PET-based Compartmental Modeling of (124)I-A33 Antibody: Quantitative Characterization of Patient-specific Tumor Targeting in Colorectal Cancer

Overview

Journal Eur J Nucl Med Mol Imaging

Specialties Biophysics
Nuclear Medicine
Radiology

Date 2015 Jul 22

PMID 26194713

Citations 11

Authors

Pat Zanzonico

Jorge A Carrasquillo

Neeta Pandit-Taskar

Joseph A ODonoghue

John L Humm

Peter Smith-Jones

Shutian Ruan

Chaitanya Divgi

Andrew M Scott

Nancy E Kemeny

Yuman Fong

Douglas Wong

David Scheinberg

Gerd Ritter

Achem Jungbluth

Lloyd J Old

Steven M Larson

Affiliations

Soon will be listed here.

Abstract

Purpose: The molecular specificity of monoclonal antibodies (mAbs) directed against tumor antigens has proven effective for targeted therapy of human cancers, as shown by a growing list of successful antibody-based drug products. We describe a novel, nonlinear compartmental model using PET-derived data to determine the "best-fit" parameters and model-derived quantities for optimizing biodistribution of intravenously injected (124)I-labeled antitumor antibodies.

Methods: As an example of this paradigm, quantitative image and kinetic analyses of anti-A33 humanized mAb (also known as "A33") were performed in 11 colorectal cancer patients. Serial whole-body PET scans of (124)I-labeled A33 and blood samples were acquired and the resulting tissue time-activity data for each patient were fit to a nonlinear compartmental model using the SAAM II computer code.

Results: Excellent agreement was observed between fitted and measured parameters of tumor uptake, "off-target" uptake in bowel mucosa, blood clearance, tumor antigen levels, and percent antigen occupancy.

Conclusion: This approach should be generally applicable to antibody-antigen systems in human tumors for which the masses of antigen-expressing tumor and of normal tissues can be estimated and for which antibody kinetics can be measured with PET. Ultimately, based on each patient's resulting "best-fit" nonlinear model, a patient-specific optimum mAb dose (in micromoles, for example) may be derived.

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