Search Results (157)

Multiple myeloma (MM) is a clonal malignancy of plasma cells that remains largely incurable despite major advances in proteasome inhibitors, immunomodulatory drugs, and monoclonal antibodies. Chimeric antigen receptor (CAR)-engineered immune cells have transformed the therapeutic landscape, but CAR-T cell therapy faces challenges such as severe cytokine release syndrome (CRS), neurotoxicity, limited persistence, and logistical complexity. In recent years, natural killer (NK) cells have emerged as a promising platform for next-generation cellular immunotherapy, offering innate antitumor activity, a reduced risk of graft-versus-host disease (GvHD), and the feasibility of “off-the-shelf” allogeneic production. This review summarizes current advances in CAR-NK cell therapy for MM, focusing on two major aspects: the diversity of cell sources—including NK-92, peripheral (PB) and cord blood (CB), and induced pluripotent stem cell (iPSC)-derived NK cells—and the expanding repertoire of target antigens such as BCMA (B-cell maturation antigen), NKG2D, CD38, CD70, SLAMF7, CD138, and GPRC5D. We highlight preclinical and early clinical studies demonstrating potent cytotoxicity, favorable safety profiles, and innovative multi-targeting strategies designed to overcome antigen escape and enhance persistence. Emerging clinical data suggest that CAR-NK cell therapy may combine the specificity of CAR recognition with the inherent safety and versatility of NK biology, offering a potential paradigm shift in the treatment of relapsed or refractory MM. Further clinical validation will determine whether CAR-NK cell therapy can achieve durable remission and complement or surpass current CAR-T modalities. Full article

Pediatric oral rhabdomyosarcoma (RMS) is a rare and aggressive cancer of the head and neck, characterized by a complex and mostly immunosuppressive tumor–immune microenvironment. Unlike adult cancers, pediatric RMS typically exhibits a “cold” immune profile, characterized by minimal T-cell infiltration, a low mutational burden, and resistance to immune checkpoint blockade. The tumor’s location in the oral cavity adds difficulty to treatment because of anatomical and functional limitations. Additionally, the presence of fusion oncogenes, such as PAX3:FOXO1, hampers immunogenicity and treatment response by disrupting antigen presentation and reducing immune cell infiltration. Advances in immuno-oncology have introduced new strategies, including immune checkpoint inhibitors, chimeric antigen receptor (CAR) therapies, cancer vaccines, and oncolytic viruses. However, these approaches face specific challenges in the pediatric population due to developmental immune factors. This narrative review highlights recent findings on the immunobiology of pediatric oral RMS, focusing on tumor–immune interactions and their impact on disease progression and treatment resistance. We reviewed the cellular components of the TIME, the mechanisms of immune evasion, and the expression of immune checkpoints, including PD-L1 and B7-H3. Emerging immunotherapies, including CAR-T, CAR-NK, and CAR-CIK cell therapies; checkpoint inhibitors; oncolytic viruses; and cancer vaccines, are discussed, with an emphasis on their current limitations and potential to transform the pediatric RMS immune landscape. Full article

Chimeric antigen receptor (CAR) T cell therapy has revolutionized the treatment of certain hematologic malignancies, yet its success in solid tumors has been limited by antigen heterogeneity, an immunosuppressive tumor microenvironment, and barriers to cell trafficking and persistence. To expand the reach of cellular immunotherapy, multiple immune cell types—γδ T cells, invariant NKT cells, virus-specific T cells, natural killer (ΝΚ) cells, and myeloid effectors such as macrophages and dendritic cells—are now being explored as alternative or complementary CAR platforms. Each lineage brings unique advantages, such as the innate cytotoxicity and safety profile of CAR NK cells, the tissue infiltration and microenvironment-modulating capacity of CAR macrophages, or the MHC-independent recognition offered by γδ T cells. Recent advances in pharmacological strategies, synthetic biology, and artificial intelligence provide additional opportunities to overcome barriers and optimize CAR design and manufacturing scale-up. Here, we review the state of the art in engineering diverse immune cells for solid tumor therapy, highlight safety considerations across autologous, allogeneic, and in vivo CAR cell therapy approaches, and provide our perspective on which platforms might best address current unmet clinical needs. Collectively, these developments lay the foundation for next-generation strategies to achieve durable immunotherapy responses in solid tumors. Full article

Chimeric antigen receptor-expressing NK (CAR-NK) cells represent an advancing frontier in cancer immunotherapy, building upon decades of natural killer cell research and recent breakthroughs in CAR technology. While early CAR-NK manufacturing protocols have demonstrated feasibility, existing manufacturing methods, whether utilizing cord blood or peripheral blood sources, often require extended culture periods and intensive labor, creating bottlenecks for widespread therapeutic application. To address these manufacturing hurdles, we have developed an optimized protocol for ex vivo CAR-NK cell production from human peripheral blood that incorporates lessons learned from previous methodologies while introducing novel efficiency improvements. This protocol offers a practical solution for scalable CAR-NK cell manufacturing that can be readily adapted across different production facilities, potentially accelerating the clinical development of CAR-NK therapies. Full article

Chimeric antigen receptor (CAR) cell therapy, encompassing CAR T, CAR NK, and CAR macrophage cells, demonstrates high efficacy in tumor treatment, conferring durable and effective responses, notably in hematologic malignancies. However, challenges persist in the manufacture of CAR cells, and treatment is associated with serious adverse events, notably cytokine release syndrome (CRS), a potentially life-threatening complication. Owing to the inherent properties of exosomes, CAR cell-derived exosomes offer distinct advantages in cancer therapeutics. CAR cells-derived exosomes retain the inherent tumor-killing function of the parent cells while also exhibiting key practical advantages, including wide availability, safety, and ease of storage and transport. Furthermore, CAR cell-derived exosomes can be combined with other tumor therapies; this combinatorial approach significantly enhances efficacy while reducing side effects. To accelerate the clinical translation of CAR cell-derived exosomes in tumor therapy, this paper reviews their biogenesis, engineering strategies, antitumor mechanisms and clinical evidence, including case studies of combination therapies with other antitumor modalities. Full article

Chimeric antigen receptor (CAR)-engineered NK cells are a promising approach for targeted immunotherapy in Her2-positive cancers. This study aimed to generate anti-Her2 CAR-NK92 cells, to evaluate their selective cytotoxicity against Her2-positive cancer cells, and to isolate and characterize their released exosomes. NK92 cells were electroporated with piggyBac transposon vectors encoding anti-Her2 CAR and the helper transposase. Puromycin selection was performed to enrich the transduced cells. CAR and GFP expression were assessed by flow cytometry, and exosomes were isolated and characterized in terms of protein cargo and surface protein expression. Cytotoxicity was evaluated using real-time cell analysis against Her2-positive SK-BR3 cells and Her2-negative MCF-7 cells. Electroporation did not significantly affect NK92 cell viability. Puromycin selection efficiently enriched for CAR-expressing cells, with GFP positivity reaching 99.8% and a 15-fold increase in CAR surface expression compared to wild-type cells. CAR-NK92 cells demonstrated robust, Her2-specific cytotoxicity in a E:T-dependent manner, with the greatest effect observed at a 10:1 effector-to-target ratio. Exosomes derived from CAR-NK92 cells contained CAR molecules and selectively targeted Her2-positive cells. Anti-Her2 CAR-NK92 cells and their exosomes exhibit potent and selective cytotoxicity against Her2-positive cancer cells, supporting their potential as innovative immunotherapeutic agents for solid tumors. Full article

Adoptive cell therapies have transformed the treatment landscape for hematologic malignancies. Yet, translation to solid tumors remains constrained by antigen heterogeneity, an immunosuppressive tumor microenvironment (TME), and poor persistence of conventional CAR-T cells. In response, innate immune cell platforms, particularly chimeric antigen receptor–engineered natural killer (CAR-NK) cells and chimeric antigen receptor–macrophages (CAR-MΦ), have emerged as promising alternatives. This review summarizes recent advances in the design and application of CAR-NK and CAR-MΦ therapies for solid tumors. We highlight key innovations, including the use of lineage-specific intracellular signaling domains (e.g., DAP12, 2B4, FcRγ), novel effector constructs (e.g., NKG7-overexpressing CARs, TME-responsive CARs), and scalable induced pluripotent stem cell (iPSC)-derived platforms. Preclinical data support enhanced antitumor activity through mechanisms such as major histocompatibility complex (MHC)-unrestricted cytotoxicity, phagocytosis, trogocytosis, cytokine secretion, and cross-talk with adaptive immunity. Early-phase clinical studies (e.g., CT-0508) demonstrate feasibility and TME remodeling with CAR-MΦ. However, persistent challenges remain, including transient in vivo survival, manufacturing complexity, and risks of off-target inflammation. Emerging combinatorial strategies, such as dual-effector regimens (CAR-NK⁺ CAR-MΦ), cytokine-modulated cross-support, and bispecific or logic-gated CARs, may overcome these barriers and provide more durable, tumor-selective responses. Taken together, CAR-NK and CAR-MΦ platforms are poised to expand the reach of engineered cell therapy into the solid tumor domain. Full article

Background/Objectives: Chimeric antigen receptor T-cell (CAR-T) therapy is a novel form of adoptive cellular immunotherapy that involves modifying autologous T cells to recognize and target tumor-associated antigens (TAAs) on malignant cells, independent of major histocompatibility complex (MHC) restriction. Although CAR-T therapy has shown remarkable success in treating hematologic malignancies, its efficacy in solid tumors remains limited, largely due to the lack of tumor-specific antigens and the complexity of the tumor microenvironment. This review aims to explore the rationale for continuing the development of adoptive cellular therapies in head and neck cancer (HNC), offering insights into the diagnostic and therapeutic challenges associated with this heterogeneous group of malignancies. Methods: We conducted a comprehensive literature review using the PubMed database to identify relevant studies on the application of CAR-T cell therapy in the management of HNC. Results: HNC presented numerous barriers to CAR-T cell infiltration, primarily due to the unique characteristics of its tumor microenvironment (TME). The TME in HNC is notably immunosuppressive, with a lymphocytic infiltrate predominantly composed of regulatory T cells (Tregs) and natural killer (NK) cells. These immune cells typically exhibit low expression of the CD16 receptor, which plays a crucial role in mediating antibody-dependent cellular cytotoxicity (ADCC), thereby limiting the effectiveness of CAR-T cell therapy. Conclusions: This comprehensive review suggests a potential clinical applicability of CAR-T therapy in HNC management. Full article

Cancer remains one of the leading causes of death worldwide. New treatments like immunotherapy—especially checkpoint inhibitors and CAR-T cell therapy—have improved outcomes for some patients. However, these therapies often struggle to treat solid tumours effectively. Natural killer (NK) cells are part of the immune system and can naturally detect and destroy cancer cells without previous adaption. Scientists are now enhancing these cells by adding special receptors, called CARs (chimeric antigen receptors), to help them better recognize and attack cancer, an approach originally developed for T cells. CAR-NK cell therapy has some advantages over CAR-T therapy. It tends to cause fewer severe side effects, such as strong immune reactions or off-target effects in healthy tissues. Within some limitations, the allogenic use of CAR-NK cells is possible, as these cells exert less graft-versus-host activity. Such CAR-NK cell products can be produced in larger quantities and stored, making treatment more accessible. Still, there are challenges. It can be difficult to create enough modified NK cells, and the tumour microenvironment can block their activity. This review highlights recent progress in CAR-NK therapy, including early lab and clinical research. It also explores ways to improve these treatments and how they might work alongside other cancer therapies to help more patients in the future. Full article

Chimeric antigen receptor (CAR)-engineered natural killer (NK) cells are a promising platform for off-the-shelf immunotherapy due to their safety advantages over CAR-T cells, including lower risk of graft-versus-host disease, cytokine release syndrome, and neurotoxicity. However, their persistence and efficacy are limited by immunological challenges such as host T-cell-mediated rejection, NK cell fratricide, and macrophage-mediated clearance. This review summarizes gene editing strategies to overcome these barriers, including β2-microglobulin (B2M) knockout and HLA-E overexpression to evade T and NK cell attacks, CD47 overexpression to inhibit phagocytosis, and TIGIT deletion to enhance cytotoxicity. In addition, we discuss functional enhancements such as IL-15 pathway activation, KIR modulation, and transcriptional reprogramming (e.g., FOXO1 knockout) to improve persistence and antitumor activity. We also highlight the role of induced pluripotent stem cell (iPSC)-derived NK platforms, enabling standardized, scalable, and multiplex gene-edited products. Finally, we explore artificial intelligence (AI) applications in immunogenomic profiling and predictive editing to tailor NK cell therapies to patient-specific HLA/KIR/SIRPα contexts. By integrating immune evasion, functional reinforcement, and computational design, we propose a unified roadmap for next-generation CAR-NK development, supporting durable and broadly applicable cell-based therapies. Full article

Chimeric antigen receptor (CAR)-engineered immune cells, particularly CAR T lymphocytes and CAR natural killer (NK) cells, have revolutionized cancer immunotherapy. However, their therapeutic efficacy and safety can be influenced by the tumor microenvironment, particularly the presence of mesenchymal stem cells (MSCs). MSCs are immunomodulatory cells which can alter the function of tumor-infiltrated immune cells in both supportive and suppressive ways. Results obtained in recently conducted experimental studies demonstrate that MSCs modulate proliferation, cytotoxicity, cytokine production and anti-tumor activity in CAR-expressing immune cells in both a juxtacrine and a paracrine manner. While MSCs can enhance CAR cell viability and persistence through trophic support, they may also impair cytotoxic function and promote an immunosuppressive phenotype under certain conditions. Understanding the dualistic nature of MSCs in CAR-based immunotherapy for malignant diseases is critical for optimizing clinical outcomes. Additionally, MSCs may serve as vehicles for targeted delivery of immunomodulatory agents, and should be considered as active components in the design of next-generation CAR-based immunotherapies. Accordingly, in this review article we emphasize molecular and cellular mechanisms involved in MSC-dependent modulation of CAR-expressing immune cells, paving the way for more efficient CAR-based immunotherapy for malignant diseases. Full article

Chimeric antigen receptor (CAR)-engineered cell therapy represents a landmark advancement in cancer immunotherapy. While αβ CAR-T therapy has demonstrated remarkable success in hematological malignancies, its efficacy in solid tumors remains constrained mainly by factors such as antigen heterogeneity, immunosuppressive microenvironments, and on-target/off-tumor toxicity. To overcome these limitations, emerging CAR platforms that utilize alternative immune effectors, including natural killer (NK) cells, macrophages, and γδ T lymphocytes, are rapidly gaining traction. This review systematically analyzes the mechanistic advantages of CAR-NK, CAR-M, and CAR-γδ T cell therapies, while critically evaluating persistent challenges in clinical translation, including limited cell persistence, manufacturing scalability, and dynamic immune evasion mechanisms. We further discuss innovative strategies to enhance therapeutic efficacy through some viable strategies. By bridging fundamental immunology with translational engineering, this work provides a roadmap for developing CAR therapies capable of addressing the complexities of solid tumor eradication. Full article

The NK-92 cell line has become a very relevant tool for natural killer (NK) cell research, largely because it largely mirrors the characteristics of human blood-derived NK cells. It also has a doubling time of less than 30 h, making it possible to generate a significant number of cells in a relatively short time. Its safety as an anti-cancer cell therapy has been documented in over 200 cancer patients. Various genetically engineered variants have been generated that express a high-affinity Fc-receptor and various chimeric antigen receptors (CARs) and secrete immune-active cytokines. NK-92 cells expressing CARs for HER-2, PD-L1, and CD19 CAR are in advanced clinical trials in cancer patients. These cells also have cytotoxic activity against targets infected with bacteria, fungi, and viruses. More recently, the cellular lysate of NK-92 cells, generated by simple freeze/thaw, has shown anti-cancer potential when injected intra-tumor. Since a comprehensive review of NK-92 was recently published on the occasion of its 30-year “anniversary”, this review will focus on more recent research initiatives and results with the cell line. Full article

Background: The remarkable efficacy of B-cell maturation antigen (BCMA)-directed chimeric antigen receptor T-cell therapy (CAR-T) has had a significant impact on treatment strategies for relapsed/refractory multiple myeloma (RRMM). However, response durability remains a concern, necessitating the optimization of CAR-T procedures. Therapies preceding CAR-T therapy are crucial for disease control and preserving T-cell fitness. Methods: This review summarizes the evidence supporting the potential of selinexor-based regimens as holding or bridging therapy with preclinical research, demonstrating selinexor’s ability to foster an anti-inflammatory tumor microenvironment. Results: Selinexor enhances CD8+ T-lymphocyte and NK cell activation, re-polarizes macrophages, and inhibits immunosuppressive cells. Bone marrow samples from patients in clinical studies show that selinexor increases CD8 and granzyme B expression in T-cells. Selinexor also disrupts NK cell inhibition, enhances anti-tumor activity, and reduces pro-inflammatory cytokines. Selinexor may upregulate BCMA expression and increase myeloma cell immunogenicity. Real-world data suggests selinexor as bridging therapy does not compromise CAR-T outcomes and may even improve them. Conclusions: Overall, the evidence indicates selinexor’s potential to optimize CAR-T outcomes, warranting further investigation as a holding or bridging therapy for CAR-T. Full article

Neuroblastoma (NB) is the most prevalent extracranial childhood tumor and the third leading cause of death from cancer in children. Despite having a high overall survival rate for low- and intermediate-risk patients, survival rates for high-risk cases remain unsatisfactory. The current standard treatment for high-risk NB involves surgery, chemotherapy, radiotherapy, autologous stem cell transplantation, immunotherapy with anti-ganglioside GD2, and differentiation therapy with isotretinoin. Besides not being enough to achieve a high survival rate in high-risk patients, these treatments are associated with significant side effects. With next-generation sequencing technologies, a better understanding of the genetic and epigenetic landscapes of NB has been achieved. This has led to the study of novel treatments to improve the overall survival rate of high-risk NB and reduce the toxicity of conventional treatments. Current research is focusing on the development of targeted drugs for genetic and epigenetic alterations, and protein degraders. Moreover, immunotherapy to enhance anticancer immune responses and by using cell-engineering techniques with chimeric antigen receptor (CAR) T and NK cells are being explored to target NB cells. Here, we review promising novel treatment strategies for NB, which target genetics, epigenetics, the tumor microenvironment, and the immune landscape, highlighting preclinical studies and ongoing clinical trials. Full article