A useful EGFR-TK ligand for tumor diagnosis with SPECT: development of radioiodinated 6-(3-morpholinopropoxy)-7-ethoxy-4-(3'-iodophenoxy)quinazoline.

OBJECTIVE: Epidermal growth factor receptor tyrosine kinase (EGFR-TK) represents an attractive target for tumor diagnosis agents. Previously, radioiodinated 4-(3-iodophenoxy)-6,7-diethoxyquinazoline (PHY) was reported to possess good characteristics as a tumor imaging agent. We have explored the feasibility of developing tumor diagnosis ligands superior to radioiodinated PHY. METHODS: New phenoxyquinazoline derivatives were designed with various side chains introduced to the 6th position of PHY. The IC50 values of the new derivatives to interrupt EGFR-TK phosphorylation were evaluated and compared to well-known EGFR-TK inhibitors. Tumor uptake studies of the new (125)I-labeled derivatives were conducted with A431 tumor-bearing mice. Selectivity and binding characteristics were analyzed by in vitro blocking studies and a binding assay. Furthermore, SPECT/CT scans were performed using A431 tumor-bearing mice. RESULTS: Six quinazoline derivatives were designed and synthesized, and among these, 6a-d were found to have relatively high EGFR-TK inhibitory potency. In tumor uptake studies, [(125)I]6a ([(125)I]PYK) was found to have the highest tumor uptake and longest retention in tumors. In contrast, [(125)I]PYK was rapidly cleared from peripheral tissues, resulting in a high tumor-to-tissue ratio 24 h after injection. Moreover, the EGFR-TK selectivity of [(125)I]PYK was confirmed by pretreatment experiments with specific EGFR-TK inhibitors. Furthermore, [(125)I]PYK provided clear SPECT images of tumors. CONCLUSIONS: Radioiodinated PYK, one of the newly synthesized quinazoline derivatives, was found to be a desirable ligand for EGFR-TK SPECT imaging. [(125)I]PYK showed high tumor accumulation and selective EGFR-TK binding and also succeeded in delivering high contrast imaging of tumors. These favorable characteristics of [(125)I]PYK suggest that the (123)I-labeled counterpart, [(123)I]PYK, would have great potential for diagnostic SPECT tumor imaging.

Synthesis and evaluation of radioiodinated phenoxyquinazoline and benzylaminoquinazoline derivatives as new EGF receptor tyrosine kinase imaging ligands for tumor diagnosis using SPECT.

OBJECTIVE: Epidermal growth factor receptor tyrosine kinase (EGFR-TK) represents an attractive target for tumor diagnosis agents. Previously, the radioiodinated 4-(3-iodoanilino)-6,7-diethoxyquinazoline ([(125)I]m-IPQ) has been reported to possess good characteristics as a tumor imaging agent; however, it was also found to have low in vivo stability. To improve the in vivo stability, m-IPQ derivatives, 4-(3-iodophenoxy)-6,7-diethoxyquinazoline (PHY) and 4-(3-iodobenzylamino)-6,7-diethoxyquinazoline (BAY) were designed and synthesized, and the biological studies of [(125)I]PHY and [(125)I]BAY were performed to evaluate these new ligands as in vivo tumor diagnosis agents. METHODS: PHY and BAY were synthesized according to previous reports. The EGFR-TK inhibitory potency of these new compounds was measured and compared to other EGFR-TK inhibitors. Radiolabeled [(125)I]PHY and [(125)I]BAY were synthesized by an iododestannylation reaction. Biodistribution studies of these radioligands were conducted in normal mice and tumor-bearing mice. Furthermore, selectivity and binding characteristics of [(125)I]PHY were analyzed by in vitro blocking studies and a binding assay. RESULTS: The new derivatives were found to have high inhibitory potency against EGFR-TK (PHY: IC50 = 12.7 ± 7.2 nM, BAY: IC50 = 51.0 ± 8.9 nM). [(125)I]PHY and [(125)I]BAY were conveniently synthesized from tributylstannyl precursors. In in vivo biodistribution studies, [(125)I]PHY and [(125)I]BAY were observed to have lower uptake in the stomach, an indication of deiodination, than [(125)I]m-IPQ. Moreover, [(125)I]PHY showed high uptake and prolonged retention in tumors and low accumulation in blood and muscle tissue resulting in a good tumor-to-blood ratio (0.94-1.50) and tumor-to-muscle ratio (1.02-1.95). The EGFR-TK selectivity of [(125)I]PHY was confirmed by pretreatment experiments with specific EGFR-TK inhibitors. CONCLUSION: New radioiodinated quinazoline derivatives were synthesized, which were found to have improved in vivo stability. In particular, [(125)I]PHY showed higher tumor accumulation than the other ligands which was indicative of selective binding to EGFR-TK. These desirable characteristics for [(125)I]PHY suggest that the (123)I-labeled counterpart, [(123)I]PHY, could be a possible candidate for cancer diagnosis radiopharmaceutical.

Evaluation of radioiodinated quinazoline derivative as a new ligand for EGF receptor tyrosine kinase activity using SPECT.

OBJECTIVE: A radioiodinated analog of PD153035 (m-IPQ) was evaluated as a potential epidermal growth factor receptor tyrosine kinase (EGFR-TK) activity imaging ligand for SPECT. METHODS: The 50% inhibition concentration (IC50) value of m-IPQ for EGFR-TK phosphorylation inhibition was evaluated and compared to various EGFR-TK inhibitors. [(125)I]m-IPQ was synthesized by iododestannylation reaction. Biodistribution study of [(125)I]m-IPQ was conducted in normal mice and tumor-bearing mice. The selectivity and binding characteristics (B(max) and K(d)) were analyzed. RESULTS: The quinazoline derivative m-IPQ was found to have high inhibitory potency (IC50: 50.5 ± 3.5 nM) and selectivity toward EGFR-TK. In vivo biodistribution studies of [(125)I]m-IPQ demonstrated its rapid clearance and low retention in normal tissue. On the other hand, high tumor uptake was observed. However, the increase in [(125)I]m-IPQ uptake in the stomach as a deiodination parameter was found. Thus, [(125)I]m-IPQ showed low in vivo stability. The selectivity toward EGFR-TK of m-IPQ was confirmed by the pretreatment experiment with EGFR-TK specific inhibitors, PD153035, Genistein. [(125)I]m-IPQ bound to single population of binding sites with high affinity and kinetic parameter. In addition, [(125)I]m-IPQ was bound to EGFR-TK according to the amount of EGFR-TK expression in the tumor. CONCLUSIONS: [(125)I]m-IPQ showed a relatively high tumor accumulation with selective EGFR-TK binding. Moreover, the tumor uptake of [(125)I]m-IPQ might be reflected in the amount of EGFR-TK expression in the tumor. These good characteristics of [(125)I]m-IPQ suggested that a ¹²³I-labeled counterpart, [¹²³I]m-IPQ, would have great potential for EGFR-TK imaging with SPECT. However, the in vivo stability of this compound needs to improve.