Cortical thickness correlates of specific cognitive performance accounted for by the general factor of intelligence in healthy children aged 6 to 18

doi:10.1016/j.neuroimage.2011.01.016

. 2011 Apr 15;55(4):1443-53.

doi: 10.1016/j.neuroimage.2011.01.016. Epub 2011 Jan 15.

Cortical thickness correlates of specific cognitive performance accounted for by the general factor of intelligence in healthy children aged 6 to 18

Sherif Karama¹, Roberto Colom, Wendy Johnson, Ian J Deary, Richard Haier, Deborah P Waber, Claude Lepage, Hooman Ganjavi, Rex Jung, Alan C Evans; Brain Development Cooperative Group

Collaborators, Affiliations

Collaborators

Brain Development Cooperative Group:
William S Ball, Anna Weber Byars, Mark Schapiro, Wendy Bommer, April Carr, April German, Scott Dunn, Michael J Rivkin, Deborah Waber, Robert Mulkern, Sridhar Vajapeyam, Abigail Chiverton, Peter Davis, Julie Koo, Jacki Marmor, Christine Mrakotsky, Richard Robertson, Gloria McAnulty, Michael E Brandt, Jack M Fletcher, Larry A Kramer, Grace Yang, Cara McCormack, Kathleen M Hebert, Hilda Volero, Kelly Botteron, Robert C McKinstry, William Warren, Tomoyuki Nishino, C Robert Almli, Richard Todd, John Constantino, James T McCracken, Jennifer Levitt, Jeffrey Alger, Joseph O'Neil, Arthur Toga, Robert Asarnow, David Fadale, Laura Heinichen, Cedric Ireland, Dah-Jyuu Wang, Edward Moss, Robert A Zimmerman, Brooke Bintliff, Ruth Bradford, Janice Newman, Alan C Evans, Rozalia Arnaoutelis, G Bruce Pike, D Louis Collins, Gabriel Leonard, Tomas Paus, Alex Zijdenbos, Samir Das, Vladimir Fonov, Luke Fu, Jonathan Harlap, Ilana Leppert, Denise Milovan, Dario Vins, Thomas Zeffiro, John Van Meter, Nicholas Lange, Michael P Froimowitz, Kelly Botteron, C Robert Almli, Cheryl Rainey, Stan Henderson, Tomoyuki Nishino, William Warren, Jennifer L Edwards, Diane Dubois, Karla Smith, Tish Singer, Aaron A Wilber, Carlo Pierpaoli, Peter J Basser, Lin-Ching Chang, Chen Guan Koay, Lindsay Walker, Lisa Freund, Judith Rumsey, Lauren Baskir, Laurence Stanford, Karen Sirocco, Katrina Gwinn-Hardy, Giovanna Spinella, James T McCracken, Jeffry R Alger, Jennifer Levitt, Joseph O'Neill

Affiliation

¹ McConnell Brain Imaging Centre, Montreal Neurological Institute, McGill University, Montreal, QC, Canada. sherif.karama@mail.mcgill.ca

PMID: 21241809
PMCID: PMC3070152
DOI: 10.1016/j.neuroimage.2011.01.016

Cortical thickness correlates of specific cognitive performance accounted for by the general factor of intelligence in healthy children aged 6 to 18

Sherif Karama et al. Neuroimage. 2011.

. 2011 Apr 15;55(4):1443-53.

doi: 10.1016/j.neuroimage.2011.01.016. Epub 2011 Jan 15.

Authors

Sherif Karama¹, Roberto Colom, Wendy Johnson, Ian J Deary, Richard Haier, Deborah P Waber, Claude Lepage, Hooman Ganjavi, Rex Jung, Alan C Evans; Brain Development Cooperative Group

Collaborators

Brain Development Cooperative Group:
William S Ball, Anna Weber Byars, Mark Schapiro, Wendy Bommer, April Carr, April German, Scott Dunn, Michael J Rivkin, Deborah Waber, Robert Mulkern, Sridhar Vajapeyam, Abigail Chiverton, Peter Davis, Julie Koo, Jacki Marmor, Christine Mrakotsky, Richard Robertson, Gloria McAnulty, Michael E Brandt, Jack M Fletcher, Larry A Kramer, Grace Yang, Cara McCormack, Kathleen M Hebert, Hilda Volero, Kelly Botteron, Robert C McKinstry, William Warren, Tomoyuki Nishino, C Robert Almli, Richard Todd, John Constantino, James T McCracken, Jennifer Levitt, Jeffrey Alger, Joseph O'Neil, Arthur Toga, Robert Asarnow, David Fadale, Laura Heinichen, Cedric Ireland, Dah-Jyuu Wang, Edward Moss, Robert A Zimmerman, Brooke Bintliff, Ruth Bradford, Janice Newman, Alan C Evans, Rozalia Arnaoutelis, G Bruce Pike, D Louis Collins, Gabriel Leonard, Tomas Paus, Alex Zijdenbos, Samir Das, Vladimir Fonov, Luke Fu, Jonathan Harlap, Ilana Leppert, Denise Milovan, Dario Vins, Thomas Zeffiro, John Van Meter, Nicholas Lange, Michael P Froimowitz, Kelly Botteron, C Robert Almli, Cheryl Rainey, Stan Henderson, Tomoyuki Nishino, William Warren, Jennifer L Edwards, Diane Dubois, Karla Smith, Tish Singer, Aaron A Wilber, Carlo Pierpaoli, Peter J Basser, Lin-Ching Chang, Chen Guan Koay, Lindsay Walker, Lisa Freund, Judith Rumsey, Lauren Baskir, Laurence Stanford, Karen Sirocco, Katrina Gwinn-Hardy, Giovanna Spinella, James T McCracken, Jeffry R Alger, Jennifer Levitt, Joseph O'Neill

Affiliation

¹ McConnell Brain Imaging Centre, Montreal Neurological Institute, McGill University, Montreal, QC, Canada. sherif.karama@mail.mcgill.ca

PMID: 21241809
PMCID: PMC3070152
DOI: 10.1016/j.neuroimage.2011.01.016

Abstract

Prevailing psychometric theories of intelligence posit that individual differences in cognitive performance are attributable to three main sources of variance: the general factor of intelligence (g), cognitive ability domains, and specific test requirements and idiosyncrasies. Cortical thickness has been previously associated with g. In the present study, we systematically analyzed associations between cortical thickness and cognitive performance with and without adjusting for the effects of g in a representative sample of children and adolescents (N=207, Mean age=11.8; SD=3.5; Range=6 to 18.3 years). Seven cognitive tests were included in a measurement model that identified three first-order factors (representing cognitive ability domains) and one second-order factor representing g. Residuals of the cognitive ability domain scores were computed to represent g-independent variance for the three domains and seven tests. Cognitive domain and individual test scores as well as residualized scores were regressed against cortical thickness, adjusting for age, gender and a proxy measure of brain volume. g and cognitive domain scores were positively correlated with cortical thickness in very similar areas across the brain. Adjusting for the effects of g eliminated associations of domain and test scores with cortical thickness. Within a psychometric framework, cortical thickness correlates of cognitive performance on complex tasks are well captured by g in this demographically representative sample.

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Figures

**Figure 1**
Measurement model for the cognitive ability measures.

**Figure 2**
Distribution of g-independent cognitive ability domain scores. Note the approximately normal distribution.

**Figure 3**
Results of cortical thickness regressed against g. An FDR threshold of 0.05 is used to control for multiple comparisons across the brain. Colors, representing q values (which are metrics used for FDR that can be viewed as analogues to p values), are superimposed on left and right lateral average surface templates generated from the ICBM152 dataset. Results are corrected for gender, age, total brain volume and scanner.

**Figure 4**
Results of cortical thickness regressed against each of the three domains before (left) and after (right) controlling for g. Here also, an FDR threshold of 0.05 is used to control for multiple comparisons across the brain and colors, representing q values, are superimposed on left and right lateral average surface templates generated from the ICBM152 dataset. Results are corrected for gender, age, total brain volume and scanner.

**Figure 5**
Results of cortical thickness regressed against the Passage Comprehension, Matrix Reasoning, Block Design, and Vocabulary tests before (periphery) and after (center) controlling for g. Here also, an FDR threshold of 0.05 is used to control for multiple comparisons and colors, representing q values, are superimposed on left and right lateral average surface templates generated from the ICBM152 dataset. Results are corrected for gender, age, scanner, and a proxy measure of brain volume.

**Figure A1 (Appendix)**
Plot of the association between Mean Cortical Thickness and Cortical Gray Matter Volume

**Figure A2 (Appendix)**
Figures showing the association between g and cortical thickness after controlling for pBV (White Matter + Intracerebral CSF + Subcortical Gray Matter) or TBV (White Matter + Intracerebral CSF + Cortical and Subcortical Gray Matter). The top right g map is identical to Figure 3 and is reproduced here for convenience to facilitate comparisons between figures.

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References

1. Ad-Dab'bagh Y, Lyttelton O, Muehlboeck J-S, Lepage C, Einarson D, Mok K, Ivanov O, Vincent RD, Lerch J, Fombonne E, Evans AC. The CIVET Image-Processing Environment: A Fully Automated Comprehensive Pipeline for Anatomical Neuroimaging Research. In: Corbetta M, editor. Proceedings of the 12th Annual Meeting of the Organization for Human Brain Mapping; Florence, Italy. 2006. p. S45.
1. Andreasen NC, Flaum M, Swayze V, 2nd, O'Leary DS, Alliger R, Cohen G, Ehrhardt J, Yuh WT. Intelligence and brain structure in normal individuals. Am J Psychiatry. 1993;150:130–134. - PubMed
1. Benjamini Y, Hochberg Y. Controlling the False Discovery Rate: A Practical and Powerful Approach to Multiple Testing. Journal of the Royal Statistical Society, Series B (Methodological) 1995;57:289–300.
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[1] Ad-Dab'bagh Y, Lyttelton O, Muehlboeck J-S, Lepage C, Einarson D, Mok K, Ivanov O, Vincent RD, Lerch J, Fombonne E, Evans AC. The CIVET Image-Processing Environment: A Fully Automated Comprehensive Pipeline for Anatomical Neuroimaging Research. In: Corbetta M, editor. Proceedings of the 12th Annual Meeting of the Organization for Human Brain Mapping; Florence, Italy. 2006. p. S45.

[2] Ad-Dab'bagh Y, Lyttelton O, Muehlboeck J-S, Lepage C, Einarson D, Mok K, Ivanov O, Vincent RD, Lerch J, Fombonne E, Evans AC. The CIVET Image-Processing Environment: A Fully Automated Comprehensive Pipeline for Anatomical Neuroimaging Research. In: Corbetta M, editor. Proceedings of the 12th Annual Meeting of the Organization for Human Brain Mapping; Florence, Italy. 2006. p. S45.

[3] Andreasen NC, Flaum M, Swayze V, 2nd, O'Leary DS, Alliger R, Cohen G, Ehrhardt J, Yuh WT. Intelligence and brain structure in normal individuals. Am J Psychiatry. 1993;150:130–134. - PubMed

[4] Andreasen NC, Flaum M, Swayze V, 2nd, O'Leary DS, Alliger R, Cohen G, Ehrhardt J, Yuh WT. Intelligence and brain structure in normal individuals. Am J Psychiatry. 1993;150:130–134. - PubMed

[5] Benjamini Y, Hochberg Y. Controlling the False Discovery Rate: A Practical and Powerful Approach to Multiple Testing. Journal of the Royal Statistical Society, Series B (Methodological) 1995;57:289–300.

[6] Benjamini Y, Hochberg Y. Controlling the False Discovery Rate: A Practical and Powerful Approach to Multiple Testing. Journal of the Royal Statistical Society, Series B (Methodological) 1995;57:289–300.

[7] Bollen KA. Structure Equations with Latent Variables. New York: John Wiley & Sons; 1989.

[8] Bollen KA. Structure Equations with Latent Variables. New York: John Wiley & Sons; 1989.

[9] Boyke J, Driemeyer J, Gaser C, Buchel C, May A. Training-induced brain structure changes in the elderly. J Neurosci. 2008;28:7031–7035. - PMC - PubMed

[10] Boyke J, Driemeyer J, Gaser C, Buchel C, May A. Training-induced brain structure changes in the elderly. J Neurosci. 2008;28:7031–7035. - PMC - PubMed

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Cortical thickness correlates of specific cognitive performance accounted for by the general factor of intelligence in healthy children aged 6 to 18

Collaborators

Affiliation

Cortical thickness correlates of specific cognitive performance accounted for by the general factor of intelligence in healthy children aged 6 to 18

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Collaborators

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Abstract

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