Recent Progress of Bioinspired Cell Membrane in Cancer Immunotherapy

Red blood cell membrane–modified nanocarrier

Red blood cells (RBCs) are the most abundant cells in the blood and are responsible for oxygen transportation. Red blood cell membranes (RMs) have been widely used as surface modifications for drug carriers and are among the most established surface modification strategies. ⁹ The most remarkable feature of RMs is long-term circulation ability which is ascribed to the existence of special surface markers, such as cluster of differentiation 58 (CD58), CD59, and CD47 and their inherent physiological characteristics, providing the characteristics of immune evasion, flexibility, and high biocompatibility.^10-12 As a result, nanocarriers modified with RMs manifest excellent development prospects.

To enhance immunosuppression in the tumor microenvironment (TME) and increase tumor-infiltrating lymphocytes (TILs), Yang et al ¹³ modified nitric oxide poly (acrylamide-co-acrylonitrile-co-vinylimidazole)-S-nitrosothiols (PAAV-SNO) polymer that contains a near-infrared II (NIR-II) photothermal agent (IR1061) and the indoleamine 2,3-dioxygenase 1 (IDO-1) inhibitor 1-methyl-tryptophan (1-MT) using RMs. Through the combination of biomimetic red cell technology, PTT, and immunotherapy, the recruitment of CD8⁺ cytotoxic T lymphocytes (CTLs) at tumor sites and the normalization of blood vessels were achieved, resulting in favorable curative outcomes for primary and metastatic breast cancer. In another work, Liang et al ¹⁴ developed a biomimetic formulation, black phosphorus quantum dot-RM nanovesicle (BPQD-RMNV) containing biomimetic BPQDs coated with RMs. The combination of BPQD-RMNV-mediated PTT with programmed cell death protein 1 (PD-1) antibody programmed cell death protein 1 (aPD-1) effectively inhibited the growth of basal-like breast tumors. In addition, RM-modified nanocarriers can also be used in combination with chemotherapy and immunotherapy for tumor treatment. For example, Song et al ¹⁵ investigated RM-based nano gel (hydroxypropyl-β-cyclodextrin acrylate and 2 opposite-charged chitosan derivatives) containing paclitaxel, which demonstrated a significant enhancement in antitumor activity. To address the problem of systemic and thermal toxicities, Ou et al ¹⁶ designed a nano-therapy system consisting of a poly-L-histidine (H)-grafted black phosphorus (BP) base core and an erythrocyte membrane (EM) shell (Figure 2A). This nanosystem containing an Ephrin-A2 receptor-specific peptide, interleukin (IL)-1α–silencing small interfering RNA, and paclitaxel provided an intelligent carrier for the combined treatment of tumors.

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Figure 2.

Application of blood cell for membrane-functionalized particles. (A). Schematic presentation of BP-H-ILsi-X@EM-YSA nanosystems using RBC. An intelligent all-in-one nanosystem was prepared using an ephrin-A2 receptor-specific peptide (YSA, targeting cancer cells) anchored EM as the “shell.” The “core” contained (1) poly-L-histidine (H) grafted tailored BP as the near-infrared-stimulus core, (2) IL-1α–silencing small interfering RNA (ILsi) that abrogated IL expression resulting in restricted C-C motif chemokine ligand 22 (CCL22) secretion, and Treg cell accumulation to induce antitumor immune response, and (3) paclitaxel (X) that induced therapeutic effects. Adopted and revised with permission from Ou et al. ¹⁶ (B) Functionalization and characterization of PLTM-derived vesicle (PMDV)-coated Si particles (a) Schematic of preparing PLTM-coated Si particles. Longitudinal bioluminescence imaging at week 4 following injection detected reduced lung metastases in the experimental group compared with tris-buffered saline (TBS). Revised and reproduced with permission from Li et al. ¹⁷ (C) Illustration of neutrophil membrane–coated poly (lactic-co-glycolic acid) (PLGA) NPs loaded with carfilzomib (NM-NP-CFZ). NM-NP-CFZ was synthesized to target circulating tumor cell (CTC) in circulation and inflamed endothelial cells in the metastatic lesion where the interaction of (Leukocyte Function-associated Antigen-1) LFA-1 with intercellular cell adhesion molecule-1 (ICAM-1), CD44 with L-selectin, and β1 integrin with vascular cell adhesion molecule-1 (VCAM-1) was involved in the targeting and subsequent effect. Adopted and revised with permission from Kang et al. ¹⁸

Tumor vaccine is one of the highly concerned focus nowadays. To improve dendritic cell (DC) targeting and antigen presentation efficiency, Guo et al ¹⁹ developed a PLGA NP wrapped by RM as a nano-vaccine. The research findings showed that the nano-vaccine could inhibit metastasis and prevent melanoma. In addition, the nano-vaccine augmented interferon-γ (IFN-γ) secretion and CD8⁺ T-cell response. In another study, Reuven et al ²⁰ designed an active cancer vaccine with anti-N-glycolylneuraminic acid (Neu5GC) antibodies loaded on RMs, which was experimentally proved to induce the production of anti-Neu5Gc IgG antibodies in mice and inhibit tumor growth.

Platelet membrane–modified nanocarrier

Platelets are small, irregularly shaped cells released by the mature megakaryocytes during cytoplasmic fragmentation in the bone marrow and are extremely important for the hemostatic function of the body. Due to the presence of CD47 protein and P-selectin on PLTMs, ²¹ nanocarriers modified with PLTMs can not only prolong blood circulation time and escape immune clearance but also have the ability of active targeting, ²² thereby, playing an important role in antitumor metastasis. There are associated antigens and functional proteins on PLTs, they are associated with immune defense and targeting of damaged vascular systems, while also responding to invasive microorganisms. ²³ Given the above advantages, PLTM-modified nanocarriers are a promising targeted therapy for tumors.

Circulating tumor cells spread through the blood, causing tumor metastasis of distant organs. Circulating tumor cells exhibit distinct characteristics compared with the TME of solid tumors. Inspired by this, Li and co-workers synthesized activated PLTM-functionalized silica particles and bound the cancer-specific tumor necrosis factor-related (TNF-related) apoptosis-inducing ligand (TRAIL) on the surface (Figure 2B). ¹⁷ Although CTCs are protected by activated PLTs and fibrin deposition in blood circulation to avoid immune attacks, a nanocarrier disguised with PLTMs can transport anti-cancer drugs directly to CTC thrombosis. Furthermore, TRAIL offers the advantage of inducing apoptosis in cancer cells while presenting low toxicity to normal cells.^24,25 Mouse breast cancer experiments demonstrated that the nanocarriers were effective in reducing lung metastasis. Hu and co-workers developed PLGA NPs based on PLTM modification and loaded docetaxel in them. ²⁶ Besides avoiding immune attacks and inhibiting tumor growth, the nanodrug delivery system was capable of reducing the damage caused by free docetaxel to blood vessels. Similarly, Wang designed porous NPs using PLTMs that were demonstrated to be more effective in tumor growth inhibition compared with bufalin preparations. ²¹ These findings suggest PLTMs as exceptionally promising materials in the preparation of tumor nano-vaccines.

White blood cell membrane–modified nanocarrier

White blood cells are a crucial part of the body’s innate immune system that resists pathogen invasion. ²⁷ These cells are not only found in blood and lymphatic vessels but also widely distributed throughout various tissues. White blood cell can be classified into 3 main categories based on their morphology, function, and location of origin: granulocyte, monocyte, and lymphocyte. Examples include macrophages, neutrophils, T lymphocytes, and natural killer cells. Tumors are often present in an inflammatory microenvironment, which can cause the tumor cells to overexpress various inflammatory factors. This, in turn, recruits various immune cells to the tumor site, although EM and PLTM-modified nanocarriers showed excellent performance in evading reticuloendothelium-mediated uptake and immune recognition monitoring. The immune cell membrane has specific surface markers (a variety of specific proteins and sugars), which makes the immune cell membrane unique functions. Therefore, it is of great research value to use different immune cells to build nanocarriers.

Macrophages are vital components of the human immune system and are widely distributed in the blood and tissues throughout the body. They function for identifying, engulfing, and eliminating foreign bodies such as bacteria and viruses. ²⁸ Macrophage membrane–coated nanocarriers can play an important role in inducing both innate and acquired immune responses. For instance, Cao et al ²⁹ developed macrophage membrane–modified EMTANSINE liposomes, which can improve the efficiency of drug delivery and significantly inhibit breast cancer lung metastasis. In addition, Zhang reported a NP (CSKC-PPIP/PTX@MA) wrapped in macrophage membrane that can control drug release step by step. ³⁰ To better meet clinical needs, Liu et al ³¹ designed a macrophage membrane–covered laser-response variable nano-pharmaceutical (I-P@NPS@M) with good permeability, retention, and targeting. Advantageous properties, including good biocompatibility and immunomodulatory effects, make macrophages a promising material for the development of tumor vaccines. To optimize the immune response and minimize potential side effects of dendrobium devonianum polygonatum (DP), Zhang et al ³² developed a novel tumor vaccine by coating PLGA NPs (PLGA-DP/Ovalbumin (OVA)) with macrophage membranes, which demonstrated to effectively activate the immune response in mice. In addition, M1 macrophage membrane coating has better tumor-targeting ability. For example, the M1-macrophage cell-coated NPs ([C/I]BP@B-A(D)&M1 m) constructed by Hu et al, ³³ can effectively inhibit the recurrence and metastasis of primary tumors, and are characterized by laser response, variable size, on-demand drug release, and prolonged circulation retention.

The DC membranes play a crucial role in antigen presentation and can specifically activate memory T cells and primary T cells. In addition, DCs are capable of releasing a wide range of cytokines, including costimulatory and adhesion molecules, which promote the interaction between DCs and T cells to regulate the adaptive immune response of the body.^34,35 In recent years, the DC tumor vaccine has made significant progress in prostate cancer and recurrent ovarian cancer.^36-39 Compared with the traditional DC vaccine, the “mini DC” vaccine prepared by the co-extrusion method is more clinically feasible. ⁴⁰ Cheng et al used PLGA NPs loaded with IL-2 and encapsulated with DC membrane. In vivo and in vitro experiments have demonstrated that this vaccine can effectively inhibit the growth and metastasis of ovarian cancer and activate the immune response of the entire body. Besides, it is easy to store and has a long shelf life.

As a host’s first line of defense against invading pathogens, neutrophils are the most abundant type of granulocyte. ⁴¹ Neutrophils play a central role in the acute inflammatory phase. They can also target CTCs. ⁴² In the TME, neutrophils can interact with metastatic tumors and CTC through intercellular adhesion molecules. ⁴³ Based on this property, Kang et al ¹⁸ designed neutrophil-coated PLGA NPs (NM-NP) that showed a profound cell binding affinity in vitro and CTC capture efficiency in vivo (Figure 2C). Interestingly, CFZ loaded by NM-NP could kill CTCs in the circulatory system and prevent early metastasis of tumor cells. Thus, nanocarriers based on neutrophil membrane can prevent tumor metastasis through a variety of different mechanisms.

Both T cells and NK cells are lymphocytes. First, T cells are an important type of lymphocyte with tumor-specific recognition ability and immune response, making them potentially applicable in cancer treatment. Given the limitations of traditional treatments, Ma et al ⁴⁴ have constructed a new nanodrug delivery system that involves IR780-loaded mesoporous silica NPs coated with CAR-T cell membrane which specifically recognized Glypican-3 (GPC3) protein on the surface of liver cancer cells. This new drug delivery system has better immune targeting and photothermal antitumor ability. Due to the mutagenicity, heterogeneity, and immune escape of tumor cells, the dual-targeting strategy is more advantageous. Researchers constructed indocyanine green nanoparticles. ⁴⁵ Next, natural killer (NK) cells are the most cytotoxic cells and can directly kill tumor cells. ⁴⁶ They possess a variety of protein receptors including NKp46, CD226, and NKG2D, among others, that enable them to recognize and kill tumors. ³⁴ Cai et al designed an allergy agent the 4,4′,4′′,4′′′-(porphine-5,10,15,20-tetrayl) tetrakis (benzoic acid) (TCPP) NPs coated with NK cell membrane (NK-NPs). ⁴⁷ Nanoparticles coated with NK cell membrane can polarize M1 macrophages and produce an antitumor effect. In addition, after laser irradiation, NK-NPs can effectively inhibit tumor development and metastasis.

Moreover, nanocarriers can also be prepared using membranes from other important immune cells such as bone marrow–derived suppressor cells (MDSCs) and bone marrow–derived macrophages (BMDMs).^48,49 These novel approaches offer promising immunotherapeutic options for treating tumors.

Cancer cell membrane–modified nanocarrier

In recent years, tumor cells have become a major focus of research due to their distinctive characteristics. First, tumor cells are relatively easy to expand in vitro to obtain cell membranes. Second, tumor cell membranes can play important roles in immune activation, immune escape, and prolonging blood circulation time. ⁵⁰ Finally, tumor cell membranes also have unique homologous binding properties.^50,51 These functions are primarily attributed to the surface proteins of tumor cell membranes, including N-cadherin, epithelial cell adhesion molecule (EpCAM), and galactose lectin-3.^52-55 Therefore, cancer cell membranes are a promising modification material for antitumor immunotherapy. When modified by tumor cell membranes, the carrier can not only promote immune response, targeted aggregation, and drug delivery but also has substantial potential in developing personalized tumor vaccines.

The tumor cell membrane can be modified by combining membrane core structure usually with various organic or inorganic materials, such as magnetic iron oxide nanoparticles (MNPs), ⁵⁶ silica NPs (Figure 3A),^57,58 and PLGA NPs.^59-61 For example, B16-F10 cancer cell membrane–modified PLGA nanoparticles (CCNPs) can effectively deliver tumor-associated antigens to immune cells for processing and subsequent antigen-specific T-cell stimulation. ⁶⁰ Similarly, it was demonstrated that PLGA NP coated with cancer cell membrane fractions (CCMFs) that contain intact membrane-associated proteins, including C-X-C chemokine receptor type 4 (CXCR4) and CD44, can reduce the migration and metastasis of tumor cells. These CCMF-PLGA NPs were capable of migrating to nearby lymph nodes and enhancing the percentage of CD8⁺ and CD4⁺ cytotoxic T-lymphocyte populations in the spleen and lymph nodes of immunized mice. ⁵⁹ In addition, these nanocarriers showed the homologous targeting of cancer cells.

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Figure 3.

Application of tumor cell and bacterial for membrane-functionalized particles. (A) Schematic diagram of CMSN-Gox inducing antitumor immune response and enhancing anti-PD-1 immunotherapy. Adopted and revised with permission from Xie et al. ⁵⁸ (B) Schematic diagram of in situ vaccine induced by bacterial membrane–coated nanoparticles (BNPs) combined with RT. Diagram of how BNP interacts with TME to enhance antigen presenting cell (APC) uptake and activation. Schematic diagram of in situ vaccine induced by BNP in combination with RT. The composition and the function of each component of BNP. Adopted and revised with permission from Patel et al. ⁶²

For most vaccines, immune adjuvants substantially enhance the immune response. Hence, when an adjuvant is injected into the body along with the antigen, it can significantly boost the immune response to the antigen. Currently, aluminum salt and Toll-like receptors (TLR) agonists, such as monophosphoryl lipid A (MPLA), CpG oligonucleotides, and R837, are the main clinically used immune adjuvants. ⁵¹ ,^61-66 For the first time, PLGA NPs were loaded with immune adjuvant R837 and then coated with mannose-modified tumor cell membranes to prepare nano-vaccines (NP-R@M-M). ⁶¹ The resulting nano-vaccines facilitated the maturation of DCs and triggered an immune response. Similarly, the immunoadjuvant CpG can also promote the maturation of antigen-presenting cells. For instance, Kroll et al developed a novel nano-vaccine (CpG-CCNPs) by coating CpG-loaded PLGA nuclei (CpG-NPs) with B16-F10 mouse melanoma cell membrane. Nevertheless, several tumor vaccines that do not contain immune adjuvants have also demonstrated remarkable antitumor effects.^67,68 Personalized tumor vaccine has emerged as a promising area of research aimed at overcoming the limitations of low antigen immunogenicity and weak immune response. A personalized photothermal vaccine (Gel-BPQD-CCNVs) was prepared from the surgically removed tumor, which effectively activated DCs. ⁶⁹ Furthermore, in combination with ICBs, photodynamic therapy, and “starvation therapy,” the nanocarriers demonstrated complementary advantages and achieved better therapeutic outcomes.^{57,58,61,64,65},^68-70

Bacterial membrane–modified nanocarrier

Bacterial membrane–modified nanocarriers have the characteristics of immune stimulation, prolonging cycle time, and tumor imaging. ⁷¹ The bacterial membrane-coated nanoparticles (BNPs) have also been employed in targeted drug delivery systems for antitumor therapy, as a wide range of bacterial-related membrane components can be used for immune stimulation or tumor-specific enrichment. Moreover, bacterial-mediated nanocarriers can migrate toward hypoxic tumor environments. ⁷² To enhance the immune response following systemic radiation therapy (RT) in immunologically “cold” tumors, Patel et al developed a BNP containing immune-activating PC7A/CpG polyplex. They extracted the bacterial membrane from a non-pathogenic strain (mycobacterium minor), which exhibited strong immunogenicity (Figure 3B). ⁶² After RT, BNP can capture cancer neoantigens, improve DC uptake, and promote antitumor T-cell responses. In addition, tumor immunotherapeutic agents constructed by using outer membrane vesicles of gram-negative bacteria exhibited promising potential in eradicating tumors with low toxicity. ⁷³

Hybrid cell membranes modified nanocarrier

The membranes of different types of cells have specific characteristics. The fusion of cell membranes is one of the simple and effective approaches to increasing the function of nanocarriers. ⁷⁴ For example, when erythrocyte and PLTMs are fused, the protein marker molecules of the 2 membranes (CD235a, CD41, CD61, and CD44) remain on them. ²² Subsequently, Liu et al ⁷⁵ proposed the concept of using DCs and tumor cell–derived FC bio-recombinant membranes (FM) for modifying tumor nano-vaccines. This offers a personalized treatment option for various tumors. In addition, various other types of membrane fusions are also reported, including tumor cell-Lactobacillus membrane, erythrocyte-cancer cell membrane, macrophage-tumor cell membrane, and multiple cell membrane fusion.^76-79 Consequently, FC membrane presents a promising technical advancement for the development of a multi-functional bionic drug delivery platform.

Other types of cell membranes modified nanocarrier

Stem cells are pluripotent cells with low immunogenicity and self-replicating ability that can target tumor cells, such as mesenchymal stem cells (MSCs), neural stem cells, and hematopoietic stem cells. ⁸⁰ Nanocarriers modified by different types of stem cells can target different types of tumor cells. Moreover, MSC membranes possess a variety of receptors including cytokine receptors, growth factor receptors, cell-matrix receptors, chemokine receptors, and cell-cell interaction receptors.^81,82 To improve drug delivery efficiency and reduce the risk of vascular adverse reactions, Gao et al ⁸³ developed a nanodelivery system (SCMGs) for mesenchymal dry cell membrane–modified gelatin nano gels. This system maintained the biological function and stability of dry cell membranes.