Autoantigenic Peptide and Immunomodulator Codelivery System for Rheumatoid Arthritis Treatment by Reestablishing Immune Tolerance.

Rheumatoid arthritis (RA) is a systemic autoimmune disease characterized by abnormal activation of CD4+ T cells and an imbalance of T helper 17 (Th17) and regulatory T (Treg) cells. Tolerogenic therapy via administration of self-antigens is a promising strategy for RA treatment, but delivery of autoantigens alone may exacerbate disease conditions. Current studies indicated that codelivery of autoantigens with immunomodulators can lead to a more tolerogenic immune response. Here, we constructed an autoantigen type II collagen peptide (CII250-270)- and immunomodulator leflunomide (LEF)-coloaded phosphatidylserine liposome vaccine (CII250-270-LEF-PSL) for RA treatment via induction of tolerant dendritic cells (tolDC) for further activation of Treg cells. The in vivo results showed that CII250-270-LEF-PSL can effectively induce tolDC, regulate the balance of Th1/Th2 and Th17/Treg, and reduce the secretion of pro-inflammatory cytokines (IFN-γ, IL-1ß, and IL-17A) and IgG antibodies to inhibit synovial inflammation and bone erosion. Furthermore, our study also suggested that LEF regulated Th1 cell differentiation by inhibiting the activation of the JAK1/STAT1 signaling pathway, further alleviating RA. Overall, this work proved that the combination of autoantigenic peptides and immunomodulators was a promising modality for RA treatment by reestablishing antigen-specific immune tolerance, which also inspired additional insights into the development of combination therapies for the tolerability of RA.

The potential application of complement inhibitors-loaded nanosystem for autoimmune diseases via regulation immune balance.

The complement is an important arm of the innate immune system, once activated, the complement system rapidly generates large quantities of protein fragments that are potent mediators of inflammation. Recent studies have shown that over-activated complement is the main proinflammatory system of autoimmune diseases (ADs). In addition, activated complements interact with autoantibodies, immune cells exacerbate inflammation, further worsening ADs. With the increasing threat of ADs to human health, complement-based immunotherapy has attracted wide attention. Nevertheless, efficient and targeted delivery of complement inhibitors remains a significant challenge owing to their inherent poor targeting, degradability, and low bioavailability. Nanosystems offer innovative solutions to surmount these obstacles and amplify the potency of complement inhibitors. This prime aim to present the current knowledge of complement in ADs, analyse the function of complement in the pathogenesis and treatment of ADs, we underscore the current situation of nanosystems assisting complement inhibitors in the treatment of ADs. Considering technological, physiological, and clinical validation challenges, we critically appraise the challenges for successfully translating the findings of preclinical studies of these nanosystem assisted-complement inhibitors into the clinic, and future perspectives were also summarised. (The graphical abstract is by BioRender.).

Immunotherapeutic treatment of lung cancer and bone metastasis with a mPLA/mRNA tumor vaccine.

Malignant expansion and rapid metastasis are the main limiting factors to successful treatment of lung cancer. Messenger RNA (mRNA) tumor vaccines are a promising immunotherapeutic treatment for lung cancer as well as other metastatic cancers. Herein, we developed a mPLA/mRNA tumor vaccine (mLPR) to escort mRNA into the cytoplasm and improve immune response with the help of TLR4 agonist mPLA. After nasal administration, the mLPR vaccine stimulated the maturation of dendritic cells, reprogramed M2 macrophages into M1 macrophages, as well cross-activated innate and adaptive immune responses. The mLPR vaccine inhibited the development of lung cancer and reduced bone metastasis by means of immune cell activation, IFN-γ/IL-12 cytokine secretion, and natural killer cell-mediated antibody dependent cellular cytotoxicity. The mPLA/mRNA tumor vaccine will provide ideas and application prospects for the use of mRNA tumor vaccine in the treatment of lung cancer. STATEMENT OF SIGNIFICANCE: Lung cancer and bone metastasis seriously affect patient survival, and traditional treatment methods are inefficient and have many side effects. We have constructed an mRNA vaccine that simultaneously activates the innate immune and adaptive responses of the body, in order to achieve better immunotherapeutic effects. To sum up, we confirmed through vaccine design and in vitro and in vivo immunological studies that the mLPR vaccine stimulated the maturation of dendritic cells, reprogrammed M2 macrophages into M1 macrophages, as well cross activated in vivo and adaptive immune responses.

Therapeutic potential of tolerance-based peptide vaccines in autoimmune diseases.

Autoimmune diseases are caused by the dysfunction of the body's immune regulatory system, which leads to the recognition of self-antigens and the destruction of self-tissues and is mediated by immune cells such as T and B cells, and affects 5-10% of the population worldwide. Current treatments such as non-steroidal anti-inflammatory drugs and glucocorticoids can only relieve symptoms of the disease and are accompanied by serious side effects that affect patient quality of life. The recent rise in antigen-specific therapies, especially vaccines carrying autoantigenic peptides, promises to change this disadvantage, where research has increased dramatically in the last decade. This therapy established specific immune tolerance by delivering peptide fragments containing disease-specific self-antigen epitopes to suppress excessive immune responses, thereby exerting a therapeutic effect, with high safety and specificity. This article presents the latest progress on the treatment of autoimmune diseases with autoantigen peptide vaccines. It includes the construction of peptide vaccine delivery system, the mechanism of inducing immune tolerance and its application.

The main battlefield of mRNA vaccine - Tumor immune microenvironment.

With the increasing threat of tumors to humans, mRNA vaccine-based immunotherapy has received extensive attention; however, the killing effect is sometimes unsatisfactory. The occurrence of tumors is closely related to the abnormality of the tumor immune microenvironment, including the increase in the number of immunosuppressive cells, the anomaly of some cells with tumor-killing function, and the increase in the glycolysis pathway, all of which will affect the anti-tumor effect of mRNA vaccines. Furthermore, delivery in the body and successful escape from lysosome are also essential steps that involve the result of killing. Starting from inhibiting tumor growth and metastasis by mRNA vaccines, this paper summarizes the tumor microenvironment constructed by immunosuppressive cells and cytokines, which inhibit immune cells from exerting anti-tumor effects, emphasizing the increase of glycolytic pathway after tumor formation, which makes tumors have a high probability of metastasis. In the present study, mRNA vaccines adjust the number of immune cells by combining adjuvants or immune checkpoint inhibitors (ICIs), thereby improving the tumor immune microenvironment (TIME) and tilting the balance in favor of immune-potent cells can achieve better anti-tumor effects. All efforts to understand the relationship between TIME and mRNA vaccine will provide a basis for tumor treatment in the future.

Combination of a cationic complexes loaded with mRNA and α-Galactose ceramide enhances antitumor immunity and affects the tumor immune microenvironment.

mRNA vaccination is considered to be a promising strategy for tumor immunotherapy. Among, adequate antigen expression and regulation of tumor immune microenvironment are still the key to achieving therapeutic immounotherapy. In oreder to protect mRNA delivered to cells and reverse damaged dendritic cells(DCs), a novel vaccine delivery system composed of an α-Galactose ceramide/cationic liposome complex(α-GC-Lip) was constructed. The α-GC-liposome/protamine/mRNA vaccine complexes(α-GC-LPR) enabled the mRNA to be successfully translated into protein in the cytoplasm of antigen-presenting cells. Further, α-GC-LPR could stimulate dendritic cell maturation via significantly increasing the expression of bone marrow-derived cells(BMDCs) surface molecules and secretion of cytokines to improve the efficacy of immunotherapy. In vivo study, the α-GC-LPR was combined with programmed cell death protein 1(PD-1) inhibitor could activate natural killer cell(NK), T cells as well as significantly reduce the immunosuppression of immune cells, which induced strong antigen-specific immunity in breast cancer model. Our study indicated that the α-GC-LPR combined with immune checkpoint inhibitors as a potential design strategy to effectively enhance the antitumor immune response.

Enhanced Influenza Immunity by Nasal Mucosal Administration of the TPGS-Modified Liposomal Vaccine.

Influenza infection is difficult to prevent, control, and treat because of rapid viral mutation, fast disease progression, and high mortality. Vaccination is the main means by which to prevent and control influenza, but effectiveness is limited in that poor cellular uptake and weak immunogenicity of vaccines provides less than optimal host protection. Liposomal influenza vaccines are a promising strategy to overcome these limitations and the use of liposomal immune modulators and intranasal administration of liposomal influenza vaccines may be a means by which to improve influenza protection. The cationic lipids, i.e., dimethyldioctadecylammonium (DDA), 1,2-dioctadecanoyl-sn-glycero-3-phosphocholine (DSPC), and D-α-tocopherol polyethylene glycol 1000 (TPGS) can form blank liposomes, which can incorporate influenza antigens to produce an influenza vaccine (DDA-DSPC-TPGS). Herein, this vaccine was shown to induce dendritic cell maturation, increase host cellular uptake of the vaccine, and enhance immune responses both in vitro and in vivo. The addition of TPGS, as an amphiphilic immune adjuvant, significantly reduced the toxicity of the DDA liposomal influenza vaccine. Further, the polyethylene glycol component and tocopherol structure of TPGS enhanced the cellular uptake of the vaccine by means of stealth properties and the capacity to inhibit cellular efflux. After nasal mucosal immunization, enhanced cellular uptake rates and abundant immune cells in the nasopharyngeal-associated lymphoid tissue promoted the production of immunoglobulin A, immunoglobulin G1, and interferon-γ, which in turn mediated a more robust immune response against influenza virus. In summary, the DDA-DSPC-TPGS influenza vaccine is a safe and effective means by which to activate the immune system. The results herein provide an effective strategy by which to overcome current difficulties associated with the prevention and treatment of influenza.

Nanocrystals with different stabilizers overcome the mucus and epithelial barriers for oral delivery of multicomponent Bufadienolides.

Using nanocrystals (NCs) technology may be a promising drug delivery strategy for oral administration of multicomponent anticancer drugs. However, the intestinal epithelium and the mucus layer on the intestine extremely limited drug transport and absorption by orally. In this study, we selected multicomponent inartificial compound Bufadienolides (BU) with broad spectrum antitumor activity as the model drug to prepare BU NCs with different stabilizers by wet grinding, and explored the efficiency of penetrating through the mucus layer and transporting intestinal epithelial cells in vitro and ex vivo. Results revealed that BU NCs can dramatically improve dissolution behavior synergistically and the efficiency of mucus permeation. Besides, we found that BU NCs with different stabilizers enhanced cellular uptake, which was mainly attributed to increasing or changing the endocytosis pathway and plasma membrane/Endoplasmic reticulum (ER) pathway involved in the transmembrane transport of NCs. Furthermore, BU NCs could definitely improve intestinal absorption efficiency and change the absorption site of BU ex vivo. This multi-angle exploration will provide reference for the development of BU oral delivery formulations.

Improved transdermal permeability of tanshinone IIA from cataplasms by loading onto nanocrystals and porous silica.

Novel transdermal cataplasms have been designed to improve permeability of poorly soluble drugs by different pretreatments. Nanocrystal and porous silica solid dispersions were loaded with Tanshinone IIA and incorporated into a cross-linked hydrogel matrix of cataplasm. It was shown that the small particle size and improved dissolution would increase dermal bioavailability. The adhesion, rheological properties, drug release, skin permeation, skin deposition and in vivo skin absorption of the different formulations were investigated. In an in vitro experiment using mouse skin, cumulative amount of drug permeated within 24 h was 7.32 ± 0.98 µg/cm2 from conventional cataplasm, 13.14 ± 0.70 µg/cm2 from nanocrystal-loaded cataplasm and 11.40 ± 0.13 µg/cm2 from porous silica solid dispersion-loaded cataplasm. In vitro dissolution profiles showed that drug release was 76.5% and 74.9% from two optimized cataplasms within 24 h, while conventional cataplasm was 55.0%. The cross-linking characteristics of the cataplasms were preserved after incorporation of different drug forms, while the elastic and viscous behaviors of the hydrogel layers increased. In vivo evaluation by CLSM showed the more favorable skin permeation for two optimized cataplasms. These findings suggest that applications of nanocrystal and porous silica systems on cataplasms enable effective transdermal delivery of poorly soluble drugs. The resulting drug delivery and rheological properties are desirable for transdermal application.AbbreviationAll the abbreviations that appear in this article are shown in Table 1.

Nanocrystals for Improving Oral Bioavailability of Drugs: Intestinal Transport Mechanisms and Influencing Factors.

With the limitation of solubility and dissolution rate of insoluble drugs, following oral administration, they would rifely prove poor and volatile bioavailability, which may fail to realize its therapeutic value. The drug nanocrystals are perceived as effective tactic for oral administration of insoluble drugs attributes to possess many prominent properties such as elevating dissolution rate and saturation solubility, high drug loading capacity, and improving oral bioavailability. Based on these advantages, the application of nanocrystals in oral drug delivery has acquired significant achievement, and so far more than 20 products of drug nanocrystals have been confirmed in the market. However, the oral absorption of drug nanocrystals is still facing huge challenges due to the limitation of many factors. Intrinsic properties of the drugs and complex physiological environment of the intestinal tract are the two most important factors affecting the oral bioavailability of drugs. In addition, the research on the multi-aspect mechanisms of nanocrystals promoting gastrointestinal absorption and bioavailability has been gradually deepened. In this review, we summarized recent advances of the nanocrystals delivered orally, and provided an overview to the research progress for crossing the intestinal tract transport mechanisms of the nanocrystals by some new research techniques. Meanwhile, the factors relevant to the transport of drug nanocrystals were also elaborated in detail. Graphical Abstract.

Docetaxel-loaded D-α-tocopheryl polyethylene glycol-1000 succinate liposomes improve lung cancer chemotherapy and reverse multidrug resistance.

In this study, D-alpha-tocopheryl polyethylene glycol-1000 succinate (TPGS)-coated docetaxel-loaded liposomes were developed to reverse multidrug resistance (MDR) and enhance lung cancer therapy. Evaluations were performed using human lung cancer A549 and resistant A549/DDP cells. The reversal multidrug resistant effect was assessed by P-gp inhibition assay, cytotoxicity, cellular uptake, and apoptosis assay. The tumor xenograft model was built by subcutaneous injection of A549/DDP cells in the right dorsal area of nude mice. The tumor volumes and body weights were measured every other day. The TPGS-coated liposomes showed a concentration- and time-dependent cytotoxicity and significantly enhanced the cytotoxicity of docetaxel in A549/DDP cells. Confocal laser scanning images indicated that higher concentrations of coumarin-6 were successfully delivered into the cytoplasm, and the TPGS-coated liposomes enhanced intracellular drug accumulation by inhibiting overexpressed P-glycoprotein. The TPGS-coated liposomes were shown to induce apoptosis. Furthermore, in vivo anti-tumor studies revealed that TPGS-coated docetaxel-loaded liposomes had outstanding anti-tumor efficacy in an A549/DDP xenograft model. The TPGS-coated liposomes, compared with PEG-coated liposomes, showed significant advantages in vitro and in vivo. The TPGS-coated liposomes were able to reverse MDR and enhance lung cancer therapy. Graphical abstract .

Multi-directionally evaluating the formation mechanism of 1,4-dihydropyridine drug nanosuspensions through experimental validation and computer-aided drug design.

The poor aqueous solubility of 1,4-dihydropyridine drugs needs to be solved urgently to improve bioavailability. Nanotechnology can improve drug solubility and dissolution by reducing particle size, but usually, a specific polymer or surfactant is required for stabilization. In this study, Poloxamer-407(P-407) was screened as the optimal stabilize through energy simulation, molecular docking, and particle size. the morphological study, X-ray diffraction, differential scanning calorimetry, Fourier transform infrared spectroscopy, Raman, in vitro dissolution test, and molecular simulation of interactions were utilized to explore the formation mechanisms of four 1,4-dihydropyridine drugs/P-407 nanosuspensions. The result shows that the optimized nanosuspensions had the particle size in the nano-size range and maintained the original crystal state. The in vitro dissolution rate of the nanosuspension was 3-4 times higher than the corresponding API and could reduce the restriction of drug dissolution in different pH environments. Raman spectroscopy, FTIR, and molecular docking simulations provided strong supporting evidence for the formation mechanism of 1,4-dihydropyridine drugs/P-407 nanosuspensions at the molecular level, which confirmed that the stable intermolecular hydrogen bond adsorption and hydrophobic interaction were formed between the drug and P-407. This research will provide practical concepts and technologies, which are helpful to develop nanosuspensions for the same class of drugs.

Intranasal delivery of cationic liposome-protamine complex mRNA vaccine elicits effective anti-tumor immunity.

Immunization with synthetic mRNA encoding tumor-associated antigens is an emerging vaccine strategy for the treatment of cancer. In order to prevent mRNA degradation, promote antigen-presenting cells antigen presentation, and induce an anti-tumor immune response, we investigated the nasal administration of mRNA vaccines with positively charged protamine to concentrate mRNA, form a stable polycation-mRNA complex, and encapsulate the complex with DOTAP/Chol/DSPE-PEG cationic liposomes. Cationic liposome/protamine complex (LPC) showed significantly greater efficiency in uptake of vaccine particles in vitro and stronger capacities to stimulate dendritic cell maturation, which further induced a potent anti-tumor immune response. Intranasal immunization of mice with cationic LPC containing mRNA encoding cytokeratin 19 provoked a strong cellular immune response and slowed tumor growth in an aggressive Lewis lung cancer model. The results of this study provide evidence that cationic LPC can be used as a safe and effective adjuvant and this mRNA formulation provides a basis for anti-cancer vaccination of humans.

Preparation and characterisation of tetrandrine nanosuspensions and in vitro estimate antitumour activity on A549 lung cancer cell line.

Aim: The aim of this study was to improve solubility and antitumour ability in vitro of tetrandrine (Tet) via preparing nanosuspensions (NSs).Methods: The Tet-NSs were prepared by wet media milling. The Tet-CCS-NS was prepared with croscarmellose sodium (CCS) as single stabiliser. The Tet-HACC-TPGS-NS was manufactured with D-α-tocopheryl polyethylene glycol 1,000 succinate (TPGS) and hydroponically trimethyl ammonium chloride chitosan (HACC) as combined stabilisers. Physicochemical properties of the NSs such as particle size, surface morphologies, crystallinity and molecular interactions were investigated. In addition, the in vitro dissolution and antitumour activities using A549 human lung cancer cells were evaluated.Results: The mean particle sizes and Zeta potential of freshly prepared Tet-CCS-NS, Tet-HACC-TPGS-NS were 469.1 ± 14nm and 157.3 ± 5nm, -29.4 ± 0.26 mV and 23.3 ± 0.36 mV, respectively. In comparison to pure Tet, the cumulative dissolution of Tet-NSs were increased by 4 ∼ 5 times in 2 h. In vitro antitumour studies on Tet- NSs in A549 cells, the cell survival rate of the Tet-NSs at high concentration (30-50µg/ml) were less than 10% within 48 h. Meanwhile, Tet-NSs were revealed to induce A549 cells apoptosis and promote cell uptake.Conclusion: The present study has proved that the Tet-NSs can increase Tet solubility as well as improve Tet antitumour activity in vitro.

Isoliquiritigenin Nanosuspension Enhances Cytostatic Effects in A549 Lung Cancer Cells.

Isoliquiritigenin, a flavonoid extracted from licorice root, has been shown to be active against most cancer cells; however, its antitumor activity is limited by its poor water solubility. The aim of this study was to develop a stable isoliquiritigenin nanosuspension for enhanced solubility and to evaluate its in vitro cytostatic activity in A549 cells. The nanosuspension of isoliquiritigenin was prepared through wet media milling with HPC SSL (hydroxypropyl cellulose-SSL) and PVP K30 (polyinylpyrrolidone-K30) as stabilizers, and the samples were then characterized according to particle size, zeta-potential, SEM (scanning electron microscopy), TEM (transmission electron microscopy), DSC (differential scanning calorimetry), XRPD (X-ray powder diffraction), FTIR (Fourier transform infrared spectroscopy), XPS (X-ray photoelectron spectroscopy), and in vitro release. The isoliquiritigenin nanosuspension prepared with HPC SSL and PVP K30 had particle sizes of 238.1 ± 4.9 nm and 354.1 ± 9.1 nm, respectively. Both nanosuspensions showed a surface charge of approximately - 20 mV and a lamelliform or ellipse shape. The dissolution of isoliquiritigenin from the 2 nanosuspensions was markedly higher than that of free isoliquiritigenin. In vitro studies on A549 cells indicated that the cytotoxicity and cellular uptake significantly improved after treatment with both nanosuspensions in comparison to the isoliquiritigenin solution. Furthermore, cell apoptosis analysis showed a 7.5 - 10-fold increase in the apoptosis rate induced by both nanosuspensions compared with pure drug. However, the cytotoxicity of pure drug and nanosuspension on normal cells (HELF) was lower, which indicated both isoliquiritigenin nanosuspensions have low toxicity to normal cells. Therefore, the isoliquiritigenin nanosuspension prepared with HPC SSL and PVP K30 as stabilizers may be a promising approach to improve the solubility and cytostatic activity of isoliquiritigenin.

Mechanism and Improved Dissolution of Glycyrrhetinic Acid Solid Dispersion by Alkalizers.

The purpose of this study was to increase the dissolution of glycyrrhetinic acid (GA) by preparing ternary solid dispersion (TSD) systems containing alkalizers, and to explore the modulating mechanism of alkalizers in solid dispersion systems. GA TSDs were prepared by hot melt extrusion (HME) with Kollidon® VA64 as the carrier and L-arginine/meglumine as the alkalizers. The in vitro release of the TSD was investigated with a dissolution test, and the dissociation constant (pKa) was used to describe the ionization degree of the drug in different pH buffers. Scanning electron microscopy (SEM), differential scanning calorimetry (DSC), X-ray powder diffraction (XRPD), Fourier Transform Infrared Spectroscopy (FTIR), Raman spectra, X-ray photoelectron spectroscopy (XPS), and a molecular model were used for solid-state characterizations and to study the dissolution mechanism of the TSDs. It was evident that the dissolution of GA significantly increased as a result of the TSD compared to the pure drug and binary solid dispersion. SEM, DSC, and XPRD data showed that GA transformed into an amorphous form in TSD. As illustrated by FTIR, Raman, XPS, and molecular docking, high binding energy ion-pair complexes formed between GA and the alkalizers during the process of HME. These can destroy the H-bond between GA molecules. Further, intermolecular H-bonds formed between the alkalizers and Kollidon® VA64, which can increase the wettability of the drug. Our results will significantly improve the solubility and dissolution of GA. In addition, the lower pKa value of TSD indicates that higher ionization is beneficial to the dissolution of the drug. This study should facilitate further developments of TSDs containing alkalizers to improve the dissolution of weakly acidic drugs and gain a richer understanding of the mechanism of dissolution.

Targeting strategies of liposomal subunit vaccine delivery systems to improve vaccine efficacy.

Liposomes are versatile delivery systems and immunological adjuvants that not only can load various antigens, such as proteins, peptides, nucleic acids and carbohydrates, but also can combine them with immunostimulators. Liposomes have great potential in the development of new types of vaccines, and much effort has been devoted to enhancing vaccine efficacy in recent years. Different types of immune cells such as macrophages and dendritic cells play an important role in the immune response and in preventing or treating cancer, allergy or many other infectious diseases. Targeting liposome-based delivery systems to certain immune cells and organs is one of the most effective measures in such treatments. Extensive research has shown that liposomes combined with immunostimulators or modified with pattern recognition receptor ligands can target various immune cells and the lymphatic system, thus not only inducing and promoting the desired immune response but also decreasing adverse effects throughout the body and avoiding targeting irrelevant cell types or tissues. Therefore, in this review, we outline some targeting strategies that can be adopted in the design of liposomal vaccines to improve vaccine efficacy, and we summarise the related liposome-based vaccine applications in several diseases. These applications have great potential to treat or prevent some infectious and intractable diseases.