Storage | Should always be stored at in the dark at 4 °C, except when brought to room temperature for brief periods prior to animal dosing. DO NOT FREEZE. If the suspension is frozen, the encapsulated drug can be released from the liposomes thus limiting its effectiveness. In addition, that the size of the liposomes will also change upon freezing and thawing. |
Appearance | White translucent liquid made of nano size unilamellar liposomes. Usually due to the small size of liposomes no settling will occur in the bottom of the vial. The liposomes are packaged in an amber vial. |
Description | The fundamental structure of cell membranes is bilayers composed of phospholipids, and the vital function of the phospholipids in the membrane is to help keep it fluid and semi-permeable. Conventional glycerophospholipids have acyl chains attached to the sn-1 and sn-2 positions of the glycerol backbone via an ester bond. Ether lipids are a unique class of glycerophospholipids that have an alkyl chain attached to the sn-1 position by an ether bond (glycerol-ether lipids). In ether lipids, the alcohol group attached to the phosphate is generally choline or ethanolamine. Ether-linked phospholipids such as 1-alkyl-2-acyl-phosphatidylcholine and dialkylphosphatidylcholine are also found in the plasma and organelle membranes of mammalian species. Ether lipids form approximately 20% of the total phospholipid in mammals with different tissue distribution; brain, heart, spleen and white blood cells have the highest levels, while liver have a very little amount of ether lipids. Studies on the formation and thermodynamic properties of ether-linked phospholipid bilayer membranes have indicated that in contrast to ester-linked phospholipid, the formation of the non-bilayer structure takes place spontaneously. This is attributed to the weaker interaction between polar headgroups in the ether-linked than that in the ester-linked phospholipids. It has also shown that the phase behavior of the ether-linked phospholipid bilayer membranes in ambient pressure is almost equivalent to that of the ester-linked phospholipid bilayer membranes under high temperatures and pressures, and the difference in the phase behavior decrease as the alkyl-chain length increases. Due to distinctive properties of ether lipids, liposomes made from ether lipids exhibit very unique characteristics and performance: a) the ether bonds are more stable than ester linkages over a wide range of acidic or alkaline pH; b) stability properties of the liposomes is enhanced by bipolar lipids, and the saturated alkyl chains gives stability towards degradation in oxidative conditions; c) the unusual stereochemistry of the glycerol backbone enhance the resistance against the attacks by other organism phospholipases. Phospholipase A2 (PLA2) cannot hydrolyze the ether lipid liposomes. Diether lipids do not go through hydrolysis due to having an ether bond instead of an acyl bond and therefore to due that they are a suitable candidates for experiments that needs to be performed at a higher temperature for an extended period of time. |
Lipid composition | 14/0 Diether PC/Cholesterol (70/30 molar ratio) |
Liposome Size | 100 nm |
Lipid Molar Concentration | 10 mM |
Buffer | Phosphate Buffered Saline, pH 7.4 |
Shelf-life | 4 months. |
Technical Notes | Liposomes are unilamellar and sized to 100 nm. If you need them to be made in another size then you should mention that at the time of ordering. Unilamellar liposomes can be made in 50 nm and 200 nm sizes. Liposomes that are larger than 200 nm are multilamellar structure. Liposomes are made in PBS buffer at pH 7.4 but it can be made in any other buffer of your choice. You can specify your buffer at the time of ordering. Liposomes are made in degassed buffer that is purged with argon to avoid oxidation of the unsaturated phospholipids. Liposomes are made under sterile condition. Liposomes are unilamellar and therefore due to their small size they will not settle in the bottom of the vial. If you need to take multiple aliquots out of the vial during a period of time, then it is advised to take extreme care in not contaminating the vial. It is recommended to handle the vial under a sterile hood to maintain the sterility of the product. Liposomes should never be frozen. Crystal ice that is formed during freezing will rupture the lipid membrane of the liposomes and change the size the liposomes particles. |
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×Product Name | Catalog | Lipid composition | Liposome Size | Price |
---|---|---|---|---|
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDELPCG-1244 | DSPC/Cholesterol/PEG2000-DSPE (65/30/5 molar ratio) | 100 nm (after hydration) | $2100 |
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDEPG-13 | 100% DSPC | 70-120 nm | $1200 |
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDELUP-1212 | 100% 18/1-18/0 PC | 100 nm (after hydration) | $2100 |
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDELDE-1313 | 100% 16/0 Diether PC | 100 nm (after hydration) | $2100 |
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDECHP-1569 | 100% 16/0-18/0 PC | 100 nm | $2100 |
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDECHP-1558 | 100% 17/0 PC | 100 nm | $2100 |
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDELDE-1319 | 16/0 Diether PC/Cholesterol (70/30 molar ratio) | 100 nm (after hydration) | $2100 |
Clipos™ Diether Phosphatidylcholine (PC) Liposomes | CDECHP-1572 | 14/0 PC (DMPC)/Cholesterol (70/30 molar ratio) | 100 nm | $2100 |
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