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.
Scientists first became aware of the process during the 1960s, and their discovery ultimately led to new and more effective means of administering drugs internally. Today, it is widely used in the treatment of age-related degenerative conditions affecting vision, stubborn fungal infections, and even some kinds of cancer. Although standard methods of delivery still predominate medically, encapsulation has proven to be a viable alternative.
For drugs to survive the upper digestive tract intact, they need to be protected by some kind of barrier that does not cause any additional physical problems. The best solution so far is to create microscopic drug capsules using a material that is already a part of cellular walls throughout the human organism. When activated using one of three primary methods available today, tiny protective liposome bubbles are formed.
They are microscopic, and can easily pass through the stomach into the small intestine where the coating slowly dissolves, allowing the medication to be absorbed. In many cases, this process actually improves the therapeutic impact, and has the additional benefit of producing fewer side effects. Not all types of medicine are adaptable to this delivery system, which is primarily associated with water-soluble substances.
Because it involves fewer undesirable reactions than invasive delivery, there are immediate advantages of using this process. Liposomes are bio-compatible and biodegradable, leaving behind no undesirable toxins. They not only survive the onslaught of digestive acids, but are able to function as small time-release ports within the gut. When potentially toxic drugs must be used to fight cancers, fewer sensitive tissues face unwanted exposure.
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 several years witnessed a transition from mainly medical use to include internal delivery of nutritional supplements and even cosmetic substances. Anecdotal evidence abounds regarding the increased effectiveness of administering both vitamins and minerals in this manner. For years Vitamin C has enjoyed an enviable reputation for fighting upper respiratory viral infections, and encapsulated forms are thought to produce even better results.
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.
Scientists first became aware of the process during the 1960s, and their discovery ultimately led to new and more effective means of administering drugs internally. Today, it is widely used in the treatment of age-related degenerative conditions affecting vision, stubborn fungal infections, and even some kinds of cancer. Although standard methods of delivery still predominate medically, encapsulation has proven to be a viable alternative.
For drugs to survive the upper digestive tract intact, they need to be protected by some kind of barrier that does not cause any additional physical problems. The best solution so far is to create microscopic drug capsules using a material that is already a part of cellular walls throughout the human organism. When activated using one of three primary methods available today, tiny protective liposome bubbles are formed.
They are microscopic, and can easily pass through the stomach into the small intestine where the coating slowly dissolves, allowing the medication to be absorbed. In many cases, this process actually improves the therapeutic impact, and has the additional benefit of producing fewer side effects. Not all types of medicine are adaptable to this delivery system, which is primarily associated with water-soluble substances.
Because it involves fewer undesirable reactions than invasive delivery, there are immediate advantages of using this process. Liposomes are bio-compatible and biodegradable, leaving behind no undesirable toxins. They not only survive the onslaught of digestive acids, but are able to function as small time-release ports within the gut. When potentially toxic drugs must be used to fight cancers, fewer sensitive tissues face unwanted exposure.
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 several years witnessed a transition from mainly medical use to include internal delivery of nutritional supplements and even cosmetic substances. Anecdotal evidence abounds regarding the increased effectiveness of administering both vitamins and minerals in this manner. For years Vitamin C has enjoyed an enviable reputation for fighting upper respiratory viral infections, and encapsulated forms are thought to produce even better results.
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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