Nutritional supplements and most medications are meant to target specific physical systems or organs. Intravenous drip and injection are the most effective methods of delivery, transferring necessary chemicals directly to the blood. When swallowed, medications usually face degradation in the acids of the upper digestive tract. Liposomal encapsulation creates a protective barrier, ultimately allowing more complete 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 a medication to pass through the upper digestive tract without being dissolved, it must be protected by a safe and non-toxic barrier. The substance used to encapsulate these drugs is an organic material that closely mimics human cellular walls, making it safer to ingest. After it has been activated by using one of three common processes, small bubbles of liposomes are formed around the tiny grains of medication.
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.
There are fewer unwanted physical reactions, and immediate advantages for patients. Because lipsomes are biodegradable and always physically compatible, they leave no toxic substances behind. Not only can they survive an attack by harsh digestive acids, but later function as tiny time-release agents within the intestine. Many drugs used to fight cancer can create collateral damage, and this form of delivery provides greater control.
Even though already proven effective through use, there is a slight down side. Production costs are significantly high, but will likely experience a decline as greater demand influences the market. Seal leakage has been reported in some cases, and oxidation sometimes reduces overall effectiveness. During the process some drugs have experienced a decline in their half-life, and stability issues have occurred, but positive benefits still predominate.
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.
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 a medication to pass through the upper digestive tract without being dissolved, it must be protected by a safe and non-toxic barrier. The substance used to encapsulate these drugs is an organic material that closely mimics human cellular walls, making it safer to ingest. After it has been activated by using one of three common processes, small bubbles of liposomes are formed around the tiny grains of medication.
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.
There are fewer unwanted physical reactions, and immediate advantages for patients. Because lipsomes are biodegradable and always physically compatible, they leave no toxic substances behind. Not only can they survive an attack by harsh digestive acids, but later function as tiny time-release agents within the intestine. Many drugs used to fight cancer can create collateral damage, and this form of delivery provides greater control.
Even though already proven effective through use, there is a slight down side. Production costs are significantly high, but will likely experience a decline as greater demand influences the market. Seal leakage has been reported in some cases, and oxidation sometimes reduces overall effectiveness. During the process some drugs have experienced a decline in their half-life, and stability issues have occurred, but positive benefits still predominate.
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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