Abstract
BackgroundCerenkov luminescence tomography (CLT) provides the three-dimensional (3D) radiopharmaceutical biodistribution in small living animals, which is vital to biomedical imaging. However, existing single-spectral and multispectral methods are not very efficient and effective at reconstructing the distribution of the radionuclide tracer. In this paper, we present a semi-quantitative Cerenkov radiation spectral characteristic-based source reconstruction method named the hybrid spectral CLT, to efficiently reconstruct the radionuclide tracer with both encouraging reconstruction results and less acquisition and image reconstruction time.Methodology/Principal FindingsWe constructed the implantation mouse model implanted with a 400 µCi Na131I radioactive source and the physiological mouse model received an intravenous tail injection of 400 µCi radiopharmaceutical Iodine-131 (I-131) to validate the performance of the hybrid spectral CLT and compared the reconstruction results, acquisition, and image reconstruction time with that of single-spectral and multispectral CLT. Furthermore, we performed 3D noninvasive monitoring of I-131 uptake in the thyroid and quantified I-131 uptake in vivo using hybrid spectral CLT. Results showed that the reconstruction based on the hybrid spectral CLT was more accurate in localization and quantification than using single-spectral CLT, and was more efficient in the in vivo experiment compared with multispectral CLT. Additionally, 3D visualization of longitudinal observations suggested that the reconstructed energy of I-131 uptake in the thyroid increased with acquisition time and there was a robust correlation between the reconstructed energy versus the gamma ray counts of I-131 (). The ex vivo biodistribution experiment further confirmed the I-131 uptake in the thyroid for hybrid spectral CLT.Conclusions/SignificanceResults indicated that hybrid spectral CLT could be potentially used for thyroid imaging to evaluate its function and monitor its treatment for thyroid cancer.
Highlights
Cerenkov radiation was first observed as early as 1934, which was named after Russian scientist Pavel Alekseyevich Cherenkov, the 1958 Nobel Physics Laureate who first characterized it rigorously [1]
We presented a semi-quantitative Cerenkov radiation spectral characteristic-based Cerenkov luminescent source reconstruction method called hybrid spectral Cerenkov luminescence tomography (CLT), which was based on a single 2D planar image
We present a semi-quantitative Cerenkov radiation spectral characteristic-based source reconstruction method for CLT known as hybrid spectral CLT, which is based on a single 2D planar image acquired without using filters
Summary
Cerenkov radiation was first observed as early as 1934, which was named after Russian scientist Pavel Alekseyevich Cherenkov, the 1958 Nobel Physics Laureate who first characterized it rigorously [1]. With the development of the highly sensitive charge-coupled device (CCD) camera, Cerenkov radiation has been applied to in vivo optical imaging of small living animals in recent years [4,5,6,7,8,9,10,11,12,13,14,15,16]. Cerenkov luminescence tomography (CLT) provides the three-dimensional (3D) radiopharmaceutical biodistribution in small living animals, which is vital to biomedical imaging. We present a semi-quantitative Cerenkov radiation spectral characteristic-based source reconstruction method named the hybrid spectral CLT, to efficiently reconstruct the radionuclide tracer with both encouraging reconstruction results and less acquisition and image reconstruction time
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