Lisa Honold et al, Molecular Imaging and Biology, 2022
Summary
Introduction: Dysregulated activity of matrix metalloproteinases (MMPs) drives a variety of pathophysiological conditions. Non-invasive imaging of MMP activity in vivo promises diagnostic and prognostic value. However, current targeting strategies by small molecules are typically limited with respect to the bioavailability of the labeled MMP binders in vivo. To this end, we here introduce and compare three chemical modifcations of a recently developed barbiturate-based radiotracer with respect to bioavailability and potential to image MMP activity in vivo.
Methods: Barbiturate-based MMP inhibitors with an identical targeting unit but varying hydrophilicity were synthesized, labeled with technetium-99m, and evaluated in vitro and in vivo. Biodistribution and radiotracer elimination were determined in C57/BL6 mice by serial SPECT imaging. MMP activity was imaged in a MMP-positive subcutaneous xenograft model of human K1 papillary thyroid tumors. In vivo data were validated by scintillation counting, autoradiography, and MMP immunohistochemistry.
Results: We prepared three new 99mTc‐labeled MMP inhibitors, bearing either a glycine ([99mTc]MEA39), lysine ([99mTc]MEA61), or the ligand HYNIC with the ionic co-ligand TPPTS ([99mTc]MEA223) yielding gradually increasing hydrophilicity. [99mTc]MEA39 and [99mTc]MEA61 were rapidly eliminated via hepatobiliary pathways. In contrast, [99mTc]MEA223 showed delayed in vivo clearance and primary renal elimination. In a thyroid tumor xenograft model, only [99mTc]MEA223 exhibited a high tumor- o-blood ratio that could easily be delineated in SPECT images.
Conclusion: Introduction of HYNIC/TPPTS into the barbiturate lead structure ([99mTc]MEA223) results in delayed renal elimination and allows non-invasive MMP imaging with high signal-to-noise ratios in a papillary thyroid tumor xenograft model.
Results from nanoScan® SPECT/CT
In vivo biodistribution was determined in adult female C57/BL6 mice. Dynamic SPECT scans were acquired over the course of 90 min p.i. (9 × 10 min frames, field of view 108 mm). Following the acquisition, CT contrast agent (Ultravist®-370, 5 µl/g bw) was injected via the tail vein catheter, and a CT image was obtained. Mice underwent subsequent SPECT/ CT scans 4 h p.i. (1 × 30 min frame) and 24 h p.i. (1 × 60 min frame). For in vivo tumor uptake studies, mice were imaged 0–60 min and 4 h p.i. of tracer with a reduced feld of view (1 × 30 min frame, 26 mm).
For tumor studies, 2 × 106 K1-LITG human thyroid cancer cells in 40–60 µl plain DMEM medium were subcutaneously injected above each shoulder of CD1nude/nude mice. Imaging experiments were performed 15 days post-implantation.
Results show that:
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Tu sum up: amino acid-based MMP tracers [99mTc]MEA39 and [99mTc]MEA61 were rapidly eliminated via hepatobiliary pathways. In contrast, the more hydrophilic [99mTc]MEA223 was primarily excreted via the kidneys and showed a signifcantly increased bioavailability for the frst 90 min after injection. In a thyroid tumor xenograft model [99mTc]MEA223 exhibited a high tumor-to-blood ratio that could easily be delineated in SPECT images. The newly developed [99mTc]MEA223 hence allows non-invasive imaging of MMP activity with high signal-to-noise and should be investigated in additional pathophysiological conditions.
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