Classification of Alzheimer disease, mild cognitive impairment, and normal cognitive status with large-scale network analysis based on resting-state functional MR imaging - PubMed (original) (raw)

Classification of Alzheimer disease, mild cognitive impairment, and normal cognitive status with large-scale network analysis based on resting-state functional MR imaging

Gang Chen et al. Radiology. 2011 Apr.

Abstract

Purpose: To use large-scale network (LSN) analysis to classify subjects with Alzheimer disease (AD), those with amnestic mild cognitive impairment (aMCI), and cognitively normal (CN) subjects.

Materials and methods: The study was conducted with institutional review board approval and was in compliance with HIPAA regulations. Written informed consent was obtained from each participant. Resting-state functional magnetic resonance (MR) imaging was used to acquire the voxelwise time series in 55 subjects with clinically diagnosed AD (n = 20), aMCI (n =15), and normal cognitive function (n = 20). The brains were divided into 116 regions of interest (ROIs). The Pearson product moment correlation coefficients of pairwise ROIs were used to classify these subjects. Error estimation of the classifications was performed with the leave-one-out cross-validation method. Linear regression analysis was performed to analyze the relationship between changes in network connectivity strengths and behavioral scores.

Results: The area under the receiver operating characteristic curve (AUC) yielded 87% classification power, 85% sensitivity, and 80% specificity between the AD group and the non-AD group (subjects with aMCI and CN subjects) in the first-step classification. For differentiation between subjects with aMCI and CN subjects, AUC was 95%; sensitivity, 93%; and specificity, 90%. The decreased network indexes were significantly correlated with the Mini-Mental State Examination score in all tested subjects. Similarly, changes in network indexes significantly correlated with Rey Auditory Verbal Leaning Test delayed recall scores in subjects with aMCI and CN subjects.

Conclusion: LSN analysis revealed that interconnectivity patterns of brain regions can be used to classify subjects with AD, those with aMCI, and CN subjects. In addition, the altered connectivity networks were significantly correlated with the results of cognitive tests.

© RSNA, 2011.

PubMed Disclaimer

Figures

Figure 1a:

Images obtained with LSN classification. (a) W matrix obtained when AD and non-AD groups were compared. In the W matrix, the upper right 6670 z values are symmetrical to the lower left 6670 values along the diagonal line, similar to the r matrices in Figure E2 (online). Color bar shows z values. (b) Distribution of z values in the W matrix between AD and non-AD groups. In AD and non-AD classification, a threshold (z < −1.96, uncorrected for multiple comparison) was empirically used. (c) Distribution of z values in the W matrix between aMCI and CN groups. In aMCI and CN classification, four decreased connections and two increased connections were empirically used to enable better classification. (d) Result from LOO procedure during aMCI versus CN classification. In the LOO procedure, one subject with aMCI was left out; therefore, 14 subjects with aMCI and 20 CN subjects were used for training. Thus, classification criteria were determined by using all subjects except the one to be evaluated. As a result, Fisher linear discriminant function (diagonal line) was used to identify the subject with aMCI who was left out in the beginning. Ellipses represent 50% and 90% probability containment for the aMCI and CN groups, respectively. B.G. 1 Tha = basal ganglia and thalamus, DCI = decreased connectivity index, ICI = increased connectivity index.

Figure 1b:

Images obtained with LSN classification. (a) W matrix obtained when AD and non-AD groups were compared. In the W matrix, the upper right 6670 z values are symmetrical to the lower left 6670 values along the diagonal line, similar to the r matrices in Figure E2 (online). Color bar shows z values. (b) Distribution of z values in the W matrix between AD and non-AD groups. In AD and non-AD classification, a threshold (z < −1.96, uncorrected for multiple comparison) was empirically used. (c) Distribution of z values in the W matrix between aMCI and CN groups. In aMCI and CN classification, four decreased connections and two increased connections were empirically used to enable better classification. (d) Result from LOO procedure during aMCI versus CN classification. In the LOO procedure, one subject with aMCI was left out; therefore, 14 subjects with aMCI and 20 CN subjects were used for training. Thus, classification criteria were determined by using all subjects except the one to be evaluated. As a result, Fisher linear discriminant function (diagonal line) was used to identify the subject with aMCI who was left out in the beginning. Ellipses represent 50% and 90% probability containment for the aMCI and CN groups, respectively. B.G. 1 Tha = basal ganglia and thalamus, DCI = decreased connectivity index, ICI = increased connectivity index.

Figure 1c:

Images obtained with LSN classification. (a) W matrix obtained when AD and non-AD groups were compared. In the W matrix, the upper right 6670 z values are symmetrical to the lower left 6670 values along the diagonal line, similar to the r matrices in Figure E2 (online). Color bar shows z values. (b) Distribution of z values in the W matrix between AD and non-AD groups. In AD and non-AD classification, a threshold (z < −1.96, uncorrected for multiple comparison) was empirically used. (c) Distribution of z values in the W matrix between aMCI and CN groups. In aMCI and CN classification, four decreased connections and two increased connections were empirically used to enable better classification. (d) Result from LOO procedure during aMCI versus CN classification. In the LOO procedure, one subject with aMCI was left out; therefore, 14 subjects with aMCI and 20 CN subjects were used for training. Thus, classification criteria were determined by using all subjects except the one to be evaluated. As a result, Fisher linear discriminant function (diagonal line) was used to identify the subject with aMCI who was left out in the beginning. Ellipses represent 50% and 90% probability containment for the aMCI and CN groups, respectively. B.G. 1 Tha = basal ganglia and thalamus, DCI = decreased connectivity index, ICI = increased connectivity index.

Figure 1d:

Images obtained with LSN classification. (a) W matrix obtained when AD and non-AD groups were compared. In the W matrix, the upper right 6670 z values are symmetrical to the lower left 6670 values along the diagonal line, similar to the r matrices in Figure E2 (online). Color bar shows z values. (b) Distribution of z values in the W matrix between AD and non-AD groups. In AD and non-AD classification, a threshold (z < −1.96, uncorrected for multiple comparison) was empirically used. (c) Distribution of z values in the W matrix between aMCI and CN groups. In aMCI and CN classification, four decreased connections and two increased connections were empirically used to enable better classification. (d) Result from LOO procedure during aMCI versus CN classification. In the LOO procedure, one subject with aMCI was left out; therefore, 14 subjects with aMCI and 20 CN subjects were used for training. Thus, classification criteria were determined by using all subjects except the one to be evaluated. As a result, Fisher linear discriminant function (diagonal line) was used to identify the subject with aMCI who was left out in the beginning. Ellipses represent 50% and 90% probability containment for the aMCI and CN groups, respectively. B.G. 1 Tha = basal ganglia and thalamus, DCI = decreased connectivity index, ICI = increased connectivity index.

Figure 2a:

ROC curve and behavioral importance of altered network connectivity strengths. (a) ROC curve shows that use of the LSN method resulted in accurate classification of subjects with AD and those without AD (area under the ROC curve, 0.87). (b) Relationship between Mini-Mental State Examination (MMSE) scores and decreased connectivity index (DCI). MMSE = 30/[1 + exp(−8.1·DCI − 2.7)]. F = 61.26; df = 1, 53; P < .001.

Figure 2b:

ROC curve and behavioral importance of altered network connectivity strengths. (a) ROC curve shows that use of the LSN method resulted in accurate classification of subjects with AD and those without AD (area under the ROC curve, 0.87). (b) Relationship between Mini-Mental State Examination (MMSE) scores and decreased connectivity index (DCI). MMSE = 30/[1 + exp(−8.1·DCI − 2.7)]. F = 61.26; df = 1, 53; P < .001.

Figure 3a:

ROC curve and behavioral importance of altered network connectivity strengths. (a) ROC curve shows that use of the LSN method resulted in accurate classification of subjects with aMCI and CN subjects (area under the ROC curve, 0.95). (b) Relationship between Rey Auditory Verbal Leaning Test (RAVLT) score and altered connectivity indexes. DCI = decreased connectivity index, ICI = increased connectivity index. (RAVLT = 15/[1 + exp(−1.2·DCI + 3.2·ICI−1.4)]; F = 6.70; df = 2, 32; P < .004.

Figure 3b:

ROC curve and behavioral importance of altered network connectivity strengths. (a) ROC curve shows that use of the LSN method resulted in accurate classification of subjects with aMCI and CN subjects (area under the ROC curve, 0.95). (b) Relationship between Rey Auditory Verbal Leaning Test (RAVLT) score and altered connectivity indexes. DCI = decreased connectivity index, ICI = increased connectivity index. (RAVLT = 15/[1 + exp(−1.2·DCI + 3.2·ICI−1.4)]; F = 6.70; df = 2, 32; P < .004.

Comment in

• Quantitative markers for neuropsychiatric disease: give it a rest.
  Rosen BR, Napadow V. Rosen BR, et al. Radiology. 2011 Apr;259(1):17-9. doi: 10.1148/radiol.10102253. Radiology. 2011. PMID: 21436093 Free PMC article.

Similar articles

• Quantitative markers for neuropsychiatric disease: give it a rest.
  Rosen BR, Napadow V. Rosen BR, et al. Radiology. 2011 Apr;259(1):17-9. doi: 10.1148/radiol.10102253. Radiology. 2011. PMID: 21436093 Free PMC article.
• MR imaging texture analysis of the corpus callosum and thalamus in amnestic mild cognitive impairment and mild Alzheimer disease.
  de Oliveira MS, Balthazar ML, D'Abreu A, Yasuda CL, Damasceno BP, Cendes F, Castellano G. de Oliveira MS, et al. AJNR Am J Neuroradiol. 2011 Jan;32(1):60-6. doi: 10.3174/ajnr.A2232. Epub 2010 Oct 21. AJNR Am J Neuroradiol. 2011. PMID: 20966061 Free PMC article.
• Alzheimer disease: quantitative structural neuroimaging for detection and prediction of clinical and structural changes in mild cognitive impairment.
  McEvoy LK, Fennema-Notestine C, Roddey JC, Hagler DJ Jr, Holland D, Karow DS, Pung CJ, Brewer JB, Dale AM; Alzheimer's Disease Neuroimaging Initiative. McEvoy LK, et al. Radiology. 2009 Apr;251(1):195-205. doi: 10.1148/radiol.2511080924. Epub 2009 Feb 6. Radiology. 2009. PMID: 19201945 Free PMC article.
• Discrimination between Alzheimer disease, mild cognitive impairment, and normal aging by using automated segmentation of the hippocampus.
  Colliot O, Chételat G, Chupin M, Desgranges B, Magnin B, Benali H, Dubois B, Garnero L, Eustache F, Lehéricy S. Colliot O, et al. Radiology. 2008 Jul;248(1):194-201. doi: 10.1148/radiol.2481070876. Epub 2008 May 5. Radiology. 2008. PMID: 18458242
• Functional and structural MR imaging in neuropsychiatric disorders, Part 1: imaging techniques and their application in mild cognitive impairment and Alzheimer disease.
  Mueller S, Keeser D, Reiser MF, Teipel S, Meindl T. Mueller S, et al. AJNR Am J Neuroradiol. 2012 Nov;33(10):1845-50. doi: 10.3174/ajnr.A2799. Epub 2011 Dec 15. AJNR Am J Neuroradiol. 2012. PMID: 22173754 Free PMC article. Review.

Cited by

• Detecting Alzheimer's Disease Stages and Frontotemporal Dementia in Time Courses of Resting-State fMRI Data Using a Machine Learning Approach.
  Sadeghi MA, Stevens D, Kundu S, Sanghera R, Dagher R, Yedavalli V, Jones C, Sair H, Luna LP; Alzheimer’s Disease Neuroimaging Initiative and the Frontotemporal Lobar Degeneration Neuroimaging Initiative. Sadeghi MA, et al. J Imaging Inform Med. 2024 May 23. doi: 10.1007/s10278-024-01101-1. Online ahead of print. J Imaging Inform Med. 2024. PMID: 38780666
• A Method to Estimate Longitudinal Change Patterns in Functional Network Connectivity of the Developing Brain Relevant to Psychiatric Problems, Cognition, and Age.
  Saha R, Saha DK, Rahaman MA, Fu Z, Liu J, Calhoun VD. Saha R, et al. Brain Connect. 2024 Mar;14(2):130-140. doi: 10.1089/brain.2023.0040. Brain Connect. 2024. PMID: 38308475
• Causal functional connectivity in Alzheimer's disease computed from time series fMRI data.
  Biswas R, Sripada S. Biswas R, et al. Front Comput Neurosci. 2023 Dec 19;17:1251301. doi: 10.3389/fncom.2023.1251301. eCollection 2023. Front Comput Neurosci. 2023. PMID: 38169714 Free PMC article.
• Textural features of the frontal white matter could be used to discriminate amnestic mild cognitive impairment patients from the normal population.
  Zheng W, Mu R, Liu F, Qin X, Li X, Yang P, Li X, Liang Y, Zhu X. Zheng W, et al. Brain Behav. 2023 Nov;13(11):e3222. doi: 10.1002/brb3.3222. Epub 2023 Aug 17. Brain Behav. 2023. PMID: 37587901 Free PMC article. Clinical Trial.
• Temporal Irreversibility of Large-Scale Brain Dynamics in Alzheimer's Disease.
  Cruzat J, Herzog R, Prado P, Sanz-Perl Y, Gonzalez-Gomez R, Moguilner S, Kringelbach ML, Deco G, Tagliazucchi E, Ibañez A. Cruzat J, et al. J Neurosci. 2023 Mar 1;43(9):1643-1656. doi: 10.1523/JNEUROSCI.1312-22.2022. Epub 2023 Feb 2. J Neurosci. 2023. PMID: 36732071 Free PMC article.

References

1. 1. Heron M, Hoyert DL, Murphy SL, Xu J, Kochanek KD, Tejada-Vera B. Deaths: final data for 2006. Natl Vital Stat Rep 2009;57(14):1–134 - PubMed
2. 1. Biswal B, Yetkin FZ, Haughton VM, Hyde JS. Functional connectivity in the motor cortex of resting human brain using echo-planar MRI. Magn Reson Med 1995;34(4):537–541 - PubMed
3. 1. Raichle ME, Snyder AZ. A default mode of brain function: a brief history of an evolving idea. Neuroimage 2007;37(4):1083–1090; discussion 1097–1099 - PubMed
4. 1. Stam CJ, Jones BF, Nolte G, Breakspear M, Scheltens P. Small-world networks and functional connectivity in Alzheimer’s disease. Cereb Cortex 2007;17(1):92–99 - PubMed
5. 1. Stam CJ, de Haan W, Daffertshofer A, et al. Graph theoretical analysis of magnetoencephalographic functional connectivity in Alzheimer’s disease. Brain 2009;132(pt 1):213–224 - PubMed

Publication types

MeSH terms

LinkOut - more resources

• Full Text Sources

  • Atypon
  • Europe PubMed Central
  • PubMed Central

• Other Literature Sources

  • The Lens - Patent Citations

• Medical

  • MedlinePlus Health Information