Nicolas Sax1, Tetsuya Kodama. 1. Molecular Delivery System Laboratory Graduate School of Biomedical Engineering, Tohoku University, 4-1 Seiryo-machi, Aoba-ku, Sendai 980-0872, Japan.
Abstract
PURPOSE: Liposomes encapsulating perfluoropropane gas, termed acoustic liposomes (ALs), which can serve both for ultrasound (US) imaging and US-mediated gene delivery, have been reported. However, the echogenicity of ALs decreases within minutes in vivo due to gas diffusion and leakage, hindering time-consuming procedures such as contrast-enhanced 3D US imaging and raising the need for improvement of their stability. METHODS: The stability of ALs preparations incorporating increasing ratios of anionic / unsaturated phospholipids, polyethylene glycol (PEG)ylated phospholipid and cholesterol was investigated by measurement of their reflectivity over time using a high-frequency US imaging system, both in vitro and in vivo. RESULTS: The retention of echogenicity of ALs in vitro is enhanced with increasing molar ratios of PEGylated lipids. Addition of 10 molar percent of an anionic phospholipid resulted in a 31% longer half-life, while cholesterol had the opposite effect. Assessment of the stability of an optimized composition showed a more than 2-fold increase of the detection half-life in mice. CONCLUSIONS: Presence of a PEG coating not only serves to provide "stealth" properties in vivo, but also contributes to the retention of the encapsulated gas. The optimized ALs reported here can be used as a contrast agent for lengthier imaging procedures.
PURPOSE: Liposomes encapsulating perfluoropropane gas, termed acoustic liposomes (ALs), which can serve both for ultrasound (US) imaging and US-mediated gene delivery, have been reported. However, the echogenicity of ALs decreases within minutes in vivo due to gas diffusion and leakage, hindering time-consuming procedures such as contrast-enhanced 3D US imaging and raising the need for improvement of their stability. METHODS: The stability of ALs preparations incorporating increasing ratios of anionic / unsaturated phospholipids, polyethylene glycol (PEG)ylated phospholipid and cholesterol was investigated by measurement of their reflectivity over time using a high-frequency US imaging system, both in vitro and in vivo. RESULTS: The retention of echogenicity of ALs in vitro is enhanced with increasing molar ratios of PEGylated lipids. Addition of 10 molar percent of an anionic phospholipid resulted in a 31% longer half-life, while cholesterol had the opposite effect. Assessment of the stability of an optimized composition showed a more than 2-fold increase of the detection half-life in mice. CONCLUSIONS: Presence of a PEG coating not only serves to provide "stealth" properties in vivo, but also contributes to the retention of the encapsulated gas. The optimized ALs reported here can be used as a contrast agent for lengthier imaging procedures.
Authors: H Alkan-Onyuksel; S M Demos; G M Lanza; M J Vonesh; M E Klegerman; B J Kane; J Kuszak; D D McPherson Journal: J Pharm Sci Date: 1996-05 Impact factor: 3.534
Authors: Denise A B Smith; Sampada S Vaidya; Jonathan A Kopechek; Shao-Ling Huang; Melvin E Klegerman; David D McPherson; Christy K Holland Journal: Ultrasound Med Biol Date: 2010-01 Impact factor: 2.998