Nanotechnology is a branch of science that manipulates materials on a molecular and atomic level. Liposomes are artificially created microscopic bubbles composed of materials similar to human cell membranes called phospholipids, portions of which are alternately repelled or attracted to water. Liposomal formulation is a process that creates these structures for a more effective use in the delivery of medications.
The significance of these very small vesicular forms that are able to enclose molecules soluble in water became apparent soon after being introduced during the 1960s. Pharmacists and research scientists became keenly aware of their potential to improve methods of drug delivery when fighting cancer and other serious illness. They encourage more accurate targeting of malicious cells while avoiding issues that plague other forms 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 drug molecules encased within each structure are suspended in water and surrounded by an artificially or naturally created membrane. The formulation of designed liposomes turns them into ideal mechanisms for hydrophilic drugs, or those that are attracted to and become suspended in water. When prepared according to current methods, the structures exist in two primary types, unilammelar or multilammelar. There are subcategories that include different sizes.
The liposomes are made to surround the medications with membranes, and when activated release those molecules into other cells. This can be done by fusing the layers, causing them to interact with adjacent human cells, and releasing medication in the process. Other activation strategies include using specific chemical reactions to encourage molecular diffusion. The end result is a controlled, steady delivery.
This not only creates medicines that are more easily administered and managed, but does so in a bio-compatible way that leaves little toxic residue in non-targeted organs. Relatively recent developments involve the use of ultrasound to trigger release in specific locations where they are necessary. Other delivery methods include using the respiratory system, especially the lungs, where they can be activated slowly, reducing unwanted toxicity.
Manufacturing these tiny capsules for medical purposes is still expensive. As research continues and use becomes more widespread, costs will likely decrease, but will still remain substantial. Because the technology is still relatively new, many issues have yet been completely resolved. Some types of artificial cells have experienced problems with wall leakage, while others are still affected by natural degradation processes such as oxidation.
Like many medical innovations, liposomes are increasingly being used commercially. They are being called a better way to deliver vitamin, herbal and mineral supplements, and there are popular recipes for the personal creation of dietary supplements. While these uses produce their own controversies, the continued development of better medication delivery systems gives additional hope for advanced treatments.
The significance of these very small vesicular forms that are able to enclose molecules soluble in water became apparent soon after being introduced during the 1960s. Pharmacists and research scientists became keenly aware of their potential to improve methods of drug delivery when fighting cancer and other serious illness. They encourage more accurate targeting of malicious cells while avoiding issues that plague other forms 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 drug molecules encased within each structure are suspended in water and surrounded by an artificially or naturally created membrane. The formulation of designed liposomes turns them into ideal mechanisms for hydrophilic drugs, or those that are attracted to and become suspended in water. When prepared according to current methods, the structures exist in two primary types, unilammelar or multilammelar. There are subcategories that include different sizes.
The liposomes are made to surround the medications with membranes, and when activated release those molecules into other cells. This can be done by fusing the layers, causing them to interact with adjacent human cells, and releasing medication in the process. Other activation strategies include using specific chemical reactions to encourage molecular diffusion. The end result is a controlled, steady delivery.
This not only creates medicines that are more easily administered and managed, but does so in a bio-compatible way that leaves little toxic residue in non-targeted organs. Relatively recent developments involve the use of ultrasound to trigger release in specific locations where they are necessary. Other delivery methods include using the respiratory system, especially the lungs, where they can be activated slowly, reducing unwanted toxicity.
Manufacturing these tiny capsules for medical purposes is still expensive. As research continues and use becomes more widespread, costs will likely decrease, but will still remain substantial. Because the technology is still relatively new, many issues have yet been completely resolved. Some types of artificial cells have experienced problems with wall leakage, while others are still affected by natural degradation processes such as oxidation.
Like many medical innovations, liposomes are increasingly being used commercially. They are being called a better way to deliver vitamin, herbal and mineral supplements, and there are popular recipes for the personal creation of dietary supplements. While these uses produce their own controversies, the continued development of better medication delivery systems gives additional hope for advanced treatments.
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