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@#Abstract: Membrane proteins, which play a critical role in various life processes, particularly in regulating cell-cell contact and signal transduction, are closely linked to cell differentiation and maturation. Therefore, it is of great theoretical and practical significance to develop a variety of methods to thoroughly explore the interactions between membrane proteins. In addition to traditional techniques such as immunoprecipitation, newly developed proximity labeling (PL) techniques have gradually become important means to study membrane protein interaction. PL methods are based on engineered enzymes fused with bait protein to catalyze small molecules, label neighboring target proteins, and detect the interactions by flow cytometry, mass spectrometry, confocal microscopic imaging, etc. This paper focuses on the recent developments in PL techniques for studying membrane protein interactions, with a prospect of the potential future directions for research in this area.
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BACKGROUND:Photothermal therapy is a novel tumor treatment strategy that uses photothermal agents to transform light energy into heat energy to accomplish non-invasive tumor ablation.The rise of photothermal therapy and nanotechnology has provided a new perspective on breast cancer treatment.OBJECTIVE:To prepare a new type of near-infrared biomimetic nanoprobe that has been modified by breast cancer cell membrane,to investigate the effect of near-infrared fluorescence/ultrasound imaging in vitro,and to observe its targeting ability and photothermal therapy effect on homologous tumor cells in vitro.METHODS:Organic small molecule ITIC-4CI with A-D-A structure was used as photothermal agents;polylactic acid/glycolic acid copolymer as nanocarrier;4T1 cell membrane of mouse breast cancer cells as a surface modifier of nanoparticles;perfluorohexane(PFH)was loaded.A novel near-infrared biomimetic nanoprobe(4T1m/ITIC-4CI/PFH)was prepared by the double emulsion evaporation method and sonication method.The basic characterization of the nanoprobe and the homologous targeting ability were detected.The photothermal properties and photothermal stability of the probe were investigated,and the near-infrared fluorescence/ultrasound imaging effect of the probe under laser irradiation was observed.The CCK-8 assay and calcein/propidium iodide staining were used to assess the efficacy of photothermal therapy.RESULTS AND CONCLUSION:(1)The prepared 4T1m/ITIC-4CI/PFH nanoprobes had uniform size,high stability,and an average particle size of(92.7±2.3)nm.The probe's protein composition was identical to that of the 4T1 cell membrane.The nanoprobe's ability to target homologous 4T1 cells was validated by an in vitro cell uptake assay.(2)The nanoprobe had a red-shift absorption spectrum and tail emission extending to the near-infrared-Ⅱ,which emitted a bright near-infrared-Ⅱ fluorescence signal under laser irradiation.(3)After laser irradiation,the nanoprobe 4T1m/ITIC-4CI/PFH could be turned into microbubbles and enhanced ultrasound imaging.The results of CCK-8 assay and calcein/propidium iodide staining showed that the nanoprobe 4T1m/ITIC-4CI/PFH had an obvious photothermal killing effect on 4T1 cells.(4)The results show that the nanoprobe 4T1m/ITIC-4CI/PFH has the ability to target homologous tumors and enhance near-infrared-Ⅱ fluorescence imaging/ultrasound imaging and photothermal therapy effects.
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Traditional Chinese medicine (TCM) is extensively utilized for clinical disease prevention and treatment. However, due to the intricate nature of its material basis and the multiple factors involved in the preparation process, ensuring comprehensive quality control of TCM proves to be challenging. By instilling a clear understanding of its effective and harmful substances and implementing control over the content and limit of TCM during the preparation process, the controllability and repeatability of its quality can be guaranteed. Currently, China is facing a dearth of innovative technology for drug development, necessitating an increase in research and development efficiency, especially in the realm of high-throughput precision analytical equipment. The country has long relied on imported pharmaceutical analysis equipment with a particular efficiency in high-end intelligent analysis equipment. This is especially concerning considering the urgent requirement to establish a "pharmaceutical intelligent analysis system." This project, supported by the Major Instrument Development Project of the National Science and Technology Funds, employs cell membrane chromatography technology, complemented by biotechnology and artificial intelligence technology, to devise a two-dimensional cell membrane chromatography (2D/CMC) analyzer. The project has successfully conducted a demonstration application of the "2D/CMC-Traditional Chinese Medicine Pharmacodynamic Substance Analyzer" and the "2D/CMC-Traditional Chinese Medicine Injection Allergen Analyzer" . These tools have enhanced the screening and discovery efficiency of TCM’s effective substances and allergen components. Moreover, the equipment amalgamates qualitative and quantitative analysis, thereby serving as an effective analytical tool to enhance the quality and efficacy of traditional Chinese medicine.
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OBJECTIVE To study the antifungal activity of Huangqin decoction (HQD) against Trichophyton mentagrophytes and explore its mechanism. METHODS Minimal inhibitory concentration (MIC), minimal fungicidal concentration (MFC), mycelial length, spore germination rate, biomass and mycelium ultrastructure observation were performed to evaluate the antifungal activity of HQD against T. mentagrophytes. The effects of HQD on the cell wall of T. mentagrophytes were detected through sorbitol protection experiment. By measuring the content of ergosterol and the activities of squalene epoxide (SE) and lanosterol 14α-demethylase (CYP51), the activity of HQD on the cell membrane of T. mentagrophytes was investigated. The effects of HQD on T. mentagrophytes mitochondria were investigated by determining the activities of malate dehydrogenase (MDH), succinate dehydrogenase (SDH), and ATPases (including sodium potassium ATPase, calcium magnesium ATPase, and total ATPase). RESULTS HQD exhibited significant antifungal activity against T. mentagrophytes with MIC of 3.13 mg/mL and MFC of 25 mg/mL. After intervention with HQD, the mycelial length of T. mentagrophytes was significantly shortened (P<0.05); spore germination rate, biomass, the content of ergosterol in the cell membrane, the activities of SE and CYP51 in the cell membrane and MDH, SDH and ATPase in mitochondria were all decreased significantly (P<0.05); cell structure had been ;damaged to a certain extent, but the integrity of the cell wall had not been affected. CONCLUSIONS HQD shows significant antifungal activity against T. mentagrophytes, the mechanism of which may be associated with reducing the 0791- content of ergosterol in the cell membrane and the activities of SE, CYP51, and mitochondria-related enzymes.
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Cell membrane-modified nanoparticles (NPs) have attracted widespread attention as a new approach for malignant brain tumors in recent years. This method can enhance the targeting, biocompatibility, and circulation time of NPs by preserving the characteristics of source cell membrane, thereby ensuring efficient drug delivery to intracranial lesions. This paper focuses on the research progress in this field, especially advantages of NPs penetrating the blood-brain barrier, immune evasion and drug delivery, as well as modified effect of different cell membrane on NPs, in order to provide help for treatment of malignant brain tumors.
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Chemotherapy is one of the major approaches for the treatment of metastatic lung cancer, although it is limited by the low tumor delivery efficacy of anticancer drugs. Bacterial therapy is emerging for cancer treatment due to its high immune stimulation effect; however, excessively generated immunogenicity will cause serious inflammatory response syndrome. Here, we prepared cancer cell membrane-coated liposomal paclitaxel-loaded bacterial ghosts (LP@BG@CCM) by layer-by-layer encapsulation for the treatment of metastatic lung cancer. The preparation processes were simple, only involving film formation, electroporation, and pore extrusion. LP@BG@CCM owned much higher 4T1 cancer cell toxicity than LP@BG due to its faster fusion with cancer cells. In the 4T1 breast cancer metastatic lung cancer mouse models, the remarkably higher lung targeting of intravenously injected LP@BG@CCM was observed with the almost normalized lung appearance, the reduced lung weight, the clear lung tissue structure, and the enhanced cancer cell apoptosis compared to its precursors. Moreover, several major immune factors were improved after administration of LP@BG@CCM, including the CD4+/CD8a+ T cells in the spleen and the TNF-α, IFN-γ, and IL-4 in the lung. LP@BG@CCM exhibits the optimal synergistic chemo-immunotherapy, which is a promising medication for the treatment of metastatic lung cancer.
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Iron (Fe) is an essential micronutrient for plant growth and development, but excessive iron uptake can cause iron toxicity, leading to damage to plant cell membranes, reduced growth, yield, and overall health. This review paper discusses the issue of iron toxicity in plants, a common problem that affects crops such as rice, soybean, wheat, vegetables and is a common issue in Southeast Asia, Brazil, Africa, Australia, and the United States. Iron toxicity is more likely to occur in soils with high pH, high organic matter, or elevated levels of available iron. It discusses the various mechanisms that cause iron toxicity in plants, such as competition with other essential elements, oxidative stress, and changes in gene expression and phytohormones. The excess iron ions can cause damage to the root cells and the plasma membrane, leading to oxidative stress and increased production of reactive oxygen species (ROS). ROS can cause damage to cellular components, such as lipids, proteins, and DNA, leading to the death of root cells. Plants have specific mechanisms to take up iron, including transport proteins that are responsible for moving Fe2+ across the plasma membrane of root cells. Furthermore, it discusses the impact of iron toxicity on plant growth and development, including stunted growth, reduced root development, decreased water and nutrient uptake, and reduced photosynthetic activity. Highlights the importance of proper management of iron levels in soils to prevent iron toxicity and promote healthy plant growth.
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Cell membrane camouflaged nanoparticles have been widely used in the field of drug leads discovery attribute to their unique biointerface targeting function. However, random orientation of cell membrane coating does not guarantee effective and appropriate binding of drugs to specific sites, especially when applied to intracellular regions of transmembrane proteins. Bioorthogonal reactions have been rapidly developed as a specific and reliable method for cell membrane functionalization without disturbing living biosystem. Herein, inside-out cell membrane camouflaged magnetic nanoparticles (IOCMMNPs) were accurately constructed via bioorthogonal reactions to screen small molecule inhibitors targeting intracellular tyrosine kinase domain of vascular endothelial growth factor recptor-2. Azide functionalized cell membrane acted as a platform for specific covalently coupling with alkynyl functionalized magnetic Fe3O4 nanoparticles to prepare IOCMMNPs. The inside-out orientation of cell membrane was successfully verified by immunogold staining and sialic acid quantification assay. Ultimately, two compounds, senkyunolide A and ligustilidel, were successfully captured, and their potential antiproliferative activities were further testified by pharmacological experiments. It is anticipated that the proposed inside-out cell membrane coating strategy endows tremendous versatility for engineering cell membrane camouflaged nanoparticles and promotes the development of drug leads discovery platforms.
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Lung is susceptible to external disturbance, resulting in a variety of acute and chronic lung diseases. Functionalized nanoparticles as carriers can carry drugs through multiple biological barriers of lung into lung lesions, but there are some problems such as poor targeting and low therapeutic efficiency. As a drug carrier, membrane-coated biomimetic nanoparticles have the characteristics of immune system escape, active targeting, inflammatory chemotaxis and crossing physiological barriers due to the retention of the characteristics of the source cells. Therefore, it has been widely used in the treatment of lung diseases in recent years. In this review, the application of membrane-coated biomimetic nanoparticles in the treatment of lung diseases in the recent years was summarized and classified. Cell membrane sources include erythrocyte membrane, platelet membrane, macrophage membrane, neutrophil membrane, lung epithelial membrane, lung surfactant, endothelial membrane, cancer cell membrane, bacterial membrane, hybrid membrane and so on. The purpose of this review is to provide a new idea for treating lung diseases with membrane-coated biomimetic nanoparticles.
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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.
Subject(s)
Pharmaceutical Preparations , Drug Delivery Systems , Vaccines , Erythrocytes , NanoparticlesABSTRACT
As an edible eukaryotic microorganism, Saccharomyces cerevisiae has the characteristics of high safety, rapid proliferation, low cost, easy transformation, etc. It has been widely used to produce vaccines, antibodies, insulin, etc. Up to now, yeast components, such as cell wall and yeast microcapsules, have been widely used in the treatment of tumors, inflammatory virus infection, post-traumatic osteoarthritis and other diseases. Among them, the components of yeast cell membrane are relatively simple and stable, which are easy to be extracted on a large scale. Therefore, yeast cell membrane material was used to construct yeast membrane vesicle nanosystem, and its biomedical application was preliminarily explored. In this study, Saccharomyces cerevisiae membrane vesicle (SMV) was prepared by co-extrusion method, and the particle size and surface potential of SMV, drug loading and release characteristics, stability, cell safety, and in vitro therapeutic effect were investigated. The results showed that the average particle size of SMV was 185.1 nm. Curcumin and silica nanoparticles were effectively encapsulated by co-incubation and ultrasonic methods, and the characteristics of cell membrane proteins were maintained. Moreover, SMV had good stability and biocompatibility. In addition, SMV could be effectively uptaken by macrophages RAW 264.7, and curcumin loaded SMV could effectively eliminate reactive oxygen species (ROS). In conclusion, the yeast plasma membrane vesicles prepared in this study could effectively deliver curcumin drugs and encapsulate nanoparticles, and could be effectively absorbed by macrophages and effectively eliminate ROS, providing new ideas and new methods for biomedical applications of yeast membrane materials.
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Nanocarriers prepared from organic or inorganic materials are widely used in drug targeting system and diagnosis and treatment of disease. However, there are some problems, such as poor targeting, short circulation time in vivo and improvement in the biocompatibility. Biomimetic nanocarriers has carried out research on the issues, which based on different kinds of cell membrane for the nanocarriers modification, endogenous biofilm improving the biocompatibility of carriers in vivo, more accurate targeting, and even producing immunotherapeutic effect. The principle, method, targeting mechanism and therapeutic effect of biomimetic nano carrier technology of cell membrane have been reviewed in this paper, which provide a new direction for the research of new drug delivery system.
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Metastasis is the leading cause of cancer-related death. Despite extensive treatment, the prognosis for patients with metastatic cancer remains poor. In addition to conventional surgical resection, radiotherapy, immunotherapy, chemotherapy, and targeted therapy, various nanobiomaterials have attracted attention for their enhanced antitumor performance and low off-target effects. However, nanomedicines exhibit certain limitations in clinical applications, such as rapid clearance from the body, low biological stability, and poor targeting ability. Biomimetic methods utilize the natural biomembrane to mimic or hybridize nanoparticles and circumvent some of these limitations. Considering the involvement of immune cells in the tumor microenvironment of the metastatic cascade, biomimetic methods using immune cell membranes have been proposed with unique tumor-homing ability and high biocompatibility. In this review, we explore the impact of immune cells on various processes of tumor metastasis. Furthermore, we summarize the synthesis and applications of immune cell membrane-based nanocarriers increasing therapeutic efficacy against cancer metastases via immune evasion, prolonged circulation, enhanced tumor accumulation, and immunosuppression of the tumor microenvironment. Moreover, we describe the prospects and existing challenges in clinical translation.
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Objective:To explore the role of α-synuclein (α-Syn) in pathogenesis of Parkinson's disease (PD) and multiple system atrophy (MSA) by observing the ability of α-Syn aggregates incubated with PD and MSA patients' plasma to destroy cell membrane.Methods:Peripheral blood samples were collected from 5 PD patients and 5 MSA patients diagnosed in Department of Neurology, Affiliated Hospital of Guilin Medical University from January 2018 to January 2022, as well as 5 physical examination healthy control subjects (HCs) during the same period. The α-Syn was dissolved in 0.01 mol/L PBS and then incubated with PBS, and plasma from HCs, PD patients and MSA patients at 37 ℃ for 4 d, respectively (named as PBS group, HC group, PD group and MSA group). Small unilamellar vesicles (SUVs) containing calcein were prepared with acidic phospholipid, 1-palmityl-2-oleoyl-Sn-glycerol-3-phospho-L-serine (POPS), by membrane dispersion-ultrasonic method; the particle size and morphology of SUVs were analyzed by Malvern Zetasizer Nano ZS and transmission electron microscope. SUVs and human neuroblastoma cells (SH-SY5Y) were treated with different concentrations of α-Syn aggregates (0.5, 1.0, 2.0, 4.0, 8.0 and 16.0 μmol/L). The abilities of α-Syn aggregates formed under different conditions to destroy liposomes and cell membrane were evaluated by measuring the calcein relative release and intracellular calcein fluorescent value after dialysis.Results:(1) Destructive effect of α-Syn aggregates on SUVs: calcein induced by α-Syn aggregates in each group increasingly released with the increase of protein concentration; at protein concentration of 8 μmol/L, the calcein released from SUVs in PD and MSA groups was significantly higher than that in PBS and HC groups, and the calcein released from SUVs in MSA group was further significantly higher than that in the PD group ( P<0.05). (2) Destructive effect of α-Syn aggregates on cell membrane in SH-SY5Y: the calcein fluorescent value in each group decreased with the increase of protein concentration; at protein concentration of 8 μmol/L, the intracellular calcein fluorescent value in PD and MSA groups were significantly decreased compared with that in PBS and HC groups ( P<0.05); the intracellular calcein fluorescent value in MSA group was further significantly decreased compared with that in PD group ( P<0.05). (3) Effect of α-Syn aggregates on SH-SY5Y cell survival: at protein concentration of 8 μmol/L, the viability of SH-SY5Y cells in each group decreased obviously; PD and MSA groups had significantly decreased cell viability compared with PBS and HC groups ( P<0.05); and the viability in MSA group was further statistically decreased compared with that in PD group ( P<0.05). Conclusion:The ability of α-Syn aggregates incubated with PD and MSA patients' plasma to destroy cell membrane is greater than that with HCs' plasma, especially those with MSA patients' plasma.
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Objective @# Cas9-RNP biomimetic nanoparticles cas9-RNP@ MMs were prepared by encapsulating the Cas9 Ribonucleoprotein complex (RNP) using mouse macrophage membranes,with the aim of utilizing this biomimetic nanoparticle to deliver the Cas9-RNP complex for gene editing ,and further study the endocytosis of Cas9- RNP@ MMs and its gene editing effect in mouse macrophage RAW264. 7 in vitro ,providing evidence for the development oflow-toxicity biomimetic nanoparticle carriers that inhibit NLRP3 therapeutic targets.@*Methods @#The purified mouse macrophage membrane was mixed with the prepared cas9-RNP mixture,and after ultrasound,the CAS9- RNP@ MMS was obtained by liposome extrusion instrument ; The particle size of Cas9-RNP@ MMswas measured by nanoparticle tracking analysis,and the particle morphology of Cas9-RNP@ MMs was observed under transmission electron microscope.Laser confocal Fluorescence microscope imaging was used to analyze the endocytosis Cas9-RNP @ MMs.The Biocompatibility of Cas9-RNP@ MMs was measured by MTT assay.The expression of NLRP3 was detected by qPCR and Western blot to verify the knockdown effect of Cas9-RNP@ MMs on NLRP3 gene. @*Results@#The average particle diameter of Cas9-RNP@ MMs prepared from macrophages was about 216 nm.Under laser confocal fluorescence microscope,the Cas9-RNP@ MMs could be successfully endocysed by Raw246. 7 cell.MTT assay indicated that the Cas9-RNP@ MMs-treated mouse macrophage RAW246. 7 had good biocompatibility.qPCR and Western blot showed that two NLRP3-specific guide RNA were mediated by Cas9-RNP@ MMs,with good effect of knockdown NLRP3 gene expression.@*Conclusion@# Nano-scale vesicles Cas9-RNP@ MMs loaded with Cas9-RNP complexes were successfully prepared by biomimetic nanoparticles. Cas9-RNP@ MMs have good biocompatibility and can be efficiently endocytosed by RAW246. 7 cells.Cas9-RNP@ MMs containing NLRP3-specific sgRNA can specifically knock down NLRP3 gene expression.
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The biomimetic strategy of using the cell membrane-coated nanoparticles can retain the physical and chemical properties of the nanoparticles and show the biological characteristics of the source cell membrane, which can further enhance the role of the nanodrug in tumor treatment. A hybrid cell membrane is the fusion of two or more different types of cell membranes. A hybrid cell membrane can endow nanoparticles with multiple biofunctions derived from the source cells compared with a single cell membrane. Hybrid cell membranes provide a foundation to stimulate extensive research into multifunctional biomimetic nano-drug delivery system (NDDS), which is expected to broaden the application of biomimetic nanotechnology in drug delivery systems. In this review paper, the types of hybrid cell membrane used to construct nano-drug delivery systems, the preparation and characterization methods, and cancer treatment research progress in recent years were reviewed.
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Biomimetic nanoengineering presents great potential in biomedical research by integrating cell membrane (CM) with functional nanoparticles. However, preparation of CM biomimetic nanomaterials for custom applications that can avoid the aggregation of nanocarriers while maintaining the biological activity of CM remains a challenge. Herein, a high-performance CM biomimetic graphene nanodecoy was fabricated via purposeful surface engineering, where polyethylene glycol (PEG) was used to modifying magnetic graphene oxide (MGO) to improve its stability in physiological solution, so as to improve the screening efficiency to active components of traditional Chinese medicine (TCM). With this strategy, the constructed PEGylated MGO (PMGO) could keep stable at least 10 days, thus improving the CM coating efficiency. Meanwhile, by taking advantage of the inherent ability of HeLa cell membrane (HM) to interact with specific ligands, HM-camouflaged PMGO showed satisfied adsorption capacity (116.2 mg/g) and selectivity. Finally, three potential active components, byakangelicol, imperatorin, and isoimperatorin, were screened from Angelica dahurica, whose potential antiproliferative activity were further validated by pharmacological studies. These results demonstrated that the purposeful surface engineering is a promising strategy for the design of efficient CM biomimetic nanomaterials, which will promote the development of active components screening in TCM.
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In the development of chemo-immunotherapy, many efforts have been focusing on designing suitable carriers to realize the co-delivery of chemotherapeutic and immunotherapeutic with different physicochemical properties and mechanisms of action. Besides, rapid drug release at the tumor site with minimal drug degradation is also essential to facilitate the antitumor effect in a short time. Here, we reported a cancer cell membrane-coated pH-responsive nanogel (NG@M) to co-deliver chemotherapeutic paclitaxel (PTX) and immunotherapeutic agent interleukin-2 (IL-2) under mild conditions for combinational treatment of triple-negative breast cancer. In the designed nanogels, the synthetic copolymer PDEA-co-HP-β-cyclodextrin-co-Pluronic F127 and charge reversible polymer dimethylmaleic anhydride-modified polyethyleneimine endowed nanogels with excellent drug-loading capacity and rapid responsive drug-releasing behavior under acidic tumor microenvironment. Benefited from tumor homologous targeting capacity, NG@M exhibited 4.59-fold higher accumulation at the homologous tumor site than heterologous cancer cell membrane-coated NG. Rapidly released PTX and IL-2 enhanced the maturation of dendritic cells and quickly activated the antitumor immune response in situ, followed by prompted infiltration of immune effector cells. By the combined chemo-immunotherapy, enhanced antitumor effect and efficient pulmonary metastasis inhibition were achieved with a prolonged median survival rate (39 days).
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OBJECTIVE To prepare and evalu ate doxorubicin-loaded red blood cell membrane chitosan-targeted nanoparticles of targeting tumor cell folate acid (FA)receptor(FA-RBC-DOX-CS-NPs). METHODS Doxorubicin-loaded chitosan nanoparticles (DOX-CS-NPs) were prepared by ion cross-linking method. FA and amino polyethylene glycol phospholithin (NH2- PEG2000-DSPE)were covalently linked to modify the red blood cell membrane to construct FA-RBC-DOX-CS-NPS. FA-RBC- DOX-CS-NPs were characterized and investigated on in vitro drug release characteristics ,antitumor activity and endocytosis ability (investigation with human breast cancer MCF- 7 cells). RESULTS Average particle size of FA-RBC-DOX-CS-NPs was (254.200± 2.651)nm,and polydispersity index was 0.199±0.031;Zeta potential was (-10.100±0.213)mV. FA-RBC-DOX-CS-NPs released fast in the tumor microenvironment (pH6.5). Cellular experiments showed that ,the nanoparticles could inhibit the activity of MCF- 7 cell proliferation and improve the efficiency of endocytosis. CONCLUSIONS FA-RBC-DOX-CS-NPs are prepared successfully. The nanoparticles have good tumor cell targeting and endocytosis ability ,and can realize the enrichment of drugs in tumor cells.
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Objective@#To investigate the mechanisms by which D-methionine (D-Met) eradicates Porphyromonas gingivalis biofilms by suppressing cyclic dimeric GMP (c-di-GMP) levels.@*Methods @#Cell viability, minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC) were measured to determine the effective concentrations of D-Met, which were subsequently used in the following experiments. During the P. gingivalis biofilm formation inhibition experiment and the mature biofilm disassembly experiment, biofilm biomass, exopolysaccharide (EPS), biofilm morphology, integrity of the cell membrane, and the level of c-di-GMP were determined. @*Results @# D-Met < 40 mmol/L was biocompatible. During the biofilm formation inhibition and mature biofilm disassembly experiments, D-Met ≥ 20 mmol/L decreased the biofilm biomass and the production of EPS. SEM analysis showed that the extracellular matrix and bacterial density were drastically reduced by D-Met ≥ 20 mmol/L. TEM detection showed that 35 mmol/L D-Met ruptured the cell membrane during biofilm formation and increased the permeability of the cell membrane in the disassembly phase of mature biofilms. C-di-GMP levels decreased with increasing concentrations of D-Met in a concentration-dependent manner.@* Conclusion @# D-Met ≥ 20 mmol/L could eradicate P. gingivalis biofilms by suppressing c-di-GMP levels.