# The impact of AI correction on Centiloid in a same subject visual read comparison of 18F‐Florbetapir and 18F‐NAV4694 Aβ PET

**Authors:** Christopher C. Rowe, Ishara Paranawithana, Vincent Dore, Aurora Poon, H. B. Toh, Tanyaluck Thientunyakit, Tawika Kaewchur, Antony Sutherland, Kun Huang, Azadeh Feizpour, Jurgen Fripp, Victor L. Villemagne, Pierrick Bourgeat

PMC · DOI: 10.1002/alz70856_106283 · 2026-01-07

## TL;DR

This study compares the accuracy of visual reads of two amyloid PET tracers, NAV4694 and Florbetapir, using AI correction to improve agreement with Centiloid measurements.

## Contribution

The study introduces an AI-based correction method (DeepSUVR) that improves the correlation between amyloid PET scans and Centiloid thresholds.

## Key findings

- AI correction (DeepSUVR) improved the correlation between NAV and Florbetapir Centiloid values from R²=0.82 to R²=0.94.
- NAV4694 showed higher sensitivity than Florbetapir at low amyloid levels, even after AI correction.
- Visual read thresholds for amyloid positivity varied by tracer and correction method.

## Abstract

Visual read of Aβ PET remains standard clinical practice. 18F‐NAV4694 (NAV) has high affinity for Aβ and low non‐specific binding so may be more accurate than older Aβ tracers. We compared visual read of NAV to 18F‐Florbetapir (FBP) PET using standard and AI corrected Centiloid (CL) thresholds as gold standard.

150 participants (71.3±6.0 years) in the AIBL study underwent both scans within 2 years. Scans were read by 6 nuclear medicine physicians blinded to CL. Reader performance was compared against various CL thresholds. CL was measured with CapAIBL using a) the standard method, b) a composite cerebellum plus hemispheric white matter reference region for FBP and c) with an AI correction method for the CL SUVR (DeepSUVR). The DeepSUVR correction was learnt from a separate dataset of longitudinal scans where unexpected temporal changes were penalized and a tracer specific SUVR correction factor was developed for application to single scans.

CL frequency distribution graphs differed for NAV and FBP. Applying the DeepSUVR correction improved the correlation (R2) between NAV and FBP CL from 0.82 to 0.94, predominantly by boosting many mid‐range FBP CL values and reducing FBP variance around zero CL (Figure 1). The FBP composite reference region had a similar though less marked effect. The thresholds that produced peak visual read accuracy with standard and DeepSUVR CL methods were 15CL and 11CL for NAV, and 29CL and 21CL for FBP (Figure 2). Mean sensitivity at peak accuracy thresholds was higher in NAV with 97% for standard and 96% for DeepSUVR methods compared to 93% for both methods in FBP. Mean specificity at the same thresholds was similar with 95% for NAV and FBP with standard CL while DeepSUVR produced a specificity of 97% for both tracers.

Visual read of amyloid PET can accurately detect levels of amyloid below the traditional thresholds of 20 or 25CL for a positive scan. Visual read thresholds vary by tracer and reader experience. AI correction of CL with the DeepSUVR method significantly improves the performance of Florbetapir but NAV4694 remains more sensitive to low amyloid levels.

## Linked entities

- **Chemicals:** 18F-Florbetapir (PubChem CID 24822371), 18F-NAV4694 (PubChem CID 44815683)

## Figures

2 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12779607/full.md

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Source: https://tomesphere.com/paper/PMC12779607