Nanotechnology is a dynamic branch of science that transforms and manipulates substances on a molecular and even atomic level. Liposomes refer to microscopic cellular bubbles made of materials called phospholipids, which are similar to human cell material and are both attracted to and repelled by water. Liposomal formulation helps create these structures for use in the targeted delivery of medication.
First appearing during the 1960s, the importance of these tiny vesicular structures that enclose water-soluble molecules soon became apparent. Researchers and pharmacists became aware of their potential to deliver specific drugs used in the treatment of cancer and other serious diseases. The process encourages more accurate targeting of unhealthy cells and avoids problems associated with other types of administration.
The concept they use is radically different because it does not depend of standard modes of absorption typical of IV or oral administration. Conventional chemical processes can make management of specialized drugs more difficult. They are indiscriminate in their toxicity, and affect healthy organs as well, resulting in unnecessary damage and more lengthy recovery. When delivered via liposomes, release of toxic medication can be better controlled.
The molecules of a drug are suspended in water within the structure of the artificial cell, which is surrounded by a manufactured membrane. The formulating process of specifically designed liposomes transforms them into mechanisms ideal for transporting hydrophilic drugs, or those that are attracted to water and dissolve effectively. Current methods produce two primary forms called unilammelar and multilammelar, and subcategories include varying sizes.
Individual liposomes surround the drug molecules with a membrane, and then transfer those medications to other cells when activated. Molecules can be released into the body by fusing certain layers with other physical cells, effectively delivering a small amount of medication. Others strategies rely on chemical reactions that encourage diffusion on a molecular level. The net result is a steadier, more controlled release.
This process is not only more effectively managed, but is also bio-compatible with human cells, and leaves no additional toxic residue. Some recently developed types of these capsules can be activated using ultrasound, which increases their efficacy in the locations where they are most needed. Others are dispensed via the respiratory system, and are directly deposited into the lungs and then slowly released, reducing overall toxicity.
It is still costly to manufacture these microscopic capsules for medical use. As continuing research produces a growing number of uses for this kind of nanotechnology, the overall expense will decline, but will not become cheap. Because this is relatively new technology in many ways, there are issues that still must be resolved. Some types of structures have experienced cellular leaking, and others have been affected by oxidation.
Like other technologies developed for medicine, liposomes have a growing commercial use. They are being touted as superior methods of delivering vitamin, mineral, and herb formulations, and some individuals today even create their own supplements. While those uses are controversial in some aspects, the creation of new medication delivery and activation systems continues to provide new hope for more effective treatments.
First appearing during the 1960s, the importance of these tiny vesicular structures that enclose water-soluble molecules soon became apparent. Researchers and pharmacists became aware of their potential to deliver specific drugs used in the treatment of cancer and other serious diseases. The process encourages more accurate targeting of unhealthy cells and avoids problems associated with other types of administration.
The concept they use is radically different because it does not depend of standard modes of absorption typical of IV or oral administration. Conventional chemical processes can make management of specialized drugs more difficult. They are indiscriminate in their toxicity, and affect healthy organs as well, resulting in unnecessary damage and more lengthy recovery. When delivered via liposomes, release of toxic medication can be better controlled.
The molecules of a drug are suspended in water within the structure of the artificial cell, which is surrounded by a manufactured membrane. The formulating process of specifically designed liposomes transforms them into mechanisms ideal for transporting hydrophilic drugs, or those that are attracted to water and dissolve effectively. Current methods produce two primary forms called unilammelar and multilammelar, and subcategories include varying sizes.
Individual liposomes surround the drug molecules with a membrane, and then transfer those medications to other cells when activated. Molecules can be released into the body by fusing certain layers with other physical cells, effectively delivering a small amount of medication. Others strategies rely on chemical reactions that encourage diffusion on a molecular level. The net result is a steadier, more controlled release.
This process is not only more effectively managed, but is also bio-compatible with human cells, and leaves no additional toxic residue. Some recently developed types of these capsules can be activated using ultrasound, which increases their efficacy in the locations where they are most needed. Others are dispensed via the respiratory system, and are directly deposited into the lungs and then slowly released, reducing overall toxicity.
It is still costly to manufacture these microscopic capsules for medical use. As continuing research produces a growing number of uses for this kind of nanotechnology, the overall expense will decline, but will not become cheap. Because this is relatively new technology in many ways, there are issues that still must be resolved. Some types of structures have experienced cellular leaking, and others have been affected by oxidation.
Like other technologies developed for medicine, liposomes have a growing commercial use. They are being touted as superior methods of delivering vitamin, mineral, and herb formulations, and some individuals today even create their own supplements. While those uses are controversial in some aspects, the creation of new medication delivery and activation systems continues to provide new hope for more effective treatments.
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