M. Ossanlou scite author profile

A detergent dialysis procedure is described which allows of up to 70% and permits inclusion of 'fusigenic' lipids such encapsulation of plasmid DNA within a lipid envelope, as dioleoylphosphatidylethanolamine (DOPE). The in vitro where the resulting particle is stabilized in aqueous media transfection capabilities of SPLP are demonstrated to be by the presence of a poly(ethyleneglycol) (PEG) coating. strongly dependent on the length of the acyl chain conThese 'stabilized plasmid-lipid particles' (SPLP) exhibit an tained in the ceramide group used to anchor the PEG polyaverage size of 70 nm in diameter, contain one plasmid mer to the surface of the SPLP. Shorter acyl chain lengths per particle and fully protect the encapsulated plasmid from result in a PEG coating which can dissociate from the digestion by serum nucleases and E. coli DNase I. Encap-SPLP surface, transforming the SPLP from a stable parsulation is a sensitive function of cationic lipid content, with ticle to a transfection-competent entity. It is suggested that maximum entrapment observed at dioleoyldimethylam-SPLP may have utility as systemic gene delivery systems monium chloride (DODAC) contents of 5 to 10 mol%. The for gene therapy protocols. formulation process results in plasmid-trapping efficiencies

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Encapsulation of Plasmid DNA in Stabilized Plasmid – Lipid Particles Composed of Different Cationic Lipid Concentration for Optimal Transfection Activity

Saravolac

Ludkovski

Skirrow

et al. 2000

Journal of Drug Targeting

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In previous work (Wheeler et al. (1999) Gene Therapy 6, 271-281) we have shown that plasmid DNA can be entrapped in "stabilized plasmid lipid particles" (SPLP) using low levels (5-10 mol%) of cationic lipid, the fusogenic lipid dioleoylphosphatidylethanolamine (DOPE), and a polyethyleneglycol (PEG) coating for stabilization. The PEG moieties are attached to a ceramide anchor containing an arachidoyl acyl group (PEG-CerC20). However, these SPLP exhibit low transfection potencies in vitro as compared to plasmid/cationic lipid complexes formed with liposomes composed of cationic and neutral lipid at a 1:1 lipid ratio. The objective of this study was to construct SPLPs with increased cationic lipid contents that result in maximum transfection levels. A phosphate buffer detergent dialysis technique is described resulting in formation of SPLP containing 7-42.5 mol% DODAC with reproducible encapsulation efficiency of up to 80%. An octanoyl acyl group was used as anchor for the PEG moiety (PEG-CerC8) permitting a quick exchange out of the SPLP to further optimize the in vitro and in vivo transfection. We have demonstrated that this technique can be used to encapsulate either linearized DNA or supercoiled plasmids ranging from 3-20 kb. The SPLP formed could be isolated from empty vesicles by sucrose density gradient centrifugation, and exhibited a narrow size distribution of approximately 75 +/- 6 nm as determined by cryo-electron microscopy. The high plasmid-to-lipid ratio observed corresponded to one plasmid per particle. The SPLP consist of a lipid bilayer surrounding the plasmid DNA as visualized by cryo-electron microscopy. SPLP containing a range of DODAC concentrations were tested for in vitro and in vivo transfection. In vitro, in COS-7 cells transfection reached a maximum after 48 h. The transfection efficiency increased when the DODAC concentration in the SPLP was decreased from 42.5 to 24 mol% DODAC. Decreasing the cationic lipid concentration improved transfection in part due to decreased toxicity. In vivo studies using an intraperitoneal B16 tumor model and intraperitoneal administration of SPLP showed maximum transfection activity for SPLP containing 24 mol% DODAC. Gene expression observed in tumor cells was increased by approximately one magnitude as compared to cationic lipid/DNA complexes. The SPLP were stable and upon storage at 4 degrees C no significant change in the transfection activity was observed over a one-year period. Thus this phosphate buffer detergent dialysis technique can be used to generate SPLP formulations containing a wide range of cationic lipid concentrations to determine optimal SPLP composition for high transfection activity and low toxicity.

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M. Ossanlou

Stabilized plasmid-lipid particles: construction and characterization

Encapsulation of Plasmid DNA in Stabilized Plasmid – Lipid Particles Composed of Different Cationic Lipid Concentration for Optimal Transfection Activity

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