Restricted accessResearch articleFirst published online 2017-8-29
Fully Automatic MRI-Based Hippocampus Volumetry Using FSL-FIRST: Intra-Scanner Test-Retest Stability,Inter-Field Strength Variability,and Performance as Enrichment Biomarker for Clinical Trials Using Prodromal Target Populations at Risk for Alzheimer’s Disease
MRI-based hippocampus volume is a core clinical biomarker for identification of Alzheimer’s disease (AD).
Objective:
To assess robustness of automatic hippocampus volumetry with the freely available FSL-FIRST software with respect to short-term repeat and across field strength imaging. FSL-FIRST hippocampus volume (FIRST-HV) was also evaluated as enrichment biomarker for mild cognitive impairment (MCI) trials.
Methods:
Robustness of FIRST-HV was assessed in 51 healthy controls (HC), 74 MCI subjects, and 28 patients with AD dementia from ADNI1, each with two pairs of back-to-back scans, one at 1.5T one at 3T. Enrichment performance was tested in a second sample of 287 ADNI MCI subjects.
Results:
FSL-FIRST worked properly in all four scans in 147 out of 153 subjects of the first sample (49 HC, 72 MCI, 26 AD). In these subjects, FIRST-HV did not differ between the first and the second scan within an imaging session, neither at 1.5T nor at 3T (p≥0.302). FIRST-HV was on average 0.78% larger at 3T compared to 1.5T (p = 0.012). The variance of the FIRST-HV difference was larger in the inter-field strength setting than in the intra-scanner settings (p < 0.0005). Computer simulations suggested that the additional variability encountered in the inter-field strength scenario does not cause a relevant degradation of FIRST-HV’s prognostic performance in MCI. FIRST-HV based enrichment resulted in considerably increased effect size of the 2-years change of cognitive measures.
Conclusion:
The impact of intra-scanner test-retest and inter-field strength variability of FIRST-HV on clinical tasks is negligible. In addition, FIRST-HV is useful for enrichment in clinical MCI trials.
PiniL, PievaniM, BocchettaM, AltomareD, BoscoP, CavedoE, GalluzziS, MarizzoniM, FrisoniGB (2016) Brain atrophy in Alzheimer’s disease and aging. Ageing Res Rev30, 25–48.
2.
TeipelSJ, GrotheM, ListaS, ToschiN, GaraciFG, HampelH (2013) Relevance of magnetic resonance imaging for early detection and diagnosis of Alzheimer disease. Med Clin North Am97, 399–424.
3.
HampelH, BurgerK, TeipelSJ, BokdeAL, ZetterbergH, BlennowK (2008) Core candidate neurochemical and imaging biomarkers of Alzheimer’s disease. Alzheimers Dement4, 38–48.
4.
TeipelSJ, MeindlT, GrinbergL, HeinsenH, HampelH (2008) Novel MRI techniques in the assessment of dementia. Eur J Nucl Med Mol Imaging35(Suppl 1), S58–S69.
5.
AlbertMS, DeKoskyST, DicksonD, DuboisB, FeldmanHH, FoxNC, GamstA, HoltzmanDM, JagustWJ, PetersenRC, SnyderPJ, CarrilloMC, ThiesB, PhelpsCH (2011) The diagnosis of mild cognitive impairment due to Alzheimer’s disease: Recommendations from the National Institute on Aging-Alzheimer’s Association workgroups on diagnostic guidelines for Alzheimer’s disease. Alzheimers Dement7, 270–279.
HillDL, SchwarzAJ, IsaacM, PaniL, VamvakasS, HemmingsR, CarrilloMC, YuP, SunJ, BeckettL, BoccardiM, BrewerJ, BrumfieldM, CantillonM, ColePE, FoxN, FrisoniGB, JackC, KelleherT, LuoF, NovakG, MaguireP, MeibachR, PattersonP, BainL, SampaioC, RaunigD, SoaresH, SuhyJ, WangH, WolzR, StephensonD (2014) Coalition Against Major Diseases/European Medicines Agency biomarker qualification of hippocampal volume for enrichment of clinical trials in predementia stages of Alzheimer’s disease. Alzheimers Dement10, 421–429.e3.
8.
ShiF, LiuB, ZhouY, YuC, JiangT (2009) Hippocampal volume and asymmetry in mild cognitive impairment and Alzheimer’s disease: Meta-analyses of MRI studies. Hippocampus19, 1055–1064.
9.
DaleAM, FischlB, SerenoMI (1999) Cortical surface-based analysis. I. Segmentation and surface reconstruction. Neuroimage9, 179–194.
10.
BrewerJB (2009) Fully-automated volumetric MRI with normative ranges: Translation to clinical practice. Behav Neurol21, 21–28.
11.
BrewerJB, MagdaS, AirriessC, SmithME (2009) Fully-automated quantification of regional brain volumes for improved detection of focal atrophy in Alzheimer disease. AJNR Am J Neuroradiol30, 578–580.
BarnesJ, FosterJ, BoyesRG, PeppleT, MooreEK, SchottJM, FrostC, ScahillRI, FoxNC (2008) A comparison of methods for the automated calculation of volumes and atrophy rates in the hippocampus. Neuroimage40, 1655–1671.
14.
LeungKK, BarnesJ, RidgwayGR, BartlettJW, ClarksonMJ, MacdonaldK, SchuffN, FoxNC, OurselinS (2010) Automated cross-sectional and longitudinal hippocampal volume measurement in mild cognitive impairment and Alzheimer’s disease. Neuroimage51, 1345–1359.
15.
SuppaP, HampelH, KeppT, LangeC, SpiesL, FiebachJB, DuboisB, BuchertR, Alzheimer’s Disease Neuroimaging Iniatitive (2016) Performance of hippocampus volumetry with FSL-FIRST for prediction of Alzheimer’s disease dementia in at risk subjects with amnestic mild cognitive impairment. J Alzheimers Dis51, 867–873.
16.
PatenaudeB, SmithSM, KennedyDN, JenkinsonM (2011) A Bayesian model of shape and appearance for subcortical brain segmentation. Neuroimage56, 907–922.
17.
SuppaP, AnkerU, SpiesL, BoppI, Ruegger-FreyB, KlaghoferR, GockeC, HampelH, BeckS, BuchertR (2015) Fully automated atlas-based hippocampal volumetry for detection of Alzheimer’s disease in a memory clinic setting. J Alzheimers Dis44, 183–193.
18.
SuppaP, HampelH, SpiesL, FiebachJB, DuboisB, BuchertR, Alzheimer’s Disease Neuroimaging Initiative (2015) Fully automated atlas-based hippocampus volumetry for clinical routine: Validation in subjects with mild cognitive impairment from the ADNI cohort. J Alzheimers Dis46, 199–209.
19.
RisacherSL, SaykinAJ, WestJD, ShenL, FirpiHA, McDonaldBC (2009) Baseline MRI predictors of conversion from MCI to probable AD in the ADNI cohort. Curr Alzheimer Res6, 347–361.
20.
WolzR, SchwarzAJ, YuP, ColePE, RueckertD, JackCRJr, RaunigD, HillD, Alzheimer’s Disease Neuroimaging Initiative (2014) Robustness of automated hippocampal volumetry across magnetic resonance field strengths and repeat images. Alzheimers Dement10, 430–438, e432.
HalchenkoYO, HankeM (2012) Open is not enough. Let’s take the next step: An integrated, community-driven computing platform for neuroscience. Front Neuroinform6, 22.
TeamRC (2016) R Foundation for Statistical Computing, Vienna, Austria.
28.
YuP, SunJ, WolzR, StephensonD, BrewerJ, FoxNC, ColePE, JackCRJr, HillDL, SchwarzAJ, Coalition Against Major Diseases, the Alzheimer’s Disease Neuroimaging Initiative (2014) Operationalizing hippocampal volume as an enrichment biomarker for amnestic mild cognitive impairment trials: Effect of algorithm, test-retest variability, and cut point on trial cost, duration, and sample size. Neurobiol Aging35, 808–818.
29.
MaloneIB, LeungKK, CleggS, BarnesJ, WhitwellJL, AshburnerJ, FoxNC, RidgwayGR (2015) Accurate automatic estimation of total intracranial volume: A nuisance variable with less nuisance. Neuroimage104, 366–372.
30.
ArmitageP, BerryG (1994) Statistical methods in medical research, Science, Blackwell, Oxford, UK.
31.
LotjonenJ, WolzR, KoikkalainenJ, JulkunenV, ThurfjellL, LundqvistR, WaldemarG, SoininenH, RueckertD, Alzheimer’s Disease Neuroimaging Initiative (2011) Fast and robust extraction of hippocampus from MR images for diagnostics of Alzheimer’s disease. Neuroimage56, 185–196.
