Cancer-Cell-Biomimetic Nanoparticles for Targeted Therapy of Homotypic Tumors

Incorporation of cellular membrane protein extracts into lipid nanoparticles enhances their cellular uptake and mRNA delivery efficiency

mRNA therapeutics enable transient expression of desired proteins within cells, holding great potential for advancements in vaccines, protein replacement therapies and gene editing approaches. Lipid nanoparticles (LNPs) are arguably the leading nanoplatform for mRNA delivery due to their scalability and transfection efficiency. However, their limited ability to target specific cell types, inefficient cellular uptake by many cell types, and endosomal entrapment represent challenges for improving targeted mRNA delivery. To address this, we evaluated a novel class of LNPs functionalized with cell-derived membrane proteins, that we refer to as hybrisomes. Membrane protein extracts (MPEs) were isolated from cultured cells using a mild detergent-based extraction protocol. Cy5-labeled mRNA encoding for eGFP was used to form LNPs and hybrisomes to investigate their internalization efficiency and mRNA delivery via flow cytometry and microscopy, with MPE content incorporated into hybrisomes during microfluidic mixing. MPEs were successfully incorporated into the lipid membrane of hybrisomes. Remarkably, the cellular uptake of hybrisomes was up to 15-fold higher than LNPs, while the mRNA delivery efficiency improved up to 8-fold depending on the MPE content incorporated into the hybrisomes. Further studies confirmed that the enhanced cellular uptake of hybrisomes and mRNA is partially explained by the presence of membrane proteins and hybrisomes' unique morphology including bleb-like structures. Moreover, the versatility of hybrisomes was demonstrated by producing formulations using MPEs isolated from different cell types, which led to variations in cellular uptake and mRNA delivery, suggesting that the cell type from which MPEs are derived influences their biological function. These findings pave the way for the development of more targeted and effective nanotherapeutic strategies.

Glutaraldehyde-crosslinked Naringenin-loaded Albumin Nanoparticles (GNANPs) induce antimicrobial properties and apoptosis in gastric cancer cells

An assessment of the anticancer activity of Glutaraldehyde-crosslinked Naringenin-loaded Albumin Nanoparticles (GNANPs) against gastric cancer cells was the purpose of this study. The increasing prevalence of gastric cancer and the limitations of conventional therapies necessitate novel approaches that combine targeted drug delivery with therapeutic efficacy. Several techniques were used to characterize the synthesized GNANPs, including UV-visible spectroscopy, X-ray diffractometer (XRD), scanning electron microscope (SEM), transmission electron microscope (TEM), Fourier transform infrared (FT-IR), dynamic light scattering (DLS), and photoluminescence (PL). They were evaluated for their antimicrobial properties, cytotoxicity, ROS accumulation, apoptotic activity, and oxidative stress markers against AGS cells. The characterization analyses indicated the existence of Glutaraldehyde-crosslinked Naringenin-loaded Albumin Nanoparticles with an oval-shaped morphology and an average particle size of 127.80 nm. The existence of several elements and functional groups in the GNANPs was also detected using EDX and FT-IR analyses, respectively. The synthesized GNANPs have shown exceptional antibacterial activities by effectively inhibiting the growth of several infections. The treatment of GNANPs efficiently inhibited the growth of AGS cells. Fluorescence staining studies showed increased apoptosis and oxidative stress markers in AGS cells treated with synthesized Glutaraldehyde-crosslinked Naringenin-loaded Albumin Nanoparticles, indicating their potential as a viable cancer treatment option.

A biomimetic manganese-phycocyanin nanodrug-carrying system and its sonodynamic-immunological anti-tumor therapy

Cutaneous melanoma is characterized by malignant proliferation, high aggressiveness, high metastasis, rapid recurrence, and low survival rate; therefore, research on its treatment is vital. In this study, a novel nano system combining sonodynamics and immunotherapy for cutaneous melanoma treatment was designed and developed. Based on the use of phycocyanin for the biomineralization of manganese ions, smart and multifunctional manganese phycocyanin nanoparticles encapsulating the immune adjuvant levamisole (LMS) with melanoma B16-OVA cell membranes wrapped around its outer layer (Mn-PCNP-LMS@CM) were designed and prepared. The experimental results showed that Mn-PCNP-LMS@CM efficiently targeted cutaneous melanomas. Under ultrasonic excitation, it catalyzed oxygen production from hydrogen peroxide in the tumor environment, reduced high glutathione levels in tumor tissues, and significantly enhanced (reactive oxygen species) ROS generation, thus improving the outcome of sonodynamic therapy. In contrast, sonodynamic therapy induced immunogenic death of tumor cells, together with the loaded immune adjuvant levamisole, which promoted the maturation of dendritic cells (DCs), modulated the immunosuppressive microenvironment, enhanced the immunotherapeutic effect, and stimulated the function of long-term immune memory to prevent tumor growth and recurrence. This study is expected to provide new ideas for developing novel anti-tumor nano systems and achieving anti-tumor synergistic therapy.

Tumor Cell Membrane Biomimetic Mesoporous Silicon Materials in Combination with PD-L1 Knockout Achieved through the CRISPR/Cas9 System for Targeted and Immunotherapeutic Purposes

Nanoparticle-based drug delivery systems, which enable the effective and targeted delivery of chemotherapeutic drugs to tumors, have revolutionized cancer therapy. Mesoporous silicon materials (MSN) have emerged as promising candidates for drug delivery due to their unique properties. The therapeutic efficacy can be significantly enhanced when treatments exhibit both targeting and antiphagocytic properties. In this study, cell membranes extracted from B16-F10 cells were used to encapsulate carboplatin (CBP)-loaded MSN via physical extrusion. Additionally, we intratumorally injected a plasmid containing the CRISPR/Cas9 system to achieve PD-L1 knockout, thereby reactivating the immune system. The cell membrane coating endowed the CBP@MSN with excellent slow-release capability and cytocompatibility. Enhanced tumor cell uptake of CBP@MSN@M was observed due to homologous targeting by cancer cell membranes. Moreover, CBP@MSN@M demonstrated enhanced antitumor efficacy in vivo and promoted the proliferation of immune cells. Finally, the antitumor effect was further improved by the knockout of PD-L1 within the tumor microenvironment. These results suggest that the newly prepared CBP@MSN@M, combined with PD-L1 knockout, holds significant potential as an effective therapeutic approach for treating tumors.

Albumin-based synergistic chemiexcited photodynamic biomimetic nanoreactor overcoming adaptive immune resistance for enhanced cancer immunotherapy

The application of traditional photodynamic therapy (PDT) is hindered by poor tissue penetration of external light and adaptive immune resistance. Here, we report an albumin-based chemiexcited photodynamic nanoreactor (CC@HSA/GOX@Z(Arg/1-MT)m) for anticancer therapy. Photosensitizer Ce6 and CPPO were incorporated into the hydrophobic domains of human serum albumin (HSA). High concentration of H2O2 reacts with CPPO to activate Ce6, generating singlet oxygen for immunogenic cell death (ICD) induction. This process fostered an immune-promoting tumor microenvironment, characterized by enhanced intratumoral infiltration of cytotoxic T lymphocytes, and a reduction in immunosuppressive cell infiltration. However, due to persistent stimulation of tumor antigens induced by ICD, the expression of IDO in the tumor was also upregulated. This upregulation contributed to the development of immune tolerance to subsequent treatments and limited the efficacy of immunotherapy. The addition of IDO inhibitor can compensate for this defect. CC@HSA/GOX@Z(Arg/1-MT)m could maintain its immune-promoting effects and alleviate post-treatment immune tolerance induced by elevated IDO expression. These findings demonstrated that the combination of IDO inhibitor and PDT represents a promising strategy for enhancing the immune response and ultimately inhibiting tumor growth.

Advancements in Cell Membrane-Derived Biomimetic Nanotherapeutics for Breast Cancer

Breast cancer remains the leading cause of female mortality worldwide, necessitating innovative and multifaceted approaches to address its various subtypes. Nanotechnology has attracted considerable attention due to its nanoscale dimensions, diverse carrier types, suitability for hydrophobic drug delivery, and capacity for controlled and targeted administration. Nano-sized particles have become prevalent carriers for therapeutic agents targeting breast cancer, thanks to their reproducible synthesis and adjustable properties, including size, shape, and surface characteristics. In addition, certain nanoparticles can enhance therapeutic effects synergistically. However, the immune system often detects and removes these nanoparticles, limiting their efficacy. As a promising alternative, cell membrane-based delivery systems have gained attention due to their biocompatibility and targeting specificity. These membrane-coated drug delivery systems are derived from various cell sources, including blood cells, cancer cells, and stem cells. Leveraging the unique properties of these cell membranes enables precise targeting of breast cancer tumors and associated biomarkers. Inspired by natural structures, cell membranes disguise nanoparticles in the bloodstream, enhancing their retention time in vivo and improving tumor targeting. Consequently, cell membrane-derived nanoparticles (CMDNPs) have been investigated for their potential applications in breast cancer diagnostics, photothermal therapy (PTT), and vaccine development. This review comprehensively explores the potential and limitations of cell membrane-derived drug delivery systems in clinical applications against breast cancer.

Biomimetic nanosystems for pancreatic cancer therapy: A review

Pancreatic cancer (PC) is a highly lethal and aggressive malignancy, currently one of the leading causes of cancer-related deaths worldwide, in both women and men. PC is highly resistant to standard chemotherapy (CT) because its immunosuppressive and hypoxic tumor microenvironment and a dense desmoplastic stroma compartment extensively limit drug accessibility and perfusion. Although CT is one of the main therapeutic strategies for PC management contributing to tumor eradication through a cytotoxic effect, CT is associated with a poor pharmacokinetic profile and provokes deleterious systemic toxicity. This low efficacy-poor safety scenario urgently calls for innovative and highly specific therapeutic strategies to counteract this urgent clinical challenge. Nanotechnology-based precision materials for cancer may help improve drug stability and minimize the systemic cytotoxic effects by increasing drug tumor accumulation and also enabling controlled release, but several drawbacks still persist, such as the poor targeting efficiency. In the last few years increased attention has been paid to bioinspired nanosystems that can mimic either partially or totally biological systems, including lipid layers as suitable stealth coatings resembling the composition of cell membranes, lipoprotein- and blood protein-based nanosystems, and cell membrane-derived systems, such as extracellular vesicles, cell membrane nanovesicles and cell membrane-coated nanosystems, which display intrinsic cancer-targeting abilities, enhanced biocompatibility, decreased immunogenicity, and prolonged blood circulation profile. This review covers the recent breakthroughs on advanced biomimetic PC-targeted nanosystems, focusing on their design, properties and applications as innovative, multifunctional and versatile tools paving the way to improved PC diagnosis and treatment.

Promoting Drug Delivery to the Brain by Modulating the Transcytosis Process across the Blood-Brain Barrier

The blood-brain barrier (BBB) presents a major challenge in the theranostics of brain diseases by impeding the delivery of drugs to the brain. Currently the most common strategy for transferring substances across the BBB is receptor-mediated transcytosis, which is restricted by several key factors, including insufficient endocytosis by brain microvessel endothelial cells (BMECs) due to underexpressed pinocytotic vesicles, lysosomal retention, and limited exocytosis to the brain parenchyma. We report a hybrid cell membrane (HCM)-coated and 2-methacryloyloxyethyl phosphorylcholine (MPC)-modified nanocarrier to promote drug delivery across the BBB by modulating the transcytosis process. The HCM incorporates a brain metastatic tumor cell membrane for recognition of BMECs and a GFP-293-S cell membrane expressing Spike protein to facilitate membrane fusion between the nanocarrier and BMECs, thereby bypassing vesicle-dependent endocytosis and enhancing cellular uptake. Membrane fusion reduces the chance of lysosomal retention, and MPC modification enhances exocytosis into the brain parenchyma via the interaction of MPC with transporters expressed on the abluminal endothelial membrane. The nanocarrier achieves significantly improved delivery of CuS, a photothermal agent, to the brain and thus enables highly efficient therapy of brain glioma.

Carrier-Free Self-Assembled Nanoparticles for Triple-Amplified Tumor Chemodynamic Therapy and Cuproptosis Induction

Chemodynamic therapy (CDT) holds great promise in cancer treatment, whereas its efficacy is severely compromised by the low concentration of endogenous hydrogen peroxide(H2O2), insufficient exogenous catalytic ions, and the presence of high levels of cellular glutathione (GSH). Herein, a dissociable, tumor cell membrane-camouflaged carrier-free nanoparticle is developed through the molecular interaction of copper ions (Cu2+), dequalinium (DQ), and β-Lapachone (β-Lap). Upon homotypic tumor targeting, the system releases Cu2+ (exogenous catalytic ions), β-Lap (H2O2 donor), and DQ (GSH scavenger), achieving triple amplification of CDT efficacy. Concurrently, the intracellular accumulation of Cu2+ induces cuproptosis, thereby synergistically augmenting CDT efficacy and strikingly restraining tumor growth. Overall, the integration of Cu2+ supplementation, H2O2 self-supplying, and GSH depletion offers a promising avenue for improving cancer treatment outcomes and paves a new way for multimodal cancer therapy.

Advances in nanocarriers for targeted drug delivery and controlled drug release

Nanocarrier-based drug delivery systems (nDDSs) present significant opportunities for improving disease treatment, offering advantages in drug encapsulation, solubilization, stability enhancement, and optimized pharmacokinetics and biodistribution. nDDSs, comprising lipid, polymeric, protein, and inorganic nanovehicles, can be guided by or respond to biological cues for precise disease treatment and management. Equipping nanocarriers with tissue/cell-targeted ligands enables effective navigation in complex environments, while functionalization with stimuli-responsive moieties facilitates site-specific controlled release. These strategies enhance drug delivery efficiency, augment therapeutic efficacy, and reduce side effects. This article reviews recent strategies and ongoing advancements in nDDSs for targeted drug delivery and controlled release, examining lesion-targeted nanomedicines through surface modification with small molecules, peptides, antibodies, carbohydrates, or cell membranes, and controlled-release nanocarriers responding to endogenous signals such as pH, redox conditions, enzymes, or external triggers like light, temperature, and magnetism. The article also discusses perspectives on future developments.

Remodeling of Effector and Regulatory T Cells by Capture and Utilization of miRNAs Using Nanocomposite Hydrogel for Tumor-Specific Photothermal Immunotherapy

In immunotherapy for malignant tumors, the dysregulation of the balance between effector T cells and regulatory T cells (Tregs) and the uncertain efficacy due to individual differences have been considered as two critical challenges. In this study, we engineered an injectable nanocomposite hydrogel system (SNAs@M-Gel) capable of suppressing Treg proliferation and blocking PD-1/PD-L1-mediated immune evasion effectively, achieved through the stimulus-responsive modulation of multiple tumor-associated microRNAs. Simultaneously, this system enables microRNA-dependent photothermal immunotherapy, facilitating a highly efficient and personalized approach to tumor treatment. Specifically, oxidized sodium alginate (OSA) and cancer cell membrane (CCM)-encapsulated spherical nucleic acid nanoparticles (SNAs@M) were used to construct the SNAs@M-Gel hydrogel in situ at the tumor site through the formation of pH-sensitive Schiff base bonding and cross-linking using endogenous calcium ions (Ca2+). During treatment, SNAs@M-Gel was retained locally for up to 10 days, and SNAs@M nanoparticles were continuously released into the tumor microenvironment. Through the targeting ability of CCM, SNAs@M precisely entered tumor cells and specifically hybridized with the overexpressed miR-214 and miR-130a, leading to a significant downregulation of PD-L1 expression on tumor cells and the restoration of cytotoxic T lymphocyte (CTL) function suppressed by Tregs, thereby remodeling the immune microenvironment. In addition, miRNAs functioned as cross-linking agents, facilitating the aggregation of SNAs and allowing the localized production of photothermal agents directly inside tumor cells, which, under near-infrared (NIR) irradiation, promoted highly selective photothermal therapy. This cascade of events not only led to the destruction of the primary tumor but also resulted in the release of a substantial number of tumor-related antigens, which triggered the maturation of adjacent dendritic cells (DCs) and subsequent priming of tumor-specific CTLs, while simultaneously depleting Tregs, thereby reversing the tumor-promoting immune microenvironment and enhancing the overall therapeutic efficacy of photothermal immunotherapy.

Biomimetic Copper-Based Nanoplatform for Enhanced Tumor Targeting and Effective Melanoma Therapy

Designing advanced biomimetic nanoplatforms that combine photothermal therapy (PTT) and immune activation represents a modern approach to addressing the challenges of cancer therapy. This study presents a nanobiomimetic hollow copper-sulfide (HCuS) platform for precise homotypic tumor targeting and melanoma treatment. The HCuS@OVA@CM (COC) nanoplatform-encapsulated ovalbumin (OVA) antigen protein within HCuS nanoparticles and was coated with melanoma cell membranes (B16F10). Importantly, this design facilitates specific tumor accumulation and achieves 16.0% photothermal conversion efficiency under 1064 nm NIR-II irradiation, which is a key factor for therapeutic success. In vitro studies have demonstrated that this nanoplatform induces immunogenic cell death (ICD), enhances antigen presentation, and stimulates dendritic cell (DCs) maturation. In vivo experiments confirmed that COC-mediated NIR-II photothermal treatment significantly suppressed tumor growth without notable body weight loss. This biomimetic nanoplatform approach offers a targeted, enhanced, and effective immune response for tumor photothermal immunotherapy, making it a promising candidate for advanced melanoma treatment and anticancer therapy.

Nanocarriers for cutting-edge cancer immunotherapies

Cancer immunotherapy aims to harness the body's own immune system for effective and long-lasting elimination of malignant neoplastic tissues. Owing to the advance in understanding of cancer pathology and immunology, many novel strategies for enhancing immunological responses against various cancers have been successfully developed, and some have translated into excellent clinical outcomes. As one promising strategy for the next generation of immunotherapies, activating the multi-cellular network (MCN) within the tumor microenvironment (TME) to deploy multiple mechanisms of action (MOAs) has attracted significant attention. To achieve this effectively and safely, delivering multiple or pleiotropic therapeutic cargoes to the targeted sites of cancerous tissues, cells, and intracellular organelles is critical, for which numerous nanocarriers have been developed and leveraged. In this review, we first introduce therapeutic payloads categorized according to their predicted functions in cancer immunotherapy and their physicochemical structures and forms. Then, various nanocarriers, along with their unique characteristics, properties, advantages, and limitations, are introduced with notable recent applications in cancer immunotherapy. Following discussions on targeting strategies, a summary of each nanocarrier matching with suitable therapeutic cargoes is provided with comprehensive background information for designing cancer immunotherapy regimens.

Cancer cell membrane-coated sulindac-ortho ester nanoprodrug for inhibiting COX-2 expression and chemo-photothermal synergistic antitumor therapy

The paper reported a cancer cell membrane bio-mimetic nanodrug to inhibit the expression of COX-2 in tumor area and realize enhanced chemo-photothermal synergistic anti-tumor effect. Ortho ester bond-coupled sulindac dimer (SU-OE) was first synthesized and co-assembled with doxorubicin to obtain pH-sensitive nanodrug (SU-OE@DOX NPs). Indocyanine green (ICG)-encapsulated H22 cell membrane vesicles (HM) were then co-extruded with SU-OE@DOX NPs to give the bio-mimetic nanoparticles (HM@I/NPs). HM@I/NPs displayed excellent stability and photothermal conversion efficiency. Compared to naked nanoparticles, the cell membrane-coated nanoparticles improved H22 cell uptake through homotypic targeting and effectively reduced internalization of macrophages. In vivo imaging results demonstrated that the nanoparticles could be enriched at tumor site and could raise the temperature of the tumor area to 56.7 °C under NIR laser irradiation. The released SU from HM@I/NPs can inhibit the expression of COX-2, and finally enhanced the chemo-PTT synergistic anti-tumor effect.

Engineered endoplasmic reticulum-targeting nanodrugs with Piezo1 inhibition and promotion of cell uptake for subarachnoid hemorrhage inflammation repair

Subarachnoid hemorrhage (SAH) is a life-threatening acute hemorrhagic cerebrovascular condition, often presenting with severe headaches caused by intracranial hypertension, which in severe cases can lead to brain herniation. Piezo1 is a mechanosensitive ion channel protein whose mechanical properties are closely linked to central nervous system diseases. In this study, we developed an engineered endoplasmic reticulum membrane-based nanomedicine (CAQKERM@GsMTx4) using HEK293T cells, aimed at targeted delivery to acute hemorrhagic regions, rapid absorption, and precise inhibition of Piezo1 therapy. To ensure optimal targeting and therapeutic efficacy, we fused the CAQK peptide gene to the N-terminus of TRP-PK1, presenting the CAQK peptide on the endoplasmic reticulum membrane, and loaded GsMTx4 into engineered vesicles (EVs) derived from this engineered membrane. Through in vivo and in vitro experiments and multi-omics analysis, we have demonstrated the marked advantages of endoplasmic reticulum membrane vesicles over cell membrane-based vesicles. CAQKERM@GsMTx4 successfully inhibits Piezo1 in SAH, helps microglia change from the M1 phenotype to the M2 phenotype, and inhibits inflammatory responses and neuronal damage. Overall, this novel engineered endoplasmic reticulum membrane nanomedicine provides a potential effective strategy for the clinical treatment of subarachnoid hemorrhage.

Multieffect Specific Nanovesicles for Homing Resistant Tumors and Overcoming Osimertinib-Acquired Resistance in NSCLC

Acquired resistance to osimertinib (Osi) remains a major obstacle in the treatment of patients with EGFR-mutant non-small cell lung cancer (NSCLC). AXL elevation is a known key mechanism of Osi-resistance, and therapeutic strategies remain scarce. Emerging evidence reveals that an increased intracellular glutathione (GSH) level induces Osi resistance. In this study, a new mechanism is identified by which GSH regulates AXL expression via glutathione peroxidase 4 (GPX4) in Osi-resistant cells. A multifunctional covalent organic framework (COF) nanoplatform for GSH consumption, AXL inhibition, and co-delivery of the AXL inhibitor (Brigatinib) and Osi is creatively constructed to confirm whether Osi sensitivity improves by simultaneously targeting GSH-AXL resistance mechanisms. Furthermore, it is coated, for the first time, the COF carrier system with specific vesicles to precisely home it into resistant tumors, where CDH2 adhesion molecules play a crucial role. The engineered multifunctional antiresistance-specific nanovesicles effectively inhibited the GSH-AXL axis, induced apoptosis in Osi-resistant cells both in vitro and in vivo, and delayed the progression of Osi-resistant tumors. Overall, these findings provide a novel strategy to overcome the Osi-acquired resistance caused by high AXL levels in NSCLC.

Nanomedicine Innovations for Lung Cancer Diagnosis and Therapy

Lung cancer remains a challenge within the realm of oncology. Characterized by late-stage diagnosis and resistance to conventional treatments, the currently available therapeutic strategies encompass surgery, radiotherapy, chemotherapy, immunotherapy, and biological therapy; however, overall patient survival remains suboptimal. Nanotechnology has ushered in a new era by offering innovative nanomaterials with the potential to precisely target cancer cells while sparing healthy tissues. It holds the potential to reshape the landscape of cancer management, offering hope for patients and clinicians. The assessment of these nanotechnologies follows a rigorous evaluation process similar to that applied to chemical drugs, which includes considerations of their pharmacokinetics, pharmacodynamics, toxicology, and clinical effectiveness. However, because of the characteristics of nanoparticles, standard toxicological tests require modifications to accommodate their unique characteristics. Effective therapeutic strategies demand a profound understanding of the disease and consideration of clinical outcomes, physicochemical attributes of nanomaterials, nanobiointeractions, nanotoxicity, and regulatory compliance to ensure patient safety. This review explores the promise of nanomedicine in lung cancer treatment by capitalizing on its unique physicochemical properties. We address the multifaceted challenges of lung cancer and its tumor microenvironment and provide an overview of recent developments in nanoplatforms for early diagnosis and treatment that can enhance patient outcomes and overall quality of life.

Biomimetic celastrol nanocrystals with enhanced efficacy and reduced toxicity for suppressing breast cancer invasion and metastasis

Breast cancer and its lung metastases pose significant threats to women's health worldwide, impacting their quality of life. Although several therapeutic strategies against breast cancer have been developed, they often cause serious side effects due to their high toxicity and low specificity. Therefore, novel therapeutic strategies that offer potent anti-tumor activity with minimal toxicity are urgently needed to combat the threat of breast cancer and lung metastases. Celastrol (Cela), a triterpenoid extracted from Tripterygium wilfordii, exerts anti-tumor effects by inhibiting tumor angiogenesis as well as tumor cell proliferation, invasion, and metastasis. However, its poor solubility and potential for severe organ toxicity hinder its clinical application. Therefore, in this study, we prepared Cela nanocrystals (Cela-NCs), which effectively increased the solubility of Cela and improved its bioavailability. Subsequently, Cela-NCs were encapsulated within the cell membrane (CCM) derived from breast cancer cells to generate CCM/Cela-NCs and leverage the homologous targeting ability of the CCM. Notably, CCM/Cela-NCs showed immune evasion and could homologously target tumor cells. Both in vitro and in vivo, CCM/Cela-NCs could effectively inhibit the growth and metastasis of breast cancer cells. They also exerted minimal hepatotoxicity in mice during treatment. In conclusion, this Cela-based biomimetic strategy that exploits the biological properties of tumor cells offers a new idea for the effective treatment of breast cancer and its lung metastasis.

Light-activated photosensitizer/quercetin co-loaded extracellular vesicles for precise oral squamous cell carcinoma therapy

Oral squamous cell carcinoma (OSCC) is the most common subtype of head and neck malignancies, characterized by a five-year survival rate that remains persistently below 50%, indicative of limited progress in therapeutic interventions. There is an urgent imperative to develop innovative therapeutic strategies, warranting the investigation of advanced treatment modalities. Nanocarriers offer a promising avenue by significantly enhancing drug properties and pharmacokinetics. Extracellular vesicles (EVs) are naturally occurring nanocarriers produced by cells and have become a focal point in drug delivery research. Quercetin, one of the most abundant dietary flavonoids, exhibits potent anticancer effects. However, its pharmaceutical application is hampered by poor water solubility, instability under physiological conditions, and low bioavailability. To overcome these obstacles, we propose using bio-derived EVs as carriers to co-encapsulate quercetin with the photosensitizer chlorin e6. This strategy leverages the intrinsic targeting capabilities of EVs for precise drug delivery to tumors, along with light-activated drug release, enabling rapid quercetin release under near-infrared light, effectively inhibiting cellular proliferation and inducing apoptosis in tumor cells. In vivo studies demonstrated that drug-loaded EVs exhibited robust tumor-targeting efficacy, resulting in effective and selective tumor ablation upon photoactivation in mice bearing subcutaneous MOC2 tumors.

Tumor microenvironment-mimicking macrophage nanovesicles as a targeted therapy platform for colorectal cancer

Macrophages are a pivotal immune cell population in the tumor microenvironment of colorectal cancer (CRC). Differently-polarized macrophages could be exploited to yield naturally-tailored biomimetic nanoparticles for CRC targeting. Here, membrane proteins were isolated from the THP-1 cell line, and anti-tumor macrophages (M1) were obtained from differentiation of THP-1. Membrane proteins were isolated from THP-1 and M1 and used to produce lipid nanovesicles (LNVs; T-LNVs and M1-LNVs) by microfluidic process, which were loaded with doxorubicin (DOXO). The DOXO loaded T-LNVs and M1-LNVs showed similar size (120-145 nm), PDI (0.11-0.28), zeta potential (-15 to -30 mV) and drug loading efficiency (65-75 %). Mass-spectrometry confirmed the presence of the membrane proteins in the LNVs. The abundance of proteins related to stealth properties, cancer targeting, endothelial adhesion and immune-related markers was significantly different in T-LNVs and M1-LNVs. Cell culture studies showed that M1-LNVs possessed higher cancer cell targeting, uptake and cytotoxicity compared to T-LNVs. In vivo studies performed with zebrafish embryos showed that M1-LNVs yielded higher cancer cell targeting and cytotoxicity while systemic cytotoxicity was lower compared to free DOXO. These findings confirm the potentiality and versatility of M1-LNVs for cancer treatment, which could be exploited as new avenue of nanoparticles-based therapies for precision medicine.

Remotely Sequential Activation of Biofunctional MXenes for Spatiotemporally Controlled Photothermal Cancer Therapy Integrated with Multimodal Imaging

Spatiotemporally controlled cancer therapy may offer great advantages in precision medicine, but still remains some challenges in programmed sequential release and co-localization of components at target sites. Herein, a MXene-based nanoprobe (TCC@M) is meticulously designed by engineering of photodynamically activated CRISPR-Cas9 and cancer cell membrane-camouflaged Ti3C2 MXenes for targeting delivery and spatiotemporally controlled gene regulation followed by enhanced photothermal therapy (PTT) via two near-infrared irradiations. The first irradiation can activate the photosensitizer bound in cancer cells internalized TCC@M to release Cas9 ribonucleoprotein (RNP) by photodynamic effect. The released Cas9 RNP then enters the nuclei directed by the fused nuclear localization sequence in Cas9 to cleave the heat shock protein (HSP) 90α gene, which greatly reduces the expression of HSP90α protein and thus effectively sensitizes cancer cells to heat, leading to enhanced PTT at a mild temperature (<45 °C) risen by Ti₃C₂ MXenes under the second irradiation. Simultaneously, TCC@M can produce fluorescence, photoacoustic, and thermal imaging signals to guide the optimal irradiation timing. The in vivo studies have demonstrated the spatiotemporally selective therapeutic efficacy of the designed TCC@M. This innovative approach presents an effective integration of gene regulation and enhanced PTT, exemplifying a precise cancer treatment strategy.

Carbohydrate polymer-based nanoparticles with cell membrane camouflage for cancer therapy: A review

Recent developments in biomimetic nanoparticles, specifically carbohydrate polymer-coated cell membrane nanoparticles, have demonstrated considerable promise in treating cancer. These systems improve drug delivery by imitating natural cell actions, enhancing biocompatibility, and decreasing immune clearance. Conventional drug delivery methods frequently face challenges with non-specific dispersal and immune detection, which can hinder their efficiency and safety. These biomimetic nanoparticles improve target specificity, retention times, and therapeutic efficiency by using biological components like chitosan, hyaluronic acid, and alginate. Chitosan-based nanoparticles, which come from polysaccharides found in nature, have self-assembly abilities that make them better drug carriers. Hyaluronic acid helps target tissues more effectively, especially in cancer environments where there are high levels of hyaluronic acid receptors. Alginate-based systems also enhance drug delivery by being biocompatible and degradable, making them ideal choices for advanced therapeutic uses. Moreover, these particles hold potential for overcoming resistance to multiple drugs and boosting the body's immune reaction to tumors through precise delivery and decreased side effects of chemotherapy drugs. This review delves into the possibilities of using carbohydrate polymer-functionalized nanoparticles and their impact on enhancing the efficacy of cancer treatment.

Biohybrid nano-platforms manifesting effective cancer therapy: Fabrication, characterization, challenges and clinical perspective

Nanotechnology-based delivery systems have brought a paradigm shift in the management of cancer. However, the main obstacles to nanocarrier-based delivery are their limited circulation duration, excessive immune clearance, inefficiency in interacting effectively in a biological context and overcoming biological barriers. This demands effective engineering of nanocarriers to achieve maximum efficacy. Nanocarriers can be maneuvered with biological components to acquire biological identity for further regulating their biodistribution and cell-to-cell cross-talk. Thus, the integration of synthetic and biological components to deliver therapeutic cargo is called a biohybrid delivery system. These delivery systems possess the advantage of synthetic nanocarriers, such as high drug loading, engineerable surface, reproducibility, adequate communication and immune evasion ability of biological constituents. The biohybrid delivery vectors offer an excellent opportunity to harness the synergistic properties of the best entities of the two worlds for improved therapeutic outputs. The major spotlights of this review are different biological components, synthetic counterparts of biohybrid nanocarriers, recent advances in hybridization techniques, and the design of biohybrid delivery systems for cancer therapy. Moreover, this review provides an overview of biohybrid systems with therapeutic and diagnostic applications. In a nutshell, this article summarizes the advantages and limitations of various biohybrid nano-platforms, their clinical potential and future directions for successful translation in cancer management.

Cell Membrane Camouflaged Biomimetic Nanoparticles as a Versatile Platform for Brain Diseases Treatment

Although there are various advancements in biomedical in the past few decades, there are still challenges in the treatment of brain diseases. The main difficulties are the inability to deliver a therapeutic dose of the drug to the brain through the blood-brain barrier (BBB) and the serious side effects of the drug. Thus, it is essential to select biocompatible drug carriers and novel therapeutic tools to better enhance the effect of brain disease treatment. In recent years, biomimetic nanoparticles (BNPs) based on natural cell membranes, which have excellent biocompatibility and low immunogenicity, are widely used in the treatment of brain diseases to enable the drug to successfully cross the BBB and target brain lesions. BNPs can prolong the circulation time in vivo, are more conducive to drug aggregation in brain lesions. Cell membranes (CMs) from cancer cells (CCs), red blood cells (RBCs), white blood cells (WBCs), and so on are used as biomimetic coatings for nanoparticles (NPs) to achieve the ability to target, evade clearance, or stimulate the immune system. This review summarizes the application of different cell sources as BNPs coatings in the treatment of brain diseases and discusses the possibilities and challenges of clinical translation.

Interleukin 15-Presenting Nanovesicles with Doxorubicin-Loaded Ferritin Cores for Cancer Immunochemotherapy

Interleukin 15 (IL15) is crucial for fostering the survival and proliferation of nature killer (NK) cells and cytotoxic T lymphocytes (CTLs), playing a pivotal role in tumor control. However, IL15 supplementary therapy encounters challenges such as systemic inflammation and non-specific stimulation of cancer cells. Herein, a nanovesicle termed DoxFILN, comprising a membrane presenting IL15/IL15 receptor α complexes (IL15c) and a core of doxorubicin-loaded ferritin (Dox-Fn) are reported. The DoxFILN significantly enhances the densities and activities of intratumoral CTLs and NK cells. Mechanistically, DoxFILN undergoes deshelling in the acidic tumor microenvironment, releasing Dox-Fn and membrane-bound IL15c. Dox-Fn selectively target transferrin receptors on cancerous cells, facilitating intracellular Dox release and inducing immunogenic cell death. Concurrently, membrane-bound IL15c recognizes and activates IL15 receptor β/γc heterodimers, leading to a remarkable increase in the proliferation and activation of CTLs (16-fold and 28-fold) and NK cells (37-fold and 50-fold). The IL15-displaying nanovesicle introduced here holds promise as a potential platform for immunochemotherapy in the treatment of cancer.

Plasma Membrane-Derived Biomimetic Apoptotic Nanovesicles Targeting Inflammation and Cartilage Degeneration for Osteoarthritis

Osteoarthritis (OA) is a degenerative whole-joint disease in which the synovium and joint cartilage become inflamed and damaged. The essential role of inflammation in the development of OA has been recognized recently. Accordingly, simultaneous regulation of local inflammation and tissue degeneration is proposed as a promising therapeutic strategy. Herein, multifunctional biomimetic apoptotic nanovesicles (Apo-NVs) are constructed with plasma membrane derived from apoptotic T cells. The anti-inflammatory microRNA-124 is further encapsulated into Apo-NVs in the hope of achieving an enhanced immunomodulatory effect. It is found that apoptotic nanovesicles, including Apo-NVs and Apo-NVs-miR-124, both efficiently promote the M2 repolarization of M1 macrophages and inhibit the degenerative phenotype of chondrocytes. Further in vivo studies show that Apo-NVs and Apo-NVs-miR-124 alleviate synovial inflammation and protect cartilage tissue from degeneration in OA mice. The study highlights the potential of Apo-NVs in treating OA and other inflammation-related diseases.

A Magnetic-Responsive Biomimetic Nanosystem Coated with Glioma Stem Cell Membranes Effectively Targets and Eliminates Malignant Gliomas

Glioblastoma multiforme (GBM) is among the most challenging malignant brain tumors, making the development of new treatment strategies highly necessary. Glioma stem cells (GSCs) markedly contribute to drug resistance, radiation resistance, and tumor recurrence in GBM. The therapeutic potential of nanomaterials targeting GSCs in GBM urgently needs to be explored. A magnetic-responsive biomimetic nanosystem (FDPM), coated with glioma stem cell membranes (CMs), was designed for the targeted eradication of GSCs as well as their associated tumor cells. Identified nanobodies were extensively characterized with various assays. The application tests on nanomaterials were conducted in vitro and in vivo. The tumor-suppressive effects of the nanosystem were evaluated in vitro and in vivo. FDPM can be artificially directed under magnetic guidance while inheriting various biological functions from CM. Upon intravenous injection, FDPM was drawn to the tumor site by magnetic attraction, where it could cross the blood-brain barrier aided by CM. Its homologous targeting ability originates from active proteins on CM, enabling it to specifically target GSCs and related tumor cells. The encapsulated doxorubicin (DOX) within the nanoparticle then destroyed these tumor cells. FDPM demonstrated excellent biocompatibility and tumor-targeting efficiency, effectively targeting malignant gliomas initiated by GSCs. FDPM significantly reduced tumor cells, inhibited tumor growth, and notably extended the survival of glioma-bearing nude mice. The findings position FDPM as a promising nanoplatform to target GSCs and related tumor cells for improving the therapeutic effect of glioma.

Recent Progress in Nanomedicine for the Diagnosis and Treatment of Alzheimer's Diseases

Alzheimer's disease (AD) is a neurodegenerative disease that causes memory loss and progressive and permanent deterioration of cognitive function. The most challenging issue in combating AD is its complicated pathogenesis, which includes the deposition of amyloid β (Aβ) plaques, intracellular hyperphosphorylated tau protein, neurofibrillary tangles (NFT), etc. Despite rapid advancements in mechanistic research and drug development for AD, the currently developed drugs only improve cognitive ability and temporarily relieve symptoms but cannot prevent the development of AD. Moreover, the blood-brain barrier (BBB) creates a huge barrier to drug delivery in the brain. Therefore, effective diagnostic tools and treatments are urgently needed. In recent years, nanomedicine has provided opportunities to overcome the challenges and limitations associated with traditional diagnostics or treatments. Various types of nanoparticles (NPs) play an essential role in nanomedicine for the diagnosis and treatment of AD, acting as drug carriers to improve targeting and bioavailability across/bypass the BBB or acting as drugs directly on AD lesions. This review categorizes different types of NPs and summarizes their applications in nanomedicine for the diagnosis and treatment of AD. It also discusses the challenges associated with clinical applications and explores the latest developments and prospects of nanomedicine for AD.

Carcinoma-Astrocyte Gap Junction Interruption by a Dual-Targeted Biomimetic Liposomal System to Attenuate Chemoresistance and Treat Brain Metastasis

Brain metastasis contributes substantially to the morbidity and mortality of various malignancies and is characterized by high chemoresistance. Intracellular communication between carcinoma cells and astrocytes through gap junctions, which are assembled mainly by the connexin 43 protein, has been shown to play a vital role in this process. However, effectively blocking the gap junctions between the two cell types remains extremely challenging because of insufficient drug delivery to the target site. Herein, we designed a connexin blocker-carbenoxolone (CBX)-loaded biomimetic liposomal system with artificial liposomes fused with brain metastatic cell and reactive astrocyte membranes (LAsomes) to block gap junctions and attenuate chemoresistance. LAsomes effectively penetrated the blood-brain barrier via semaphorin 4D (SEMA 4D)─Plexin B1 interactions and actively migrated to their source cells via homotypic recognition. Consequently, LAsomes effectively inhibited material transfer and Ca2+ flow from metastatic cells to astrocytes via gap junctions, thereby markedly increasing the sensitivity of metastatic tumor cells to chemotherapy. These results reveal that closing the gap junctions may be a promising therapeutic strategy for intractable brain metastasis.

Innovative utilization of cell membrane-coated nanoparticles in precision cancer therapy

Cell membrane-coated nanoparticles (CMNPs) have recently emerged as a promising platform for cancer therapy. By encapsulating therapeutic agents within a cell membrane-derived coating, these nanoparticles combine the advantages of synthetic nanoparticles and natural cell membranes. This review provides a comprehensive overview of the recent advancements in utilizing CMNPs as effective drug delivery vehicles for cancer therapy. The synthesis and fabrication methods of CMNPs are comprehensively discussed. Various techniques, such as extrusion, sonication, and self-assembly, are employed to coat synthetic nanoparticles with cell membranes derived from different cell types. The cell membrane coating enables biocompatibility, reducing the risk of an immune response and enhancing the stability of the nanoparticles in the bloodstream. Moreover, functionalization strategies for CMNPs, primarily chemical modification, genetic engineering, and external stimuli, are highlighted. The presence of specific cell surface markers on the coated membrane allows targeted drug delivery to cancer cells and maximizes therapeutic efficacy. Preclinical studies utilizing CMNPs for cancer therapy demonstrated the successful delivery of various therapeutic agents, such as chemotherapeutic drugs, nucleic acids, and immunotherapeutic agents, using CMNPs. Furthermore, the article explores the future directions and challenges of this technology while offering insights into its clinical potential.

Recent advances in biomimetic strategies for the immunotherapy of glioblastoma

Immunotherapy is regarded as one of the most promising approaches for treating tumors, with a multitude of immunotherapeutic thoughts currently under consideration for the lethal glioblastoma (GBM). However, issues with immunotherapeutic agents, such as limited in vivo stability, poor blood-brain barrier (BBB) penetration, insufficient GBM targeting, and represented monotherapy, have hindered the success of immunotherapeutic interventions. Moreover, even with the aid of conventional drug delivery systems, outcomes remain suboptimal. Biomimetic strategies seek to overcome these formidable drug delivery challenges by emulating nature's intelligent structures and functions. Leveraging the variety of biological structures and functions, biomimetic drug delivery systems afford a versatile platform with enhanced biocompatibility for the co-delivery of diverse immunotherapeutic agents. Moreover, their inherent capacity to traverse the BBB and home in on GBM holds promise for augmenting the efficacy of GBM immunotherapy. Thus, this review begins by revisiting the various thoughts and agents on immunotherapy for GBM. Then, the barriers to successful GBM immunotherapy are analyzed, and the corresponding biomimetic strategies are explored from the perspective of function and structure. Finally, the clinical translation's current state and prospects of biomimetic strategy are addressed. This review aspires to provide fresh perspectives on the advancement of immunotherapy for GBM.

Peroxynitrite-Responsive Near-Infrared Fluorescent Imaging Guided Synergistic Chemo-Photodynamic Therapy via Biomimetic Metal-Organic Frameworks

Peroxynitrite (ONOO-) plays a crucial role in maintaining cellular redox homeostasis and regulating diffusive processes, cellular transport, and signal transduction. Extensive studies have revealed that increased ONOO- levels during tumor progression are associated with heightened levels of oxidative stress. However, current methods lack noninvasive visualization, immediate reporting, and highly sensitive fluorescence sensing. In light of this, we have designed a biomimetic fluorescent nanoplatform, named Z-C-T@CM, for peroxynitrite-responsive near-infrared fluorescent imaging guided cancer treatment. The nanoplatform comprises tetrakis(4-carboxyphenyl) porphyrin (TCPP) and curcumin (CCM) encapsulated within a zeolitic imidazolate framework-8 (ZIF-8), which is coated with a mouse breast cancer cell membrane for enhanced biocompatibility and targeting, while evading immune clearance. In vitro experimental results demonstrate that the as-prepared nanoplatform exhibits enhanced near-infrared fluorescence emission upon exposure to ONOO-, indicating a significant potential for noninvasive in vivo imaging of ONOO- during tumor progression. Additionally, Z-C-T@CM readily degrades in the tumor microenvironment, releasing TCPP and CCM, enabling a synergistic chemo-photodynamic therapy with near-infrared illumination. Further investigations indicate that Z-C-T@CM efficiently stimulates a tumor immune response and facilitates therapeutic efficiency. Collectively, this work introduces a novel noninvasive strategy for ONOO- detection, shedding new light on the integration of cancer diagnosis and efficient treatment.

Inhibition of Aβ Aggregation and Tau Phosphorylation with Functionalized Biomimetic Nanoparticles for Synergic Alzheimer's Disease Therapy

The main pathological mechanisms of Alzheimer's Disease (AD) are extracellular senile plaques caused by β-amyloid (Aβ) deposition and intracellular neurofibrillary tangles derived from hyperphosphorylated Tau protein (p-Tau). However, it is difficult to obtain a good curative effect because of the poor brain bioavailability of drugs, which is attributed to the blood-brain barrier (BBB) restriction and complicated brain conditions. Herein, HM-DK was proposed for synergistic therapy of AD by using hollow mesoporous manganese dioxide (HM) as a carrier to deliver an Aβ-inhibiting peptide and a Dp-peptide inhibitor of Tau-related fibril formation synergistically. Inspired by 4T1 cancer cells promoting BBB penetration during brain metastasis, a prospective biomimetic nanocarrier (HM-DK@CM) encapsulated by 4T1 cell membranes was designed. After crossing the BBB, HM-DK@CM inhibited Aβ aggregation and prevented Tau phosphorylation simultaneously. Moreover, by taking advantage of the catalase-like activity of HM, HM-DK@CM relieved oxidative stress and altered the microenvironment associated with the development of AD. Compared with the single therapeutic drug, HM-DK@CM restored nerve damage and improved AD mice's learning and memory abilities by decreasing Aβ oligomer, p-Tau protein, and inflammation through various pathways for synergistic therapy, which has broad prospects for the effective treatment of AD.

Sono-Triggered Biomimetically Nanoantibiotics Mediate Precise Sequential Therapy of MRSA-Induced Lung Infection

Bacterial-induced lower respiratory tract infections are a growing global health concern, exacerbated by the inefficacy of conventional antibiotics and delivery methods to effectively target the lower respiratory tract, leading to suboptimal therapeutic outcomes. To address this challenge, this work engineers PBP2a antibody-presenting membrane nanovesicles (AMVs) specifically designed to target the penicillin-binding protein variant on the surface of methicillin-resistant Staphylococcus aureus (MRSA). Concurrently, this work develops pure ciprofloxacin nanoparticles (NanoCip) that, for the first time, exhibits exceptional self-generated sonodynamic properties, attributed to hydrogen-bond-driven self-assembly, while maintaining their inherent pharmacological efficacy. These NanoCip particles are integrated with AMVs to create a novel biomimetic nanomedicine, AMV@NanoCip. This formulation demonstrated remarkable MRSA-targeting affinity in both in vitro and in vivo models, significantly enhancing antibacterial activity. Upon ultrasound stimulation, AMV@NanoCip achieves over 99.99% sterilization of MRSA in vitro, with a reduction exceeding 5.14 Log CFU. Prokaryotic transcriptomic analysis further elucidates the synergistic mechanisms by which AMV@NanoCip, coupled with ultrasound, disrupts the MRSA exoskeleton. In a MRSA-induced pneumonia animal model, AMV@NanoCip+US results in a substantial bacterial load reduction in the lungs (99.99%, 4.02 Log CFU). This sequential treatment strategy (adhesion-membrane disruption-synergistic therapy) offers significant promise as an innovative therapeutic approach for combating bacterial infections.

Application of targeted drug delivery by cell membrane-based biomimetic nanoparticles for inflammatory diseases and cancers

Drug-carrying nanoparticles can be recognized and captured by macrophages and cleared away by the immune system, resulting in reduced drug efficacy and representing the main drawbacks. Biomimetic nanoparticles, which are coated with cell membranes from natural resources, have been applied to address this problem. This type of nanoparticle maintains some specific biological activities, allowing them to carry drugs reaching designated tissues effectively and have a longer time in circulation. This review article aims to summarize recent progress on biomimetic nanoparticles based on cell membranes. In this paper, we have introduced the classification of biomimetic nanoparticles, their preparation and characterization, and their applications in inflammatory diseases and malignant tumors. We have also analyzed the shortcomings and prospects of this technology, hoping to provide some clues for basic researchers and clinicians engaged in this field.

Developing Cell-Membrane-Associated Liposomes for Liver Diseases

Over the past decade, a marked escalation in the prevalence of hepatic pathologies has been observed, adversely impacting the quality of life for many. The predominant therapeutic strategy for liver diseases has been pharmacological intervention; however, its efficacy is often constrained. Currently, liposomes are tiny structures that can deliver drugs directly to targeted areas, enhancing their effectiveness. Specifically, cell membrane-associated liposomes have gained significant attention. Despite this, there is still much to learn about the binding mechanism of this type of liposome. Thus, this review comprehensively summarizes relevant information on cell membrane-associated liposomes, including their clinical applications and future development directions. First, we will briefly introduce the composition and types of cell membrane-associated liposomes. We will provide an overview of their structure and discuss the various types of liposomes associated with cell membranes. Second, we will thoroughly discuss various strategies of drug delivery using these liposomes. Lastly, we will discuss the application and clinical challenges associated with using cell membrane-associated liposomes in treating liver diseases. We will explore their potential benefits while also addressing the obstacles that need to be overcome. Furthermore, we will provide prospects for future development in this field. In summary, this review underscores the promise of cell membrane-associated liposomes in enhancing liver disease treatment and highlights the need for further research to optimize their utilization. In summary, this review underscores the promise of cell membrane-associated liposomes in enhancing liver disease treatment and highlights the need for further research to optimize their utilization.

Biomimetic Nanoparticles for Basic Drug Delivery

Biomimetic nanoparticles (BMNPs) are innovative nanovehicles that replicate the properties of naturally occurring extracellular vesicles, facilitating highly efficient drug delivery across biological barriers to target organs and tissues while ensuring maximal biocompatibility and minimal-to-no toxicity. BMNPs can be utilized for the delivery of therapeutic payloads and for imparting novel properties to other nanotechnologies based on organic and inorganic materials. The application of specifically modified biological membranes for coating organic and inorganic nanoparticles has the potential to enhance their therapeutic efficacy and biocompatibility, presenting a promising pathway for the advancement of drug delivery technologies. This manuscript is grounded in the fundamentals of biomimetic technologies, offering a comprehensive overview and analytical perspective on the preparation and functionalization of BMNPs, which include cell membrane-coated nanoparticles (CMCNPs), artificial cell-derived vesicles (ACDVs), and fully synthetic vesicles (fSVs). This review examines both "top-down" and "bottom-up" approaches for nanoparticle preparation, with a particular focus on techniques such as cell membrane coating, cargo loading, and microfluidic fabrication. Additionally, it addresses the technological challenges and potential solutions associated with the large-scale production and clinical application of BMNPs and related technologies.

Targeted blood-brain barrier penetration and precise imaging of infiltrative glioblastoma margins using hybrid cell membrane-coated ICG liposomes

Surgical resection remains the primary treatment modality for glioblastoma (GBM); however, the infiltrative nature of GBM margins complicates achieving complete tumor removal. Additionally, the blood-brain barrier (BBB) poses a formidable challenge to effective probe delivery, thereby hindering precise imaging-guided surgery. Here, we introduce hybrid cell membrane-coated indocyanine green (ICG) liposomes (HM-Lipo-ICG) as biomimetic near-infrared (NIR) fluorescent probes for targeted BBB penetration and accurate delineation of infiltrative GBM margins. HM-Lipo-ICG encapsulates clinically approved ICG within its core and utilizes a hybrid cell membrane exterior, enabling specific targeting and enhanced BBB permeation. Quantitative assessments demonstrate that HM-Lipo-ICG achieves BBB penetration efficiency 2.8 times higher than conventional ICG liposomes. Mechanistically, CD44 receptor-mediated endocytosis facilitates BBB translocation of HM-Lipo-ICG. Furthermore, HM-Lipo-ICG enables high-contrast NIR imaging, achieving a signal-to-background ratio of 6.5 in GBM regions of an orthotopic glioma mouse model, thereby improving tumor margin detection accuracy fourfold (84.4% vs. 22.7%) compared to conventional ICG liposomes. Application of HM-Lipo-ICG facilitates fluorescence-guided precision surgery, resulting in complete resection of GBM cells. This study underscores the potential of hybrid cell membrane-coated liposomal probes in precisely visualizing and treating infiltrative GBM margins.

Multifunctional Biomimetic Liposomes with Improved Tumor-Targeting for TNBC Treatment by Combination of Chemotherapy, Antiangiogenesis and Immunotherapy

Triple negative breast cancer (TNBC) featuring high relapses and metastasis shows limited clinical therapeutic efficiency with chemotherapy for the extremely complex tumor microenvironment, especially angiogenesis and immunosuppression. Combination of antiangiogenesis and immunotherapy holds promise for effective inhibition of tumor proliferation and invasion, while it remains challenging for specific targeting drug delivery to tumors and metastatic lesions. Here, a multifunctional biomimetic liposome loading Gambogic acid (G/R-MLP) is developed using Ginsenoside Rg3 (Rg3) to substitute cholesterol and cancer cell membrane coating, which is designed to increase long-circulating action by a low immunogenicity and specifically deliver gambogic acid (GA) to tumor site and metastatic lesions by homologous targeting and glucose transporter targeting. After G/R-MLP accumulates in the primary tumors and metastatic nodules, it synergistically enhances the antitumor efficacy of GA, effectively suppressing the tumor growth and lung metastasis by killing tumor cells, inhibiting tumor cell migration and invasion, achieving antiangiogenesis and improving the antitumor immunity. All in all, the strategy combining chemotherapy, antiangiogenesis, and immunotherapy improves therapeutic efficiency and prolonged survival, providing a new perspective for the clinical treatment of TNBC.

Metal nanozymes modulation of reactive oxygen species as promising strategies for cancer therapy

Nanozymes, nanostructured materials emulating natural enzyme activities, exhibit potential in catalyzing reactive oxygen species (ROS) production for cancer treatment. By facilitating oxidative reactions, elevating ROS levels, and influencing the tumor microenvironment (TME), nanozymes foster the eradication of cancer cells. Noteworthy are their superior stability, ease of preservation, and cost-effectiveness compared to natural enzymes, rendering them invaluable for medical applications. This comprehensive review intricately explores the interplay between ROS and tumor therapy, with a focused examination of metal-based nanozyme strategies mitigating tumor hypoxia. It provides nuanced insights into diverse catalytic processes, mechanisms, and surface modifications of various metal nanozymes, shedding light on their role in intra-tumoral ROS generation and applications in antioxidant therapy. The review concludes by delineating specific potential prospects and challenges associated with the burgeoning use of metal nanozymes in future tumor therapies.

Biomimetic nanomedicine cocktail enables selective cell targeting to enhance ovarian Cancer chemo- and immunotherapy

Ovarian cancer is one of the deadliest cancers, and combined chemo- and immunotherapies are potential strategies to combat it. However, the anti-cancer efficacy of the combined therapies may be limited by the non-selective co-delivery of chemotherapy and immunotherapy. Herein, a combined chemo- and immunotherapy is designed to selectively target ovarian tumor (ID8) cells and dendritic cells (DCs) using ID8 cell membrane (IM) and bacterial outer membrane vesicles (OMVs), respectively. Doxorubicin (DOX) and Ovalbumin (OVA) peptide (OVA257-264) are chosen as model chemotherapy and immunotherapy agents, respectively. A DNA nanocube capable of easily loading DOX or OVA257-264 is chosen as the carrier. Firstly, the DNA nanocube is used to load DOX or OVA257-264 to prepare cube-DOX or cube-OVA. This nanocube was then encapsulated with IM to form IM@Cube-DOX and with OMV to form OMV@Cube-OVA. IM@Cube-DOX can be selectively taken up by ID8 cells, leading to effective cell killing, while OMV@Cube-OVA targets and activates DC2.4 cells in vitro. Both IM@Cube-DOX and OMV@Cube-OVA show increased accumulation at ID8 tumors in C57BL/6 mice. Combined IM@Cube-DOX + OMV@Cube-OVA therapy demonstrates better anti-tumor efficacy than non-selective delivery methods such as OMV@(Cube-DOX + Cube-OVA) or IM@(Cube-DOX + Cube-OVA) in ID8-OVA tumor-bearing mice. In conclusion, this study demonstrates a biomimetic delivery strategy that enables selective drug delivery to tumor cells and DCs, thereby enhancing the anti-tumor efficacy of combined chemo- and immunotherapy through the selective delivery strategy.

Genetically Engineered Membrane-Coated Nanoparticles for Enhanced Prostate-Specific Membrane Antigen Targeting and Ferroptosis Treatment of Castration-Resistant Prostate Cancer

Conventional androgen deprivation therapy (ADT) targets the androgen receptor (AR) inhibiting prostate cancer (PCa) progression; however, it can eventually lead to recurrence as castration-resistant PCa (CRPC), which has high mortality rates and lacks effective treatment modalities. The study confirms the presence of high glutathione peroxidase 4 (GPX4) expression, a key regulator of ferroptosis (i.e., iron-dependent program cell death) in CRPC cells. Therefore, inducing ferroptosis in CRPC cells might be an effective therapeutic modality for CRPC. However, nonspecific uptake of ferroptosis inducers can result in undesirable cytotoxicity in major organs. Thus, to precisely induce ferroptosis in CRPC cells, a genetic engineering strategy is proposed to embed a prostate-specific membrane antigen (PSMA)-targeting antibody fragment (gy1) in the macrophage membrane, which is then coated onto mesoporous polydopamine (MPDA) nanoparticles to produce a biomimetic nanoplatform. The results indicate that the membrane-coated nanoparticles (MNPs) exhibit high specificity and affinity toward CRPC cells. On further encapsulation with the ferroptosis inducers RSL3 and iron ions, MPDA/Fe/RSL3@M-gy1 demonstrates superior synergistic effects in highly targeted ferroptosis therapy eliciting significant therapeutic efficacy against CRPC tumor growth and bone metastasis without increased cytotoxicity. In conclusion, a new therapeutic strategy is reported for the PSMA-specific, CRPC-targeting platform for ferroptosis induction with increased efficacy and safety.

Homologous Tumor Cell-Derived Biomimetic Nano-Trojan Horse Integrating Chemotherapy with Genetherapy for Boosting Triple-Negative Breast Cancer Therapy

Triple-negative breast cancer (TNBC) is a subtype of breast cancer that carries the worst prognosis and lacks specific therapeutic targets. To achieve accurate "cargos" delivery at the TNBC site, we herein constructed a novel biomimetic nano-Trojan horse integrating chemotherapy with gene therapy for boosting TNBC treatment. Briefly, we initially introduce the diselenide-bond-containing organosilica moieties into the framework of mesoporous silica nanoparticles (MONs), thereby conferring biodegradability to intratumoral redox conditions in the obtained MONSe. Subsequently, doxorubicin (Dox) and therapeutic miR-34a are loaded into MONSe, thus achieving the combination of chemotherapy and gene-therapy. After homologous tumor cell membrane coating, the ultimate homologous tumor cell-derived biomimetic nano-Trojan horse (namely, MONSe@Dox@miR-34a@CM) can selectively enter the tumor cells in a stealth-like fashion. Notably, such a nanoplatform not only synergistically eradicated the tumor but also inhibited the proliferation of breast cancer stem-like cells (BCSCs) in vitro and in vivo. With the integration of homologous tumor cell membrane-facilitated intratumoral accumulation, excellent biodegradability, and synergistic gene-chemotherapy, our biomimetic nanocarriers hold tremendous promise for the cure of TNBC in the future.

Red blood cells based nanotheranostics: A smart biomimetic approach for fighting against cancer

The technique of engineering drug delivery vehicles continues to develop, which bring enhancements in working more efficiently and minimizing side effects to make it more effective and safer. The intense capability of therapeutic agents to remain undamaged in a harsh extracellular environment is helpful to the success of drug development efforts. With this in mind, alterations of biopharmaceuticals with enhanced stability and decreased immunogenicity have been an increasingly active focus of such efforts. Red blood cells (RBCs), also known as erythrocytes have undergone extensive scrutiny as potential vehicles for drug delivery due to their remarkable attributes over the years of research. These include intrinsic biocompatibility, minimal immunogenicity, flexibility, and prolonged systemic circulation. Throughout the course of investigation, a diverse array of drug delivery platforms based on RBCs has emerged. These encompass genetically engineered RBCs, non-genetically modified RBCs, and RBC membrane-coated nanoparticles, each devised to cater to a range of biomedical objectives. Given their prevalence in the circulatory system, RBCs have gained significant attention for their potential to serve as biomimetic coatings for artificial nanocarriers. By virtue of their surface emulation capabilities and customizable core materials, nanocarriers mimicking these RBCs, hold considerable promise across a spectrum of applications, spanning drug delivery, imaging, phototherapy, immunomodulation, sensing, and detection. These multifaceted functionalities underscore the considerable therapeutic and diagnostic potential across various diseases. Our proposed review provides the synthesis of recent strides in the theranostic utilization of erythrocytes in the context of cancer. It also delves into the principal challenges and prospects intrinsic to this realm of research. The focal point of this review pertains to accentuating the significance of erythrocyte-based theranostic systems in combating cancer. Furthermore, it precisely records the latest and the most specific methodologies for tailoring the attributes of these biomimetic nanoscale formulations, attenuating various discoveries for the treatment and management of cancer.

FeP-Based Nanotheranostic Platform for Enhanced Phototherapy/Ferroptosis/Chemodynamic Therapy

Ferroptosis is an iron-dependent and lipid peroxides (LPO)-overloaded programmed damage cell death, induced by glutathione (GSH) depletion and glutathione peroxide 4 (GPX4) inactivation. However, the inadequacy of endogenous iron and reactive oxygen species (ROS) restricts the efficacy of ferroptosis. To overcome this obstacle, a near-infrared photo-responsive FeP@PEG NPs is fabricated. Exogenous iron pool can enhance the effect of ferroptosis via the depletion of GSH and further regulate GPX4 inactivation. Generation of ·OH derived from the Fenton reaction is proved by increased accumulation of lipid peroxides. The heat generated by photothermal therapy and ROS generated by photodynamic therapy can enhance cell apoptosis under near-infrared (NIR-808 nm) irradiation, as evidenced by mitochondrial dysfunction and further accumulation of lipid peroxide content. FeP@PEG NPs can significantly inhibit the growth of several types of cancer cells in vitro and in vivo, which is validated by theoretical and experimental results. Meanwhile, FeP@PEG NPs show excellent T2-weighted magnetic resonance imaging (MRI) property. In summary, the FeP-based nanotheranostic platform for enhanced phototherapy/ferroptosis/chemodynamic therapy provides a reliable opportunity for clinical cancer theranostics.

Recent advances in biomimetic cell membrane-camouflaged nanoparticles for cancer therapy

The emerging strategy of biomimetic nanoparticles (NPs) via cellular membrane camouflage holds great promise in cancer therapy. This scholarly review explores the utilization of cellular membranes derived from diverse cellular entities; blood cells, immune cells, cancer cells, stem cells, and bacterial cells as examples of NP coatings. The camouflaging strategy endows NPs with nuanced tumor-targeting abilities such as self-recognition, homotypic targeting, and long-lasting circulation, thus also improving tumor therapy efficacy overall. The comprehensive examination encompasses a variety of cell membrane camouflaged NPs (CMCNPs), elucidating their underlying targeted therapy mechanisms and delineating diverse strategies for anti-cancer applications. Furthermore, the review systematically presents the synthesis of source materials and methodologies employed in order to construct and characterize these CMCNPs, with a specific emphasis on their use in cancer treatment.

Cancer cell membrane-camouflaged paclitaxel/PLGA nanoparticles for targeted therapy against lung cancer

Paclitaxel (PTX) is a first-line drug for the treatment of lung cancer, but its targeting and therapeutic effect are unsatisfactory. Herein, lung cancer cell (A549) membrane biomimetic PTX-loaded poly (lactic-co-glycolic acid) (PLGA) nanoparticles (AM@PTX-NPs) were constructed to eliminate the shortcomings of PTX. The AM@PTX-NPs were successfully prepared with a high drug loading efficiency (10.90±0.06 %). Moreover, transmission electron microscopy, SDS-PAGE, and western blotting proved that AM@PTX-NPs were spherical nanoparticles camouflaged by the A549 cell membrane. Both in vitro and in vivo assays revealed that the AM@PTX-NPs displayed outstanding targeting capacity due to A549 membrane modification. The cytotoxicity experiment showed that the developed biomimetic formulation was able to effectively reduce the proliferation of A549 cells. Moreover, AM@PTX-NPs exhibited a significant tumor growth inhibition rate (73.00 %) with good safety in the tumor-bearing mice, which was higher than that of the PTX-NPs without A549 membrane coating (37.39 %). Overall, the constructed bioinspired vector could provide a novel platform for the PTX delivery and demonstrated a promising strategy for the targeted cancer treatment.

Engineered Cell Membrane-Coated Nanoparticles: New Strategies in Glioma Targeted Therapy and Immune Modulation

Gliomas, the most prevalent primary brain tumors, pose considerable challenges due to their heterogeneity, intricate tumor microenvironment (TME), and blood-brain barrier (BBB), which restrict the effectiveness of traditional treatments like surgery and chemotherapy. This review provides an overview of engineered cell membrane technologies in glioma therapy, with a specific emphasis on targeted drug delivery and modulation of the immune microenvironment. This study investigates the progress in engineered cell membranes, encompassing physical, chemical, and genetic alterations, to improve drug delivery across the BBB and effectively target gliomas. The examination focuses on the interaction of engineered cell membrane-coated nanoparticles (ECM-NPs) with the TME in gliomas, emphasizing their potential to modulate glioma cell behavior and TME to enhance therapeutic efficacy. The review further explores the involvement of ECM-NPs in immunomodulation techniques, highlighting their impact on immune reactions. While facing obstacles related to membrane stability and manufacturing scalability, the review outlines forthcoming research directions focused on enhancing membrane performance. This review underscores the promise of ECM-NPs in surpassing conventional therapeutic constraints, proposing novel approaches for efficacious glioma treatment.

Tumor Cell Membrane-Encapsulated MLA Solid Lipid Nanoparticles for Targeted Diagnosis and Radiosensitization Therapy of Cutaneous Squamous Cell Carcinoma

Squamous cell carcinoma (SCC) is a common nonmelanoma skin cancer. Radiotherapy plays an integral role in treating SCC due to its characteristics, such as diminished intercellular adhesion, heightened cell migration and invasion capabilities, and immune evasion. These problems lead to inaccurate tumor boundary positioning and radiotherapy tolerance in SCC treatment. Thus, accurate localization and enhanced radiotherapy sensitivity are imperative for effective SCC treatment. To address the existing limitations in SCC therapy, we developed monoglyceride solid lipid nanoparticles (MG SLNs) and enveloped them with the A431 cell membrane (A431 CM) to create A431@MG. The characterization results showed that A431@MG was spherical. Furthermore, A431@MG had specific targeting for A431 cells. In A431 tumor-bearing mice, A431@MG demonstrated prolonged accumulation within tumors, ensuring precise boundary localization of SCC. We further advanced the approach by preparing MG SLNs encapsulating 5-aminolevulinic acid methyl ester (MLA) and desferrioxamine (DFO) with an A431 CM coating to yield A431@MG-MLA/DFO. Several studies have revealed that DFO effectively reduced iron content, impeding protoporphyrin IX (PpIX) biotransformation and promoting PpIX accumulation. Simultaneously, MLA was metabolized into PpIX upon cellular entry. During radiotherapy, the heightened PpIX levels enhanced reactive oxygen species (ROS) generation, inducing DNA and mitochondrial damage and leading to cell apoptosis. In A431 tumor-bearing mice, the A431@MG-MLA/DFO group exhibited notable radiotherapy sensitization, displaying superior tumor growth inhibition. Combining A431@MG-MLA/DFO with radiotherapy significantly improved anticancer efficacy, highlighting its potential to serve as an integrated diagnostic and therapeutic strategy for SCC.

Bacterial outer membrane vesicle-cancer cell hybrid membrane-coated nanoparticles for sonodynamic therapy in the treatment of breast cancer bone metastasis

Breast cancer bone metastasis is a terminal-stage disease and is typically treated with radiotherapy and chemotherapy, which causes severe side effects and limited effectiveness. To improve this, Sonodynamic therapy may be a more safe and effective approach in the future. Bacterial outer membrane vesicles (OMV) have excellent immune-regulating properties, including modulating macrophage polarization, promoting DC cell maturation, and enhancing anti-tumor effects. Combining OMV with Sonodynamic therapy can result in synergetic anti-tumor effects. Therefore, we constructed multifunctional nanoparticles for treating breast cancer bone metastasis. We fused breast cancer cell membranes and bacterial outer membrane vesicles to form a hybrid membrane (HM) and then encapsulated IR780-loaded PLGA with HM to produce the nanoparticles, IR780@PLGA@HM, which had tumor targeting, immune regulating, and Sonodynamic abilities. Experiments showed that the IR780@PLGA@HM nanoparticles had good biocompatibility, effectively targeted to 4T1 tumors, promoted macrophage type I polarization and DC cells activation, strengthened anti-tumor inflammatory factors expression, and presented the ability to effectively kill tumors both in vitro and in vivo, which showed a promising therapeutic effect on breast cancer bone metastasis. Therefore, the nanoparticles we constructed provided a new strategy for effectively treating breast cancer bone metastasis.