Enhancing cancer immunotherapy with photodynamic therapy and nanoparticle: making tumor microenvironment hotter to make immunotherapeutic work better

Deciphering the complex interactions among components within the TME is crucial for enhancing the efficacy of cancer immunotherapy by combining PDT. The TME is a heterogeneous mix of cancer cells, immune cells, stromal cells, and components of the extracellular matrix, including specialized cells such as cancer associated fibroblasts (CAFs), mesenchymal stem/stromal cells (MSCs), cancer associated adipocytes (CAAs), tumor endothelial cells (TECs), and pericytes (PCs) (54, 55). These cells significantly influence tumor progression and immune evasion, fostering a tumor-supportive environment for the tumor through dynamic interactions (56). PDT, which leverages light-activated PS to generate cytotoxic ROS, targets these supportive stromal cells also resulting in the disruption of tumor-promoting environment within the tumor tissue. This approach not only reduces the tumor burden, but also shifts the TME toward a state less favorable for tumor progression. Recent advancements focus on targeting tumor stromal cells to improve the accuracy and effectiveness of cancer treatment. These strategies aim to (i) thwart stromal cell entry into the TME, (ii) deplete pro-tumorigenic stromal cells, (iii) inhibit stromal cell secretion of growth factors and exosomes, (iv) modify the extracellular matrix composition to inhibit tumor growth (57). Single-cell RNA sequencing (scRNA-seq) offers valuable insights into TME complexity, enabling the identification of distinct stromal cell subtypes. This approach paves the way for developing personalized therapeutic strategies targeting specific subtypes, ultimately enhancing the precision of cancer treatment (56). Despite the potential of these targeted strategies, clinical validations remain in preliminary phases, highlighting the need for further research. A notable advancement in PDT is the development of a nanodrug named MSNs@RA/GA co-loaded with retinoic acid and gallinic acid within mesoporous silica nanoparticles. This formulation specifically targets CAFs, aiming to reverse their pro-tumorigenic state and enhance PDT efficacy. Additionally, the nanodrug modifies the TME, favoring the infiltration of immunostimulatory cells over immunosuppressive ones, showcasing promise in sensitizing tumors to PDT (58). Moreover, recent discoveries emphasize the role of CAF-derived TGFβ1 in inducing resistance to PDT in specific cancers, like cutaneous squamous cell carcinoma. This resistance could be overcome by employing TGFβ1 receptor inhibitors, suggesting the potential of CAF-derived TGFβ1 as a biomarker for PDT responsiveness and for tailoring treatments to individual tumors (59). Integrating PDT with immunotherapy, leveraging its immunostimulatory effects, holds promise for significantly boosting anti-cancer immunity. Studies reveal that low-dose PDT can augment the secretion of pro-angiogenic factors and enhance the immunogenicity of MSCs, underscoring the multifaceted role of PDT in cancer treatment and its potential to redefine therapeutic strategies within the TME (59). As shown in Figure 2, the disruption of immunosuppressive stromal cells with PDT will further enhance the therapeutic efficacy of PDT in combination with immunotherapy.

PDT can directly damage TME vascular endothelial cells and subsequently interfere with the blood supply to cancer cells. This may enhance the infiltration of immune cells into the TME and promote anti-tumor immune responses. However, tumor hypoxia can also induce the expression of immunosuppressive factors such as vascular endothelial growth factor (VEGF) and programmed death ligand 1 (PD-L1), which can limit the effectiveness of the immune response (60, 61). Strategies to overcome these immunosuppressive factors, such as combining PDT with VEGF inhibitors or hypoxia-activated prodrugs, are being explored to improve treatment outcomes. The PS-activated ROS irreversibly destroys tumor cells and nearby endothelial cells. The damage to tumor micro vessels and capillaries leads to acute inflammation (62). During the early stages of PDT, various mechanisms potentiate the detrimental effects of ROS-mediated endothelial damage on the blood supply to the tumor. These include platelet aggregation, edema formation, thrombus formation, thromboxane release, and complement cascade activation. These events lead to further damage to the endothelial cells, followed by vasoconstriction and increased permeability of the blood vessel walls (63). The membrane attack complex generated by complement cascade activation contributes to impaired blood supply in PDT-treated tumors (64). Furthermore, PDT-induced oxidative stress promotes the activation of the complement system and the infiltration of inflammatory cells, which involves the Hsp70-TLR2/TLR4-NFκB axis (65). The vascular endothelial injury caused by PDT results in hypoxia, which leads to elevated levels of hypoxia-inducible factor 1α (HIF-1 α). HIF-1α activation can promote immune escape and immunosuppression by activating TAMs, myelosuppressive cells (MDSCs), lymphocytes, and dendritic cells (DCs) (66). Hypoxic characteristics of solid tumor TME limit PDT therapeutic effects. Moreover, the oxygen consumption in TME following PDT would overload the tumor hypoxia, which will promote tumor growth, metastasis, and invasion, resulting in a poor prognosis of treatment (67). In this context, many efforts have been made to increase the oxygen content in TME to enhance PDT efficacy (68). The rationale is that while PDT-induced insults to the tumor vasculature would have contradictory effects on the therapeutic outcomes: compromised blood supply to TME should accelerate tumor cell death. At the same time, HIF-1α-mediated hypoxic response would result in tumor-promoting consequences.

PDT significantly impacts the immune system, changing immune cell populations and functions. It destroys tumors and prompts an acute inflammatory response by generating ROS, which mobilizes dendritic cells (DCs) and macrophages. These cells trigger subsequent innate and adaptive immune responses, including memory formation (69). A notable immediate effect of PDT is the surge in neutrophils, attributed to Tumor necrosis factor α (TNFα) induced by ROS, marking the beginning of the immune system’s assault on the tumor (70). Macrophages, essential for the immune-mediated effects of PDT, proliferate and become selectively activated in a dose-dependent manner with low-dose PDT. They release compounds that enhance their tumor-fighting capabilities, including lysophosphatidylcholine which is a precursor of the macrophage-activating factor (70). Additionally, PDT bolsters macrophage phagocytic activity, aiding the clearance of necrotic cells. The amplified immune response involves CD4⁺ and CD8⁺ T cells, which deliver cytotoxic actions against the tumor, signifying PDT’s role in inducing tumor specific adaptive immunity (71). The ROS produced during PDT not only target cancer cells but also stimulate a comprehensive immune response, enhancing both phagocytic activities and B cell-mediated antibody production (72). PDT’s effectiveness and the nature of elicited immune response are influenced by several factors, including the type of cell death induced (immunogenic or non-immunogenic), the light doses used, and the overall therapeutic protocol. Unlike traditional cancer treatments that mainly induce apoptosis, PDT’s ability to trigger necrosis and ICD leads to a controlled inflammation and a specific immune response (73–76). This response is facilitated by the secretion of cytokines and immune mediators during PDT, further involving acute phase proteins and the complement system (64, 77–79). PDT significantly reshapes the TME to activate broad innate immune defenses, such as igniting phagocytic cells and stimulating the release of chemokines and cytokines, thereby inducing a strong inflammatory response (80). Beyond these general defenses, PDT specifically triggers adaptive immune responses through potentiated antigen presentation and selective expansion of lymphocytes, equipping them for the enduring recognition of tumor-specific antigens (73, 74, 81). This capability underscores the dual impact of PDT: not only does it combat primary tumors through ICD, but it also contributes to a sustained anti-tumor effect through induction of memory immune responses (82, 83). This effect is influenced by several factors, including the tumor’s inherent immunogenic properties, the specifics of the PDT protocol, and the patient’s preexisting immune status (84). PDT-modulated cytokines play a pivotal role here, with pro-inflammatory cytokines enhancing immune cell proliferation and anti-inflammatory ones dampening responses (85–88). PDT’s influence extends to cytokine modulation, as demonstrated by recent studies showing changes in VEGF, CXCL9, HIF-1α, and PD-L1 levels post-therapy (89–91). These alterations in cytokine levels not only signal a dynamic local inflammatory response but also influence the balance between pro-inflammatory, which promote immune cell proliferation, and anti-inflammatory activities, which might temper immune reactions. Understanding the fluctuations in these cytokine levels before, during, and after PDT can offer critical insights, guiding the optimization of treatment protocols.

The first efforts used lysates/supernatants from Photofrin-PDT treated cells (PDT-based lysates vaccine), which was tested as a prophylactic vaccine in a mouse mammary tumor model. The vaccine showed significant tumor growth suppression. Such an anti-tumor effect was tumor-specific and correlated with DC maturation and IL-12 production. Importantly, in the same experimental system, no protection was observed for vaccines prepared by ionizing radiation, UV light, hyperthermia, or freeze/thaw cell lysis (37). This result strongly suggests that ICD was induced only by PDT and immunogenic tumor antigens were liberated from PDT-affected cancer cells. Later, similar results were reported with other PSs such as benzo-porphyrin derivative, chlorin, hypocretins, hematoporphyrin, and redaporfin, with strong immunologic evidence showing the involvement of lymphocytes and dendritic cells (34, 93–95). Based on the successful prophylactic vaccine results, therapeutic vaccine strategies were tried using pre-established tumor models with substantial success (96). These studies revealed that PDT-based lysate or whole-cell vaccines are tumor-specific, which means that protection is limited to rechallenges with the same cell types (96). PDT-generated whole-cell vaccines elicited an accumulation of DCs and their functional maturation (37). Maturation of DCs and interferon-producing T cells are also often reported, as well as the loss of effect when immunodeficient mice were used (96). Immature DCs co-incubated with vaccine cells undergo phenotypic maturation and become IL-12 producers (96). As PDT-generated lysate whole-cell tumor vaccines require the crucial role of DCs to induce antigen-specific cytotoxic T-cell responses, many PDT/immunology research groups later adopted the DC vaccine strategy. Optimally activated DCs induce enhanced immunological memory, contributing to the effective suppression of recurrence and metastasis. Dying/dead cancer cells by PDT should provide excellent tumor antigens and DAMPs generated by ICD. For example, EMT6 mammary cancer cells killed with PDT were pulsed to immature DCs. The matured tumor antigen-pulsed DC vaccine exerted a significant tumor suppression correlated with the generation of antigen-specific IFNγ-producing lymphocytes in the spleen. In contrast, notable tumor suppression was not observed in animals vaccinated with DCs pulsed with freeze/thaw-killed tumor cells or PDT-treated tumor lysates (97).

ALA (aminolaevulinic acid)-PDT was also used to induce ICD in the skin squamous carcinoma PECA cell line, which was pulsed to immature DC cells. ALA-PDT-based DC vaccines provided protection to mice against the rechallenge with live cancer cells, while such protection was not observed with freeze/thaw-based DC vaccines (98). DCs pulsed with apoptotic hypericin-PDT-treated Lewis lung carcinoma (LLC) cells also activated DCs, being able to stimulate CD8⁺ T cells to produce IFNγ. PDT-treated cancer cell pulsed DC vaccine showed superior tumor suppression to PDT-treated whole-cell vaccine, which was correlated with increased IFNγ-producing CD8⁺ T cells and decreased Tregs (99). In a peritoneal mesothelioma model, photosensitizer, an OR141-PDT-based DC vaccine, was administered intraperitoneally. The PDT-based DC vaccine-treated group showed significantly extended survival compared to the group treated with anti-CTLA4 antibody. Enhanced CD8⁺ and CD4⁺ T cell response was noted both locally and systemically, with strong IFNγ⁺ T cell infiltration in mesothelioma tumors. The DCs pulsed with PDT-killed mesothelioma cells also manifested significantly increased expression of CCR7, suggesting more efficient homing to T cell areas of draining lymph nodes (100).

High-grade malignant glioma and glioblastoma (GBM) are aggressive types of primary brain tumors that are almost universally fatal despite some progress in treatment and management. Malignant brain tumors generally form cold (immunosuppressive) TME, which should account for the unsuccessful ICB treatment outcomes (101). Unfortunately, all immunotherapies tested to date have failed to improve clinical outcomes in unselected cohorts of patients with GBM (102). In a recent meta-analysis, the active immunotherapy of GBM reduced the risk of 2-year mortality by as much as 2.5% compared to the control group (103). Cancer cells undergoing ICD by appropriate PDT should potentially activate autologous DCs by providing highly immunogenic tumor antigens and strong DAMP signals. A preclinical study proved this possibility well (104). The study used a hypericin-PDT-treated mouse glioma cell line (GL261), being partially immunotherapy-susceptible, and demonstrated that these dying cells could efficiently induce the maturation of DC. Vaccination experiments revealed that the hypericin-PDT-based DC vaccine induced a strong anti-tumor immune response, efficaciously protecting mice from intra-brain challenge with homologous live cancer cells. The ability of DC vaccines to elicit tumor rejection was significantly blunted if cancer cell–associated reactive oxygen species and emanating danger signals (CRT, ATP, HMGB1) were blocked singly or concomitantly. In a curative setting, hypericin-PDT-based DC vaccines synergized with standard-of-care chemotherapy (temozolomide) to increase the survival of high-grade glioma-bearing mice by ~300%, resulting in ~50% long-term survivors. The DC vaccine induced an immunostimulatory shift in the brain TME from regulatory T cells to Th1/cytotoxic T lymphocyte/Th17 cells (53).

Enhancing the efficacy of PDT through nanoparticle platforms is a promising strategy in cancer therapy. The limited functionality of tumor-infiltrating DCs in presenting tumor-specific antigens is a critical barrier to generating effective antitumor immune responses (148). To address this, the integration of nanoparticle technology in cancer immunotherapeutic regimens has been attempted to bolster antitumor immunity by facilitating the presentation of antigens, which should be the rate-limiting step in initiating anti-tumor immune responses (149). Innovations such as the use of CpG oligodeoxynucleotides, which act as adjuvants by targeting TLR9, have shown promise in clinical studies for enhancing immunity against solid tumors (150, 151). For example, Im et al. developed a mesoporous silica nanocarrier that responds to hypoxia (termed CAGE), which was encapsulated with both Ce6 and CpG adjuvant (150). Once the CAGE accumulates in hypoxic tumor region, azo linkers were cleaved to rapidly release CpG and ROS-induced DAMPs were released from melanoma by local Near infrared (NIR) irradiation. Simultaneously, CpG released earlier recruited DCs and promoted the maturation of DCs leading large number of CTL infiltration (150). Yang et al. on the other hand, developed a polymersome encapsulating HPPH(2-(1-hexyloxyethyl)-2-devinyl pyropheophorbide-a, a chlorin based PS) and doxorubicin (152). The polymersome (CCPS) acts as an adjuvant by its own due to the presence of primary and tertiary amines on the surface (152). The vaccine composed of CCPS/HPPH/Dox polymerosome and subjected to NIR irradiation led to an increase in the presence of mature DCs in lymph nodes and killer T cells at the tumor tissue (152). This was further enhanced by integrating ICD with an adjuvant, which, when combined with PDT, significantly inhibited the growth of both primary and metastatic tumors in experiments conducted on a colon adenocarcinoma cell line (MC38) tumor-bearing C57BL/6 mice (152). In a related study, Cheng and colleagues engineered a unique chimeric peptide, PpIX-PEG8-KVPRNQDWL, which self-assembles into nanoparticles (PPMA) aimed at melanoma targets. This peptide, designed to recognize a specific melanoma antigen (KVPRNQDWL), has been shown to facilitate the entry of cytotoxic T cells into the TME, thereby boosting the efficacy of PDT against malignant melanoma (153). In an effort to enhance the presentation of antigens, Xu and their team created a biodegradable mesoporous silica nanoparticle system that carries both CpG and Ce6. This comprehensive nano system, when evaluated against solo applications of PDT, vaccine, or adjuvant, attracted a higher number of tumor-infiltrating cytotoxic T cells and showed superior anti-tumor performance on both primary and abscopal site MC-38 tumors (154). Hence, this approach of using multiple stimuli has shown to be a highly promising strategy for inducing a strong anti-tumor immune response (154). Recent studies showed that DSPE-PEG-maleimide could form thioether bonds with proteins, this feature of the material can be used to capture tumor-derived antigens from the TME (155). Based on this report, antigen-capturing platforms have been developed for photoimmunotherapy, designed to improve antigen uptake and presentation efficiency (156). These platforms utilize nanoparticles to capture tumor-derived protein antigens during PDT, enhancing the ICD effect and inducing stronger immune responses. This strategy represents a novel approach to increase the specificity and efficiency of anti-tumor immune responses through targeted delivery and presentation of tumor antigens. Liu et al., designed up-conversion nanoparticles (UCNPs) modified with DSPE-PEG-mal., co-loaded with ICG and rose Bengal (RB) as PS. This NIR-triggered antigen-capturing nanoplatform generated significant ¹O₂. These nanoparticles also captured tumor-derived protein antigens from dying cells, which could increase the efficiency of antigen presentation to induce a stronger immune response (157).

Binbin Ding (158) created an innovative type of nanoparticle named UCMS, which is a large-pore mesoporous silica-coated up-conversion nanoparticle, notable for its sub-100 nm dimensions and its ability to load significant quantities of biomolecules thanks to its extensive mesoporous framework. This UCMS, when loaded with the PS merocyanine 540 (MC540) and the model protein chicken ovalbumin (OVA), demonstrated enhanced immunostimulatory effects under NIR laser irradiation. Furthermore, when tumor cell fragments were loaded, the combination of UCMS-MC540-TF significantly inhibited tumor progression and improved survival in mice bearing CT26 tumors. In a related development, Huaji Wang encapsulated OVA within nanoparticles using a disulfide bond network among OVA molecules (159). These nanoparticles were then coated with a membrane from B16-OVA cells and incorporated both OVA and the PS Ce6, resulting in the creation of a membrane-cloaked OVA nanoparticle (MON). This MON was shown to trigger the activation of bone marrow-derived dendritic cells (BMDCs) and promote antigen cross-presentation, effectively triggering an immune response in vivo. Utilizing the B16-OVA tumor model, MON-facilitated PDT succeeded in completely eliminating primary tumors and establishing a durable antitumor immune memory. Neoantigens, which are unique to each tumor, have emerged as powerful triggers of the immune system’s response against tumors. The evolution of high-throughput omics technologies and neoantigen prediction methods have ushered in neoantigen-based therapies as a significant area of research.

The advancement of PDT into clinical application will confront several challenges that necessitate further development and optimization of PSs. Currently, innovative approaches are enhancing the safety and efficacy of PDT in treating malignancies, with research focused on three main strategies (169). Firstly, there is an effort to create PSs that can effectively produce ROS even in the low-oxygen environments of tumors, thereby overcoming the limitations posed by TME hypoxia. Secondly, the development of PSs that are selectively activated in TME and the use of tumor-targeted nanocarriers aim to improve the precision of PDT. Lastly, enhancing the penetration depth of the excitation light is critical for the effectiveness of PDT (170). Each therapeutic modality, including combination with chemotherapy or immunotherapy, presents its own set of advantages and challenges. For instance, optimizing the chemotherapy-phototherapy ratio is crucial in combination treatments to maximize efficacy (171). Furthermore, PDT is being explored as an intraoperative adjuvant treatment, offering visual aids to surgeons through PS-stimulated fluorescence and allowing for precise removal and ICD induction (172). However, the standardization of PDT protocols, including the selection of the ideal PS, photo dose, and drug-optical intervals, remains a prerequisite for its widespread application. Additionally, there is a need for specialized irradiation equipment designed for different surgical approaches, such as endoscopic resection or open surgery, to facilitate the integration of PDT into clinical practice (170).

The key obstacles encountered in PDT are: (i) inadequate distribution of photosensitizers (PS) after intravenous administration; (ii) diminished light efficacy in reaching the tumor due to tissue absorption; (iii) depletion of oxygen within the tumor environment, restricting the effectiveness of PDT; (iv) temporary or incomplete damage to tumor blood vessels post-PDT, often followed by the formation or repair of new vessels; and (v) incomplete eradication of the tumor, potentially leading to its recurrence (173). Optimizing nanoparticle (NP) design in PDT is crucial. This includes surface modifications for improved targeting and controlled drug release, as well as developing multifunctional NPs that enable therapeutic and imaging capabilities (174). Accurate dosimetry, considering the tissue penetration and the prevention of normal tissue damage, is essential for delivering precise treatment (172). Addressing potential safety concerns associated with NP-based cancer therapy is another critical aspect. This involves thorough biocompatibility testing, optimization of NP characteristics for safe interaction with biological systems, and controlled drug release to minimize off-target effects and long-term accumulation (175). Designing NPs to specifically target receptors can also reduce the risk of unintended off-target interactions (176). Collaborative efforts in research and development are necessary to advance this promising therapeutic modality (177). Incorporating various drugs into nanoparticle-enabled PDT introduces complexities related to potential toxicity and unexpected side effects. For wider clinical application, thorough preclinical and clinical evaluations should be carried out to maximize efficacy and safety (178).