Abstract
Single Photon Emission Computed Tomography (SPECT) has become a promising experimental approach to monitor changes in β-cell mass (BCM) during diabetes progression. SPECT imaging of pancreatic islets is most commonly cross-validated by stereological analysis of histological pancreatic sections after insulin staining. Typically, stereological methods do not accurately determine the total β-cell volume, which is inconvenient when correlating total pancreatic tracer uptake with BCM. Alternative methods are therefore warranted to cross-validate β-cell imaging using radiotracers. In this study, we introduce multimodal SPECT - optical projection tomography (OPT) imaging as an accurate approach to cross-validate radionuclide-based imaging of β-cells. Uptake of a promising radiotracer for β-cell imaging by SPECT, 111In-exendin-3, was measured by ex vivo-SPECT and cross evaluated by 3D quantitative OPT imaging as well as with histology within healthy and alloxan-treated Brown Norway rat pancreata. SPECT signal was in excellent linear correlation with OPT data as compared to histology. While histological determination of islet spatial distribution was challenging, SPECT and OPT revealed similar distribution patterns of 111In-exendin-3 and insulin positive β-cell volumes between different pancreatic lobes, both visually and quantitatively. We propose ex vivo SPECT-OPT multimodal imaging as a highly accurate strategy for validating the performance of β-cell radiotracers.
Highlights
The prevalence of diabetes in 2013 was 382 million and according to the 2015 International Diabetes Federation report, the number of diabetes cases has risen to 415 million[1]
Correlation of Single Photon Emission Computed Tomography (SPECT) imaging with morphometric determination of between β -cell mass (BCM). 111In-exendin-3 uptake was quantified by SPECT imaging of single pancreatic lobes from healthy and diabetic animals, and the accuracy of the measurements was verified by the linear correlation between SPECT data and gamma-counter based analysis of radioactivity (r2 = 0.85) (Supplementary Figure S1A)
In the present study we examined the utility of SPECT-Optical Projection Tomography (OPT) multimodal imaging for fast and accurate validation of radionuclide-based imaging of β -cells
Summary
The prevalence of diabetes in 2013 was 382 million and according to the 2015 International Diabetes Federation report, the number of diabetes cases has risen to 415 million[1]. Specific targeting of β -cells by 111In-exendin-3 followed by Single Photon Emission Computed Tomography (SPECT) was reported as a promising tool to detect and quantify small differences in BCM in type 1 diabetes (T1D) rodent models as well as T1D patients[6,7] These studies showed a linear correlation between 111In-exendin-3 uptake and histological quantitative analysis of BCM in rodents. Previous studies developed an Optical Projection Tomography (OPT)-based method that allows visualizing and studying fixated biological specimens at high spatial resolution[12] This technique was remarkably accurate for quantifying BCM and determining the spatial distribution within and between the lobes of the pancreas down to the resolution of single islets after ex vivo antibody-based targeting of insulin[8,9,13]. Uptake of 111In-labeled [Lys40(DTPA)6]-exendin-3 by the β -cells was quantified by SPECT and was cross-examined by OPT-based assessment of insulin positive β -cell volumes followed by histological analysis of insulin positive β -cell areas in the splenic, gastric and duodenal lobes[14] of healthy and alloxan-treated diabetic Brown Norway (BN) rats
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