Twin-Singleton Differences in Neonatal Brain Structure

Rebecca C. Knickmeyer; Chaeryon Kang; Sandra Woolson; J. Keith Smith; Robert M. Hamer; Weili Lin; Guido Gerig; Martin Styner; John H. Gilmore

doi:10.1375/twin.14.3.268

Abstract

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Twin studies suggest that global and regional brain volumes are highly heritable. However, estimates of heritability vary across development. Given that all twin studies are open to the potential criticism of non-generalizability due to differences in intrauterine environment between twins and singletons, these age effects may reflect the influence of perinatal environmental factors, which are unique to twins and which may be especially evident early in life. To address this question, we compared brain volumes and the relationship of brain volumes to gestational age in 136 singletons (67 male, 69 female) and 154 twins (75 male, 79 female; 82 DZ, 72 MZ) who had received high resolution MRI scans of the brain in the first month of life. Intracranial volume, total white matter, and ventricle volumes did not differ between twins and singletons. However, cerebrospinal fluid and frontal white matter volume was greater in twins compared to singletons. While gray matter volumes at MRI did not differ between groups, the slope of the relationship between total and cortical gray matter and gestational age at the MRI scan was steeper in MZ twins compared to DZ twins. Post-hoc analyses suggested that gray matter development is delayed in MZ twins in utero and that they experience ‘catch-up’ growth in the first month of life. These differences should be taken into account when interpreting and designing studies in the early postnatal period.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Gilmore, J. H. Shi, F. Woolson, S. L. Knickmeyer, R. C. Short, S. J. Lin, W. Zhu, H. Hamer, R. M. Styner, M. and Shen, D. 2012. Longitudinal Development of Cortical and Subcortical Gray Matter from Birth to 2 Years. Cerebral Cortex, Vol. 22, Issue. 11, p. 2478.

Charney, Evan 2012. Behavior genetics and postgenomics. Behavioral and Brain Sciences, Vol. 35, Issue. 5, p. 331.

El-Sayed, Abdulrahman M Koenen, Karestan C and Galea, Sandro 2013. Putting the ‘epi’ into epigenetics research in psychiatry. Journal of Epidemiology and Community Health, Vol. 67, Issue. 7, p. 610.

Zhang, Yajing Chang, Linda Ceritoglu, Can Skranes, Jon Ernst, Thomas Mori, Susumu Miller, Michael I. and Oishi, Kenichi 2014. A Bayesian approach to the creation of a study-customized neonatal brain atlas. NeuroImage, Vol. 101, Issue. , p. 256.

Grewen, Karen Burchinal, Margaret Vachet, Clement Gouttard, Sylvain Gilmore, John H. Lin, Weili Johns, Josephine Elam, Mala and Gerig, Guido 2014. Prenatal cocaine effects on brain structure in early infancy. NeuroImage, Vol. 101, Issue. , p. 114.

Gimi, Barjor Molthen, Robert C. Lee, Kevin Cherel, Marie Budin, Francois Gilmore, John Zaldarriaga Consing, Kirsten Rasmussen, Jerod Wadhwa, Pathik D. Entringer, Sonja Glasser, Matthew F. Van Essen, David C. Buss, Claudia and Styner, Martin 2015. Early postnatal myelin content estimate of white matter via T1w/T2w ratio. Vol. 9417, Issue. , p. 94171R.

Lee, Seung Jae Steiner, Rachel J. Luo, Shikai Neale, Michael C. Styner, Martin Zhu, Hongtu and Gilmore, John H. 2015. Quantitative tract-based white matter heritability in twin neonates. NeuroImage, Vol. 111, Issue. , p. 123.

Sadeghi, N. Gerig, G. and Gilmore, J.H. 2015. Brain Mapping. p. 429.

Bekiesinska-Figatowska, Monika 2016. MRI of Fetal and Maternal Diseases in Pregnancy. p. 231.

Budisavljevic, Sanja Kawadler, Jamie M. Dell'Acqua, Flavio Rijsdijk, Frühling V. Kane, Fergus Picchioni, Marco McGuire, Philip Toulopoulou, Timothea Georgiades, Anna Kalidindi, Sridevi Kravariti, Eugenia Murray, Robin M. Murphy, Declan G. Craig, Michael C. and Catani, Marco 2016. Heritability of the limbic networks. Social Cognitive and Affective Neuroscience, Vol. 11, Issue. 5, p. 746.

Sadeghi, Neda Gilmore, John H. and Gerig, Guido 2017. Twin-singleton developmental study of brain white matter anatomy. Human Brain Mapping, Vol. 38, Issue. 2, p. 1009.

Kokkinaki, Theano and Markodimitraki, Maria 2019. Spontaneous emotional coordination of first-born dizygotic twins and singletons with their mothers in early infancy. European Journal of Developmental Psychology, Vol. 16, Issue. 3, p. 268.

Maggioni, Eleonora Squarcina, Letizia Dusi, Nicola Diwadkar, Vaibhav A. and Brambilla, Paolo 2020. Twin MRI studies on genetic and environmental determinants of brain morphology and function in the early lifespan. Neuroscience & Biobehavioral Reviews, Vol. 109, Issue. , p. 139.

Gilmore, John H. Langworthy, Benjamin Girault, Jessica B. Fine, Jason Jha, Shaili C. Kim, Sun Hyung Cornea, Emil and Styner, Martin 2020. Individual Variation of Human Cortical Structure Is Established in the First Year of Life. Biological Psychiatry: Cognitive Neuroscience and Neuroimaging, Vol. 5, Issue. 10, p. 971.

Richter, Maria Vignotto, Micol Mock, Julia Obrig, Hellmuth and Rossi, Sonja 2021. Different word-learning contexts alter phonotactic rule learning in 6-month-olds. Language, Cognition and Neuroscience, Vol. 36, Issue. 9, p. 1135.

Wilson, Sylia and Rhee, Soo Hyun 2022. Special Issue editorial: Leveraging genetically informative study designs to understand the development and familial transmission of psychopathology. Development and Psychopathology, Vol. 34, Issue. 5, p. 1645.

Khare, Ayush Gaur, Ajay Kumar Mittal, Megha and Bansal, Satvik Chaitanya 2024. Nomograms and Reference Ranges for Intra-Cranial Ventricular Dimensions in Indian Neonates. Indian Journal of Pediatrics,

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Twin-Singleton Differences in Neonatal Brain Structure

Abstract

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Twin-Singleton Differences in Neonatal Brain Structure

Abstract

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