Chemoimmunotherapy

In the early 1900s, German chemist Paul Ehrlich began creating drugs for infectious diseases and introduced the term "chemotherapy" for using chemicals to treat illnesses. He was also the first to use animal models to test the effectiveness of these chemicals, significantly advancing cancer drug development.^[3] During World War II, the Cancer Chemotherapy National Service Center was set up to develop new drugs.^[4] Successes in treating acute childhood leukemia and advanced Hodgkin's disease led to increased screening for anti-tumor chemicals. It was discovered that combining different drugs improved treatment outcomes. Initially, the idea that chemicals could kill cancer cells and lead to cancer-specific therapies was not considered possible.

James Allison, now at the University of Texas MD Anderson Cancer Center, was an early pioneer of immunotherapy. He discovered that CTLA-4 inhibits T cells from fully attacking, and hypothesized that blocking CTLA-4 could unleash the immune system to fight cancer. Initially, his idea was met with skepticism, but he continued his research and proved its validity in mice. Clinical trials later showed that anti-CTLA-4 antibodies could extend the lives of patients with metastatic melanoma by four months, and anti-PD-1 antibodies also demonstrated anti-tumor effects.^[5] Using the immune system to combat cancer has since gained popularity.

However, the interaction between tumors and the immune system creates multiple mechanisms of regulation and immune escape that suppress the immune response to tumors. Various immune cells, such as regulatory T cells (Tregs), T helper cells producing interleukin-17, myeloid-derived suppressor cells (MDSCs), and tumor-associated macrophages (TAMs), promote tumor growth and inhibit the immune response. Additionally, the tumor microenvironment further suppresses the anti-tumor immune response with high levels of suppressive cytokines (TGF-β, TNF, IL-10), expression of immune checkpoint molecules (PD-L1, B7-H4), and other alterations that help the tumor evade the immune system, such as the loss of tumor antigens necessary for antigen processing and presentation.^[3]

Chemotherapy is often seen as immunosuppressive because it suppresses immune cell production in the bone marrow in a dose-dependent manner. This suggests it might conflict with immunotherapy. However, research shows that certain chemotherapy drugs can, under specific conditions, boost the immune response against tumors and enhance the effectiveness of immunotherapy.^[6]

Chemotherapy can boost tumor immunity in two main ways: (a) by killing cancer cells through immunogenic cell death, and (b) by affecting both cancerous and normal cells in the tumor environment. Despite this, many chemotherapy treatments can also suppress the immune system by causing lymphopenia or impairing lymphocyte function. Integrating immune-based therapies with chemotherapy has the potential to alter the body's overall environment and the local tumor microenvironment, disrupting immune tolerance and suppression pathways.^[3]