The limited success of the sole use of monoclonal antibodies for cancer detection and treatment has led to the development of multistep methods using antibodies in conjunction with low molecular weight agents. For tumor pretargeting, it is important to optimize dose and schedule of relevant agents and to understand barriers to targeted delivery. Here, we address these issues for the anti-carcinoembryonic antigen bifunctional antibody-hapten and the streptavidinylated antibody-biotin systems using a recently developed physiologically based pharmacokinetic model.
Methods: For baseline conditions of a standard 70-kg man with a 20-g tumor embedded in the liver, the model was used in conjunction with the Medical Internal Radiation Dosimetry schema to: estimate absorbed doses in tumor and normal tissues; determine the dose dependence of effector agent accumulation in tumor; simulate tumor-to-background effector agent uptake ratio; and calculate the therapeutic ratio for different antibody forms and radionuclides. Alternative drug administration schemes and variable tumor physiological conditions were considered.
Results: Model simulations showed that 131I-labeled biotin with the streptavidinylated F(ab')2 provided the highest therapeutic ratio under the optimized conditions. The simulations also showed that biotin with the bifunctional streptavidinylated immunoglobulin G provided the highest tumor-to-liver uptake ratio during the early period. Sensitivity analysis showed that antibody extravasation was the major factor limiting the accretion of the effector agent in tumor, whereas antigen expression in normal tissues and tumor antigen shedding had little effect on the absorbed doses.
Conclusion: Tumor pretargeting should provide a definite advantage over direct antibody targeting with up to a 200% increase in tumor-to-background ratio in radioimmunodetection and up to a 76% increase in tumor-to-bone marrow therapeutic ratio in radioimmunotherapy. Rapid antibody clearance from the bloodstream before effector agent injection is expected to improve the therapeutic ratio marginally (3%-10%). However, continuous plasmapheresis dramatically increased the tumor-to-background ratio by a factor of 10 in RAID and the tumor-to-bone marrow therapeutic ratio by more than 110% for short-lived radionuclides in RAIT. Apart from drastic measures such as extended plasmapheresis, pretargeting selectivity was neither sensitive enough for radioimmunodetection nor effective enough for radioimmunotherapy in patients with typical solid tumors even using the optimized protocols.