A triple chain polycationic peptide-mimicking amphiphile - efficient DNA-transfer without co-lipids.

Non-viral gene delivery in its current form is largely dependent upon the ability of a delivery vehicle to protect its cargo in the extracellular environment and release it efficiently inside the target cell. Also a simple delivery system is required to simplify a GMP conform production if a marketing authorization is striven for. This work addresses these problems. We have developed a synthetic polycationic peptide-mimicking amphiphile, namely DiTT4, which shows efficient transfection rates and good biocompatibility without the use of a co-lipid in the formulation. The lipid-nucleic acid complex (lipoplex) was characterized at the structural (electron microscopy), physical (laser Doppler velocimetry and atomic force microscopy) and molecular levels (X-ray scattering). Stability studies of the lipoplexes in the presence of serum and heparin indicated a stable formation capable of protecting the cargo against the extracellular milieu. Hemocompatibility studies (hemolysis, complement activation and erythrocyte aggregation) demonstrated the biocompatibility of the formulation for systemic administration. The transfection efficiency was assessed in vitro using the GFP assay and confocal laser scanning microscopy studies. With the chorioallantoic membrane model, an animal replacement model according to the 3R strategy (replacement, refinement, and reduction), initial in vivo experiments were performed which demonstrate fast and efficient transfection in complex tissues and excellent biocompatibility.

Stabilized tetraether lipids based particles guided prophyrins photodynamic therapy.

Photodynamic therapy (PDT) that involves ergonomically delivered light in the presence of archetypical photosensitizer such as Protoporphyrin IX (PpIX) is a time-honored missile strategy in cancer therapeutics. Yet, the premature release of PpIX is one of the most abundant dilemma encounters the therapeutic outcomes of PDT due to associated toxicity and redistribution to serum proteins. In this study, ultrastable tetraether lipids (TELs) based liposomes were developed. PpIX molecules were identified to reside physically in the monolayer; thereby the inherent π-π stacking that leads to aggregation of PpIX in aqueous milieu was dramatically improved. TEL29.9 mol% and TEL62mol% based liposomes revealed PpIX sustained release diffusion pattern from spherical particles as confirmed by converged fitting to Baker & Lonsdale model. Stability in presence of human serum albumins, a key element for PDT accomplishment was emphasized. The epitome candidates were selected for vascular photodynamic (vPDT) in in-Ovo chick chorioallantoic membrane. Profoundly, TEL62mol% based liposomes proved to be the most effective liposomes that demonstrated localized effect within the irradiated area without eliciting quiescent vasculatures damages. Cellular photodynamic therapy (cPDT) revealed that various radiant exposure doses of 134, 202, 403 or 672 mJ.cm-2 could deliberately modulate the photo-responses of PpIX in TEL-liposomes.

Lipid coated chitosan-DNA nanoparticles for enhanced gene delivery.

Chitosan as a polycationic non-viral vector for gene delivery has the advantage of being a biocompatible and biodegradable polymer. However, without laborious chemical modifications to its structure, it is of limited use as a gene delivery vehicle due to its low ability to efficiently transfect under physiological conditions. To address this problem, we developed novel liposome encapsulated chitosan nanoparticles; lipochitoplexes (LCPs). Chitosan nanoparticles (CsNPs) were obtained using the ionic gelation technique. For this purpose, an ultrapure low molecular weight chitosan with a high degree of deacetylation was cross-linked using polyanionic tripolyphosphate resulting in efficient entrapment of plasmid DNA (pDNA) inside the nanoparticles. LCPs were prepared by incubating chitosan nanoparticles together with anionic liposomes (DPPC/Cholesterol). The LCPs offered better pDNA protection, reduced cytotoxicity and at least twofold increase in the transfection efficiency under physiological conditions. The efficiency of our delivery vehicle was also proved in vivo in the chorioallantoic membrane model (CAM). LCPs were able to transfect the CAM without traumatising the surrounding blood vessels. This new biocompatible composite system devoid of chemical modifications, organic solvents and harsh production conditions makes it an optimal gene delivery vehicle for in vivo applications offering new insights into the field of non-viral gene therapy.

Low level LED photodynamic therapy using curcumin loaded tetraether liposomes.

Oncological use of photodynamic therapy is an evolving field in cancer therapeutics. Photosensitisers are prone to accumulation inside healthy tissues causing undesirable effects. To avoid this, we have developed tetraether lipid liposomal formulations containing curcumin which is a naturally occurring anti-cancer substance and deemed to be safe towards healthy cells. Upon excitation with light at a specific wavelength, curcumin produces reactive oxygen species (ROS) in presence of oxygen, thereby exhibiting a cytotoxic effect towards the surrounding tissues, giving a total control on the onset of therapy. In our study, we examined two different liposomal formulations wherein curcumin is encapsulated within the hydrophobic milieu with the intent to increase its bioavailability. Hydrodynamic diameter, surface charge, stability, morphology and haemocompatibility of the liposomes were studied. The results confirmed the formation of stable nanometre range liposomal vesicles (200-220 nm) containing curcumin which were haemocompatible with coagulation time less than 50 s and a haemolytic potential below 40%. Increased ROS generation post irradiation (>50% compared to un-irradiated samples) was confirmed using fluorescence spectroscopy. The efficiency and selectivity of the PDT was demonstrated by assessing their viability post irradiation and by qualitative analysis using confocal microscopy showing nuclear perforation induced by PDT. Photo-destructive effects of PDT on the microvasculature were studied in vivo using chick chorioallantoic membrane model (CAM). Considerable phototoxicity could be observed in the irradiated area of the CAM 30 min post irradiation. Phototoxic effects in vitro (in SK-OV-3 and PCS-100-020™) and in vivo (in chorioallantoic membrane model) in combination with a novel custom manufactured LED irradiating device showed a formulation dependant selective photodynamic effect of the curcumin liposomes.

Photo-responsive tetraether lipids based vesicles for prophyrin mediated vascular targeting and direct phototherapy.

Tetraether lipids (TELs) derived from the thermoacidophilic archaeon Sulfolobus acidocaldarius are dominated by polyisoprenoid skeleton. The unique molecular stability of TELs is attributed to the presence of cyclopentane rings, methyl side groups and sugar residues that create extensive hydrogen bond network. In addition, the presence of ether linkages and the lacking of double bonds make them an epitome candidate for photodynamic therapy (PDT). A subtle blend of formulation design to trigger efficient photo responses of protoporphyrin IX (PpIX) exploiting TELs was developed. The platform has demonstrated in principle a practical potential in PDT in terms of prompt Vascular Targeting Photodynamic therapy (VTP) in-ovo chick chorioallantoic membrane (CAM) model. Short PpIX-light interval was associated with thrombosis and massive vascular occlusion in and out the irradiated area after TEL9mol% liposomes have been intravenously injected. Profoundly, TEL62mol% liposomes have proved to be the most effective liposomes that demonstrated localized suppression of angiogenesis in the irradiated area without quiescent vasculature damage. The massive thrombotic effect was no longer observed and eventually the chick has survived. After long PpIX-light interval, TEL62mol% has deliberately gained metronomic PDT at low rate of PpIX dosimetry and the radiant exposure doses in human ovarian carcinoma (SKOV-3) cells as determined by PpIXIC50. These findings could be explained by the fact that TELs impart a remarkable stability to the liposomal bilayer that makes them a potential platform for photodynamic applications.

Composite liposome-PEI/nucleic acid lipopolyplexes for safe and efficient gene delivery and gene knockdown.

Cytotoxicity is a major drawback impeding the therapeutic use of gene delivery and gene down-regulation vehicles. Apart from cytotoxicity, rapid degradation and low cellular uptake are other major factors affecting therapeutic use. Considering the above factors, formulation and development of PEI (Polyethylenimine) based, liposome encapsulated delivery vehicles with improved transfection efficiency and low cytotoxicity which can be used for gene delivery and gene knockdown. DOPE (1,2-Dioleoyl-sn-glycero-3-phosphoethanolamine), DPPC (Dipalmitoylphosphatidylcholine) and cholesterol have been considered as lipids of choice bearing in mind various factors such as rigidness and surface charge which greatly influence the formation of liposomes, polyplex encapsulation and transfection efficiency. For the condensation of plasmid DNA (pDNA) and short interfering RNA (siRNA), branched PEI 25kDa (bPEI) and deacylated linear PEI 22kDa (lPEI) were employed. lPEI and siRNA polyplexes encapsulated within DOPE/DPPC/Cholesterol (DDC) liposomes exhibited higher luc (luciferase) gene knockdown in vitro compared to the controls. They also showed superior transfection efficiencies compared to polyplexes in experiments using pCMV-luc (luciferase reporter plasmid) and pEGFP-N1 (Green Fluorescence protein reporter plasmid). This can partly be attributed to the improved integrity imparted by the liposomal layer which was confirmed by complex stability and integrity assays. Cytotoxicity and coagulation time assays of DDC-lPEI based lipopolyplexes showed decreased cytotoxic potential and negligible influence on coagulation respectively for compared to polyplexes, thus rendering them suitable for gene therapy.

Covalent immobilization of lysozyme onto woven and knitted crimped polyethylene terephthalate grafts to minimize the adhesion of broad spectrum pathogens.

Graft-associated infections entirely determine the short-term patency of polyethylene terephthalate PET cardiovascular graft. We attempted to enzymatically inhibit the initial bacterial adhesion to PET grafts using lysozyme. Lysozyme was covalently immobilized onto woven and knitted forms of crimped PET grafts by the end-point method. Our figures of merit revealed lysozyme immobilization yield of 15.7 µg/cm(2), as determined by the Bradford assay. The activity of immobilized lysozyme on woven and knitted PET manifested 58.4% and 55.87% using Micrococcus lysodeikticus cells, respectively. Noteworthy, the adhesion of vein catheter-isolated Staphylococcus epidermidis decreased by 6- to 8-folds and of Staphylococcus aureus by 11- to 12-folds, while the Gram-negative Escherichia coli showed only a decrease by 3- to 4-folds. The anti-adhesion efficiency was specific for bacterial cells and no significant effect was observed on adhesion and growth of L929 cells. In conclusion, immobilization of lysozyme onto PET grafts can inhibit the graft-associated infection.

Bipolar tetraether lipids derived from thermoacidophilic archaeon Sulfolobus acidocaldarius for membrane stabilization of chlorin e6 based liposomes for photodynamic therapy.

The initial burst release of water-soluble photosensitizers is one of the major problems encountered the development of controlled release formulations. In this study, the freely water soluble chlorin e6 (Ce6) was assembled with cationic lipid 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP) to improve its loading efficiency in the liposomal bilayer. Tetraether lipids (TELs) derived from Sulfolobus acidocaldarius were added to DOTAP:Ce6 assembly in a concentration range of 2.5×10(-4)-1.6×10(-3)M to stabilize the membrane rigidity of the liposomes and to provide controlled release system. From the comparative spectroscopic experiments, it has been shown that the assembled DOTAP:Ce6 along with addition of TELs have improved the loading efficiency of Ce6 in TELs-liposomes and obviously modified the release profile of Ce6. The in vitro cell viability of Ce6 in mouse neuro-blastoma (Neuro-2a) and ovarian cell carcinoma (SK-OV-3) confirmed neglected dark cytotoxicity and presented potential photo-induced cytotoxicity with the effect was being more pronounced in Neuro 2a than in SK-OV-3. In-situ IV-injection of chick chorioallantoic membrane (CAM) showed hemorrhage and necrosis 30 min post irradiation at 1.8 mol% TELs (19.9J/cm(2)). Higher TELs of 2.2 and 3.7 mol% in particular demonstrated localized vascular destruction within the irradiated area. Our results suggest that TELs favored slower release rates of Ce6. This, in turn, tetraether lipids can be considered as a versatile class of lipids for photodynamic modality for destruction of cancer cells and tumor vasculature while sparing the quiescent ones.

Development of thrombus-resistant and cell compatible crimped polyethylene terephthalate cardiovascular grafts using surface co-immobilized heparin and collagen.

Short-term patency of polyethylene terephthalate (PET) cardiovascular grafts is determined mainly by the inherent thrombogenicity and improper endothelialization following grafts implantation. The aim of the present study was to immobilize heparin to develop thrombus resistant grafts. Additionally, collagen was co-immobilized to enhance the host cell compatibility. The synthetic woven and knitted forms of crimped PET grafts were surface modified by Denier reduction to produce functional carboxyl groups. The produced groups were used as anchor sites for covalent immobilization of heparin or co-immobilization of heparin/collagen by the end-point method. The modified surface was characterized using Fourier transform infrared spectroscopy and X-ray photoelectron spectroscopy. The biological activity of immobilized molecules was investigated in vitro using direct blood coagulation test, and "platelet deposition under flow condition. Furthermore, the biocompatibility of modified grafts with host cells was assessed using L929 cell as model. All modified grafts showed significant resistance against fibrin and clot formation. The number of deposited platelets on heparin-immobilized woven and knitted grafts obviously decreased by 3 fold and 2.8 fold per unit surface area respectively, while the heparin/collagen co-immobilized grafts showed only a decrease by 1.7 and 1.8 fold compared to unmodified PET. Heparin-immobilized grafts reported no significant effect on L929 cells adhesion and growth (P>0.05), conversely, collagen co-immobilization considerably increased cell adhesion almost ~1.3 fold and 2 fold per unit surface area for woven and knitted grafts respectively. Our results emphasize that immobilization of heparin minimized the inherent thrombogenicity of the PET grafts. The simultaneous co-immobilization of collagen supported host cell adhesion and growth required for the grafts biocompatibility.

The chorioallantoic membrane assay is a promising ex vivo model system for the study of vascular anomalies.

UNLABELLED: The present feasibility study evaluated the chorioallantoic membrane (CAM) assay established in cancer and angiogenesis research as a tool for the study of vascular anomalies (VAs) in the head and neck area, since the lack of appropriate model systems poses a major obstacle in VA research. MATERIALS AND METHODS: VA tissues from three patients, two with an arteriovenous and one with a lymphatic malformation, were analyzed and evaluated in the CAM assay. RESULTS: The arteriovenous malformations induced a potent angiogenic reaction, resulting in new vessel growth and reperfusion by chicken embryo blood, which was comparable in extent with the positive vascular endothelial growth factor control. An angiogenic reaction, although less pronounced, was also observed in the single-tested lymphatic malformation. CONCLUSION: Our observations indicate the CAM assay to be a suitable model system for the study of VAs, as well as to show how treatment with pro- and antiangiogenic drugs affects VA growth patterns. The CAM assay has the potential to become a valuable tool for VA studies.

α2-Macroglobulin enhances vasculogenesis/angiogenesis of mouse embryonic stem cells by stimulation of nitric oxide generation and induction of fibroblast growth factor-2 expression.

α2-macroglobulin (α2M) is an acute-phase protein released upon challenges like cardiac hypertrophy and infarction. α2M signals via the low density lipoprotein receptor-related protein (LRP-1) and may induce stem cell activation. In the present study, the effects of α2M on vasculogenesis/angiogenesis and underlying signaling cascades were investigated in mouse embryonic stem (ES) cells. LRP-1 was expressed in ES cells and upregulated during differentiation. α2M dose dependently increased CD31-positive vascular structures in ES cell-derived embryoid bodies, the early cardiovascular markers isl-1, Nkx-2.5, and flk-1 as well as numbers of VE-cadherin and flk-1-positive cells, but downregulated α-smooth muscle actin. Enhancement of vasculogenesis/angiogenesis by α2M was abolished by the LRP-1 antagonist receptor-associated protein (RAP) and LRP-1 blocking antibody. Notably, α2M stimulated vascular growth in the chicken chorioallantois membrane assay, but not in a human umbilical vein endothelial cell spheroid model. α2M increased fibroblast growth factor-2 (FGF-2) protein expression, which was abolished by RAP, induced nitric oxide (NO) generation as determined by 4,5-diaminofluorescein diacetate microfluorometry, and activated nitric oxide synthase-3 (NOS-3) as well as extracellular-regulated kinase 1,2 (ERK1/2) and phosphatidyl inositol 3-kinase (PI3K). NO generation, the increase in FGF-2 expression, and the stimulation of vasculogenesis/angiogenesis by α2M were blunted by the NO synthase inhibitor L-NAME, the ERK1/2 inhibitor PD98059, and the PI3K inhibitor LY294002. Furthermore, vasculogenesis/angiogenesis by α2M was inhibited in the presence of the FGF receptor 1 antagonist SU5402. In conclusion, α2M stimulates endothelial and early cardiac, but not smooth muscle differentiation of ES cells through generation of NO, activation of ERK1/2 as well as PI3K, and induction of FGF-2 expression.

Highly potent inhibitors of proprotein convertase furin as potential drugs for treatment of infectious diseases.

Optimization of our previously described peptidomimetic furin inhibitors was performed and yielded several analogs with a significantly improved activity. The most potent compounds containing an N-terminal 4- or 3-(guanidinomethyl)phenylacetyl residue inhibit furin with K(i) values of 16 and 8 pM, respectively. These analogs inhibit other proprotein convertases, such as PC1/3, PC4, PACE4, and PC5/6, with similar potency, whereas PC2, PC7, and trypsin-like serine proteases are poorly affected. Incubation of selected compounds with Madin-Darby canine kidney cells over a period of 96 h revealed that they exhibit great stability, making them suitable candidates for further studies in cell culture. Two of the most potent derivatives were used to inhibit the hemagglutinin cleavage and viral propagation of a highly pathogenic avian H7N1 influenza virus strain. The treatment with inhibitor 24 (4-(guanidinomethyl)phenylacetyl-Arg-Val-Arg-4-amidinobenzylamide) resulted in significantly delayed virus propagation compared with an inhibitor-free control. The same analog was also effective in inhibiting Shiga toxin activation in HEp-2 cells. This antiviral effect, as well as the protective effect against a bacterial toxin, suggests that inhibitors of furin or furin-like proprotein convertases could represent promising lead structures for future drug development, in particular for the treatment of infectious diseases.