippocampal subfield volumes at 7T in early Alzheimer's disease and normal agingNeurobiology of Aging, 35
A. Mattai, Avinash Hosanagar, B. Weisinger, D. Greenstein, R. Stidd, L. Clasen, F. Lalonde, J. Rapoport, N. Gogtay (2011)
Hippocampal volume development in healthy siblings of childhood-onset schizophrenia patients.The American journal of psychiatry, 168 4
L. Radloff (1977)
The CES-D ScaleApplied Psychological Measurement, 1
L. Radloff
The CES-D Scale: A Self-Report Depression Scale for Research in the General Population — Source link
P. Lavenex, P. Lavenex (2013)
Building hippocampal circuits to learn and remember: Insights into the development of human memoryBehavioural Brain Research, 254
S. Sgouros, K. Natarajan, A. Hockley, J. Goldin, M. Wake (1999)
Skull Base Growth in ChildhoodPediatric Neurosurgery, 31
R. Olsen, D. Palombo, J. Rabin, B. Levine, J. Ryan, R. Rosenbaum (2013)
Volumetric Analysis of Medial Temporal Lobe Subregions in Developmental Amnesia using High-Resolution Magnetic Resonance ImagingHippocampus, 23
N. Malykhin, R. Lebel, N. Coupland, A. Wilman, Rawle Carter (2010)
In vivo quantification of hippocampal subfields using 4.7 T fast spin echo imagingNeuroImage, 49
P. Shrout, J. Fleiss (1979)
Intraclass correlations: uses in assessing rater reliability.Psychological bulletin, 86 2
Andrew Bender, A. Daugherty, N. Raz (2013)
Vascular Risk Moderates Associations between Hippocampal Subfield Volumes and MemoryJournal of Cognitive Neuroscience, 25
J. Keuker, T. Michaelis, G. Biurrun, P. Luiten, M. Witter, E. Fuchs (2002)
Methodological Considerations when Studying the Aging Process in the Nonhuman Primate Brain, 31
H. Duvernoy (1988)
The Human Hippocampus: An Atlas of Applied Anatomy
S. Keihaninejad, R. Heckemann, Gianlorenzo Fagiolo, M. Symms, Joseph Hajnal, A. Hammers (2010)
A robust method to estimate the intracranial volume across MRI field strengths (1.5T and 3T)Neuroimage, 50
ABSTRACT The hippocampus is composed of distinct subfields: the four cornu ammonis areas (CA1‐CA4), dentate gyrus (DG), and subiculum. The few in vivo studies of human hippocampal subfields suggest that the extent of age differences in volume varies across subfields during healthy childhood development and aging. However, the associations between age and subfield volumes across the entire lifespan are unknown. Here, we used a high‐resolution imaging technique and manually measured hippocampal subfield and entorhinal cortex volumes in a healthy lifespan sample (N = 202), ages 8–82 yrs. The magnitude of age differences in volume varied among the regions. Combined CA1‐2 volume evidenced a negative linear association with age. In contrast, the associations between age and volumes of CA3‐DG and the entorhinal cortex were negative in mid‐childhood and attenuated in later adulthood. Volume of the subiculum was unrelated to age. The different magnitudes and patterns of age differences in subfield volumes may reflect dynamic microstructural factors and have implications for cognitive functions across the lifespan. © 2015 Wiley Periodicals, Inc.
Hippocampus – Wiley
Published: Feb 1, 2016
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