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Measurement of input functions in rodents: challenges and solutions

Authors :
Michael J. Welch
Douglas J. Rowland
Nicole Fettig
Jason S. Lewis
John A. Engelbach
Terry L. Sharp
Yuan-Chuan Tai
Richard Laforest
Pilar Herrero
Joonyoung Kim
Source :
Nuclear Medicine and Biology. 32:679-685
Publication Year :
2005
Publisher :
Elsevier BV, 2005.

Abstract

Introduction Tracer kinetic modeling used in conjunction with positron emission tomography (PET) is an excellent tool for the noninvasive quantification of physiological, biological and molecular processes and their alterations due to disease. Currently, complex multi-compartment modeling approaches are being applied in a variety of clinical studies to determine myocardial perfusion, viability and glucose utilization as well as fatty acid metabolism and oxidation in the normal and diseased heart. These kinetic models require two key measurements of tracer activity over time, tracer activity in arterial blood (input function) and its corresponding activity in the organ of interest. The alteration in the time course of tracer activity as it travels from blood to the organ of interest describes the kinetics of the tracer. To be able to implement these approaches in rodent models of disease using small-animal PET (microPET), it is imperative that the input function is measured accurately. Methods The blood input functions in rodent experiments were obtained by (1) direct blood sampling, (2) direct measurement of blood activity by a beta-detecting probe that counts the activity in the blood, (3) an arterial–venous bypass (A/V shunt), (4) factor analysis of dynamic structures from dynamic PET images and (5) measurement from region-of-interest (ROI) analysis of dynamic PET images. Direct blood sampling was used as the reference standard to which the results of the other techniques were compared. Results Beta probes are difficult to operate and may not provide accurate blood input functions unless they are used intravenously, which requires complicated microsurgery. A similar limitation applies to the A/V shunt. Factor analysis successfully extracts the blood input function for mice and rats. The ROI-based method is less accurate due to limited image resolution of the PET system, which results in severe partial volume effect and spillover from myocardium. Conclusion The current reference standard, direct blood sampling, is more invasive and has limited temporal resolution. With current imaging technology, image-based extraction of blood input functions is possible by factor analysis, while forthcoming technological developments are likely to allow extraction of input function directly from the images. These techniques will reduce the level of complexity and invasiveness for animal experiments and are likely to be used more widely in the future.

Details

ISSN :
09698051
Volume :
32
Database :
OpenAIRE
Journal :
Nuclear Medicine and Biology
Accession number :
edsair.doi.dedup.....13526d1474a24596bcadd082cc046592
Full Text :
https://doi.org/10.1016/j.nucmedbio.2005.06.012