There is mounting evidence and enthusiasm for molecular imaging contribution to the diagnosis of neurodegenerative dementia. A key advance in the imaging field has been the development of selective ligands that can reveal the presence of pathologic deposition of Aβ amyloid in the cerebral cortex, consistent with dementia due to Alzheimer disease (AD) or a related neurodegeneration (1). Recently, 3 amyloid-avid radiotracers with potential for clinical use have been developed (2) and are approved for use by the U.S. Food and Drug Administration and by European regulators. The Society of Nuclear Medicine and Molecular Imaging, together with the Alzheimer Association, convened a panel of content experts to recommend the appropriate use of these new tools (3). Conservatively, the panel recommended as the first indication the use of amyloid imaging probes to distinguish patients with frontotemporal dementias (FTDs) from patients with amyloid-dependent neurodegenerations, such as typical AD, and a significant proportion also of patients with dementia with Lewy bodies. The clinical rationale for this application follows from the recognition that the diagnosis of FTD can be difficult (4–6) and may be missed in as many as 70% of patients (7). This circumstance
See page 386
can lead to inappropriate use of symptomatic medications and incorrect prognostication and, even more importantly, may limit the accuracy and power of future therapeutic trials focused on FTD versus AD pathologic pathways. The recommended use of amyloid imaging in dementia includes focus on patients with features atypical of AD, including prominent aphasia or prominent frontal lobe dysfunction, or with relatively early age of dementia onset; each of these features increases the likelihood of an FTD variant over AD.
In this issue of The Journal of Nuclear Medicine, Kobylecki et al. (8) report their experience with 18F-florbetapir in the distinction of FTD versus AD in demented patients recruited from a university-affiliated cognitive disorders clinic. The intent of the research was to assess the ability of the radiofluorinated tracer to reproduce the previously published results of amyloid imaging with 11C-Pittsburgh compound B from several laboratories (9–11). In essence, patients with clinical presentations favoring FTD over AD should have negative amyloid scan results, and patients with AD should have positive scan results. However, as often encountered in biomedical research, the study results may raise as many questions as they answer. Kobylecki et al. report that the recommended clinical interpretation approach to 18F-florbetapir scans resulted in identification of positive patterns in 25% of FTD and in 10% of normal comparison subjects. They identified positive scans in 80% of AD subjects. These findings raise critically important issues: are the rating recommendations and rules for clinical amyloid reporting suboptimal? Do the clinical diagnostic amyloid tracers perform differently from predictions based on the research amyloid tracer 11C-Pittsburgh compound B?
There are several considerations that may account for apparent discord between clinical diagnoses and 18F-florbetapir interpretations. First, the clinical diagnoses may be inaccurate. It is well established that clinical classification differs from autopsy diagnosis in a significant proportion of dementia cases (12). In the present study, the investigators used also 18F-FDG PET brain imaging, confirming that FTD patients had prominent frontal lobe hypometabolism. This feature, however, is also fallible in the diagnosis of FTD when compared with autopsy confirmation (13,14). Thus, the discrepant amyloid versus clinical classification results of the Kobylecki study add to reports suggesting potential diagnostic gain from the imaging (15–18), even beyond the contribution of 18F-FDG PET characterizations. The authors offer the possibility of multiple pathologies in some of their subjects as another explanation, noting particularly the potential impact of apolipoprotein E ε4 genotype on promotion of amyloid deposition. Although the effect of apolipoprotein E cannot be not excluded, the cooccurrence of FTD and fibrillary amyloid deposition is only rarely reported and is notably absent from most series of autopsy dementia evaluation (15). Only autopsy confirmation of dementia pathology in the currently reported cases will reveal the truth underlying the apparent disparities in the Kobylecki report.
Of much greater concern, however, is the performance of visual image interpretations by observers, who had undergone the recommended training experience before the study. Of 28 subject scans analyzed, there was a lack of concordance among the 4 independent raters in 11 cases and only a modest statistical assessment of interrater agreement. This suggests the need for additional analytic approaches to clinical reading and reporting of amyloid images. To be sure, the studies interpreted by Kobylecki et al. are challenging. Most FTD patients have significant neocortical atrophy in frontal or temporal lobes, and this may cause interpretative difficulty with tracers in subcortical white matter appearing potentially of cerebrocortical origin. Another potential source of imaging error in cognitively impaired patients is subject motion during scanning that can worsen the influence of adjacent subcortical white matter on assessment of the gray matter tracer uptake. In the present study, the potential effect of subject motion was reduced by means of a dynamic series of images over 50–60 min after injection with motion-correction image realignment. Automated MR imaging–based cerebrocortical tracer uptake values were obtained from PET voxels classified as gray matter on T1-weighted MR imaging in parallel with the visual analyses, and these quantitative data suggested better overall agreement with clinical diagnostic classifications than the visual reads. Missing from the report are open reconciliations of interpreters’ visual interpretations with the combined PET/MR image displays that could inform as to the nature of inconsistent and potentially misleading qualitative analyses.
In conclusion, the report of Kobylecki et al. provides additional evidence that clinical use of amyloid imaging has the potential to contribute to dementia diagnosis, beyond specialist clinical characterizations and 18F-FDG PET imaging. However, more sophisticated training of image interpreters and consideration of multimodality image display and review approaches may be needed to realize accurate diagnostic amyloid scanning performance in patients with suspected FTD.
DISCLOSURE
Kirk A. Frey is a consultant to AVID Radiopharmaceuticals, MIM Software, and Siemens. He has grant support from General Electric and owns common stock in Bristol Myers Squibb, General Electric, Johnson & Johnson, Medtronic, Merck, and Novo Nordisk. No other potential conflict of interest relevant to this article was reported.
Footnotes
Published online Feb. 5, 2015.
- © 2015 by the Society of Nuclear Medicine and Molecular Imaging, Inc.
REFERENCES
- Received for publication January 14, 2015.
- Accepted for publication January 19, 2015.