The discovery of liposomes with their many interesting properties has attracted much attention. These tiny spheres are suitable for using as delivery vehicles for nutrients and drugs into the human body. Identical to human cell membranes, they easily transfer and deliver active ingredients. Liposome manufacturing involves the same basic steps but the use many different techniques. Research is constantly being done to increase their effectiveness.
Formation of liposomes is not spontaneous. Lipid vesicles are formed when phospholipids like lecithin are placed in water. Each molecule has a water-loving head and two water-repelling tails. When these molecules are placed in a water-based solution, the heads line up side by side with the tails behind. The fact that the tails are repelled by water means that another layer lines up with the tails facing one another. These two rows form a protective membrane around the cell.
Liposomes are used to deliver toxic drugs to target cancer cells. They are used for delivering nutrients deficient in the body or cosmetic nutrients to the skin. Many other medical applications are possible too such as in the field of genetics. Preparation methods depend on various factors such as the characteristics of the material to be carried, the consistency offered from batch to batch and scale of production.
All liposomes consist of a lipid bilayer encapsulating a payload of therapeutic molecules. They bypass the digestive tract, so the payload remains biologically inert until such stage as the cell membrane ruptures. The difference between liposomes comes in the way, how, when and where that occurs.
The methods used in preparation may all be quite different but the basic stages remain the same. Thin lipid films are hydrated and this causes liquid bilayers to form. These large vesicles need to be reduced in size and energy output is required for this. Sonication is the use of sound waves and another mechanical method used is extrusion.
Different methods are known to have certain weaknesses and strengths. Some allow for high load dosing and others offer much lower dose loading. Some of them offer more consistency and stability. The encapsulated content is affected more by some methods than others.
Some of the problems that have to be faced are structural instability, inconsistency in size and expensive production costs. Liposomal delivery systems are still in the experimental stage. The precise ways in which they act within the body are being carefully studied as well as ways in which they can be made to target diseased tissue or a specific organ.
A great benefit involved in using liposomes is that they can be customized for different applications by varying the method of preparation, size, lipid content and surface charge. Many conventional techniques for preparing them and reducing their size are fairly simple to implement and equipment does not have to be too sophisticated. However, novel routes are being discovered for preparation due to motivation to scale-down for point-of-care applications or or to scale-up for industrial applications.
Formation of liposomes is not spontaneous. Lipid vesicles are formed when phospholipids like lecithin are placed in water. Each molecule has a water-loving head and two water-repelling tails. When these molecules are placed in a water-based solution, the heads line up side by side with the tails behind. The fact that the tails are repelled by water means that another layer lines up with the tails facing one another. These two rows form a protective membrane around the cell.
Liposomes are used to deliver toxic drugs to target cancer cells. They are used for delivering nutrients deficient in the body or cosmetic nutrients to the skin. Many other medical applications are possible too such as in the field of genetics. Preparation methods depend on various factors such as the characteristics of the material to be carried, the consistency offered from batch to batch and scale of production.
All liposomes consist of a lipid bilayer encapsulating a payload of therapeutic molecules. They bypass the digestive tract, so the payload remains biologically inert until such stage as the cell membrane ruptures. The difference between liposomes comes in the way, how, when and where that occurs.
The methods used in preparation may all be quite different but the basic stages remain the same. Thin lipid films are hydrated and this causes liquid bilayers to form. These large vesicles need to be reduced in size and energy output is required for this. Sonication is the use of sound waves and another mechanical method used is extrusion.
Different methods are known to have certain weaknesses and strengths. Some allow for high load dosing and others offer much lower dose loading. Some of them offer more consistency and stability. The encapsulated content is affected more by some methods than others.
Some of the problems that have to be faced are structural instability, inconsistency in size and expensive production costs. Liposomal delivery systems are still in the experimental stage. The precise ways in which they act within the body are being carefully studied as well as ways in which they can be made to target diseased tissue or a specific organ.
A great benefit involved in using liposomes is that they can be customized for different applications by varying the method of preparation, size, lipid content and surface charge. Many conventional techniques for preparing them and reducing their size are fairly simple to implement and equipment does not have to be too sophisticated. However, novel routes are being discovered for preparation due to motivation to scale-down for point-of-care applications or or to scale-up for industrial applications.
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