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Literature DB >> 30325048

Development of the cerebral cortex and the effect of the intrauterine environment.

Sebastian Quezada^1,2, Margie Castillo-Melendez^1,2, David W Walker³, Mary Tolcos³.

Abstract

The human brain is one of the most complex structures currently under study. Its external shape is highly convoluted, with folds and valleys over the entire surface of the cortex. Disruption of the normal pattern of folding is associated with a number of abnormal neurological outcomes, some serious for the individual. Most of our knowledge of the normal development and folding of the cerebral cortex (gyrification) focuses on the internal, biological (i.e. genetically driven) mechanisms of the brain that drive gyrification. However, the impact of an adverse intrauterine and maternal physiological environment on cortical folding during fetal development has been understudied. Accumulating evidence suggests that the state of the intrauterine and maternal environment can have a significant impact on gyrification of the fetal cerebral cortex. This review summarises our current knowledge of how development in a suboptimal intrauterine and maternal environment can affect the normal development of the folded cerebral cortex.

Entities: Species

Keywords: brain development; gyrification; intrauterine growth restriction

Mesh：

Year: 2018 PMID： 30325048 PMCID： PMC6265571 DOI： 10.1113/JP277151

Source DB: PubMed Journal: J Physiol ISSN： 0022-3751 Impact factor: 5.182

118 in total

1. Altered fate of subventricular zone progenitor cells and reduced neurogenesis following neonatal stroke.

Authors: Ruggero Spadafora; Fernando F Gonzalez; Nikita Derugin; Michael Wendland; Donna Ferriero; Patrick McQuillen
Journal: Dev Neurosci Date: 2010-05-04 Impact factor: 2.984

2. Magnetic resonance imaging study of cerebral sulci in low-risk preterm children.

Authors: Leire Zubiaurre-Elorza; Sara Soria-Pastor; Carme Junqué; Pere Vendrell; Nelly Padilla; Giuseppina Rametti; Núria Bargalló; Francesc Botet
Journal: Int J Dev Neurosci Date: 2009-06-27 Impact factor: 2.457

3. Does degree of gyrification underlie the phenotypic and genetic associations between cortical surface area and cognitive ability?

Authors: Anna R Docherty; Donald J Hagler; Matthew S Panizzon; Michael C Neale; Lisa T Eyler; Christine Fennema-Notestine; Carol E Franz; Amy Jak; Michael J Lyons; Daniel A Rinker; Wesley K Thompson; Ming T Tsuang; Anders M Dale; William S Kremen
Journal: Neuroimage Date: 2014-11-26 Impact factor: 6.556

4. Perinatal chronic hypoxia induces cortical inflammation, hypomyelination, and peripheral myelin-specific T cell autoreactivity.

Authors: Sterling B Ortega; Xiagmei Kong; Ramgopal Venkataraman; Allen Michael Savedra; Steven G Kernie; Ann M Stowe; Lakshmi Raman
Journal: J Leukoc Biol Date: 2015-06-02 Impact factor: 4.962

5. Cortical gyrification induced by fibroblast growth factor 2 in the mouse brain.

Authors: Brian G Rash; Simone Tomasi; H David Lim; Carol Y Suh; Flora M Vaccarino
Journal: J Neurosci Date: 2013-06-26 Impact factor: 6.167

Review 6. The diverse genetic landscape of neurodevelopmental disorders.

Authors: Wen F Hu; Maria H Chahrour; Christopher A Walsh
Journal: Annu Rev Genomics Hum Genet Date: 2014 Impact factor: 8.929

7. Abnormal spindle-like microcephaly-associated (ASPM) mutations strongly disrupt neocortical structure but spare the hippocampus and long-term memory.

Authors: Sandrine Passemard; Alain Verloes; Thierry Billette de Villemeur; Odile Boespflug-Tanguy; Karen Hernandez; Marion Laurent; Bertrand Isidor; Corinne Alberti; Nathalie Pouvreau; Séverine Drunat; Bénédicte Gérard; Vincent El Ghouzzi; Jorge Gallego; Monique Elmaleh-Bergès; Wieland B Huttner; Stephan Eliez; Pierre Gressens; Marie Schaer
Journal: Cortex Date: 2015-10-31 Impact factor: 4.027

8. Neural stem/progenitor cells participate in the regenerative response to perinatal hypoxia/ischemia.

Authors: Ryan J Felling; Matthew J Snyder; Michael J Romanko; Raymond P Rothstein; Amber N Ziegler; Zhengang Yang; Maria I Givogri; Ernesto R Bongarzone; Steven W Levison
Journal: J Neurosci Date: 2006-04-19 Impact factor: 6.167

9. Identification and interpretation of microstructural abnormalities in motor pathways in adolescents born preterm.

Authors: Samuel Groeschel; J-Donald Tournier; Gemma B Northam; Torsten Baldeweg; John Wyatt; Brigitte Vollmer; Alan Connelly
Journal: Neuroimage Date: 2013-10-31 Impact factor: 6.556

Review 10. From genes to folds: a review of cortical gyrification theory.

Authors: Lisa Ronan; Paul C Fletcher
Journal: Brain Struct Funct Date: 2014-12-16 Impact factor: 3.270

8 in total

1. Challenges and controversies in perinatal physiology.

Authors: L Bennet; T Ikeda; A J Llanos; J Nijhuis; A J Gunn
Journal: J Physiol Date: 2018-12 Impact factor: 5.182

2. Associations of gestational age with gyrification and neurocognition in healthy adults.

Authors: Simon Schmitt; Kai G Ringwald; Tina Meller; Frederike Stein; Katharina Brosch; Julia-Katharina Pfarr; Tim Hahn; Hannah Lemke; Susanne Meinert; Jonathan Repple; Katharina Thiel; Lena Waltemate; Alexandra Winter; Dominik Grotegerd; Astrid Dempfle; Andreas Jansen; Axel Krug; Udo Dannlowski; Igor Nenadić; Tilo Kircher
Journal: Eur Arch Psychiatry Clin Neurosci Date: 2022-07-29 Impact factor: 5.760

Development of the cerebral cortex and the effect of the intrauterine environment.

1. Altered fate of subventricular zone progenitor cells and reduced neurogenesis following neonatal stroke.

2. Magnetic resonance imaging study of cerebral sulci in low-risk preterm children.

3. Does degree of gyrification underlie the phenotypic and genetic associations between cortical surface area and cognitive ability?

4. Perinatal chronic hypoxia induces cortical inflammation, hypomyelination, and peripheral myelin-specific T cell autoreactivity.

5. Cortical gyrification induced by fibroblast growth factor 2 in the mouse brain.

Review 6. The diverse genetic landscape of neurodevelopmental disorders.

7. Abnormal spindle-like microcephaly-associated (ASPM) mutations strongly disrupt neocortical structure but spare the hippocampus and long-term memory.

8. Neural stem/progenitor cells participate in the regenerative response to perinatal hypoxia/ischemia.

9. Identification and interpretation of microstructural abnormalities in motor pathways in adolescents born preterm.

Review 10. From genes to folds: a review of cortical gyrification theory.

1. Challenges and controversies in perinatal physiology.

2. Associations of gestational age with gyrification and neurocognition in healthy adults.

3. MicroRNA-185-5p: a marker of brain-sparing in foetuses with late-onset growth restriction.

Review 4. Across Dimensions: Developing 2D and 3D Human iPSC-Based Models of Fragile X Syndrome.

5. Quantifying Genetic and Environmental Influence on Gray Matter Microstructure Using Diffusion MRI.

6. MicroRNA-132 is overexpressed in fetuses with late-onset fetal growth restriction.

7. Cortical Gyrification Morphology in Adult Males with Mild Traumatic Brain Injury.

8. Prenatal caffeine exposure: association with neurodevelopmental outcomes in 9- to 11-year-old children.