Liposomes Research Articles

Bio-Inspired Nanodelivery Platform: Platelet Membrane-Cloaked Genistein Nanosystem for Targeted Lung Cancer Therapy.

Genistein (Gen), a natural polyphenolic compound, has emerged as a promising candidate for lung cancer treatment. However, the potential clinical application of Gen is limited due to its poor solubility, low bioavailability, and toxic side effects. To address these challenges, a biomimetic delivery platform with cell membranes derived from natural cells as carrier material was constructed. This innovative approach aims to facilitate targeted drug delivery and solve the problem of biocompatibility of synthetic materials. First, the liposomes (LPs) loaded with Gen (LPs@Gen) was prepared using the ethanol injection method. Subsequently, PLTM-LPs@Gen was obtained through co-extrusion after mixing platelet membrane (PLTM) and LPs@Gen. Additionally, the biological and physicochemical properties of PLTM-LPs@Gen were investigated. Finally, the targeting ability, therapeutic efficacy, and safety of PLTM-LPs@Gen for lung cancer were evaluated using both a cell model and a tumor-bearing nude mouse model. The optimal preparation ratio for LPs@Gen was Gen: soybean lecithin: cholesterol: DSPE-PEG2000 (3:30:5:10, mass ratio), while the ideal fusion ratio of LPs@Gen and PLTM was 1:1. The particle size of PLTM-LPs@Gen was 108.33 ± 1.06 nm, and the encapsulation efficiency and drug loading were 94.29% and 3.09% respectively. Gen was released continuously and slowly from PLTM-LPs@Gen. Moreover, PLTM-LPs@Gen exhibited good stability within one week. The results of in vitro cellular uptake and in vivo distribution experiments indicated that the carrier material, PLTM-LPs, has the immune escape ability and tumor targeting ability. Consequently, it showed better therapeutic effects than free drugs and traditional LPs in vitro and in vivo tumor models. In addition, safety experiments demonstrated that PLTM-LPs@Gen possesses good biocompatibility. Biomimetic nanomedicine provides a new strategy for the precision treatment of lung cancer in clinical practice.

Construction of DNA Vaccine of Extracellular Region of Vascular Endothelial Growth Factor Receptor 2 and Its Antitumor Activity in Vivo

Introduction: it constructed recombinant DNA vaccine of extracellular region of vascular endothelial growth factor receptor 2 (VEGFR2) and analyzed its in vivo activity against H22 transplanted hepatoma. Methods: the gene fragment of VEGFR2 extracellular region 1-3 was amplified, and the pcDNA3.1(+)/exVEGFR2 recombinant plasmid was constructed. The expression of exVEGFR2 was detected by Western blot. Subsequently, liposome (LP) pcDNA3.1(+)/exVEGFR2 complex (LP-pcDNA3.1(+)/exVEGFR2) was prepared and immunized to C57BL/6 mice. The cytotoxic activity mediated by cytotoxic T cells (CTLs) was analyzed by 51Cr release assay. H22 tumor bearing C57BL/6 mouse model was prepared. Quadriceps femoris muscle was injected with normal saline (saline group, AG), LP-pcDNA3.1(+) 100 μL (1 μg/μL, LP-pcDNA3.1(+) group, BG), and LP-pcDNA3.1(+)/exVEGFR2 100 μL (1 μg/μL, LP-pcDNA3.1(+)/exVEGFR2 group, CG). Tumor growth and death were recorded, and microvessel density (MVD) was evaluated by CD31 immunohistochemical staining. Results: a 1252 bp of exVEGFR2 sequence was amplified, and a specific band expressing 44 kDa molecular weight was constructed by transfecting pcDNA3.1(+)/exVEGFR2 into COS-7 cells. After immunizing C57BL/6 mice for 6 weeks, CTLs experiment suggested that LP-pcDNA3.1(+)/exVEGFR2 could effectively mediate the toxic effect of VEGFR2 positive H22 cells. The in vivo antitumor activity experiment found that as against AG and BG, the tumor volume, weight, and MVD were markedly reduced, the tumor latency time was markedly prolonged, and the average survival time was also markedly prolonged in CG (P < 0.05). Conclusion: LP-pcDNA3.1(+)/exVEGFR2 can effectively activate C57BL/6 mice to produce specific anti-VEGFR2 immune response, and then produce anti-tumor cell immunotoxicity in vitro and in vivo. Inhibiting angiogenesis can effectively prolong the survival time of H22 tumor bearing mice.

Investigation of Dual-Loaded Doxorubicin and Sorafenib Liposomes Co-Modified with Glycyrrhetinic Acid and Cell-Penetrating Peptide TAT.

Combining Doxorubicin (DOX) with sorafenib (SF) is a promising strategy for treating Hepatocellular Carcinoma (HCC). However, strict dosage control is required for both drugs, and there is a lack of target selectivity. This study aims to develop a novel nano-drug delivery system for the combined use of DOX and SF, aiming to reduce their respective dosages, enhance therapeutic efficacy, and improve target selectivity. DOX/SF co-loaded liposomes (LPs) were prepared using the thin-film hydration method. The liposomes were modified with 1,2-distearoyl-sn-glycero-3-phospho-ethanolamine (DSPE)- polyethylene glycol (PEG2000), DSPE-PEG1000-cell penetrating peptide TAT, and Glycyrrhetinic Acid (GA). The basic properties of the liposomes were characterized. CCK-8 cell viability assays were conducted using HepG2, MHCC97-H, and PLC cell models, and apoptosis experiments were performed using HepG2 cells to determine if this delivery system could reduce the respective dosages of DOX and SF and enhance HCC cytotoxicity. Liposome uptake experiments were performed using HepG2 cells to validate the target selectivity of this delivery system. A GA/TAT-DOX/SF-LP liposomal nano drug delivery system was successfully constructed, with a particle size of 150 nm, a zeta potential of -7.9 mV, a DOX encapsulation efficiency of 92%, and an SF encapsulation efficiency of 88.7%. Cellular experiments demonstrated that this delivery system reduced the required dosages of DOX and SF, exhibited stronger cytotoxicity against liver cancer cells, and showed better target selectivity. A simple and referenceable liposomal nano drug delivery system has been developed for the combined application of DOX and SF in hepatocellular carcinoma treatment.

Multiple strategies approach: A novel crosslinked hydrogel forming chitosan-based microneedles chemowrap patch loaded with 5-fluorouracil liposomes for chronic wound cancer treatment

Untreated or poorly managed chronic wounds can progress to skin cancer. Topically applied 5-fluorouracil (5-FU), a nonspecific cytostatic agent, can cause various side effects. Its high polarity also results in low cell membrane affinity and bioavailability. Hydrogel, used for its occlusive effect, is one platform for treating chronic wounds combined with PEGylated liposomes (LPs), developed to increase drug-skin affinity. This research aimed to develop a novel hydrogel forming chitosan-based microneedles (HFM) chemowrap patch containing 5-FU PEGylated LPs, improving 5-FU efficiency for pre-carcinogenic and carcinogenic skin lesions. The results indicated that the 5-FU-PEGylated LPs-loaded HFM chemowrap patch exhibited desirable physical and mechanical characteristics with complete penetration ability. Furthermore, in vivo skin permeation studies demonstrated the highest percentage of 5-FU permeated the skin (42.06 ± 11.82 %) and skin deposition (75.90 ± 1.13 %) compared to the other treatments, with demonstrated superior percentages of complete wound healing in in vivo (47.00 ± 5.77 % wound healing at day 7) and in NHF cells (92.79 ± 7.15 % at 48 h). Furthermore, 5-FU-PEGylated LPs-loaded HFM chemowrap patches exhibit efficient anticancer activity while maintaining safety for normal cells. The results also show that the developed formulation of a 5-FU-PEGylated LPs-loaded HFM chemowrap patch could enhance apoptosis higher than that of the 5-FU solution. Consequently, 5-FU PEGylated LPs-loaded HFM chemowrap patch represented a promising drug delivery approach for treating pre-carcinogenic and carcinogenic skin lesions.

Manganese-Loaded Liposomes: An In Vitro Study for Possible Diagnostic Application.

The present study investigates the possible use of manganese (Mn)-based liposomal formulations for diagnostic applications in imaging techniques such as magnetic resonance imaging (MRI), with the aim of overcoming the toxicity limitations associated with the use of free Mn2+. Specifically, anionic liposomes carrying two model Mn(II)-based compounds, MnCl2 (MC) and Mn(HMTA) (MH), were prepared and characterised in terms of morphology, size, loading capacity, and in vitro activity. Homogeneous dispersions characterised mainly by unilamellar vesicles were obtained; furthermore, no differences in size and morphology were detected between unloaded and Mn-loaded vesicles. The encapsulation efficiency of MC and MH was evaluated on extruded liposomes by means of ICP-OES analysis. The obtained results showed that both MC and MH are almost completely retained by the lipid portion of liposomes (LPs), with encapsulation efficiencies of 99.7% for MC and 98.8% for MH. The magnetic imaging properties of the produced liposomal formulations were investigated for application in a potential preclinical scenario by collecting magnetic resonance images of a phantom designed to compare the paramagnetic contrast properties of free MC and MH compounds and the corresponding manganese-containing liposome dispersions. It was found that both LP-MC and LP-MH at low concentrations (0.5 mM) show better contrast (contrast-to-noise ratios of 194 and 209, respectively) than solutions containing free Mn at the same concentrations (117 and 134, respectively) and are safe to use on human cells at the selected dose. Taken together, the results of this comparative analysis suggest that these liposome-containing Mn compounds might be suitable for diagnostic purposes.

Association of mucoadhesive polymeric matrices and liposomes for local delivery of miconazole: A new approach for the treatment of oral candidiasis

Since the local treatment of oral candidiasis usually requires long-term administration of the antifungal drug, an ideal dosage form should be able to maintain the drug release over an extended period, assuring an adequate concentration at the infection site. In this context, we have considered the possibility of a buccal delivery of miconazole nitrate (MN) by mucoadhesive polymeric matrices. The loading of the antifungal drug in a hydrophilic matrix was made possible by taking advantage of the amphiphilic nature of liposomes (LP).The MN-loaded LP were prepared by a thin film evaporation method followed by extrusion, while solid matrices were obtained by freeze-drying a suspension of the LP in a polymeric solution based on chitosan (CH), sodium hyaluronate (HYA), or hydroxypropyl methylcellulose (HPMC).MN-loaded LP measured 284.7 ± 20.1 nm with homogeneous size distribution, adequate drug encapsulation efficiency (86.0 ± 3.3 %) and positive zeta potential (+47.4 ± 3.3). CH and HYA-based formulations almost completely inhibited C. albicans growth after 24 h, even if the HYA-based one released a higher amount of the drug. The CH-based matrix also provided the best mucoadhesive capacity and therefore represents the most promising candidate for the local treatment of oral candidiasis.

Nintedanib and miR-29b co-loaded lipoplexes in idiopathic pulmonary fibrosis: formulation, characterization, and in vitro evaluation

Objective This study was aimed to develop a cationic lipoplex formulation loaded with Nintedanib and miR-29b (LP-NIN-miR) as an alternative approach in the combination therapy of idiopathic pulmonary dibrosis (IPF) by proving its additive anti-fibrotic therapeutic effects through in vitro lung fibrosis model. Significance This is the first research article reported that the LP-NIN-MIR formulations in the treatment of IPF. Methods To optimize cationic liposomes (LPs), quality by design (QbD) approach was carried out. Optimized blank LP formulation was prepared with DOTAP, CHOL, DOPE, and DSPE-mPEG 2000 at the molar ratio of 10:10:1:1. Nintedanib loaded LP (LPs-NIN) were produced by microfluidization method and were incubated with miR-29b at room temperature for 30 min to obtain LP-NIN-miR. To evaluate the cellular uptake of LP-NIN-miR, NIH/3T3 cells were treated with 20 ng.mL-1 transforming growth factor-β1 (TGF-β1) for 96 h to establish the in vitro IPF model and incubated with LP-NIN-miR for 48 h. Results The hydrodynamic diameter, polydispersity index (PDI), and zeta potential of the LP-NIN-miR were 87.3 ± 0.9 nm, 0.184 ± 0.003, and +24 ± 1 mV, respectively. The encapsulation efficiencies of Nintedanib and miR-29b were 99.8% ± 0.08% and 99.7% ± 1.2%, respectively. The results of the cytotoxicity study conducted with NIH/3T3 cells indicated that LP-NIN-miR is a safe delivery system. Conclusions The outcome of the transfection study proved the additive anti-fibrotic therapeutic effect of LP-NIN-miR and suggested that lipoplexes are effective delivery systems for drug and nucleic acid to the NIH/3T3 cells in the treatment of IPF.

Preparation and characterization of bionics Oleosomes with high loading efficiency: The enhancement of hydrophobic space and the effect of cholesterol

Liposomes (LIP) loaded with natural active ingredients have significant potential in the food industry. However, their low loading efficiency (LE) hampers the advancement of liposomal products. To improve the loading capacity of functional compounds, bionic oleosomes (BOLE) with a monolayer of phospholipid membranes and a glyceryl tricaprylate/caprate (GTCC) oil core have first been engineered by high-pressure homogenization. TEM revealed that the core of BOLE consists of GTCC instead of water, thereby extending the hydrophobic space. Steady-state fluorescence and active loading experiments confirmed that cholesterol (CH) detached from the phospholipid membrane and entered the oil core, where it repelled cannabidiol (CBD). Based on the extending hydrophobic space, CBD-BOLE was prepared and its LE was 3.13 times higher than CBD-LIP. The CBD-phospholipid ratio (CPR) of CBD-BOLE significantly improved at least 7.8 times. Meanwhile, the free radical scavenging activity of CBD was increased and cytotoxicity was reduced.

HGG-51. INTRANASAL DELIVERY OF PDGFRA-IMMUNOLIPOSOMAL SN-38 FOR THE TREATMENT OF PEDIATRIC HIGH-GRADE GLIOMAS

Abstract INTRODUCTION pHGGs are the most common cause of cancer-related death in children, of which the most malignant and devastating tumors include diffuse midline glioma (DMG). Its anatomical location in the braistem, infiltrative nature, and blood-brain barrier (BBB) limit surgical resection and the distribution of systemically administered drugs. Intranasal delivery (IND) is a noninvasive method that bypasses the BBB, by leveraging the unique anatomic connections of the olfactory and trigeminal nerve pathways with the nasal cavity. We previously demonstrated the efficacy of IND of liposomal (LS) formulation of the active metabolite of the DNA topoisomerase I inhibitor, irinotecan, LS-SN-38, in orthotopic human brainstem xenograft models. The specificity of liposomes can be enhanced by using immunoliposome (iLS) formulation, which are coated with antibodies specific to the tumor cells leading to targeted drug delivery and reduced toxicity to normal cells. Platelet-derived growth factor receptor alpha (PDGFRA) plays a role in DMG oncogenesis and is expressed in as much as 70% of DMG by immunohistochemistry. In this study, we evaluated the specificity of anti-PDGFRA monoclonal antibody conjugated immunoliposome (PDGFRA-iLS) in pHGG cell lines. METHODS PDGFRA signals were assessed in pHGG cells using western blotting. Cells with high and low expression of PDGFRA were treated with rhodamine (Rho) labeled PDGFRA-iLS and imaged with fluorescent microscope. RESULTS DIPG007, SF7761 and KNS42 expressed high levels of PDGFRA, while SF8628 and DIPG36 cells showed low expression. Fluorescence microscopy revealed high PDGFRA-rhodamine (Rho)-iLS expression in DIPG007 cells (PDGFRA high), relative to SF8628 and DIPG36 cells (PDGFRA low). CONCLUSION PDGFRA-Rho-iLS shows increase cellular uptake in DIPG cells. Work is underway to determine the biodistribution, host toxicity, and anti-tumor activity of IND of PDGFRA-iLS-SN- 38 alone and in combination with radiation therapy in pHGG xenograft models.

Organ-selective lipid nanoparticles for precise cancer therapy: Beyond liposomes and polymeric micelles

Regulating the biodistribution of nanoparticle-based drug delivery systems (NDDSs) by tailoring their physicochemical properties for organ-selective drug delivery is a rational strategy for precise therapy of organ-related cancer. Unfortunately, it remains inconclusive and even conflicting as to the correlation between the physicochemical properties of NDDSs and their biodistribution, due to the interplay of the physicochemical properties, high diversity of NDDSs type, and lack of a criteria for biodistribution evaluation. We synthesized lipid nanoparticles (LNPs), liposomes (LPs), and polymeric micelles (PMs), the most successful NDDSs, with different compositions and surface charges, and systematically compared their biodistribution by determining loaded docetaxel (DTX). It was found that LNPs, regardless of composition and surface charge, showed generally improved biodistribution in the liver, spleen, and lung compared with LPs and PMs. Stiffer structure of LNPs than LPs contributed to the improved biodistribution by improving their pharmacokinetics and cell uptake, which was theoretically and experimentally verified. More importantly, results further suggested that lipid composition, especially lipid combination, profoundly impacted the biodistribution of LNPs and accurately tailoring LNPs formulation using commercially available lipids could effectuate selective biodistribution to the lung or liver. In lung- and liver-related tumor models, LNPs exhibited enhanced therapeutic potency, as compared to LPs and PMs, which was further significantly enhanced once endowed with organ selectivity. While LNPs are mainly focused on delivering nucleic acid molecules, this work first unveils therapeutic superiority of LNPs as carrier of chemotherapeutic agents over LPs and PMs, and highlights the potential of organ-selective LNPs in precise cancer therapy.

Treatment of hemophilic arthropathy by immunomodulatory extracellular vesicle delivered by liposome hybrid nanoparticles

In individuals afflicted with hemophilia, characterized by a deficiency of coagulation factor VIII (FVIII), the occurrence of spontaneous recurrent intra-articular hemorrhage precipitates the emergence of hemophilic arthropathy (HA). Although clotting factor replacement therapy reduces joint bleeding clinically, clotting factors need to be injected frequently due to the rapid diffusion of the drug. Hence, a novel drug delivery approach may be developed to improve the drug therapy. Platelet-derived extracellular vesicles (PEVs) are known to possess anti-inflammatory and hemostatic properties and could be used as a potential HA therapy. In this study, we constructed a PEV-LS@FVIII nanotherapeutic system by combining thioketal (TK), liposomes (LS), and FVIII to form the LS@FVIII complexes, and then hybridizing PEV with LS@FVIII. Our results demonstrated that PEV-LS@FVIII could efficiently facilitate FVIII delivery and specifically target the injured knee joint. Both in vitro and in vivo studies showed a reduction in the M1 phenotype of macrophages and an enhancement of the M2 phenotype, compared to FVIII free control. Furthermore, PEV-LS@FVIII appeared to alleviate HA-induced cartilage damage. In conclusion, our findings demonstrate that PEV-LS@FVIII could delay the progression of HA by targeting bleeding joints, modulating macrophage polarization to suppress inflammation, and mitigating cartilage damage.

Formulation, development and evaluation of hyaluronic acid-conjugated liposomal nanoparticles loaded with regorafenib and curcumin and their in vitro evaluation on colorectal cancer cell lines

Colorectal cancer is one of the major causes of global cancer, with chemotherapy and radiation therapy being effective but limited due to low specificity. Regorafenib, a multikinase inhibitor, provides hope to patients with metastatic colorectal cancer and was approved by the FDA in 2012. However, due to resistance issues and adverse events, its efficacy is compromised, necessitating further refinement. Meanwhile, curcumin, a compound of turmeric, exhibits anticancer effects through antioxidant and anti-inflammatory actions, induction of the apoptosis, arrest of cell cycle, inhibition of angiogenesis, and modulation of signaling pathways. Unfortunately, its clinical utility is limited by its poor bioavailability, pointing towards innovative drug delivery strategies for enhanced efficacy in colorectal cancer treatment.Hyaluronic acid (HA)-decorated liposomes (LIPO) have been developed to target colorectal cells through an overexpressed CD44 receptor, increasing antitumor and antimetastasis efficacy. This study investigates the possibility of loading curcumin (CUR) or regorafenib (REGO) into a liposomal formulation for passive and HA-actively targeted treatment, evaluating its critical quality attributes (CQA) (size, zeta potential, polydispersity index) and cytotoxic activity in the HT29 colorectal cancer cell line. The average particle size of the plain liposomes and those decorated with HA was 144.00 ± 0.78 nm and 140.77 ± 1.64 nm, respectively. In contrast, curcumin-loaded plain liposomes and HA-decorated liposomes had 140 ± 2.46 nm and 164.53 ± 15.13 nm, respectively. The prepared liposomes had a spherical shape with a narrow size distribution and an acceptable zeta potential of less than −30 mV. The encapsulation efficiency was 99.2 % ± 0.3 and 99.9 ± 0.2 % for HA-decorated and bare regorafenib loaded. The % EE was 98.9 ± 0.2 % and 97.5 ± 0.2 % for bare liposomal nanoparticles loaded with curcumin and coated with curcumin. The IC50 of free REGO, CUR, REGO-LIPO, CUR-LIPO, REGO-LIPO-HA and CUR-LIPO-HA were 20.17 ± 0.78, 64.4 ± 0.33, 224.8 ± 0.06, 49.66 ± 0.22, 73.66 ± 0.6, and 27.86 ± 0.49 µM, respectively. The MTT assay in HT29 cells showed significant cytotoxic activity of the HA-decorated liposomal formulation compared to the base uncoated formulation, indicating that hyaluronic acid-targeted liposomes loaded with regorafenib or curcumin could be a promising targeted formulation against colorectal cancer cells.

Cell selective BCL-2 inhibition enabled by lipid nanoparticles alleviates lung fibrosis

Idiopathic pulmonary fibrosis (IPF) is a devastating lung disease with a high mortality rate due to limited treatment options. Current therapies cannot effectively reverse the damage caused by IPF. Research suggests that promoting programmed cell death (apoptosis) in myofibroblasts, the key cells driving fibrosis, could be a promising strategy. However, inducing apoptosis in healthy cells like epithelial and endothelial cells can cause unwanted side effects. This project addresses this challenge by developing a targeted approach to induce apoptosis specifically in myofibroblasts. We designed liposomes (LPS) decorated with peptides that recognize VCAM-1, a protein highly expressed on myofibroblasts in fibrotic lungs. These VCAM1-targeted LPS encapsulate Venetoclax (VNT), a small molecule drug that inhibits BCL-2, an anti-apoptotic protein. By delivering VNT directly to myofibroblasts, we hypothesize that VCAM1-VNT-LPS can selectively induce apoptosis in these cells, leading to reduced fibrosis and improved lung function. We successfully characterized VCAM1-VNT-LPS for size, surface charge, and drug loading efficiency. Additionally, we evaluated their stability over three months at different temperatures. In vitro and in vivo studies using a bleomycin-induced mouse model of lung fibrosis demonstrated the therapeutic potential of VCAM1-VNT-LPS. These studies showed a reduction in fibrosis-associated proteins (collagen, α-SMA, VCAM1) and BCL-2, while simultaneously increasing apoptosis in myofibroblasts. These findings suggest that VCAM1-targeted delivery of BCL-2 inhibitors using liposomes presents a promising and potentially selective therapeutic approach for IPF.

Cadherin-11 targeted cell-specific liposomes enabled skin fibrosis treatment by inducing apoptosis

Continuous and aberrant activation of myofibroblasts is the hallmark of pathological fibrosis (e.g., abnormal wound healing). The deposition of excessive extracellular matrix (ECM) components alters or increases the stiffness of tissue and primarily accounts for multiple organ dysfunctions. Among various proteins, Cadherin-11 (CDH11) has been reported to be overexpressed on myofibroblasts in fibrotic tissues. Anti-apoptotic proteins such as (B cell lymphoma-2) (BCL-2) are also upregulated on myofibroblasts. Therefore, we hypothesize that CDH11 could be a targeted domain for cell-specific drug delivery and targeted inhibition of BCL-2 to ameliorate the development of fibrosis in the skin. To prove our hypothesis, we have developed liposomes (LPS) conjugated with CDH11 neutralizing antibody (antiCDH11) to target cell surface CDH11 and loaded these LPS with a BCL-2 inhibitor, Navitoclax (NAVI), to induce apoptosis of CDH11 expressing fibroblasts. The developed LPS were evaluated for physicochemical characterization, stability, in vitro therapeutic efficacy using dermal fibroblasts, and in vivo therapeutic efficacy in bleomycin-induced skin fibrosis model in mice. The findings from in vitro and in vivo studies confirmed that selectivity of LPS was improved towards CDH11 expressing myofibroblasts, thereby improving therapeutic efficacy with no indication of adverse effects. Hence, this novel research work represents a versatile LPS strategy that exhibits promising potential for treating skin fibrosis.

Construction of various lipid carriers to study the transdermal penetration mechanism of sinomenine hydrochloride

Objective To investigate the transdermal mechanisms and compare the differences in transdermal delivery of Sinomenine hydrochloride (SN) between solid lipid nanoparticles (SLN), liposomes (LS), and nanoemulsions (NE). Methods SN-SLN, SN-LS and SN-NE were prepared by ultrasound, ethanol injection and spontaneous emulsification, respectively. FTIR, DSC, in vitro skin penetration, activation energy (Ea) analysis were used to explore the mechanism of drug penetration across the skin. Results The particle size and encapsulation efficiency were 126.60 nm, 43.23 ± 0.48%(w/w) for SN-SLN, 224.90 nm, 78.31 ± 0.75%(w/w) for SN-LS, and 83.22 nm, 89.01 ± 2.16%(w/w) for SN-LS. FTIR and DSC showed the preparations had various levels of impacts on the stratum corneum’s lipid structure which was in the order of SLN > NE > LS. Ea values of SN-SLN, SN-LS, and SN-NE crossing the skin were 2.504, 1.161, and 2.510 kcal/mol, respectively. Conclusion SLN had a greater degree of alteration on the skin cuticle, which allows SN to permeate skin more effectively.

Liposome-based dry powder vaccine immunization targeting the lungs induces broad protection against pneumococcus

Streptococcus pneumoniae is an important human pathogen. Currently used conjugate vaccines are effective against invasive disease, but protection is restricted to serotypes included in the formulation, leading to serotype replacement. Furthermore, protection against non-invasive disease is reported to be considerably lower. The development of a serotype-independent vaccine is thus important and Pneumococcal surface protein A (PspA) is a promising vaccine candidate. PspA shows some diversity and can be classified in 6 clades and 3 families, with families 1 and 2 being the most frequent in clinical isolates. The ideal vaccine should thus induce protection against the two most common families of PspA. The aim of this work was to develop a liposome-based vaccine containing PspAs from family 1 and 2 and to characterize its immune response. Liposomes (LP) composed of dipalmitoylphosphatidylcholine (DPPC) and 3β-[N-(N′,N′-dimethylaminoethane)-carbamoyl]cholesterol (DC-Chol) with or without α-galactosylceramide (α-GalCer) were produced by microfluidics, encapsulating PspA from clade 1 (PspA1, family 1) and/or clade 4 (PspA4Pro, family 2) followed by spray-drying with trehalose to form nanocomposite microparticles carriers (NCMP). LP/NCMPs showed good stability and preservation of protein activity. LP/NCMPs containing PspA1 and/or PspA4Pro were used for immunization of mice targeting the lungs. High serum IgG antibody titers against both PspA1 and PspA4Pro were detected in animals immunized with LP/NCMPs containing α-GalCer, with a balance of IgG1 and IgG2a titers. IgG in sera from immunized mice bound to pneumococcal strains from different serotypes and expressing different PspA clades, indicating broad recognition. Mucosal IgG and IgA were also detected. Importantly, immunization with LP/NCMPs induced full protection against strains expressing PspAs from family 1 and 2. Furthermore, CD4+ resident memory T cells were detected in the lungs of the immunized animals that survived the challenge.

Co-delivery of VEGF and amoxicillin using LP-coated co-axial electrospun fibres for the potential treatment of diabetic wounds

Diabetic complications present throughout a wide range of body tissues, however one of the most widely recognised complications remains to be chronic diabetic wounds. Current treatment options largely rely on standard wound treatment routines which provide no promotion of wound healing mechanisms at different physiological stages of repair. Recently materials produced using novel additive manufacturing techniques have been receiving attention for applications in wound care and tissue repair. Additive manufacturing techniques have recently been used in the interest of targeted drug delivery and production of novel materials resembling characteristics of native tissues. The potential to exploit these highly tailorable manufacturing techniques for the design of novel wound care remedies is highly desirable.In the present study two additive manufacturing techniques are combined to produce a scaffold for the treatment of diabetic wounds. The combination of microfluidic manufacturing of an antimicrobial liposome (LP) formulation and a coaxial electrospinning method incorporating both antimicrobial and proangiogenic factors allowed dual delivery of therapeutics to target both infection and lack of vascularisation at wound sites. The coaxial fibres comprised of a polyvinyl alcohol (PVA) core containing vascular endothelial growth factor (VEGF) and a poly (l-lactide-co-ε-caprolactone) (PLCL) shell blended with amoxicillin (Amox). Additionally, a liposomal formulation was produced to incorporate Amox and adhered to the surface of fibres loaded with Amox and VEGF. The liposomal loading provided the potential to deliver a much higher, more clinically relevant dose of Amox without detrimentally changing the mechanical properties of the material. The growth factor release was sustained up to 7-days in vitro. The therapeutic effect of the antibiotic loading was analysed using a disk diffusion method with a significant increase in zone diameter following LP adhesion, proving the full scaffold system had improved efficacy against both Gram-positive and Gram-negative strains. Additionally, the dual-loaded scaffolds show enhanced potential for supporting vascular growth in vitro, as demonstrated via a viability assay and tubule formation studies. Results showed a significant increase in the average total number of tubes from 10 in control samples to 77 in samples fully-loaded with Amox and VEGF.

Synthesis of (10-hydroxycamptothecin intercalated layered zinc hydroxide nitrate)@liposome nanocomposites for improving drug-release performance

A hierarchical nanocomposite of 10-hydroxycamptothecin (HCPT), a nonionic and lipophilic anticancer agent, intercalated layered zinc hydroxide nitrate (LZH) encapsulated in liposomes was fabricated. HCPT molecules were incorporated into sodium cholate (Ch) micelles, and the resulting negatively charged HCPT-loaded Ch micelles were then introduced into the LZH galleries to form an HCPT/Ch intercalated LZH (designated HCPT-Ch-LZH) host-guest nanohybrid. The nanohybrid particles were then coated with liposomes (LSs), resulting in the formation of a core-shell nanocomposite denoted as (HCPT-Ch-LZH)@LS. Using XRD, FT-IR, SEM, TEM, DLS, and elemental analyses, the obtained samples were characterized. Particular attention was paid to the effect of liposome-coating on the HCPT-Ch-LZH's water solubility and drug release. The results demonstrate that the nanocomposite has superior water dispersity and enhanced drug sustained-release performance compared to HCPT-Ch-LZH, indicating that the liposome-coating of drug-LZH nanohybrids is an effective strategy for improving their water dispersity and sustained-release performances. This study presents an efficient strategy for constructing LZH-based drug delivery systems for nonionic and lipophilic medicines.

T lymphocyte-derived immunogenic hybrid nanovesicles for immunosuppression reversion and boosted photothermal immunotherapy

Photothermal therapy (PTT) can mediate the immunogenic cell death (ICD) of tumors through photothermal transformation, thus releasing tumor-associated antigens (TAAs) and damage-associated molecular patterns (DAMPs) to stimulate the maturation of dendritic cells (DCs) and elicit the immune response against tumors. However, PTT-mediated upregulation of the immune checkpoint molecule programmed cell death ligand 1 (PD-L1) will cause the immune evasion of tumor cells and thus increases the immunosuppression of cytotoxic T lymphocytes (CTLs), resulting in restricted photothermal immune activation. Taking advantage of the high expression of programmed cell death protein 1 (PD-1) in T lymphocytes, we develop an immunogenic photothermal hybrid nanovesicle to reverse immunosuppression and enhance PTT-induced ICD. The hybrid vesicle (TMVL-I) is constructed by phospholipid bilayer fusion of T cell-derived membrane vesicle (TMV) with high PD-1 expression and the indocyanine green (ICG)-loaded thermosensitive liposome (L-I). TMVL-Is bind to the tumor cells with PTT-induced upregulation of PD-L1, effectively blocking the PD-1/PD-L1 pathway between CTLs and tumor cells, thus reversing PD-L1-mediated tumor immunosuppression and intensifying photothermal-induced ICD effects. These processes significantly induce the maturation of DCs and enhance the infiltration of CTLs into both primary and distal tumors and the activation of spleen CTLs, strongly inhibiting the growth of B16 xenograft tumors and greatly improving the survival rate of B16 xenograft mice. This work provides a feasible strategy for immunosuppressive microenvironment reprogramming-based combination therapy.

Targeted nanotherapy platform mediated tumor-infiltrating CD8+ T cell immune function effects for collaborative anti-tumor photothermal immunotherapy for cervical cancer.

Photothermal immunotherapy is an innovative approach to cancer treatment. It combines immunomodulators and photothermal agents, both targeted to the tumor site. This therapy harnesses the heat generated by photothermal conversion to damage tumor cells while simultaneously releasing tumor-associated antigens. This process enhances the anti-tumor immune response of tumor-infiltrating lymphocytes (TILs) within the tumor microenvironment (TME). Photothermal immunotherapy is gaining prominence as a new method for cancer treatment. It is a current focal point in research due to its targeted efficacy, minimal systemic side effects, and reduced risk of treatment resistance. This study employed a thin-film dispersion method to fabricate liposomes (LIPO) as composite drug carriers. Indocyanine green (ICG) for clinical use was utilized as a photothermal agent (PTA), and folate (FA) was employed as a targeting agent for the nano-composite material. We encapsulated the immunoadjuvant CpG ODN within the FA@LIPO@ICG nano-system, resulting in the formation of targeted nanoparticles (NPs) for photothermal immunotherapy (FA@LIPO@ICG@CpG), and assessed the drug encapsulation rate. FA@LIPO@ICG@CpG NPs demonstrated excellent water solubility with an average size ranging from 100 to 200 nm. Furthermore, we investigated the photothermal properties of FA@LIPO@ICG@CpG NPs. Under 808 nm laser irradiation, the photothermal conversion efficiency of FA@LIPO@ICG@CpG NPs reached 39.05%. Subsequently, under 808 nm laser excitation, we conducted an analysis of lymphocyte subpopulations and their functional changes in U14 tumor-bearing mice by using flow cytometry. This treatment approach demonstrated remarkable anti-tumor efficacy. Consequently, FA@LIPO@ICG@CpG NPs hold substantial promise as a novel and promising strategy in cancer therapy.