Cell-Based Therapies for Solid Tumors: Challenges and Advances

The standard approach to TIL-based therapy begins with surgical resection of the tumor. TILs are isolated and cultured ex vivo in the presence of high concentrations of interleukin-2 (IL-2) to promote their activation and proliferation. After sufficient expansion, these TILs are infused back into the patient, typically following a lymphodepleting regimen to eliminate endogenous immune cells to enhance TIL engraftment, persistence, and functionality [33].

TILs primarily comprise T lymphocytes, especially CD8⁺ cytotoxic T lymphocytes (CTLs) and CD4⁺ helper T cells, although other immune subsets, including B cells and natural killer (NK) cells, may also be present [34,35]. CTLs play a central role in recognizing and destroying malignant cells through interactions with tumor-specific antigens presented by major histocompatibility complex (MHC) molecules. TILs are particularly valuable due to their intrinsic specificity for tumor-associated antigens, including neoantigens derived from tumor-specific mutations, enabling precise and potent immune targeting of cancer cells [36,37].

The TME, comprising malignant cells, stromal elements, immune infiltrates, and extracellular matrix components, presents numerous challenges to effective TIL function. The immunosuppressive nature of the TME is mediated by elements like regulatory T cells (Tregs), myeloid-derived suppressor cells (MDSCs), and immunomodulatory cytokines, like transforming growth factor-beta (TGF-β) and interleukin-10 (IL-10). It can significantly impair the effector functions of TILs [38,39,40]. Despite these barriers, the presence of TILs within tumors has been positively correlated with improved clinical outcomes in various malignancies, including melanoma, colorectal cancer, and ovarian cancer [41,42,43].

Clinical trials, particularly in metastatic melanoma, have demonstrated that TIL therapy can induce durable clinical responses, with some patients achieving complete remission [44,45]. TILs can overcome the TME’s immunosuppressive barriers by reintroducing a large pool of tumor-reactive T cells with restored effector function and enhanced cytotoxicity. Upon reinfusion, TILs possess the capacity to penetrate immunologically “cold” tumors, resist local T cell dysfunction, and exert targeted cytolytic activity even in the presence of immunosuppressive mediators. Furthermore, the polyclonality of TIL populations allows for recognition of multiple tumor-associated neoantigens, reducing the likelihood of immune escape and broadening anti-tumor coverage. Clinical studies have shown that TIL therapy can effectively remodel the TME, shifting it toward a pro-inflammatory and immune-permissive state, thereby facilitating durable responses in checkpoint-refractory solid tumors [46,47,48]. An example of these abilities to overcome barriers is the FDA-approved product Lifileucel (Amtagvi^TM) for PD-1-refractory metastatic melanoma, which restores anti-tumor immunity through ex vivo-expanded autologous lymphocytes capable of mediating durable responses despite prior checkpoint inhibitor failure [49].

These promising outcomes have stimulated efforts to adapt TIL therapy to other solid tumor types. However, several challenges persist, including patient selection criteria, variability in TIL expansion success, and potential treatment-related toxicities [50,51].

Despite their clinical promise, TILs face several limitations that constrain their broad applicability. First, TIL therapy requires extensive ex vivo expansion from surgically resected tumor tissue, a process that is both labor-intensive and not always feasible for patients with inaccessible or low-yield tumors [51]. Additionally, the composition and functionality of TILs can vary widely among patients, often influenced by the immunosuppressive TME, which may render them exhausted or antigen-non-specific [52,53]. Moreover, TILs are largely HLA-restricted, limiting their effectiveness across genetically diverse patient populations, and their persistence after infusion is often limited without adjunctive IL-2 support, which can itself cause severe toxicities [54].

To address these limitations, researchers are investigating next-generation strategies, such as genetic modification of TILs to enhance persistence and cytotoxicity, integration of an immune checkpoint blockade to mitigate TME-induced inhibition, and combinatorial regimens incorporating TILs with targeted therapies, vaccines, or cytokine support. These innovations aim to improve the efficacy and broaden the applicability of TIL-based immunotherapies [55,56].

TIL therapy represents a compelling and evolving approach to treating solid tumors. With their natural ability to recognize and eliminate cancer cells and ongoing technological and therapeutic advancements, TILs offer significant promise, particularly for patients with treatment-refractory malignancies.

TCR T cells are generated by isolating peripheral blood T lymphocytes from a patient or donor and genetically modifying them to express a tumor-specific TCR with high affinity for antigens presented by MHC molecules on tumor cells. The TCR transgene is typically introduced using viral vectors, such as lentivirus or retrovirus. After transduction, the modified T cells are expanded ex vivo and infused back into the patient following a lymphodepleting conditioning regimen to enhance their persistence and function [62]. The engineering of T cells to express TCRs has enabled precise targeting and elimination of malignant cells [63].

This approach has led to durable clinical responses in hematological malignancies and is increasingly being adapted for the treatment of solid tumors [63]. TCR T cells have shown promise in clinical trials, particularly in solid tumors where CAR T cell therapy has had limited success. Trials using NY-ESO-1-specific TCR T cells in synovial sarcoma and melanoma have demonstrated durable responses in some patients [64,65]. However, their effectiveness is influenced by factors like HLA restriction, tumor antigen heterogeneity, and immune evasion via MHC downregulation.

Despite these advances, the therapeutic efficacy of TRCs, like other CTLs, in solid tumors remains constrained by multiple immunologic and tumor-intrinsic barriers, including antigenic heterogeneity, defective antigen presentation machinery, and the immunosuppressive TME, which collectively impair TCR T cells’ infiltration, survival, and function [66]. To circumvent these obstacles, recent strategies have focused on the genetic engineering of TRCs to augment their persistence and resistance to immunosuppressive signals, such as through dominant-negative TGF-β receptor expression or the incorporation of costimulatory signaling domains to enhance effector function and proliferation. CAR T cells are an example of another approach for T cell application in cancer treatment [67,68,69].

CARs typically consist of three key components: an extracellular antigen-binding domain, a transmembrane domain, and an intracellular signaling domain [72,73]. The extracellular domain, responsible for antigen recognition, imparts specificity to CAR T cells, typically derived from single-chain variable fragments (scFvs) of antibodies that target TAAs or tumor-specific antigens (TSAs), such as HER2, mesothelin, EGFRvIII, GD2, and Claudin 18.2. The transmembrane domain anchors the CAR to the T cell membrane, ensuring its proper stability and signaling functionality [74]. The intracellular signaling domain transmits activation signals following antigen recognition and typically includes the CD3ζ domain, which can be combined with domains like CD28, 4-1BB (CD137), or OX40 (CD134) [75,76]. Including these co-stimulatory domains improves CAR T cell persistence, proliferation, and anti-tumor efficacy.

CAR T cells have evolved through several generations, with first-generation CARs incorporating only the CD3ζ domain, which has shown reduced in vivo efficacy [77]. Second-generation CARs incorporate a single co-stimulatory domain [78], while third-generation CARs contain two or more co-stimulatory domains [79]. Fourth-generation CARs, also known as TRUCKs (T cells Redirected for Universal Cytokine-mediated Killing), are designed to release cytokines upon antigen recognition, thus enhancing their tumor-killing potential [80,81].

CAR T cell therapy has shown remarkable efficacy in treating hematologic malignancies, such as leukemia and lymphoma, where cancer cells circulate in the blood or the lymphatic system [80]. However, the treatment landscape becomes more complex when addressing solid tumors. Unlike hematologic cancers, solid tumors present unique challenges hindering CAR T cell therapy. These include immune evasion mechanisms, which allow tumors to avoid detection by the immune system, and a hostile TME that can inhibit CAR T cell function [14,68]. The TME includes dense extracellular matrices (ECM), non-cancerous stromal cells, and immune suppressive factors that obstruct CAR T cell infiltration and survival. Additionally, the abnormal vasculature often found in solid tumors limits the effective delivery of CAR T cells [14].

Although CAR T cell therapy has shown remarkable success in hematologic malignancies, several early-phase clinical trials have also demonstrated encouraging efficacy in solid tumors. For example, GD2-targeted CAR T cells have led to objective responses in patients with neuroblastoma and diffuse midline gliomas, including a case of radiographic remission in a child with pontine glioma [82]. Claudin 18.2 CAR T cells have shown promise in gastric and pancreatic cancers, with high response rates reported in a phase I study [83]. Furthermore, mesothelin-directed CAR T cells have induced disease stabilization in mesothelioma and pancreatic cancer when combined with regional or intrapleural delivery approaches [84]. These studies illustrate the feasibility and potential of CAR T therapy in solid tumors when combined with tumor-specific targeting, optimized delivery, and resistance mitigation strategies.

One of the most significant hurdles in CAR T cell therapy for solid tumors is the identification of suitable target antigens that are both highly expressed on tumor cells and absent or minimally present in normal tissues [85,86,87]. Prominent TAAs under investigation include HER2, mesothelin, EGFRvIII, GD2, and Claudin 18.2, each associated with specific tumor types, such as breast, ovarian, glioblastoma, neuroblastoma, and gastric cancers, respectively [84,88,89,90,91]. Many tumor-associated proteins are also found in healthy tissues, raising the risk of off-target effects, including those tragically observed in early trials of HER2-CAR T cell related fatality due to cytokine-storm-like syndrome, accompanied by rapid respiratory failure and multi-organ dysfunction. Post-mortem analyses suggested that the CAR T cells had reacted not only with tumor cells but also with low-level HER2 expression in the pulmonary epithelium, leading to massive immune activation and widespread tissue damage [85]. Furthermore, solid tumors exhibit antigen heterogeneity, with varying levels or types of antigens across different tumor cells, making it challenging for CAR T cells to target and eliminate all malignant cells [92].

To address these challenges, various strategies have been explored. These include engineering CAR T cells to recognize and target multiple antigens [93], incorporating enzymes into CAR T cells that can degrade the ECM and facilitate better tumor infiltration [94], and identifying novel, highly specific antigens unique to cancer cells to improve targeting precision and reduce damage to healthy tissues [95]. Developing personalized CAR T cell therapies based on the unique antigen profile of a patient’s tumor is another promising strategy for overcoming antigen heterogeneity.

An emerging strategy to enhance the efficacy of CAR T cells in solid tumors involves co-targeting not only malignant cells but also the tumor stroma, particularly cancer-associated fibroblasts (CAFs), which play a central role in immune exclusion and therapeutic resistance. Huang et al. (2025) reported the development of a universal CAR T cell platform capable of redirecting cytotoxic activity against both tumor cells and CAFs through the use of bispecific adapter molecules [96]. Their design enabled the simultaneous engagement of tumor-associated antigens and fibroblast activation protein, a surface marker enriched on CAFs, resulting in synergistic tumor killing and stromal disruption in preclinical models of solid cancer. Importantly, the universal targeting system allowed for dynamic modulation of specificity and intensity via adapter dosing, offering a tunable approach to reduce off-tumor effects. This approach aligns with broader developments in modular CAR architectures, such as those described in the WO2024191887A2 patent, which detail adapter-mediated systems engineered to engage multiple components of the TME concurrently, thereby addressing spatial heterogeneity and immune evasion mechanisms inherent to solid tumors.

Notably, bispecific constructs targeting disialoganglioside (GD2) and prostate-specific membrane antigen (PSMA) have gained attention for their application in neuroectodermal and prostate malignancies, respectively. Preclinical models and early-phase clinical trials have shown that co-targeting GD2 and PSMA enhances T cell infiltration and cytotoxicity while potentially limiting immune escape mechanisms associated with monovalent CAR therapies. Ongoing trials, such as NCT05437315↗, continue to evaluate the safety, persistence, and anti-tumor activity of GD2/PSMA bispecific CAR T cells in solid tumors. These findings highlight the clinical feasibility of dual-targeting approaches and support the broader development of bispecific CAR platforms to overcome tumor antigen heterogeneity.

Ongoing investigations into CAR T cell therapy for solid tumors are being conducted across various cancers, including glioblastoma (NCT05577091↗, NCT04077866↗, NCT05353530↗), renal (NCT05420519↗, NCT04969354↗), prostate (NCT03873805↗), ovarian (NCT06305299↗, NCT05211557↗), and lung cancers (NCT06903117↗). Although early clinical trials have not yielded the same level of success as seen in hematologic malignancies [97,98], advances in CAR engineering and a deeper understanding of the challenges posed by the TME will drive progress in this field.

CAR NK cells can be generated from various sources, including peripheral blood, umbilical cord blood, induced pluripotent stem cells (iPSCs), and established NK cell lines, such as NK-92. Each source offers distinct advantages regarding cytotoxic efficacy, expandability, and suitability for genetic modification [100]. For example, NK-92 cells are readily expandable and amenable to CAR transduction but require irradiation prior to infusion to prevent in vivo proliferation due to their malignant origin [101].

NK cells exert innate anti-tumor activity via a balance of activating and inhibitory receptor signaling, culminating in the direct lysis of transformed cells through perforin- and granzyme-mediated apoptosis. Additionally, NK cells mediate antibody-dependent cellular cytotoxicity (ADCC) through the expression of the FcγRIIIa receptor (CD16), further expanding their cytotoxic repertoire [102]. Incorporating CAR constructs into NK cells significantly enhances their tumor specificity and cytolytic potency, allowing antigen-directed killing via synthetic antibody-like scFv domains while preserving their endogenous effector mechanisms [31].

CAR-NK cells’ clinical feasibility and therapeutic potential were first demonstrated in a landmark phase I/II clinical trial involving patients with relapsed or refractory CD19-positive lymphoid malignancies. In that study, umbilical-cord-blood-derived CAR NK cells, co-expressing interleukin-15 (IL-15) and an inducible caspase-9 safety switch, yielded objective responses in 8 out of 11 patients (73%), with no incidence of CRS, neurotoxicity, or GvHD, highlighting the favorable safety profile of this therapeutic platform [31].

Still, the application of CAR NK cells in solid tumors has been met with challenges analogous to those encountered in CAR T cell therapy. These include antigenic heterogeneity, physical and stromal barriers to infiltration, and immunosuppressive elements within the TME. Nonetheless, preclinical models have demonstrated encouraging anti-tumor activity of CAR NK cells targeting HER2, mesothelin, and epidermal growth factor receptor (EGFR) in malignancies like glioblastoma, breast cancer, and ovarian cancer [103,104,105,106].

To enhance efficacy in the context of solid tumors, current efforts are focused on the development of “armored” CAR NK cells equipped with transgenes encoding pro-survival cytokines (e.g., IL-15), dominant-negative TGF-β receptors, and chemokine receptors to improve trafficking and persistence in the TME [107]. Moreover, generating “off-the-shelf” CAR-NK cell products from allogeneic sources, such as cord blood or iPSCs, presents a scalable and potentially more accessible therapeutic alternative to autologous CAR T cell therapy [108].

Recent advances have enabled the genetic modification of human macrophages to express CARs, thereby redirecting their phagocytic activity toward tumor cells [114]. Notably, using a chimeric adenoviral vector has facilitated efficient gene delivery by circumventing innate immune barriers typically encountered in macrophage transduction. This approach has successfully reprogrammed macrophages to adopt a sustained pro-inflammatory (M1-like) phenotype, enhancing their anti-tumor potential [114].

In vitro studies have demonstrated that CAR macrophages (CAR M) exhibit antigen-specific phagocytosis and cytotoxicity against tumor cells [26]. Moreover, CAR M therapy promotes a shift in the macrophage phenotype from immunosuppressive M2 to pro-inflammatory M1, elevates pro-inflammatory cytokine and chemokine production, enhances antigen presentation, and recruits T cells into the tumor microenvironment. These effects collectively contribute to remodeling of the tumor milieu and potentiate adaptive anti-tumor immunity. In in vivo studies using humanized mouse models, CAR Ms have been shown to induce robust anti-tumor responses and promote T-lymphocyte infiltration and activity, further supporting their therapeutic potential in solid tumors [115].

Currently, several biotechnology companies are advancing CAR M platforms with distinct technological strategies:

SIRPαnt Immunotherapeutics has developed SIRPant-M^TM (SI-101), an autologous, non-genetically engineered macrophage therapy utilizing the PhagoAct^TM platform. This method activates and educates patient-derived macrophages ex vivo to recognize and eliminate cancer cells through intrinsic immune mechanisms. SIRPant-M^TM engages both cellular and humoral immune responses and promotes long-term anti-tumor immunity. The therapy is presently in preclinical development in relapsed or refractory non-Hodgkin lymphoma (ClinicalTrials.gov ID NCT05967416↗). SIRPant Immunotherapeutics announced in late 2023 that it had received FDA clearance to begin a phase 1 clinical trial of SIRPant-M^TM for the treatment of various solid tumors, such as head and neck cancer, non-melanoma skin cancers, bladder and kidney cancers, low-grade prostate cancer, triple-negative breast cancer, and certain sarcomas. Under the newly cleared Investigational New Drug, the company plans to initiate clinical investigation of SIRPant-M as a monotherapy and in combination with other immuno-stimulatory modalities, such as radiotherapy and immune checkpoint inhibitors, for the treatment of select solid tumor indications.

Carisma Therapeutics is developing CT-0508, a genetically engineered CAR M product targeting HER2-positive solid tumors (ClinicalTrials.gov ID NCT04660929↗). Preclinical data suggest that CT-0508 can effectively infiltrate tumors, kill malignant cells, reprogram the tumor microenvironment, and facilitate the recruitment of adaptive immune cells. The study demonstrated a favorable safety profile with no dose-limiting toxicities. Approximately 44% of patients with HER2 3+ tumors achieved stable disease as the best overall response. However, the development of this platform has paused as the company shifts its focus to other technologies.

Cellis has introduced a novel platform called Macrophage Drug Conjugates (MDCs). This approach leverages macrophages loaded with ferritin-based drug complexes for targeted delivery into tumor cells [116]. Central to this platform is the TRAIN (Targeted Reprogramming of Antigen-presenting Immune Networks) mechanism, which enables precise cytoplasmic delivery of therapeutic payloads, inducing tumor cell death and immunogenic modulation of the microenvironment. MDCs have demonstrated enhanced survival, reduced tumor burden, and decreased metastases in preclinical models of solid tumors. The company is preparing to initiate first-in-human phase 1 clinical trials for its lead candidate, MDC-735, in the second quarter of 2025. These trials are planned to take place in Switzerland, Germany, and Poland, targeting multiple solid tumors, including glioblastoma, ovarian, bladder, lung, and head and neck cancers. The technology is on track to enter clinical trials in Q2 2025.

Collectively, these innovations underscore the potential of CAR macrophage therapies as next-generation cell-based immunotherapies, particularly in the context of solid tumors, where conventional CAR T strategies have faced limitations.