Membrane Nanovesicles Research Articles

Cannabidiol–loaded biomimetic macrophage membrane vesicles against post–traumatic stress disorder assisted by ultrasound

Post-traumatic stress disorder (PTSD), which normally follows psychological trauma, has been increasingly studied as a brain disease. However, the blood-brain barrier (BBB) prevents conventional drugs for PTSD from entering the brain. Our previous studies proved the effectiveness of cannabidiol (CBD) against PTSD, but low water solubility, low brain targeting efficiency and poor bioavailability restricted its applications. Here, a bionic delivery system, camouflage CBD-loaded macrophage-membrane nanovesicles (CMNVs), was constructed via co-extrusion of CBD with macrophage membranes, which had inflammatory and immune escape properties. In vitro anti-inflammatory, cellular uptake and pharmacokinetic experiments respectively verified the anti-inflammatory, inflammatory targeting and immune escape properties of CMNVs. Brain targeting and excellent anti-PTSD effects of CMNVs had been validated in vivo by imaging and pharmacodynamics studies. In our study, the potential of ultrasound to open BBBs and improve the brain-targeted delivery of CBD was evaluated. In conclusion, this cell membrane bionic delivery system assisted with ultrasound had good therapeutic effect against PTSD mice, which is expected to help convey CBD to inflammatory areas within the brain and alleviate the symptoms of PTSD.

Erythrocytes-camouflaged nanoparticles: a promising delivery system for drugs and vaccines

Erythrocytes-camouflaged nanoparticles is an in vivo delivery system that uses erythrocytes or erythrocyte membrane nano vesicles as carriers for drugs, enzymes, peptides and antigens. This system has the advantages of good biocompatibility, long circulation cycle and efficient targeting. This review summarizes the type of carriers, their development history, the application of delivery strategies as well as their limitations and future challenges. Lastly, future directions and key issues in the development of this system are discussed.

Preparation and Tumor Targeting Analysis of Cell Membrane Nanovesicles Derived from Breast Cancer Cells

To prepare cell membrane nanovesicles (NVs) derived from breast cancer cells, to explore their basic characteristics, tumor cell endocytosis, and in vivo distribution in a tumor-bearing mouse model, and to investigate their tumor targeting properties. 4T1 breast cancer cells were cultured in vitro. The cell membrane of 4T1 cells was isolated through ultracentrifugation and NVs were formulated with a liposome extruder. The size distribution of NVs was determined by way of dynamic light scattering, and the morphology properties of the NVs were examined with transmission electron microscope. The stability of NVs was analyzed by measuring the diameter changes of NVs submerged in phosphate-buffered saline (PBS). The biocompatibility of NVs was investigated by measuring the viability of dendritic cells treated with NVs at different concentrations (5, 10, 20, 50, and 100 mg·L -1) by CCK-8 assay. Fluorescence microscopy was used to analyze the cellular uptake of NVs by breast cancer cells. A mice model of breast cancer model was established with mice bearing subcutaneous xenograft of 4T1 cells. The mice were treated with Cy5.5-labeled NVs injected via the tail vein and the in vivo distribution of NVs was analyzed with an imaging system for small live animals. The results showed that NVs derived from 4T1 breast cancer cells were successfully prepared. The NVs had a mean diameter of 123.2 nm and exhibited a hollow spherical structure under transmission electron microscope. No obvious change in the size of the NVs was observed after 7 days of incubation in PBS solution. CCK-8 assay results showed that the viability of dendritic cells treated with NVs at different concentrations was always higher than 90%. Fluorescence microscopic imaging showed that NVs could be efficiently internalized into breast cancer cells. in vivo biodistribution analysis revealed that breast cancer cell-derived NVs showed higher distribution in tumor tissue than the NVs prepared with normal cells did. We successfully prepared cell membrane NVs derived from 4T1 breast cancer cells. These NVs had efficient cellular uptake by breast cancer cells and sound tumor targeting properties.

Placental extracellular vesicles in maternal-fetal communication during pregnancy.

For several years, a growing number of studies have highlighted the pivotal role of placental extracellular vesicles (EVs) throughout pregnancy. These membrane nanovesicles, heterogeneous in nature, composition and origin, are secreted by several trophoblastic cell types and are found in both the maternal and fetal compartments. They can be uptaken by recipient cells and drive a wide variety of physiological and pathological processes. In this review, we provide an overview of the different described roles of placental EVs in various aspects of normal pregnancy, from placenta establishment to maternal immune tolerance towards the fetus and protection against viral infections. In the second part, we present selected examples of pathological pregnancies in which placental EVs are involved, such as gestational diabetes mellitus, pre-eclampsia, and congenital infections. Since the abundance and/or composition of placental EVs is deregulated in maternal serum during pathological pregnancies, this makes them interesting candidates as non-invasive biomarkers for gestational diseases and opens a wide field of translational perspectives.

Engineered drug-loaded cellular membrane nanovesicles for efficient treatment of postsurgical cancer recurrence and metastasis

Cancer recurrence and metastasis are still common causes of postsurgery death in patients with solid tumors, suggesting that additional consolidation therapeutic strategies are necessary. We have previously found that oxaliplatin (OXA) treatment causes further up-regulation of CD155, which is abundantly expressed in tumors for resulting in increased sensitivity of cancer to anti-CD155 therapy. Here, we report O-TPNVs, which are TIGIT-expressing cell membrane and platelet cell membrane fusion nanovesicles (TPNVs) loaded with OXA. Platelet-derived membrane components enable O-TPNVs to target postsurgery wounds and interact with circulating tumor cells (CTCs). OXA directly kills residual tumor cells and CTCs, induces immunogenic cell death, and activates the immune system. TPNVs bind to CD155 on tumor cells, block the CD155/TIGIT pathway, and restore CD8+ T cell activity. In vivo analyses reveal that O-TPNVs achieve synergistic chemotherapeutic and immunotherapeutic effects, effectively inhibiting the recurrence and metastasis of triple-negative breast cancer (4T1) after surgery.

Involvement of Bacterial Extracellular Membrane Nanovesicles in Infectious Diseases and Their Application in Medicine.

Bacterial extracellular membrane nanovesicles (EMNs) are attracting the attention of scientists more and more every year. These formations are involved in the pathogenesis of numerous diseases, among which, of course, the leading role is occupied by infectious diseases, the causative agents of which are a range of Gram-positive and Gram-negative bacteria. A separate field for the study of the role of EMN is cancer. Extracellular membrane nanovesicles nowadays have a practical application as vaccine carriers for immunization against many infectious diseases. At present, the most essential point is their role in stimulating immune response to bacterial infections and tumor cells. The possibility of nanovesicles' practical use in several disease treatments is being evaluated. In our review, we listed diseases, focusing on their multitude and diversity, for which EMNs are essential, and also considered in detail the possibilities of using EMNs in the therapy and prevention of various pathologies.

R11 modified tumor cell membrane nanovesicle-camouflaged nanoparticles with enhanced targeting and mucus-penetrating efficiency for intravesical chemotherapy for bladder cancer.

Intravesical chemotherapy is generally used in the clinic for treating bladder cancer (BCa), but its efficacy is limited due to the permeation barrier and side effects caused by the off-targeting of normal urothelial cells. In this study, BCa cell-derived membrane nanovesicles were used as drug carriers, and their homologous tumor-targeting capacity was utilized. A BCa-targeting hendeca-arginine peptide was functionalized onto the nanovesicles to impart a mucus-penetrating ability and thus overcome the permeation barrier. The tumor-targeting and mucus-penetrating nanovesicles were stable in urine, were highly permeable to the glycosaminoglycan layer, and specifically targeted BCa. The vesicles were internalized through caveolin-mediated endocytosis, were transported to nonlysosome-localized intracellular regions, and efficiently infiltrated bladder tumor spheroids. In in vivo intravesical chemotherapy, the nanovesicles achieved chemo-resection in murine orthotopic BCa models. This BCa-targeting and mucus-penetrating drug delivery system may be promising for the intravesical chemotherapy of BCa.

Brain-targeted exosome-mimetic cell membrane nanovesicles with therapeutic oligonucleotides elicit anti-tumor effects in glioblastoma animal models.

The brain-targeted delivery of therapeutic oligonucleotides has been investigated as a new treatment modality for various brain diseases, such as brain tumors. However, delivery efficiency into the brain has been limited due to the blood-brain barrier. In this research, brain-targeted exosome-mimetic cell membrane nanovesicles (CMNVs) were designed to enhance the delivery of therapeutic oligonucleotides into the brain. First, CMNVs were produced by extrusion with isolated C6 cell membrane fragments. Then, CMNVs were decorated with cholesterol-linked T7 peptides as a targeting ligand by hydrophobic interaction, producing T7-CMNV. T7-CMNV was in aqueous solution maintained its nanoparticle size for over 21 days. The targeting and delivery effects of T7-CMNVs were evaluated in an orthotopic glioblastoma animal model. 2'-O-metyl and cholesterol-TEG modified anti-microRNA-21 oligonucleotides (AMO21c) were loaded into T7-CMNVs, and biodistribution experiments indicated that T7-CMNVs delivered AMO21c more efficiently into the brain than CMNVs, scrambled T7-CMNVs, lipofectamine, and naked AMO21c after systemic administration. In addition, AMO21c down-regulated miRNA-21 (miR-21) levels in glioblastoma tissue most efficiently in the T7-CMNVs group. This enhanced suppression of miR-21 resulted in the up-regulation of PDCD4 and PTEN. Eventually, brain tumor size was reduced in the T7-CMNVs group more efficiently than in the other control groups. With stability, low toxicity, and targeting efficiency, T7-CMNVs may be useful to the development of oligonucleotide therapy for brain tumors.

Exosome secretion and cellular response of DU145 and PC3 after exposure to alpha radiation

Exosomes are spherical membrane nanovesicles secreted from cells, and they play an important role in tumor immune response, metastasis, angiogenesis, and survival. Studies investigating exosomes isolated from cells exposed to photon radiation commonly used in conventional radiotherapy demonstrate the influence of this type of radiation on exosome characteristics and secretion. There is currently no research investigating the effects of densely ionizing particles such as protons and alpha radiation on exosomes. Thus we have evaluated the cellular response of human prostate cancer cells exposed to 0, 2, and 6 Gy of alpha radiation emitted from the Am-241 source. Irradiated PC3 and DU145 cell lines, characterized by differences in radiosensitivity, were studied using apoptosis, LDH, and IL-6 assays. Additionally, the corresponding concentration and size of isolated exosomes were measured using NTA. We found that exposure to ionizing radiation resulted in gross changes in viability and cell damage. There were increased amounts of apoptotic or necrotic cells as a function of radiation dose. We demonstrated that irradiated PC3 cells secrete higher quantities of exosomes compared to DU145 cells. Additionally, we also found no statistical difference in exosome size for control and irradiated cells.

Effects of Cancer Cell-Derived Nanovesicle Vaccines Produced by the Oxidative Stress-Induced Expression of DAMP and Spontaneous Release/Filter Extrusion in the Interplay of Cancer Cells and Macrophages.

Photodynamic therapy (PDT)-based cancer vaccines are shown to be more effective modalities for treating cancer in animal models compared to other methods used to generate cancer cell-derived vaccines. The higher efficacy seems to stem from the generation of cell membrane nanovesicles or fragments that carry both cancer cell-specific antigens and high surface content of damage-associated molecular pattern (DAMP) molecules induced by oxidative stress. To develop more effective cancer vaccines in this direction, we explored the generation of cancer vaccines by applying different sources of oxidative stress on cancer cell cultures followed by spontaneous release or filter extrusions to produce cancer cell-derived DAMP-expressing nanovesicles. Through an in-vitro test based on the co-culture of cancer cells and macrophages, it was found that the nanovesicle vaccines generated by HO are as effective as those generated by PDT in diminishing cancer cell culture masses, providing a simpler way to manufacture vaccines. In addition, the nanovesicle vaccines produced by filter extrusion are as potent as those produced by spontaneous release, rendering a more stable way for vaccine production.

Activated platelet membrane nanovesicles recruit neutrophils to exert the antitumor efficiency.

Platelets play a crucial role in the recruitment of neutrophils, mediated by P-selectin, CCL5, and ICAM-2. In this study, we prepared platelet membrane nanovesicles from activated platelets. Whether activated platelet membrane nanovesicles can recruit neutrophils has not been reported, nor has their role in antitumor immunity. The results of SDS-PAGE showed that the platelet membrane nanovesicles retained almost all the proteins of platelets. Western blotting showed that both the activated platelets and the platelet membrane nanovesicles expressed P-selectin, ICAM-2, and CCL5. In vivo results of a mouse model of breast cancer-transplanted tumor showed that tumor volume reduced significantly, Ki-67-positive tumor cells decreased, and TUNEL-positive tumor cells increased in tumors after treatment with activated platelet membrane nanovesicles (aPNs). After treatment with aPNs, not only the number of neutrophils, CD8+, CD4+ T cells, and B cells increased, but also IL-12, TNF-α, and IFN-γ levels elevated significantly in tumor tissues.

The Role of Exosomes as Mediators of Neuroinflammation in the Pathogenesis and Treatment of Alzheimer's Disease.

Alzheimer’s disease (AD) is a common neurodegenerative disease characterized by progressive dementia. Accumulation of β–amyloid peptide 1–42 and phosphorylation of tau protein in the brain are the two main pathological features of AD. However, comprehensive studies have shown that neuroinflammation also plays a crucial role in the pathogenesis of AD. Neuroinflammation is associated with neuronal death and abnormal protein aggregation and promotes the pathological process of β-amyloid peptide 1–42 and tau protein. The inflammatory components associated with AD include glial cells, complement system, cytokines and chemokines. In recent years, some researchers have focused on exosomes, a type of membrane nano vesicles. Exosomes can transport proteins, lipids, microRNAs and other signaling molecules to participate in a variety of signaling pathways for signal transmission or immune response, affecting the activity of target cells and participating in important pathophysiological processes. Therefore, exosomes play an essential role in intercellular communication and may mediate neuroinflammation to promote the development of AD. This paper reviews the occurrence and development of neuroinflammation and exosomes in AD, providing a deeper understanding of the pathogenesis of AD. Furthermore, the role of exosomes in the pathogenesis and treatment of AD is further described, demonstrating their potential as therapeutic targets for neuroinflammation and AD in the future.

"Cell Membrane Nano Vesicles as Drug Carriers: Biomedical Applications"

Mahfuzul Islam* Author Affiliations Department of pharmacy, Daffodil International University, Bangladesh Received: February 18, 2022 | Published: March 01, 2022 Corresponding author: Mahfuzul Islam, Department of pharmacy, Daffodil International University, Bangladesh DOI: 10.26717/BJSTR.2022.42.006724

Leveraging biomimetic synthesis strategy for next-generation dendritic cell nanovaccines.

The activation of CD8+ cytotoxic T-lymphocytes (CTLs) plays the central role in cancer immunotherapy, which depends on the efficient recognition of peptide-major histocompatibility complex (pMHC) by the T cell receptor (TCR) for the first signal, and B7-CD28 co-stimulating for the second signal. To achieve the potent immune stimulatory effect, a genetically engineered cellular membrane nanovesicles platform that integrates antigen self-presentation and immunosuppression reversal (ASPIRE) for cancer immunotherapy was designed. In preclinical mouse models, ASPIRE could markedly improve antigen delivery to lymphoid organs and generate broad-spectrum T-cell responses that eliminate established tumors. This review highlights that the ASPIRE system represents a novel strategy for personalized cancer immunotherapy.

Near-Infrared Responsive Membrane Nanovesicles Amplify Homologous Targeting Delivery of Anti-PD Immunotherapy against Metastatic Tumors.

The major obstacles of anti-PD therapy in metastatic tumors are limited drug delivery in primary tumors and metastatic foci, and the lack of tumor-infiltrating lymphocytes (TILs). Here, the authors constructed a novel cellular membrane nanovesicles platform (M/IR NPs) based on homologous targeting and near-infrared (NIR) responsive release strategy to potentiate PD-1/PD-L1 blockade therapy against metastatic tumors. In tumor-bearing mice, biomimetic M/IR NPs targeted both primary tumors and their lung metastases. Upon laser irradiation, M/IR NPs reduced cancer-associated fibroblasts (CAFs) in tumor microenvironment, thus increasing the penetration of TILs. When shed from homologous tumor cell membranes, positively charged nanoparticles (IR NPs) core can capture released tumor-associated antigens, thereby enhancing the antigen-presenting ability of DCs to activate cytotoxic T lymphocytes. When the photothermal conversion temperature under NIR-laser is higher than 42°C, M/IR NPs initiated the rupture of cell membranes and the responsive release of PD-1/PD-L1 inhibitor BMS, which significantly attenuated tumor-associated immunosuppression and synergistically induced T cellular immunity to inhibit the tumor growth and metastasis. Overall, biomimetic M/IR NPs can improve the targeting and therapeutic efficacy of anti-PD therapy in primary tumors and metastases, opening up a new avenue for the diagnosis and treatment of metastatic tumors in the future.

Extracellular vesicles and metabolic diseases: Dangerous liaisons

Extracellular vesicles (EVs) correspond to a heterogeneous set of membrane nanovesicles secreted in the extracellular medium and circulating in the various fluids of the body. These EVs convey biological material (proteins, lipids, nucleic acids) that they can transfer to target cells/tissues thus modulating their response and/or phenotype. The metabolic dysfunctions characterizing metabolic diseases associated with obesity are associated with changes in circulating EV concentrations as well as alterations in their content. The growing interest in EVs as new vectors of intercellular communication has led to question about their role in the development of metabolic complications. In this review, we will discuss the literature on circulating EVs as potential markers of metabolic diseases and then detail inter-organ dialogue based on this EV trafficking underlying the development of related obesity. Finally, we will discuss future avenues of research that will help to better understand the link between EVs and metabolic diseases.

Cellular nanovesicles with bioorthogonal targeting enhance photodynamic/photothermal therapy in psoriasis

The interaction between over-proliferating keratinocytes and excessive activated immune cells contributes to the development and progression of psoriasis. Photodynamic therapy (PDT)/photothermal therapy (PTT) is a promising method to treat skin diseases due to their synergistic effect and low side effect. Cell membrane is an ideal cell-mediated drug delivery platform with inherent biocompatibility, but lacks of specific targeting properties to increase drug accumulation in the psoriatic site. Here, we develop a new PDT/PTT strategy to treat psoriasis, based on cell membrane functionalization by metabolic glycoengineering with unnatural sugars, which label cell membranes with chemical tags for subsequent targeting. In our study, in order to enhance the PDT/PTT effect, N3-labeled cell membrane-derived nanovesicles coated with IR-780 nanoparticals (N3-NV-INPs) are constructed, which can specifically recognize DBCO-modified psoriatic lesions through bioorthogonal click chemistry to achieve targeted PDT/PTT effect. The results showed that N3-NV-INPs could specifically target the psoriatic lesions, enhance the synergistic effect of PDT/PTT under the irradiation of near-infrared light, exhaust excessive proliferation of keratinocytes, regulate immunity, reduce the release of cytokines, such as IL-17, IL-22, TNF-α, improve epidermal hyperplasia, and effectively relieve the symptoms of psoriasis. Taken together, we constructed cellular nanovesicles based on an alternative artificial targeting strategy to enhance PDT/PTT effect in psoriasis, which shows great potential in clinical application. STATEMENT OF SIGNIFICANCE: The major challenge in the treatment of psoriasis is how to effectively deliver drugs to the lesions to exhaust overproliferating keratinocytes and modulate immunity. A newly-developed cell membrane-coating technology combined with biorthogonal targeted delivery promotes more drug accumulation at the lesions of the disease. Incorporation of an effective photosensitizer into the lesions of psoriasis site results in exert PDT/PTT effect under the irradiation of near-infrared light. The synergistic PDT/PTT effect can effectively exhaust keratinocytes and immune cells in the epidermis and dermis, reduce the release of inflammatory cytokines, and relieve the symptoms of psoriasis. This unique functional cell membrane nanovesicles combined with bioorthogonal targeting is applied to enhance the PDT/PTT effect in psoriasis and may provide a solution for the clinical treatment of other inflammatory skin diseases.

CM-Dil Staining and SEC of Plasma as an Approach to Increase Sensitivity of Extracellular Nanovesicles Quantification by Bead-Assisted Flow Cytometry.

The quantification of the specific disease-associated populations of circulating extracellular membrane nanovesicles (ENVs) has opened up new opportunities for liquid biopsy in cancer and other chronic diseases. However, the sensitivity of such methods is mediated by an optimal combination of the isolation and labeling approaches, and is not yet sufficient for routine clinical application. The presented study aimed to develop, characterize, and explore a new approach to non-specific ENV staining, followed by size-exclusive chromatography (SEC), which allows us to increase the sensitivity of bead-assisted flow cytometry. Plasma from healthy donors was purified from large components, stained with lipophilic CM-Dil dye, and fractionated by means of SEC. The obtained fractions were analyzed in terms of particle size and concentration using NTA, as well as vesicular markers and plasma protein content via dot-blotting. We characterized the process of CM-Dil-stained plasma fractionation in detail and indicated the fractions with optimal characteristics. Finally, we explored the sensitivity of on-bead flow cytometry for the analysis of specific populations of plasma ENVs and demonstrated the advantages and limitations of the proposed technique.

Терапевтические мишени при коагулопатии COVID-19

В обзоре представлены сведения о некоторых биохимических и клеточных механизмах патогенеза потенциально смертельного вирусного заболевания, получившего название COVID-19, провоцируемого вирусами из семейства коронавирусов SARS-CoV-2. Наибольшую опасность для жизни и здоровья пациентов представляет коагулопатия, обусловленная ответной реакцией на инфекцию — чрезмерной генерацией клетками пациента внеклеточных мембранных нановезикул (ВМН), которые могут спровоцировать активизацию гемостаза, приводящую к разрушительной полиорганной недостаточности. Вирусы также способны генерировать внеклеточные везикулы, называемые виросомами. Встраивая вирусные компоненты в свои виросомы, вирусы повышают персистентность за счет маскировки своих геномов, умножая вирусную инфекцию. В статье охарактеризованы свойства нейтрофильных гранулоцитов, активирующихся при инфицировании, и представлены сведения о молекулярных механизмах действия их компонентов при попадании во внеклеточное пространство. ВМН уже имеют практическое применение в качестве вакцинных носителей для иммунизации человека и животных против многих инфекционных заболеваний. В настоящее время актуальнейшей темой, обуславливающей большой практический интерес, стала роль ВМН в индуцировании иммунитета против коронавирусной инфекции. Охарактеризованы другие возможные терапевтические мишени. Virus-induced coagulopathy is a typical example of the tight connection between inflammation and thrombosis. These two reactions are linked by pro-inflammatory agents, generated by activated neutrophils and their neutrophil extracellular traps (NETs). Extracellular membrane nanobubbles (EMNs), formed by a wide variety of cell types, have recently been identified as new entrants that play a key role in coagulopathy. EMNs directly and indirectly activate coagulation systems that lead to the further upregulation of inflammation and life-threatening organ dysfunction and thrombosis. EMNs are known to be responsible for the secretion, exchange, and transmission of important active biomolecules in COVID-19. Indeed, EMNs represent an essential mechanism in intercellular communication, and the roles of EMNs in infection and thrombosis have been increasingly recognized. The extracellular microvesicles of viruses, virosomes, represent a new type of infectious agents, which determines new therapeutic goals in solving the problems of controlling viral infections. Understanding the biological nature of all these microvesicles when studying them in vivo is of paramount importance for the development of diagnostic and therapeutic methods.

Cellular signaling cross-talk between different cardiac cell populations: an insight into the role of exosomes in the heart diseases and therapy.

Exosomes are a subgroup of extracellular bilayer membrane nanovesicles that are enriched in a variety of bioactive lipids, receptors, transcription factors, surface proteins, DNA, and noncoding RNAs. They have been well recognized to play essential roles in mediating intercellular signaling by delivering bioactive molecules from host cells to regulate the physiological processes of recipient cells. In the context of heart diseases, accumulating studies have indicated that exosome-carried cellular proteins and noncoding RNA derived from different types of cardiac cells, including cardiomyocytes, fibroblasts, endothelial cells, immune cells, adipocytes, and resident stem cells, have pivotal roles in cardiac remodeling under disease conditions such as cardiac hypertrophy, diabetic cardiomyopathy, and myocardial infarction. In addition, exosomal contents derived from stem cells have been shown to be beneficial for regenerative potential of the heart. In this review, we discuss current understanding of the role of exosomes in cardiac communication, with a focus on cardiovascular pathophysiology and perspectives for their potential uses as cardiac therapies.