Post on 21-Mar-2017
Imaging tau and other molecular
markers in dementia
John O’Brien
Professor of Old Age Psychiatry
Department of Psychiatry
University of Cambridge
Imaging in Dementia
• Computed tomography (CT)
• Magnetic resonance imaging (MRI)
• Perfusion (HMPAO) SPECT
• Glucose (FDG) PET
• Dopamine (FP-CIT) SPECT (for Lewy body
dementia)
• Amyloid (PIB, florbetapir, flutemetamol, flurbetaben)
PET
• Research (Tau, inflammation, receptor)
Control AD
Sens for AD around 80%, spec for controls 80%,
Spec lower for other dementias (esp FTD)
Strongest pathological correlate is tau/ tangle pathology
Why image molecular imaging markers in
dementia?
• Subject stratification for studies
• Understanding pathophysiology – including
temporal relationship between changes
• Demonstrate target engagement in therapeutic
studies
• Outcome measure for disease modifying studies
• Improve diagnosis of challenging cases
McKhann et al, 1984
Is there a downside?
• Cost
• Availability and distribution
• 11Carbon v 18Fluorine
• Need careful validation
• Injection
• Radiation dose – 4-7 mSv
Radiation dose
• Average exposure in the UK/yr 2.7 mSv
• CT scan head 1 mSv
• CT scan chest 6.6 mSv
• Living in Cornwall/yr 7.8 mSv
• F-Amyloid PET scan 7 mSv
• Industry limits/ yr 20 mSv
• To cause radiation sickness 1000 mSv
Glucose (FDG) PET scans
Healthy Control Mild AD subject
Dopaminergic imaging, a biomarker for
Lewy body dementia
C-PBB3
• Phase 2 study of diagnosis (DLB v AD).
Sens 78% Spec 90%
• Phase 3 Study (GE Healthcare funded).
Similar diagnostic accuracy in 40 sites
• Autopsy validation
• Use in possible cases
• Pooled data analysis
Licensed for clinical use in dementia in EU (2006)
Normal
DLB
Walker et al, 2002; O’Brien et al, 2004; McKeith et al, 2007;
O’Brien et al, 2009; Colloby et al, 2012; Walker et al, 2014; O’Brien et al, 2014
Amyloid imaging in Dementia
Villemagne et al, 2011
CPIB – research tool
Now F-amyloid compounds
for clinical use
Amyloid PET imaging
Negative scan:
normal
Positive scan:
amyloid
Flurbetapir
(Amyvid)
Flutametamol
(Vizamyl
Flurbetaben
(NeuraCeq)
Time course of biomarker changes in DIAN
study
Bateman et al, NEJM, 2016
Sevigny et al, Nature, 2016
ARIA:
5% - Placebo
6% - 1mg
13% - 3mg
37% - 6mg
47% - 10mg
Novel PET markers of Tau
Chien DT et al. J Alzheimers Dis 2013;34:457-68. Maruyama M et al. Neuron 2013;79:1094-108.
C-PBB3
Radioligand [F-18]-T807
(now AV 1451)
Imaging of tau pathology with C-
PBB3 in a tauopathy mouse
model and in Alzheimer patients
compared to normal controls
C-PBB3
WIBIC imaging of AV1451 (tau) in AD
C-PBB3
Control AD
Tau deposition (AV 1451) mirrors clinical
phenotype in AD
C-PBB3
Ossenkoppele et al, 2016
Tau deposition (AV 1451) correlates with
tau in CSF
C-PBB3
Gordon et al, 2016
AD and the FTD spectrum
TAU TDP-43
AD
Mean AV-1451 uptake in Controls
0.8
-0.5
BPND
0.8
-0.5
Mean AV-1451 uptake in AD/MCI+
BPND
Mean AV-1451 uptake in PSP
0.8
-0.5
BPND
Tau imaging with AV1451 in AD and PSP
Clearly differentiates AD from PSP with
differences in keeping with known and distinct
regional distributions
Passamonti, Vázquez Rodríguez et al, Brain 2017
AD and the FTD spectrum
TAU TDP-43
AD
C-PBB3
MATP
case
Bevan-Jones, Cope et al, 2016
Tau (AV 1451) imaging in DLB
Kantarci et al, 2017
DLB (n=19) v
Controls (n=95)
DLB (n=19) v
AD (n=19)
Tau imaging in DLB
Kantarci et al, 2017
Conclusions
• CT, MR, perfusion SPECT and Glucose PET are
established clinical tools
• Molecular imaging for dopamine transporter a
diagnostic tool for DLB
• Amyloid imaging licensed, but not currently
funded
• Tau imaging developing as a research tool, still
needs further study and validation, likely to be
clinical tool in the future
Thank you!