Abstract Objective. Quantitative analysis of dynamic positron emission tomography (PET) scans requires knowledge of the arterial input function (AIF). Existing means of extracting the AIF are invasive and costly (blood sampling), or come with significant errors (image-derived input function, IDIF). We present a novel image-derived AIF method using a machine learning technique that does not require external training data. Approach. Voxel-by-voxel time-activity curves are used as individual input samples for training a customised autoencoder machine learning model. Autoencoders (AEs) are models that map input samples to themselves, with an intermediate latent layer with few nodes. This drives the training algorithm to find an optimal bottleneck representation of the input. The IDIF is extracted from the weights of the trained model. Main Results. The method was evaluated on dynamic PET scans of rats with TSPO tracer 18 FLW223. Volumes of distribution ( V T ) from arterial blood sampling (ground truth) were compared using Logan plots with IDIF-AE (mean absolute percentage error ±32%) and conventional IDIF from left ventricle (±54%). The method was also successfully adapted for scans of mice with neuro PET tracer 18 FSynVesT-1. Significance. This study demonstrates a novel machine-learning based image-derived input function for dynamic PET that can outperform classical IDIFs in determining kinetic parameter V T , without requiring external training data.
Kutos et al. (Fri,) studied this question.