Cancer Cancer treatment used to be focused on killing or removing cancer cells and tumours, with chemotherapy or surgery or radiation. In 2018 the
Nobel Prize in Physiology or Medicine was awarded to
James P. Allison and
Tasuku Honjo "for their discovery of cancer therapy by inhibition of negative immune regulation." Cancer immunotherapy attempts to stimulate the
immune system to destroy tumours. A variety of strategies are in use or are undergoing research and testing. Randomized controlled studies in different cancers resulting in significant increase in survival and disease free period have been reported and its efficacy is enhanced by 20–30% when cell-based immunotherapy is combined with conventional treatment methods. BCG immunotherapy induces both local and systemic immune responses. The mechanisms by which BCG immunotherapy mediates tumor immunity have been widely studied, but they are still not completely understood. The use of
monoclonal antibodies in cancer therapy was first introduced in 1997 with
rituximab, an anti-CD20 antibody for treatment of B cell lymphoma. Since then several monoclonal antibodies have been approved for treatment of various haematological malignancies as well as for solid tumours. The extraction of
G-CSF lymphocytes from the blood and expanding
in vitro against a tumour antigen before reinjecting the cells with appropriate stimulatory
cytokines. The cells then destroy the tumour cells that express the
antigen. Topical immunotherapy utilizes an immune enhancement cream (
imiquimod) which produces
interferon, causing the recipient's killer
T cells to destroy
warts,
actinic keratoses,
basal cell cancer,
vaginal intraepithelial neoplasia, squamous cell cancer, cutaneous lymphoma, and superficial melanoma. Injection immunotherapy ("intralesional" or "intratumoural") uses mumps, candida, the HPV vaccine or
trichophytin antigen injections to treat warts (HPV induced tumours).
Adoptive cell transfer has been tested on
lung and other cancers, with greatest success achieved in
melanoma.
Dendritic cell-based pump-priming or vaccination Dendritic cells (DC) can be stimulated to activate a
cytotoxic response towards an
antigen. Dendritic cells, a type of
antigen-presenting cell, are harvested from the person needing the immunotherapy. These cells are then either pulsed with an antigen or tumour lysate or
transfected with a
viral vector, causing them to display the antigen. Upon transfusion into the person, these activated cells present the antigen to the effector lymphocytes (
CD4+ helper T cells, cytotoxic
CD8+ T cells and
B cells). This initiates a cytotoxic response against tumour cells expressing the antigen (against which the adaptive response has now been primed). The first FDA-approved cell-based immunotherapy, the
cancer vaccine Sipuleucel-T is one example of this approach. The Immune Response Corporation (IRC) developed this immunotherapy and licensed the technology to Dendreon, which obtained FDA clearance. The current approaches for
DC-based vaccination are mainly based on antigen loading on
in vitro-generated DCs from
monocytes or
CD34+ cells, activating them with different
TLR ligands,
cytokine combinations, and injecting them back to the patients. The
in vivo targeting approaches comprise administering specific cytokines (e.g.,
Flt3L,
GM-CSF) and targeting the DCs with antibodies to C-type lectin receptors or agonistic antibodies (e.g., anti-
CD40) that are conjugated with antigen of interest. Multiple, next-generation anti-CD40 platforms are being actively developed. Future approach may target DC subsets based on their specifically expressed
C-type lectin receptors or
chemokine receptors. Another potential approach is the generation of genetically engineered DCs from
induced pluripotent stem cells and use of
neoantigen-loaded DCs for inducing better clinical outcome.
Adoptive cell therapy Adoptive cell therapy encompasses three main approaches: (1) TIL therapy, (2) T cell receptor-engineered T cells (TCR-T cells), and (3) chimeric antigen receptor T cells (CAR-T cells), with newer adaptations including CAR-NK cells and CAR-macrophages under early investigation. The first proof-of-concept for ACT was demonstrated by Steven Rosenberg and colleagues in 1988, when they showed that TILs expanded ex vivo and reinfused into patients, together with high-dose interleukin-2, could mediate tumor regression in patients with metastatic melanoma. In 2024, FDA has granted an accelerated approval for lifileucel, a TIL-based therapy for metastatic melanoma.
Adoptive cell transfer in vitro cultivates autologous, extracted T cells for later transfusion. Alternatively,
Genetically engineered T cells are created by harvesting T cells and then infecting the T cells with a
retrovirus that contains a copy of a
T cell receptor (TCR) gene that is specialised to recognise tumour antigens. The virus integrates the receptor into the T cells'
genome. The cells are expanded non-specifically and/or stimulated. The cells are then reinfused and produce an immune response against the tumour cells. The technique has been tested on refractory stage IV metastatic melanomas In 2024, the FDA granted accelerated approval to afamitresgene autoleucel (TECELTA, Adaptimmune LLC), the first TCR-T therapy for solid tumors. CAR-T therapy uses peripheral blood T cells that are genetically engineered ex vivo to express synthetic receptors targeting specific tumor antigens. To date, the FDA has approved several CAR-T cell therapies for hematological malignancies, including B-cell acute lymphoblastic leukemia, B-cell lymphoma, and multiple myeloma. The first FDA-approved CAR-T therapy, Kymriah, used this approach. To obtain the clinical and commercial supply of this CAR-T, Novartis purchased the manufacturing plant, the distribution system and hired the production team that produced Sipuleucel-T developed by Dendreon and the Immune Response Corporation. Whether T cells are genetically engineered or not, before re-infusion, lympho-depletion of the recipient is required to eliminate regulatory T cells as well as unmodified, endogenous lymphocytes that compete with the transferred cells for homeostatic cytokines. Lymphodepletion may be achieved by
myeloablative chemotherapy, to which total body irradiation may be added for greater effect. Transferred cells multiplied
in vivo and persisted in peripheral blood in many people, sometimes representing levels of 75% of all CD8+ T cells at 6–12 months after infusion. , clinical trials for metastatic melanoma were ongoing at multiple sites. Clinical responses to adoptive transfer of T cells were observed in patients with metastatic melanoma resistant to multiple immunotherapies. Although CAR-T cell therapies have shown significant success in hematological malignancies, their application in solid tumors remains limited. Several recent reviews discussed emerging strategies for solid tumor CAR-T cell therapy, and highlighted novel targets that may help overcome current challenges in antigen specificity and tumor infiltration.
Checkpoint inhibitors Anti-PD-1/PD-L1 and anti-CTLA-4 antibodies are the two types of checkpoint inhibitors currently available to patients. The approval of anti-cytotoxic T-lymphocyte-associated protein 4 (
CTLA-4) and anti-programmed cell death protein 1 (
PD-1) antibodies for human use has already resulted in significant improvements in disease outcomes for various cancers. Although these molecules were originally discovered as molecules playing a role in
T cell activation or
apoptosis, subsequent preclinical research showed their important role in the maintenance of peripheral immune tolerance. Immune checkpoint inhibitors are approved to treat some patients with a variety of cancer types, including
melanoma,
breast cancer,
bladder cancer,
cervical cancer,
colon cancer, lung cancer
head and neck cancer, or
Hodgkin lymphoma. These therapies have revolutionized
cancer immunotherapy as they showed for the first time in many years of research in metastatic
melanoma, which is considered one of the most
immunogenic human cancers, an improvement in overall survival, with an increasing group of patients benefiting long-term from these treatments, although caution remains needed for specific subgroups. The next generation of checkpoint inhibitors targets other receptors such as lymphocyte-activation gene 3 (
LAG-3), T-cell immunoglobulin and mucin-domain containing-3 (
TIM3), and T cell immunoreceptor with Ig and ITIM domains (
TIGIT). Antibodies against these receptors have been evaluated in clinical studies, but have not yet been approved for widespread use. ==Immune enhancement therapy==