Low‐Cost, High‐Pressure‐Synthesized Oxygen‐Entrapping Materials to Improve Treatment of Solid Tumors

Jianling Bi; Emily Witt; Vanessa A. Voltarelli; Vivian R. Feig; Veena Venkatachalam; Hannah Boyce; Megan McGovern; Wade R. Gutierrez; Jeffrey D. Rytlewski; Kate R. Bowman; Ashley C. Rhodes; Austin N. Cook; Benjamin N. Muller; Matthew G. Smith; Alexis Rebecca Ramos; Heena Panchal; Rebecca D. Dodd; Michael D. Henry; Adam Mailloux; Giovanni Traverso; Leo E. Otterbein; James D. Byrne

doi:10.1002/advs.202205995

Advanced Science (Apr 2023)

Low‐Cost, High‐Pressure‐Synthesized Oxygen‐Entrapping Materials to Improve Treatment of Solid Tumors

Jianling Bi,
Emily Witt,
Vanessa A. Voltarelli,
Vivian R. Feig,
Veena Venkatachalam,
Hannah Boyce,
Megan McGovern,
Wade R. Gutierrez,
Jeffrey D. Rytlewski,
Kate R. Bowman,
Ashley C. Rhodes,
Austin N. Cook,
Benjamin N. Muller,
Matthew G. Smith,
Alexis Rebecca Ramos,
Heena Panchal,
Rebecca D. Dodd,
Michael D. Henry,
Adam Mailloux,
Giovanni Traverso,
Leo E. Otterbein,
James D. Byrne

Affiliations

Jianling Bi: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA
Emily Witt: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA
Vanessa A. Voltarelli: Department of Surgery Beth Israel Deaconess Medical Center Harvard Medical School 3 Blackfan Circle Boston MA 02215 USA
Vivian R. Feig: Division of Gastroenterology Brigham and Women's Hospital Harvard Medical School 75 Francis St. Boston MA 02115 USA
Veena Venkatachalam: Department of Systems Biology Harvard Medical School 75 Francis St. Boston MA 02115 USA
Hannah Boyce: Department of Chemical Engineering Massachusetts Institute of Technology 25 Ames St. Cambridge MA 02139 USA
Megan McGovern: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA
Wade R. Gutierrez: Holden Comprehensive Cancer Center University of Iowa Iowa City IA 52242 USA
Jeffrey D. Rytlewski: Holden Comprehensive Cancer Center University of Iowa Iowa City IA 52242 USA
Kate R. Bowman: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA
Ashley C. Rhodes: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA
Austin N. Cook: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA
Benjamin N. Muller: Division of Gastroenterology Brigham and Women's Hospital Harvard Medical School 75 Francis St. Boston MA 02115 USA
Matthew G. Smith: Department of Microbiology and Immunology Carver College of Medicine University of Iowa Iowa City IA 52242 USA
Alexis Rebecca Ramos: Holden Comprehensive Cancer Center University of Iowa Iowa City IA 52242 USA
Heena Panchal: Department of Microbiology and Immunology Carver College of Medicine University of Iowa Iowa City IA 52242 USA
Rebecca D. Dodd: Holden Comprehensive Cancer Center University of Iowa Iowa City IA 52242 USA
Michael D. Henry: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA
Adam Mailloux: Holden Comprehensive Cancer Center University of Iowa Iowa City IA 52242 USA
Giovanni Traverso: Division of Gastroenterology Brigham and Women's Hospital Harvard Medical School 75 Francis St. Boston MA 02115 USA
Leo E. Otterbein: Department of Surgery Beth Israel Deaconess Medical Center Harvard Medical School 3 Blackfan Circle Boston MA 02215 USA
James D. Byrne: Department of Radiation Oncology University of Iowa 200 Hawkins Drive Iowa City IA 52242 USA

DOI: https://doi.org/10.1002/advs.202205995
Journal volume & issue: Vol. 10, no. 10
pp. n/a – n/a

Abstract

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Abstract Tumor hypoxia drives resistance to many cancer therapies, including radiotherapy and chemotherapy. Methods that increase tumor oxygen pressures, such as hyperbaric oxygen therapy and microbubble infusion, are utilized to improve the responses to current standard‐of‐care therapies. However, key obstacles remain, in particular delivery of oxygen at the appropriate dose and with optimal pharmacokinetics. Toward overcoming these hurdles, gas‐entrapping materials (GeMs) that are capable of tunable oxygen release are formulated. It is shown that injection or implantation of these materials into tumors can mitigate tumor hypoxia by delivering oxygen locally and that these GeMs enhance responsiveness to radiation and chemotherapy in multiple tumor types. This paper also demonstrates, by comparing an oxygen (O2)‐GeM to a sham GeM, that the former generates an antitumorigenic and immunogenic tumor microenvironment in malignant peripheral nerve sheath tumors. Collectively the results indicate that the use of O2‐GeMs is promising as an adjunctive strategy for the treatment of solid tumors.

Published in Advanced Science

ISSN: 2198-3844 (Online)
Publisher: Wiley
Country of publisher: Germany
LCC subjects: Science
Website: https://onlinelibrary.wiley.com/journal/21983844

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