Medications and nutritional supplements often target specific organs or systems. The most effective delivery method is by injection or intravenous drip, both of which transfer substances directly into the bloodstream. When taken orally, medications must pass through the upper digestive system, where they may be degraded. Liposomal encapsulation forms a protective barrier that allows more thorough absorption.
Discoveries leading to this process emerged nearly fifty years ago, and have led to the introduction of more controlled methods of administering medications. It is currently important in treating serious medical conditions such as some forms of cancer, treatment-resistant fungal infections, and degenerative vision conditions commonly associated with old age. Standard drug delivery mechanisms still predominate, but encapsulation is proving equally beneficial.
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 permit the medication protected inside to safely reach the bloodstream via the small intestine, where they are directly absorbed. This not only improves the overall therapeutic intent in many cases, but can also reduce the possibility of harmful side effects. Not all medications are suitable for this method of delivery, which is most effective with water-soluble drugs.
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 decade has seen a transition from strictly medical venue to include delivery of nutritional supplements and cosmetic materials. Anecdotal evidence of an increase in physical well-being associated with administering vitamins and minerals in this way are common. Vitamin C has long been touted as a natural way to combat the effects of upper respiratory infections, and this method is said to provide noticeably better results than pills alone.
Widespread information is available today regarding personal home encapsulation of vitamins, minerals, and herbal extracts. Producing high-quality encapsulated products is both costly and involved, and is not proven to effectively combat aging issues. As this effective method of physical drug delivery is improved and becomes more widespread, consumers will benefit most from its introduction to existing beneficial heal regimens.
Discoveries leading to this process emerged nearly fifty years ago, and have led to the introduction of more controlled methods of administering medications. It is currently important in treating serious medical conditions such as some forms of cancer, treatment-resistant fungal infections, and degenerative vision conditions commonly associated with old age. Standard drug delivery mechanisms still predominate, but encapsulation is proving equally beneficial.
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 permit the medication protected inside to safely reach the bloodstream via the small intestine, where they are directly absorbed. This not only improves the overall therapeutic intent in many cases, but can also reduce the possibility of harmful side effects. Not all medications are suitable for this method of delivery, which is most effective with water-soluble drugs.
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 decade has seen a transition from strictly medical venue to include delivery of nutritional supplements and cosmetic materials. Anecdotal evidence of an increase in physical well-being associated with administering vitamins and minerals in this way are common. Vitamin C has long been touted as a natural way to combat the effects of upper respiratory infections, and this method is said to provide noticeably better results than pills alone.
Widespread information is available today regarding personal home encapsulation of vitamins, minerals, and herbal extracts. Producing high-quality encapsulated products is both costly and involved, and is not proven to effectively combat aging issues. As this effective method of physical drug delivery is improved and becomes more widespread, consumers will benefit most from its introduction to existing beneficial heal regimens.
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