Liposomal Encapsulation Delivers Medications More Efficiently
Drugs used to fight disease typically target specific physical systems or organs. Intravenous drips and injections are the most directly effective delivery method, transferring those medications directly to the blood. Orally administered drugs face degradation from the substances that accompany normal digestion. Liposomal encapsulation creates a protective bubble that wards off acids, while encouraging absorption.
Medical scientists first became aware of this process than fifty years ago, leading to the development of newer and more effective methods of drug delivery. The process is currently being used during treatment of serious conditions such as stubborn fungal infections, some kinds of cancers, and even age-related conditions leading to loss of vision. While standard medication delivery methods are still predominant, the encapsulation approach is also proving beneficial.
In order to allow drugs to pass through the digestive tract without being broken down, they must be safely encased within a non-toxic protective barrier. Effectively shielding these individual microscopic capsules is possible when using an organic agent that mimics normal cellular walls. When that substance is activated using a variety of current methods, small individual bubbles made of liposomes are formed.
These individual capsules can be ingested together in a medium, and are shielded from damage until they can be absorbed into the bloodstream via the small intestine. In many cases this process improves the overall therapeutic goal, with the added benefit of fewer side effects. While a significant improvement, this method of delivery does not accommodate all drugs, and works best with water-soluble medications.
Because the process is not invasive and generates fewer negative reactions, there are immediately and obvious advantages. Liposomes are completely biodegradable, and contain no petroleum-derived compounds or other unwanted toxic substances. They easily survive an onslaught of powerful acid, and later function as mini time-release stations within the small intestine. Powerful cancer drugs administered in this way create less collateral damage to surrounding tissues.
While being used successfully today in many hospitals, there are some drawbacks. Production costs are comparatively high, but are subject to a natural decrease as product use expands. Seal leakage has been an issue in some cases, and simple oxidation processes can diminish effectiveness. Certain drugs may experience a diminished half-life, and their long-term viability may be reduced. Even with these known issues, positive benefits exceed negative reports.
The past ten years have witnessed a transition from primarily medical use to include delivery of cosmetic and nutritional substances. There is ample anecdotal evidence touting the additional well-being that may result from delivering common vitamin dosages in this fashion. Many people subscribe to the idea that vitamin C is a natural enemy of upper respiratory infections, and also believe that this type of delivery increases effectiveness.
Although information highlighting consumer ability to create encapsulated vitamins, minerals, and even herbal extracts is readily available, making high-quality formulations can be costly and involved, and will not effectively combat the normal issues associated with aging. As support and development of this process continues in the medical world, the public will benefit most from it being used in conjunction with health regimens that have already been proven effective.
Medical scientists first became aware of this process than fifty years ago, leading to the development of newer and more effective methods of drug delivery. The process is currently being used during treatment of serious conditions such as stubborn fungal infections, some kinds of cancers, and even age-related conditions leading to loss of vision. While standard medication delivery methods are still predominant, the encapsulation approach is also proving beneficial.
In order to allow drugs to pass through the digestive tract without being broken down, they must be safely encased within a non-toxic protective barrier. Effectively shielding these individual microscopic capsules is possible when using an organic agent that mimics normal cellular walls. When that substance is activated using a variety of current methods, small individual bubbles made of liposomes are formed.
These individual capsules can be ingested together in a medium, and are shielded from damage until they can be absorbed into the bloodstream via the small intestine. In many cases this process improves the overall therapeutic goal, with the added benefit of fewer side effects. While a significant improvement, this method of delivery does not accommodate all drugs, and works best with water-soluble medications.
Because the process is not invasive and generates fewer negative reactions, there are immediately and obvious advantages. Liposomes are completely biodegradable, and contain no petroleum-derived compounds or other unwanted toxic substances. They easily survive an onslaught of powerful acid, and later function as mini time-release stations within the small intestine. Powerful cancer drugs administered in this way create less collateral damage to surrounding tissues.
While being used successfully today in many hospitals, there are some drawbacks. Production costs are comparatively high, but are subject to a natural decrease as product use expands. Seal leakage has been an issue in some cases, and simple oxidation processes can diminish effectiveness. Certain drugs may experience a diminished half-life, and their long-term viability may be reduced. Even with these known issues, positive benefits exceed negative reports.
The past ten years have witnessed a transition from primarily medical use to include delivery of cosmetic and nutritional substances. There is ample anecdotal evidence touting the additional well-being that may result from delivering common vitamin dosages in this fashion. Many people subscribe to the idea that vitamin C is a natural enemy of upper respiratory infections, and also believe that this type of delivery increases effectiveness.
Although information highlighting consumer ability to create encapsulated vitamins, minerals, and even herbal extracts is readily available, making high-quality formulations can be costly and involved, and will not effectively combat the normal issues associated with aging. As support and development of this process continues in the medical world, the public will benefit most from it being used in conjunction with health regimens that have already been proven effective.
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