3179-47-3Relevant articles and documents
Cholesteryl to improve the cellular uptake of polymersomes within HeLa cells
Martin, Chloe,Marino, Nino,Curran, Ciara,McHale, Anthony P.,Callan, John F.,Callan, Bridgeen
, p. 570 - 578 (2016/08/02)
The need to develop a greater understanding of drug delivery systems has arisen through the development of alternative biological based therapeutics. Drug delivery systems need to adapt and respond to this increasing demand for cellular transportation of highly charged species. Polymersomal drug delivery systems have displayed great potential and versatility for such a task. In this manuscript we present the synthesis, characterisation and biological evaluation of six amphiphilic random co polymers with varying amounts of cholesteryl (0–39%wt) before the subsequent formation into polymersomes. The polymersomes were then analysed for size, zeta potential, encapsulation efficiency, release kinetics and cellular uptake. Results confirmed that the polymersome containing 12%wt cholesteryl polymer displayed a ten-fold increase in cellular uptake of Fitc-CM-dextran when compared to un-encapsulated drug, crossing the cellular membrane via endocytosis. The size of these vehicles ranged between 100 and 500?nm, zeta potential was shown to be neutral at ?0.82?mV ±0.2 with encapsulation efficiencies in the region of 60%. The ease of adaptability and preparation of such systems renders them a viable alternative to liposomal drug delivery systems.
TRANSESTERIFICATION PROCESS USING MIXED SALT ACETYLACETONATES CATALYSTS
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Paragraph 0070; 0071, (2013/04/13)
This invention is directed to a general catalyst of high activity and selectivity for the production of a variety of esters, particularly acrylate and methacrylate-based esters, by a transesterification reaction. This objective is achieved by reaction of an ester of a carboxylic or a carbonic acid, in particular of a saturated or unsaturated, typically, a 3 to 4 carbon atom carboxylic acid; with an alcohol in the presence of a catalyst comprising the combination of a metal 1,3-dicarbonyl complex (pref. Zn or Fe acetylacetonate) and a salt, in particular an inorganic salt, pref. ZnCl2, LiCI, NaCI, NH4CI or Lil. These catalysts are prepared from readily available starting materials within the reaction medium without the need for isolation (in-situ preparation).
Hypervalent (tert-butylperoxy)iodanes generate iodine-centered radicals at room temperature in solution: Oxidation and deprotection of benzyl and allyl ethers, and evidence for generation of α-oxy carbon radicals
Ochiai, Masahito,Ito, Takao,Takahashi, Hideo,Nakanishi, Akinobu,Toyonari, Mika,Sueda, Takuya,Goto, Satoru,Shiro, Motoo
, p. 7716 - 7730 (2007/10/03)
1-(tert-Butylperoxy)-1,2-benziodoxol-3(1H)-one (1a) oxidizes benzyl and allyl ethers to the esters at room temperature in benzene or cyclohexane in the presence of alkali metal carbonates. Since this reaction is compatible with other protecting groups such as MOM, THP, and TBDMS ethers, and acetoxy groups, and because esters are readily hydrolyzed under basic conditions, this new method provides a convenient and effective alternative to the usual reductive deprotection. Oxidation with 1a occurs readily with C-H bonds activated by both enthalpic effects (benzylic, allylic, and propargylic C-H bonds) and/or polar effects (α-oxy C-H bonds), generating α-oxy carbon-centered radicals, which can be detected by nitroxyl radical trapping. Measurement of the relative rates of oxidation for a series of ring-substituted benzyl n-butyl ethers 2d and 2p-s indicated that electron-releasing groups such as p-MeO and p-Me groups increase the rate of oxidation, and Hammett correlation of the relative rate factors with the σ+ constants of substituents afforded the reaction constant ρ+ = -0.30. The large value of the isotope effect obtained for the oxidation of benzyl n-butyl ether 2d (k(H)/k(D) = 12-14) indicates that the rate-determining step of the reactions probably involves a high degree of benzylic C-H bond breaking. The effects of molecular dioxygen were examined, and the mechanism involving the intermediacy of the tert-butylperoxy acetal 5 and/or the hydroperoxy acetal 32 is proposed. Particularly noteworthy is the finding that (tert-butylperoxy)iodane 1a can generate the tert-butylperoxy radical and the iodine-centered radical 33a, even at room temperature in solution, via homolytic bond cleavage of the hypervalent iodine(III)-peroxy bond.
