Can immuno-oncology offer a truly pan-tumour approach to therapy?

How mathematical modeling could contribute to the quantification of metastatic tumor burden under therapy: insights in immunotherapeutic treatment of non-small cell lung cancer

BACKGROUND

Cancer is one of the leading death causes globally with about 8.2 million deaths per year and an increase in numbers in recent years. About 90% of cancer deaths do not occur due to primary tumors but due to metastases, of which most are not clinically identifiable because of their relatively small size at primary diagnosis and limited technical possibilities. However, therapeutic decisions are formed depending on the existence of metastases and their properties. Therefore non-identified metastases might have huge influence in the treatment outcome. The quantification of clinically visible and invisible metastases is important for the choice of an optimal treatment of the individual patient as it could clarify the burden of non-identifiable tumors as well as the future behavior of the cancerous disease.

RESULTS

The mathematical model presented in this study gives insights in how this could be achieved, taking into account different treatment possibilities and therefore being able to compare therapy schedules for individual patients with different clinical parameters. The framework was tested on three patients with non-small cell lung cancer, one of the deadliest types of cancer worldwide, and clinical history including platinum-based chemotherapy and PD-L1-targeted immunotherapy. Results yield promising insights into the framework to establish methods to quantify effects of different therapy methods and prognostic features for individual patients already at stage of primary diagnosis.

Comparative Characterization of Lymphoid Infiltration in Different Molecular-Biological Subtypes of Invasive Breast Cancer

The morphometric study examined the cell profile of lymphoid structures and leukocytic infiltrates in mammary glands of women with different molecular-biological subtypes of invasive breast cancer (BC). A high degree of lymphoid infiltration with the formation of lymphoid nodules was typical of luminal B (LumB) subtype of BC characterized by high tumor proliferation index (Ki-67≥30%) and in triple negative BC with Ki-67 ranging 33-35%. In these BC subtypes, extensive necrotic foci and pronounced stromal fibrosis of the mammary glands were observed. Lymphoid clusters and nodules predominantly consisted of B cells (CD20⁺) and T helper cells (CD4⁺). Cytotoxic lymphocytes (CD8⁺) were mostly observed in interstitial infiltrates. Macrophages and plasma cells were primarily located near the tumor cells. The presence of lymphoid clusters in the form of lymphoid nodules and dense lymphoid infiltrates can be viewed as unfavorable sign during diagnosis of BC and prediction of the course of the tumor process.

Tumor Immunology and Immune Checkpoint Inhibitors in Non-Small Cell Lung Cancer

Lung cancer is one of the most commonly diagnosed cancers and the leading cause of cancer-related deaths worldwide. Although progress in the treatment of advanced non-small cell lung cancer (NSCLC) has been made over the past decade, the 5-year survival rate in patients with lung cancer remains only 10%–20%. Obviously, new therapeutic options are required for patients with advanced NSCLC and unmet medical needs. Cancer immunotherapy is an evolving treatment modality that uses a patient's own immune systems to fight cancer. Theoretically, cancer immunotherapy can result in long-term cancer remission and may not cause the same side effects as chemotherapy and radiation. Immuno-oncology has become an important focus of basic research as well as clinical trials for the treatment of NSCLC. Immune checkpoint inhibitors are the most promising approach for cancer immunotherapy and they have become the standard of care for patients with advanced NSCLC. This review summarizes basic tumor immunology and the relevant clinical data on immunotherapeutic approaches, especially immune checkpoint inhibitors in NSCLC.

Vaccination with trifunctional nanoparticles that address CD8+ dendritic cells inhibits growth of established melanoma

AIM

We wanted to assess the potency of a trifunctional nanoparticle (NP) that targeted and activated CD8⁺ dendritic cells (DC) and delivered an antigen to induce antitumor responses.

MATERIALS & METHODS

The DC targeting and activating properties of ferrous NPs conjugated with immunostimulatory CpG-oligonucleotides, anti-DEC205 antibody and ovalbumin (OVA) as a model antigen to induce antigen-specific T-cell responses and antitumor responses were analyzed.

RESULTS

OVA-loaded NP conjugated with immunostimulatory CpG-oligonucleotides and anti-DEC205 antibody efficiently targeted and activated CD8⁺ DC in vivo, and induced strong OVA-specific T-cell activation. Vaccination of B16/OVA tumor-burdened mice with this NP formulation resulted in tumor growth arrest.

CONCLUSION

CD8⁺ DC-targeting trifunctional nanocarriers bear significant potential for antitumor immunotherapy.

Harnessing the immune system to provide long-term survival in patients with melanoma and other solid tumors

Accumulating data from patients treated with checkpoint inhibitors and other immunomodulatory agents indicate that harnessing the power of the immune system is integral to achieve improve long-term cancer containment rates and prolong patient survival. Due to their mechanism of action, immunotherapeutic approaches have the potential to be effective against almost every tumor type. Durable responses to immunotherapy and prolonged patient survival have indeed been documented in individuals with melanoma, as well as kidney and lung cancer. These advances call for the re-evaluation of how clinical benefit is measured in an era in which long-term tumor control and survival are achievable treatment goals.

A novel personalized vaccine approach in combination with targeted therapy in advanced renal cell carcinoma

The historical treatment paradigm for metastatic renal cell carcinoma has focused on immunomodulatory agents, such as IFN-α and IL-2, which provide good clinical outcomes in only a subset of patients. The development of therapies that target the VEGF and mTOR pathways have significantly altered the treatment landscape for this disease, with novel inhibitors providing substantial improvements in progression-free and overall survival over previous standards of care. Despite these advances, toxicity from targeted therapy and the development of resistance results in disease progression. By contrast, vaccine-based immunotherapy represents a promising new approach for the treatment of patients with metastatic renal cell carcinoma; however, tumor-induced immunosuppression has limited the clinical efficacy of this modality until recently. Some evidence suggests that certain targeted therapies, such as sunitinib, may reduce this immunosuppression and enhance the tumor microenvironment to promote synergy with autologous dendritic cell vaccines.

Cancer immunotherapy: accomplishments to date and future promise

Cancer remains a devastating disease as existing therapies are too often ineffective and toxicities remain unacceptably high. Immunotherapies for cancer offer the promise of the specificity and memory of the immune system against malignant cells to achieve durable cure with minimal toxicity. Beginning with the success of bone marrow transplantation for blood-borne cancers, and the more recent development of monoclonal antibody therapeutics for a variety of tumors, immunotherapies are already among the most successful class of treatments for cancer. Greater understanding of immunoregulatory mechanisms and improved techniques for immune cell manipulation and engineering have led to new immunomodulatory approaches and cell-based therapies for cancer that have generated great excitement within the biomedical community. As these technologies continue to improve, and as new approaches for harnessing the power and specificity of the immune system are developed, immunotherapies will play an increasingly important role in the treatment of cancer. Here, we review the history of immunotherapies for cancer and discuss existing and emerging immunotherapy technologies that hope to translate the promise of immunotherapy into clinical reality.