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      Homogenizing Estimates of Heritability Among SOLAR-Eclipse, OpenMx, APACE, and FPHI Software Packages in Neuroimaging Data

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          Abstract

          Imaging genetic analyses use heritability calculations to measure the fraction of phenotypic variance attributable to additive genetic factors. We tested the agreement between heritability estimates provided by four methods that are used for heritability estimates in neuroimaging traits. SOLAR-Eclipse and OpenMx use iterative maximum likelihood estimation (MLE) methods. Accelerated Permutation inference for ACE (APACE) and fast permutation heritability inference (FPHI), employ fast, non-iterative approximation-based methods. We performed this evaluation in a simulated twin-sibling pedigree and phenotypes and in diffusion tensor imaging (DTI) data from three twin-sibling cohorts, the human connectome project (HCP), netherlands twin register (NTR) and BrainSCALE projects provided as a part of the enhancing neuro imaging genetics analysis (ENIGMA) consortium. We observed that heritability estimate may differ depending on the underlying method and dataset. The heritability estimates from the two MLE approaches provided excellent agreement in both simulated and imaging data. The heritability estimates for two approximation approaches showed reduced heritability estimates in datasets with deviations from data normality. We propose a data homogenization approach (implemented in solar-eclipse; www.solar-eclipse-genetics.org) to improve the convergence of heritability estimates across different methods. The homogenization steps include consistent regression of any nuisance covariates and enforcing normality on the trait data using inverse Gaussian transformation. Under these conditions, the heritability estimates for simulated and DTI phenotypes produced converging heritability estimates regardless of the method. Thus, using these simple suggestions may help new heritability studies to provide outcomes that are comparable regardless of software package.

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          Automated 3-D extraction and evaluation of the inner and outer cortical surfaces using a Laplacian map and partial volume effect classification.

          June Kim, Vivek Mahendrapratap Singh, Jun Ki Lee (2005)
          Accurate reconstruction of the inner and outer cortical surfaces of the human cerebrum is a critical objective for a wide variety of neuroimaging analysis purposes, including visualization, morphometry, and brain mapping. The Anatomic Segmentation using Proximity (ASP) algorithm, previously developed by our group, provides a topology-preserving cortical surface deformation method that has been extensively used for the aforementioned purposes. However, constraints in the algorithm to ensure topology preservation occasionally produce incorrect thickness measurements due to a restriction in the range of allowable distances between the gray and white matter surfaces. This problem is particularly prominent in pediatric brain images with tightly folded gyri. This paper presents a novel method for improving the conventional ASP algorithm by making use of partial volume information through probabilistic classification in order to allow for topology preservation across a less restricted range of cortical thickness values. The new algorithm also corrects the classification of the insular cortex by masking out subcortical tissues. For 70 pediatric brains, validation experiments for the modified algorithm, Constrained Laplacian ASP (CLASP), were performed by three methods: (i) volume matching between surface-masked gray matter (GM) and conventional tissue-classified GM, (ii) surface matching between simulated and CLASP-extracted surfaces, and (iii) repeatability of the surface reconstruction among 16 MRI scans of the same subject. In the volume-based evaluation, the volume enclosed by the CLASP WM and GM surfaces matched the classified GM volume 13% more accurately than using conventional ASP. In the surface-based evaluation, using synthesized thick cortex, the average difference between simulated and extracted surfaces was 4.6 +/- 1.4 mm for conventional ASP and 0.5 +/- 0.4 mm for CLASP. In a repeatability study, CLASP produced a 30% lower RMS error for the GM surface and a 8% lower RMS error for the WM surface compared with ASP.
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            Controlling the familywise error rate in functional neuroimaging: a comparative review.

            Thomas Nichols, Satoru Hayasaka (2003)
            Functional neuroimaging data embodies a massive multiple testing problem, where 100,000 correlated test statistics must be assessed. The familywise error rate, the chance of any false positives is the standard measure of Type I errors in multiple testing. In this paper we review and evaluate three approaches to thresholding images of test statistics: Bonferroni, random field and the permutation test. Owing to recent developments, improved Bonferroni procedures, such as Hochberg's methods, are now applicable to dependent data. Continuous random field methods use the smoothness of the image to adapt to the severity of the multiple testing problem. Also, increased computing power has made both permutation and bootstrap methods applicable to functional neuroimaging. We evaluate these approaches on t images using simulations and a collection of real datasets. We find that Bonferroni-related tests offer little improvement over Bonferroni, while the permutation method offers substantial improvement over the random field method for low smoothness and low degrees of freedom. We also show the limitations of trying to find an equivalent number of independent tests for an image of correlated test statistics.
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              Cortical thickness analysis examined through power analysis and a population simulation.

              Jason Lerch, Alan C. Evans (2005)
              We have previously developed a procedure for measuring the thickness of cerebral cortex over the whole brain using 3-D MRI data and a fully automated surface-extraction (ASP) algorithm. This paper examines the precision of this algorithm, its optimal performance parameters, and the sensitivity of the method to subtle, focal changes in cortical thickness. The precision of cortical thickness measurements was studied using a simulated population study and single subject reproducibility metrics. Cortical thickness was shown to be a reliable method, reaching a sensitivity (probability of a true-positive) of 0.93. Six different cortical thickness metrics were compared. The simplest and most precise method measures the distance between corresponding vertices from the white matter to the gray matter surface. Given two groups of 25 subjects, a 0.6-mm (15%) change in thickness can be recovered after blurring with a 3-D Gaussian kernel (full-width half max = 30 mm). Smoothing across the 2-D surface manifold also improves precision; in this experiment, the optimal kernel size was 30 mm.
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                Author and article information

                Contributors
                Journal
                Journal ID (nlm-ta): Front Neuroinform
                Journal ID (iso-abbrev): Front Neuroinform
                Journal ID (publisher-id): Front. Neuroinform.
                Title: Frontiers in Neuroinformatics
                Publisher: Frontiers Media S.A.
                ISSN (Electronic): 1662-5196
                Publication date (Electronic): 12 March 2019
                Publication date Collection: 2019
                Volume: 13
                Electronic Location Identifier: 16
                Affiliations
                [1] 1Maryland Psychiatric Research Center, Department of Psychiatry, University of Maryland School of Medicine , Baltimore, MD, United States
                [2] 2Department of Statistics, University of Oxford , Oxford, United Kingdom
                [3] 3Department of Cognitive Neuroscience, Maastricht University , Maastricht, Netherlands
                [4] 4Imaging Genetics Center, Keck School of Medicine of USC , Marina del Rey, CA, United States
                [5] 5Department of Biological Psychology, VU University , Amsterdam, Netherlands
                [6] 6Brain Center Rudolf Magnus, Department of Psychiatry, University Medical Center Utrecht , Utrecht, Netherlands
                [7] 7Faculty of Health, and Institute of Health and Biomedical Innovation, Queensland University of Technology (QUT) , Brisbane, QLD, Australia
                [8] 8Centre for Advanced Imaging, University of Queensland , Brisbane, QLD, Australia
                [9] 9QIMR Berghofer Medical Research Institute , Brisbane, QLD, Australia
                [10] 10Queensland Brain Institute, University of Queensland , Brisbane, QLD, Australia
                [11] 11Big Data Institute, University of Oxford , Oxford, United Kingdom
                Author notes

                Edited by: Xi-Nian Zuo, Chinese Academy of Sciences, China

                Reviewed by: Ting Xu, Child Mind Institute, United States; Stavros I. Dimitriadis, Cardiff University, United Kingdom

                *Correspondence: Peter Kochunov pkochunov@ 123456mprc.umaryland.edu

                These authors have contributed equally to this work

                Article
                DOI: 10.3389/fninf.2019.00016
                PMC ID: 6422938
                PubMed ID: 30914942
                SO-VID: 3e4b961f-968b-4feb-b69e-b07cd8eff515
                Copyright © Copyright © 2019 Kochunov, Patel, Ganjgahi, Donohue, Ryan, Hong, Chen, Adhikari, Jahanshad, Thompson, Van’t Ent, den Braber, de Geus, Brouwer, Boomsma, Hulshoff Pol, de Zubicaray, McMahon, Martin, Wright and Nichols.
                License:

                This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

                History
                Date received : 05 July 2017
                Date accepted : 25 February 2019
                Page count
                Figures: 4, Tables: 0, Equations: 2, References: 65, Pages: 11, Words: 8269
                Funding
                Funded by: Foundation for the National Institutes of Health 10.13039/100000009
                Award ID: R01 EB015611, U54EB020403, R01 HD050735, R01 MH0708143, R01 MH116147, S10OD023696
                Categories
                Subject: Neuroscience
                Subject: Original Research

                ScienceOpen disciplines: Neurosciences
                Keywords: dti,heritability,imaging genetics,reproducability,genetics,population,computational methods
                Data availability:
                ScienceOpen disciplines: Neurosciences
                Keywords: dti, heritability, imaging genetics, reproducability, genetics, population, computational methods

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