OBJECTIVE: Predictable patterns of atrophy are associated with the clinical subtypes of frontotemporal dementia (FTD): behavioral variant (bvFTD), semantic dementia (SEMD), and progressive nonfluent aphasia (PNFA). Some studies of pathologic subtypes have also suggested specific atrophy patterns; however, results are inconsistent. Our aim was to test the hypothesis that clinical, but not pathologic, classification (FTD with ubiquitin inclusions [FTD-U] and FTD with tau inclusions [FTD-T]) is associated with predictable patterns of regional atrophy. METHODS: Magnetic resonance scans of nine FTD-U and six FTD-T patients (histologically confirmed) were compared with 25 controls using voxel-based morphometry (VBM). Analyses were conducted with the patient group classified according to histologic or clinical variant. Additionally, three Alzheimer pathology patients who had the syndrome of SEMD in life (FTD-A) were analyzed. RESULTS: The VBM studies in clinical variants confirmed established patterns of atrophy (SEMD, rostral temporal; bvFTD, mesial frontal; PNFA, left insula). FTD-U and FTD-T VBM results were very similar, showing severe atrophy in the temporal poles, mesial frontal lobe, and insulae. A conjunction analysis confirmed this similarity. Subgroup analysis found that SEMD associated with either FTD-T or FTD-U was associated with similar rostral temporal atrophy; however, FTD-A had a qualitatively different pattern of left hippocampal atrophy. CONCLUSIONS: While there is predictable atrophy for clinical variants of frontotemporal dementia (FTD), histologic FTD variants show no noticeable differences. Reports of specific atrophy profiles are likely the result of idiosyncrasies in small groups. Semantic dementia associated with Alzheimer pathology, however, presented a distinct atrophy pattern.
OBJECTIVE: Predictable patterns of atrophy are associated with the clinical subtypes of frontotemporal dementia (FTD): behavioral variant (bvFTD), semantic dementia (SEMD), and progressive nonfluent aphasia (PNFA). Some studies of pathologic subtypes have also suggested specific atrophy patterns; however, results are inconsistent. Our aim was to test the hypothesis that clinical, but not pathologic, classification (FTD with ubiquitin inclusions [FTD-U] and FTD with tau inclusions [FTD-T]) is associated with predictable patterns of regional atrophy. METHODS: Magnetic resonance scans of nine FTD-U and six FTD-Tpatients (histologically confirmed) were compared with 25 controls using voxel-based morphometry (VBM). Analyses were conducted with the patient group classified according to histologic or clinical variant. Additionally, three Alzheimer pathologypatients who had the syndrome of SEMD in life (FTD-A) were analyzed. RESULTS: The VBM studies in clinical variants confirmed established patterns of atrophy (SEMD, rostral temporal; bvFTD, mesial frontal; PNFA, left insula). FTD-U and FTD-T VBM results were very similar, showing severe atrophy in the temporal poles, mesial frontal lobe, and insulae. A conjunction analysis confirmed this similarity. Subgroup analysis found that SEMD associated with either FTD-T or FTD-U was associated with similar rostral temporal atrophy; however, FTD-A had a qualitatively different pattern of left hippocampal atrophy. CONCLUSIONS: While there is predictable atrophy for clinical variants of frontotemporal dementia (FTD), histologic FTD variants show no noticeable differences. Reports of specific atrophy profiles are likely the result of idiosyncrasies in small groups. Semantic dementia associated with Alzheimer pathology, however, presented a distinct atrophy pattern.
Authors: H J Rosen; M L Gorno-Tempini; W P Goldman; R J Perry; N Schuff; M Weiner; R Feiwell; J H Kramer; B L Miller Journal: Neurology Date: 2002-01-22 Impact factor: 9.910
Authors: C J Galton; K Patterson; K Graham; M A Lambon-Ralph; G Williams; N Antoun; B J Sahakian; J R Hodges Journal: Neurology Date: 2001-07-24 Impact factor: 9.910
Authors: D Chan; N C Fox; R I Scahill; W R Crum; J L Whitwell; G Leschziner; A M Rossor; J M Stevens; L Cipolotti; M N Rossor Journal: Ann Neurol Date: 2001-04 Impact factor: 10.422
Authors: Peter J Nestor; Naida L Graham; Tim D Fryer; Guy B Williams; Karalyn Patterson; John R Hodges Journal: Brain Date: 2003-08-05 Impact factor: 13.501
Authors: Giovanni B Frisoni; Nick C Fox; Clifford R Jack; Philip Scheltens; Paul M Thompson Journal: Nat Rev Neurol Date: 2010-02 Impact factor: 42.937
Authors: Corey T McMillan; David J Irwin; Brian B Avants; John Powers; Philip A Cook; Jon B Toledo; Elisabeth McCarty Wood; Vivianna M Van Deerlin; Virginia M-Y Lee; John Q Trojanowski; Murray Grossman Journal: J Neurol Neurosurg Psychiatry Date: 2013-03-09 Impact factor: 10.154
Authors: S A Sajjadi; N Sheikh-Bahaei; J Cross; J H Gillard; D Scoffings; P J Nestor Journal: AJNR Am J Neuroradiol Date: 2017-03-24 Impact factor: 3.825
Authors: Stefan J Teipel; Wilhelm Flatz; Nibal Ackl; Michel Grothe; Ingo Kilimann; Arun L W Bokde; Lea Grinberg; Edson Amaro; Vanja Kljajevic; Eduardo Alho; Christina Knels; Anne Ebert; Helmut Heinsen; Adrian Danek Journal: Psychiatry Res Date: 2013-12-06 Impact factor: 3.222
Authors: Jonathan D Rohrer; Gerard R Ridgway; Sebastian J Crutch; Julia Hailstone; Johanna C Goll; Matthew J Clarkson; Simon Mead; Jonathan Beck; Cath Mummery; Sebastien Ourselin; Elizabeth K Warrington; Martin N Rossor; Jason D Warren Journal: Neuroimage Date: 2009-08-11 Impact factor: 6.556