Alk5 inhibition increases delivery of macromolecular and protein-bound contrast agents to tumors
Heike E. Daldrup-Link, Suchismita Mohanty, Celina Ansari, Olga Lenkov, Aubie Shaw, Ken Ito, Su Hyun Hong, Matthias Hoffmann, Laura Pisani, Nancy Boudreau, Sanjiv Sam Gambhir, Lisa M. Coussens
Heike E. Daldrup-Link, Suchismita Mohanty, Celina Ansari, Olga Lenkov, Aubie Shaw, Ken Ito, Su Hyun Hong, Matthias Hoffmann, Laura Pisani, Nancy Boudreau, Sanjiv Sam Gambhir, Lisa M. Coussens
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Research Article Oncology

Alk5 inhibition increases delivery of macromolecular and protein-bound contrast agents to tumors

Abstract

Limited transendothelial permeability across tumor microvessels represents a significant bottleneck in the development of tumor-specific diagnostic agents and theranostic drugs. Here, we show an approach to increase transendothelial permeability of macromolecular and nanoparticle-based contrast agents via inhibition of the type I TGF-β receptor, activin-like kinase 5 (Alk5), in tumors. Alk5 inhibition significantly increased tumor contrast agent delivery and enhancement on imaging studies, while healthy organs remained relatively unaffected. Imaging data correlated with significantly decreased tumor interstitial fluid pressure, while tumor vascular density remained unchanged. This immediately clinically translatable concept involving Alk5 inhibitor pretreatment prior to an imaging study could be leveraged for improved tumor delivery of macromolecular and nanoparticle-based imaging probes and, thereby, facilitate development of more sensitive imaging tests for cancer diagnosis, enhanced tumor characterization, and personalized, image-guided therapies.

Authors

Heike E. Daldrup-Link, Suchismita Mohanty, Celina Ansari, Olga Lenkov, Aubie Shaw, Ken Ito, Su Hyun Hong, Matthias Hoffmann, Laura Pisani, Nancy Boudreau, Sanjiv Sam Gambhir, Lisa M. Coussens

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Figure 7

Alk5 inhibition leads to increased iron oxide nanoparticle accumulation and enhancement of orthotopic glioblastomas on MR images.

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Alk5 inhibition leads to increased iron oxide nanoparticle accumulation ...
(A) Representative coronal T2-weighted MR images (top) and T1-weighted MR images (bottom) before and after i.v. injection of ferumoxytol nanoparticles show stronger tumor enhancement after Alk5 inhibition (arrow) compared with untreated tumors (arrowhead). (B and C) Representative plots for dynamic contrast ferumoxytol scans in blood pool versus tumor tissue of mice treated with or without Alk5 inhibitor. ΔR1 values for blood pool from PBS- or Alk5-treated mice are represented on the primary y axis, whereas ΔR1 values for tumors are represented on secondary y axis. (D and E) Corresponding quantitative changes in tumor R2 and R1 relaxation rates after ferumoxytol injection, measured as R2precontrast – R2postcontrast or R1precontrast – R1postcontrast and displayed as means for 9 animals in each group ± SD, respectively. ANOVA was used to compare the differences between various groups. *P < 0.05, **P < 0.005, between MR enhancements of Alk5-treated tumors compared with untreated controls. (F) H&E and Prussian blue staining of a representative Alk5 inhibitor-treated glioblastoma (right) and untreated control (left) mice (original magnification, ×20). Prussian blue staining shows increased ferumoxytol deposition in Alk5 inhibitor-treated glioblastoma. Scale bar: 100 μm. Alk5, activin-like kinase 5; Alk5i, Alk5 inhibition; MR, magnetic resonance