Preclinical positron emission tomography (PET) imaging revealed a mismatch between in vivo
epidermal growth factor receptor (EGFR) expression and EGFR antibody tracer
tumor uptake. Shed EGFR ectodomain (sEGFR), which is present in
cancer patient sera, can potentially bind tracer and therefore influence tracer kinetics. To optimize EGFR-PET, we examined the influence of sEGFR levels on tracer kinetics and
tumor uptake of EGFR
monoclonal antibody 89Zr-imgatuzumab in varying xenograft models. Human
cancer cell lines A431 (EGFR overexpressing, epidermoid), A549 and H441 (both EGFR medium expressing,
non-small cell lung cancer) were xenografted in mice. Xenografted mice received 10, 25 or 160 μg 89Zr-imgatuzumab, co-injected with equal doses 111In-IgG control. MicroPET scans were made 24, 72 and 144 h post injection, followed by biodistribution analysis. sEGFR levels in liver and plasma samples were determined by ELISA. 89Zr-imgatuzumab uptake in A431
tumors was highest (29.8 ± 5.4 %ID/g) in the 160 μg dose group. Contrary, highest uptake in A549 and H441
tumors was found at the lowest (10 μg) 89Zr-imgatuzumab dose. High 89Zr-imgatuzumab liver accumulation was found in A431 xenografted mice, which decreased with antibody dose increments. 89Zr-imgatuzumab liver uptake in A549 and H441 xenografted mice was low at all doses. sEGFR levels in liver and plasma of A431 bearing mice were up to 1000-fold higher than levels found in A549, H441 and non-
tumor xenografted mice. 89Zr-imgatuzumab effectively visualizes EGFR-expressing
tumors. High sEGFR levels can redirect 89Zr-imgatuzumab to the liver, in which case
tumor visualization can be improved by increasing tracer antibody dose.