AI Article Synopsis
- Tumor binding plays a crucial role in understanding unbound tumor concentrations, which helps in exploring pharmacokinetics (PK) and pharmacodynamics (PD) in cancer research.
- Research involved evaluating tumor binding across eleven different types of human and mouse tumors, with results showing strong correlations, except for the specific case of mouse melanoma (B16F10).
- Predictive models were created to estimate tumor binding when direct experimental data is lacking, suggesting alternative strategies like using surrogate tissues for initial assessments, specifically recommending OVCAR3 tumors for most cases.
Article Abstract
Tumor binding is an important parameter to derive unbound tumor concentration to explore pharmacokinetics (PK) and pharmacodynamics (PD) relationships for oncology disease targets. Tumor binding was evaluated using eleven matrices, including various commonly used ex vivo human and mouse xenograft and syngeneic tumors, tumor cell lines and liver as a surrogate tissue. The results showed that tumor binding is highly correlated among the different tumors and tumor cell lines except for the mouse melanoma (B16F10) tumor type. Liver fraction unbound (f) has a good correlation with B16F10 tumor binding. Liver also demonstrates a two-fold equivalency, on average, with binding of other tumor types when a scaling factor is applied. Predictive models were developed for tumor binding, with correlations established with LogD (acids), predicted muscle f (neutrals) and measured plasma protein binding (bases) to estimate tumor f when experimental data are not available. Many approaches can be applied to obtain and estimate tumor binding values. One strategy proposed is to use a surrogate tumor tissue, such as mouse xenograft ovarian cancer (OVCAR3) tumor, as a surrogate for tumor binding (except for B16F10) to provide an early assessment of unbound tumor concentrations for development of PK/PD relationships.
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| http://dx.doi.org/10.1016/j.xphs.2023.11.024 | DOI Listing |
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