Liposomes drug release control

Knepp, V.M., et al. 1988. Controlled drug release from a novel liposomal delivery system. 

Knepp, V.M., F.C. Szoka, and R.H. Guy. 1990. Controlled drug release from a novel liposome delivery system. II. Transdermal delivery characteristics. J Control Release 12 25. 

Volodkin D, Mohwald H, Voegel J-C et al (2007) Stabilization of negatively charged liposomes by polylysine surface coating. Drug release study. J Control Release 117 111-120... 

New Liposomal Delivery System for Controlled Drug Release... 

Dhoot, N. O., and Wheatley, M. A. (2003), Microencapsulated liposomes in controlled drug delivery Strategies to modulate drug release and eliminate the burst effect, /. Pharm. Sci., 92(3), 679-689. 

Echogenic liposomes seem to constitute one of the most sensitive ultrasound-controlled release systems yet described, with ultrasound having been used to trigger release from several different echogenic liposomal drug delivery preparations such as tissue plasminogen activator (tPA) and papaverin (22, 23). 

An ideal liposomal drug delivery system should have a long circulation time in the blood, accumulation at the target site, and controlled drug release that matches the efficacy profile of the drug. 

Paasonen, L., Laaksonen, T., Johans, C., Yliperttula, M., Kontturi, K. and Urtti, A. (2007) Gold nanoparticles enable selective light induced drug release from liposomes. Journal of Controlled Release, 122, 86-93. 

Besides liposomes, polymeric nanoparticles may be used as effective drug carrier systems using cytotic pathways. Particle size and polymeric composition help control particle degradation and drug release. Recently, it was shown in a rat study that polybutylcyanoacrylate nanoparticles, which had been surface coated with polysorbate 80, exhibited a 20-fold higher uptake into brain capillary endothelial cells compared to noncoated nanoparticles [17]. It is assumed that association of lipoproteins at the surface triggers the endocytotic uptake of the nanoparticles. 

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