Your search keyword '"Thompson, P.M."' showing total 8 results

1. Alzheimer’s Disease: MRI Studies

Author

Thompson, P.M., primary and Toga, A.W., additional

Published

2009

2. Brain Asymmetry: Evolution

Author

Toga, A.W., primary, Narr, K.L., additional, Thompson, P.M., additional, and Luders, E., additional

Published

2009

3. [Accepted Manuscript] Presymptomatic atrophy in autosomal dominant Alzheimer's disease: A serial MRI study

Author

Kinnunen, K.M., Cash, D.M., Poole, T., Frost, C., Benzinger, T.L.S., Ahsan, R.L., Leung, K.K., Cardoso, M.J., Modat, M., Malone, I.B., Morris, J.C., Bateman, R.J., Marcus, D.S., Goate, A., Salloway, S., Correia, S., Sperling, R.A., Chhatwal, J.P., Mayeux, R., Brickman, A.M., Martins, R.N., Farlow, M.R., Ghetti, B., Saykin, A.J., Jack, C.R. Jr, Schofield, P.R., McDade, E., Weiner, M.W., Ringman, J.M., Thompson, P.M., Masters, C.L., Rowe, C.C., Rossor, M.N., Ourselin, S., Fox, N.C., and Dominantly Inherited Alzheimer Network (DIAN), .

Subjects

sense organs, skin and connective tissue diseases

Abstract

Identifying at what point atrophy rates first change in Alzheimer's disease is important for informing design of presymptomatic trials. Serial T1-weighed magnetic resonance imaging scans of 94 participants (28 noncarriers, 66 carriers) from the Dominantly Inherited Alzheimer Network were used to measure brain, ventricular, and hippocampal atrophy rates. For each structure, nonlinear mixed-effects models estimated the change-points when atrophy rates deviate from normal and the rates of change before and after this point. Atrophy increased after the change-point, which occurred 1-1.5 years (assuming a single step change in atrophy rate) or 3-8 years (assuming gradual acceleration of atrophy) before expected symptom onset. At expected symptom onset, estimated atrophy rates were at least 3.6 times than those before the change-point. Atrophy rates are pathologically increased up to seven years before "expected onset". During this period, atrophy rates may be useful for inclusion and tracking of disease progression.

Published

2017

4. Genetic imaging consortium for addiction medicine: From neuroimaging to genes

Author

Mackey, S., Kan, K.-J., Chaarani, B., Alia-Klein, N., Batalla, A., Brooks, S., Cousijn, J., Dagher, D., de Ruiter, M., Desrivieres, S., Feldstein Ewing, S.W., Goldstein, R.Z., Goudriaan, A.E., Heitzeg, M.M., Hutchison, K., Li, C.S.R., London, E.D., Lorenzetti, V., Luijten, M., Martin-Santos, R., Morales, A.M., Paulus, M.P., Paus, T., Pearlson, G., Schluter, R., Momenan, R., Schmaal, L., Schumann, G., Sinha, R., Sjoerds, Z., Stein, D.J., Stein, E.A., Solowij, N., Tapert, S., Uhlmann, A., Veltman, D., van Holst, R., Walter, H., Wright, M.J., Yucel, M., Yurgelun-Todd, D., Hibar, D.P., Jahanshad, N., Thompson, P.M., Glahn, D.C., Garavan, H., Conrod, P., Ekhtiari, H., Paulus, M., and Ontwikkelingspsychologie (Psychologie, FMG)

Abstract

Since the sample size of a typical neuroimaging study lacks sufficient statistical power to explore unknown genomic associations with brain phenotypes, several international genetic imaging consortia have been organized in recent years to pool data across sites. The challenges and achievements of these consortia are considered here with the goal of leveraging these resources to study addiction. The authors of this review have joined together to form an Addiction working group within the framework of the ENIGMA project, a meta-analytic approach to multisite genetic imaging data. Collectively, the Addiction working group possesses neuroimaging and genomic data obtained from over 10,000 subjects. The deadline for contributing data to the first round of analyses occurred at the beginning of May 2015. The studies performed on this data should significantly impact our understanding of the genetic and neurobiological basis of addiction.

Published

2016

5. Common folate gene variant, MTHFR C677T, is associated with brain structure in two independent cohorts of people with mild cognitive impairment

Author

Rajagopalan, P. (Priya), Jahanshad, N. (Neda), Stein, J.L. (Jason L.), Hua, X. (Xue), Madsen, S.K. (Sarah K.), Kohannim, O. (Omid), Hibar, D.P. (Derrek P.), Toga, A.W. (Arthur W.), Jack, C.R. (Clifford R. ), Saykin, A.J. (Andrew J.), Green, R.C. (Robert C.), Weiner, M.W. (Michael W.), Bis, J.C. (Joshua C.), Kuller, L.H. (Lewis H.), Riverol, M. (Mario), Becker, J.T. (James T.), Lopez, O.L. (Óscar L.), and Thompson, P.M. (Paul M.)

Subjects

Folate gene variant, MTHFR C677T, digestive system diseases

Abstract

A commonly carried C677T polymorphism in a folate-related gene, MTHFR, is associated with higher plasma homocysteine, a well-known mediator of neuronal damage and brain atrophy. As homocysteine promotes brain atrophy, we set out to discover whether people carrying the C677T MTHFR polymorphism which increases homocysteine, might also show systematic differences in brain structure. Using tensor-based morphometry, we tested this association in 359 elderly Caucasian subjects with mild cognitive impairment (MCI) (mean age: 75 ± 7.1 years) scanned with brain MRI and genotyped as part of Alzheimer's Disease Neuroimaging Initiative. We carried out a replication study in an independent, non-overlapping sample of 51 elderly Caucasian subjects with MCI (mean age: 76 ± 5.5 years), scanned with brain MRI and genotyped for MTHFR, as part of the Cardiovascular Health Study. At each voxel in the brain, we tested to see where regional volume differences were associated with carrying one or more MTHFR 'T' alleles. In ADNI subjects, carriers of the MTHFR risk allele had detectable brain volume deficits, in the white matter, of up to 2-8% per risk T allele locally at baseline and showed accelerated brain atrophy of 0.5-1.5% per T allele at 1 year follow-up, after adjusting for age and sex. We replicated these brain volume deficits of up to 5-12% per MTHFR T allele in the independent cohort of CHS subjects. As expected, the associations weakened after controlling for homocysteine levels, which the risk gene affects. The MTHFR risk variant may thus promote brain atrophy by elevating homocysteine levels. This study aims to investigate the spatially detailed effects of this MTHFR polymorphism on brain structure in 3D, pointing to a causal pathway that may promote homocysteine-mediated brain atrophy in elderly people with MCI.

Published

2012

6. Common folate gene variant, MTHFR C677T, is associated with brain structure in two independent cohorts of people with mild cognitive impairment

Author

Rajagopalan, P. (Priya), Jahanshad, N. (Neda), Stein, J.L. (Jason L.), Hua, X. (Xue), Madsen, S.K. (Sarah K.), Kohannim, O. (Omid), Hibar, D.P. (Derrek P.), Toga, A.W. (Arthur W.), Jack, C.R. (Clifford R. ), Saykin, A.J. (Andrew J.), Green, R.C. (Robert C.), Weiner, M.W. (Michael W.), Bis, J.C. (Joshua C.), Kuller, L.H. (Lewis H.), Riverol, M. (Mario), Becker, J.T. (James T.), Lopez, O.L. (Óscar L.), Thompson, P.M. (Paul M.), Rajagopalan, P. (Priya), Jahanshad, N. (Neda), Stein, J.L. (Jason L.), Hua, X. (Xue), Madsen, S.K. (Sarah K.), Kohannim, O. (Omid), Hibar, D.P. (Derrek P.), Toga, A.W. (Arthur W.), Jack, C.R. (Clifford R. ), Saykin, A.J. (Andrew J.), Green, R.C. (Robert C.), Weiner, M.W. (Michael W.), Bis, J.C. (Joshua C.), Kuller, L.H. (Lewis H.), Riverol, M. (Mario), Becker, J.T. (James T.), Lopez, O.L. (Óscar L.), and Thompson, P.M. (Paul M.)

Abstract

A commonly carried C677T polymorphism in a folate-related gene, MTHFR, is associated with higher plasma homocysteine, a well-known mediator of neuronal damage and brain atrophy. As homocysteine promotes brain atrophy, we set out to discover whether people carrying the C677T MTHFR polymorphism which increases homocysteine, might also show systematic differences in brain structure. Using tensor-based morphometry, we tested this association in 359 elderly Caucasian subjects with mild cognitive impairment (MCI) (mean age: 75 ± 7.1 years) scanned with brain MRI and genotyped as part of Alzheimer's Disease Neuroimaging Initiative. We carried out a replication study in an independent, non-overlapping sample of 51 elderly Caucasian subjects with MCI (mean age: 76 ± 5.5 years), scanned with brain MRI and genotyped for MTHFR, as part of the Cardiovascular Health Study. At each voxel in the brain, we tested to see where regional volume differences were associated with carrying one or more MTHFR 'T' alleles. In ADNI subjects, carriers of the MTHFR risk allele had detectable brain volume deficits, in the white matter, of up to 2-8% per risk T allele locally at baseline and showed accelerated brain atrophy of 0.5-1.5% per T allele at 1 year follow-up, after adjusting for age and sex. We replicated these brain volume deficits of up to 5-12% per MTHFR T allele in the independent cohort of CHS subjects. As expected, the associations weakened after controlling for homocysteine levels, which the risk gene affects. The MTHFR risk variant may thus promote brain atrophy by elevating homocysteine levels. This study aims to investigate the spatially detailed effects of this MTHFR polymorphism on brain structure in 3D, pointing to a causal pathway that may promote homocysteine-mediated brain atrophy in elderly people with MCI.

Published

2014

7. A tensor-based morphometry analysis of regional differences in brain volume in relation to prenatal alcohol exposure

Author

Meintjes, E.M., Narr, K.L., der Kouwe, A.J.W. van, Molteno, C.D., Pirnia, T., Gutman, B., Woods, R.P., Thompson, P.M., Jacobson, J.L., and Jacobson, S.W.

Subjects

Tensor-based morphometry, Fetal alcohol spectrum disorders, Prenatal alcohol exposure, Structural MRI, Neurodevelopment, Morphology, Brain structure, AA, absolute alcohol, CSF, cerebrospinal fluid, FAS, fetal alcohol syndrome, FASD, fetal alcohol spectrum disorders, ICA, independent component analyses, MDT, minimal deformation target, MEMPRAGE, multiecho magnetization prepared rapid gradient echo, TBM, tensor-based morphometry, WISC-IV, Wechsler Intelligence Scale for Children

Abstract

Reductions in brain volumes represent a neurobiological signature of fetal alcohol spectrum disorders (FASD). Less clear is how regional brain tissue reductions differ after normalizing for brain size differences linked with FASD and whether these profiles can predict the degree of prenatal exposure to alcohol. To examine associations of regional brain tissue excesses/deficits with degree of prenatal alcohol exposure and diagnosis with and without correction for overall brain volume, tensor-based morphometry (TBM) methods were applied to structural imaging data from a well-characterized, demographically homogeneous sample of children diagnosed with FASD (n = 39, 9.6–11.0 years) and controls (n = 16, 9.5–11.0 years). Degree of prenatal alcohol exposure was significantly associated with regionally pervasive brain tissue reductions in: (1) the thalamus, midbrain, and ventromedial frontal lobe, (2) the superior cerebellum and inferior occipital lobe, (3) the dorsolateral frontal cortex, and (4) the precuneus and superior parietal lobule. When overall brain size was factored out of the analysis on a subject-by-subject basis, no regions showed significant associations with alcohol exposure. FASD diagnosis was associated with a similar deformation pattern, but few of the regions survived FDR correction. In data-driven independent component analyses (ICA) regional brain tissue deformations successfully distinguished individuals based on extent of prenatal alcohol exposure and to a lesser degree, diagnosis. The greater sensitivity of the continuous measure of alcohol exposure compared with the categorical diagnosis across diverse brain regions underscores the dose dependence of these effects. The ICA results illustrate that profiles of brain tissue alterations may be a useful indicator of prenatal alcohol exposure when reliable historical data are not available and facial features are not apparent.

Published

2014

8. Longitudinal Structural Brain Changes in Bipolar Disorder: A Multicenter Neuroimaging Study of 1232 Individuals by the ENIGMA Bipolar Disorder Working Group

Author

Abe, C., Ching, C.R.K., Liberg, B., Lebedev, A.V., Agartz, I., Akudjedu, Theophilus. N., Alda, M., Alnæs, D., Alonso-Lana, S., Benedetti, F., Berk, M., Bøen, E., Bonnin, C.D.M., Breuer, F., Brosch, K., Brouwer, R.M., Canales-Rodríguez, E.J., Cannon, D.M., Chye, Y., Dahl, A., Dandash, O., Dannlowski, U., Dohm, K., Elvsåshagen, T., Fisch, L., Fullerton, J.M., Goikolea, J.M., Grotegerd, D., Haatveit, B., Hahn, T., Hajek, T., Heindel, W., Ingvar, M., Sim, K., Kircher, T.T.J., Lenroot, R.K., Malt, U.F., McDonald, C., McWhinney, S.R., Melle, I., Meller, T., Melloni, E.M.T., Mitchell, P.B., Nabulsi, L., Nenadić, I., Opel, N., Overs, B.J., Panicalli, F., Pfarr, J.K., Poletti, S., Pomarol-Clotet, E., Radua, J., Repple, J., Ringwald, K.G., Roberts, G., Rodriguez-Cano, E., Salvador, R., Sarink, K., Sarró, S., Schmitt, S., Stein, F., Suo, C., Thomopoulos, S.I., Tronchin, G., Vieta, E., Westlye, L.T., White, A.G., Yatham, L.N., Zak, N., Thompson, P.M., Andreassen, O.A., Landen, M., Abe, C., Ching, C.R.K., Liberg, B., Lebedev, A.V., Agartz, I., Akudjedu, Theophilus. N., Alda, M., Alnæs, D., Alonso-Lana, S., Benedetti, F., Berk, M., Bøen, E., Bonnin, C.D.M., Breuer, F., Brosch, K., Brouwer, R.M., Canales-Rodríguez, E.J., Cannon, D.M., Chye, Y., Dahl, A., Dandash, O., Dannlowski, U., Dohm, K., Elvsåshagen, T., Fisch, L., Fullerton, J.M., Goikolea, J.M., Grotegerd, D., Haatveit, B., Hahn, T., Hajek, T., Heindel, W., Ingvar, M., Sim, K., Kircher, T.T.J., Lenroot, R.K., Malt, U.F., McDonald, C., McWhinney, S.R., Melle, I., Meller, T., Melloni, E.M.T., Mitchell, P.B., Nabulsi, L., Nenadić, I., Opel, N., Overs, B.J., Panicalli, F., Pfarr, J.K., Poletti, S., Pomarol-Clotet, E., Radua, J., Repple, J., Ringwald, K.G., Roberts, G., Rodriguez-Cano, E., Salvador, R., Sarink, K., Sarró, S., Schmitt, S., Stein, F., Suo, C., Thomopoulos, S.I., Tronchin, G., Vieta, E., Westlye, L.T., White, A.G., Yatham, L.N., Zak, N., Thompson, P.M., Andreassen, O.A., and Landen, M.

Abstract

Background: Bipolar disorder (BD) is associated with cortical and subcortical structural brain abnormalities. It is unclear whether such alterations progressively change over time, and how this is related to the number of mood episodes. To address this question, we analyzed a large and diverse international sample with longitudinal magnetic resonance imaging (MRI) and clinical data to examine structural brain changes over time in BD. Methods: Longitudinal structural MRI and clinical data from the ENIGMA (Enhancing Neuro Imaging Genetics through Meta Analysis) BD Working Group, including 307 patients with BD and 925 healthy control subjects, were collected from 14 sites worldwide. Male and female participants, aged 40 ± 17 years, underwent MRI at 2 time points. Cortical thickness, surface area, and subcortical volumes were estimated using FreeSurfer. Annualized change rates for each imaging phenotype were compared between patients with BD and healthy control subjects. Within patients, we related brain change rates to the number of mood episodes between time points and tested for effects of demographic and clinical variables. Results: Compared with healthy control subjects, patients with BD showed faster enlargement of ventricular volumes and slower thinning of the fusiform and parahippocampal cortex (0.18 < d < 0.22). More (hypo)manic episodes were associated with faster cortical thinning, primarily in the prefrontal cortex. Conclusions: In the hitherto largest longitudinal MRI study on BD, we did not detect accelerated cortical thinning but noted faster ventricular enlargements in BD. However, abnormal frontocortical thinning was observed in association with frequent manic episodes. Our study yields insights into disease progression in BD and highlights the importance of mania prevention in BD treatment.