Tumor Cell Membrane-based Vaccines: A Potential Boost for Cancer Immunotherapy

Overview

Journal Exploration (Beijing)

Specialty Biomedical Engineering

Date 2024 Dec 23

PMID 39713208

Authors

Muyang Yang

Jie Zhou

Liseng Lu

Deqiang Deng

Jing Huang

Zijian Tang

Xiujuan Shi

Pui-Chi Lo

Jonathan F Lovell

Yongfa Zheng

Honglin Jin

Affiliations

Soon will be listed here.

Abstract

Because therapeutic cancer vaccines can, in theory, eliminate tumor cells specifically with relatively low toxicity, they have long been considered for application in repressing cancer progression. Traditional cancer vaccines containing a single or a few discrete tumor epitopes have failed in the clinic, possibly due to challenges in epitope selection, target downregulation, cancer cell heterogeneity, tumor microenvironment immunosuppression, or a lack of vaccine immunogenicity. Whole cancer cell or cancer membrane vaccines, which provide a rich source of antigens, are emerging as viable alternatives. Autologous and allogenic cellular cancer vaccines have been evaluated as clinical treatments. Tumor cell membranes (TCMs) are an intriguing antigen source, as they provide membrane-accessible targets and, at the same time, serve as integrated carriers of vaccine adjuvants and other therapeutic agents. This review provides a summary of the properties and technologies for TCM cancer vaccines. Characteristics, categories, mechanisms, and preparation methods are discussed, as are the demonstrable additional benefits derived from combining TCM vaccines with chemotherapy, sonodynamic therapy, phototherapy, and oncolytic viruses. Further research in chemistry, biomedicine, cancer immunology, and bioinformatics to address current drawbacks could facilitate the clinical adoption of TCM vaccines.

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