Litcius/Paper detail

Cerebral blood flow measurements with <sup>15</sup> O-water PET using a non-invasive machine-learning-derived arterial input function

Samuel Kuttner, Kristoffer Wickstrøm, Mark Lubberink, Andreas Tolf, Joachim Burman, Rune Sundset, Robert Jenssen, Lieuwe Appel, Jan Axelsson

2021Journal of Cerebral Blood Flow & Metabolism39 citationsDOIOpen Access PDF

Abstract

Cerebral blood flow (CBF) can be measured with dynamic positron emission tomography (PET) of 15 O-labeled water by using tracer kinetic modelling. However, for quantification of regional CBF, an arterial input function (AIF), obtained from arterial blood sampling, is required. In this work we evaluated a novel, non-invasive approach for input function prediction based on machine learning (MLIF), against AIF for CBF PET measurements in human subjects. Twenty-five subjects underwent two 10 min dynamic 15 O-water brain PET scans with continuous arterial blood sampling, before (baseline) and following acetazolamide medication. Three different image-derived time-activity curves were automatically segmented from the carotid arteries and used as input into a Gaussian process-based AIF prediction model, considering both baseline and acetazolamide scans as training data. The MLIF approach was evaluated by comparing AIF and MLIF curves, as well as whole-brain grey matter CBF values estimated by kinetic modelling derived with either AIF or MLIF. The results showed that AIF and MLIF curves were similar and that corresponding CBF values were highly correlated and successfully differentiated before and after acetazolamide medication. In conclusion, our non-invasive MLIF method shows potential to replace the AIF obtained from blood sampling for CBF measurements using 15 O-water PET and kinetic modelling.

Topics & Concepts

Positron emission tomographyCerebral blood flowBlood samplingAcetazolamideBlood flowNuclear medicineMedicineSampling (signal processing)Biomedical engineeringComputer scienceRadiologyInternal medicineFilter (signal processing)Computer visionMedical Imaging Techniques and ApplicationsAdvanced MRI Techniques and ApplicationsRadiomics and Machine Learning in Medical Imaging