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Recent successful medical trials of a cancer treatment involving the use of "Nanotechnology" may open up important new avenues for the diagnosis and treatment of other cancers and diseases. Nanotechnology is a broad term covering the building of structures and "machines" on an atomic or molecular scale-in the range from 1 to 100 nanometres. A nanometre is one billionth of a metre or about the size of 10 hydrogen atoms. The techniques range from various chemical and biological processes used to "construct" structures-in some cases atom by atom-to the etching methods used to produce computer chips. The field of nanotechnology has over the last decade or so been surrounded by considerable hype. Some of the visions of what is possible in medicine conjure up the Science Fiction classic film Fantastic Voyage where tiny submarine ships were injected into the body and travelled through the bloodstream to eradicate foreign bodies. The reality is more prosaic, but the potential is nonetheless exciting. Many of the standard radiation and drug therapies now used to treat cancers can have serious side effects. The use of radiation and chemicals to kill fast-growing tumour cells inevitably affects and kills other cells in the body. Nanotechnology offers the possibility of far more precisely localising the treatment and thus minimising the damage to healthy tissue. In early April, the nanotechnology company pSivida announced the very promising results of the Phase 2 clinical trials of its product "BrachySil" for patients with liver cancer. BrachySil is a tiny structure about one-millionth of a metre in size and made up of modified particles of silicon impregnated with the radioactive isotope of phosphorus 32P. Unlike other radiation treatments that involve focussing beams of radiation on tumours, BrachySil is injected directly into the cancer using a fine gauge needle. By using 32P, the radiation is limited to a range of just 8 millimetres, resulting in the killing of tumour cells rather than healthy tissue. For several years, doctors have been using a similar technique known as brachytherapy-injecting radioisotopes directly into tumours. The difficulty was that the injected material would not remain in the cancer, but would over time be carried to other parts of the body. The advantage of BrachySil is that its silicon structures, while small, prevent the radioisotope from leaking away. The result is that the dose of radiation is focussed very precisely on the tumour itself. The silicon eventually breaks down and is excreted. 32P, which has a half-life of 14 days, eventually decomposes to stable isotopes or is excreted. Because the treatment is localised, the side effects are likely to be less than other forms of brachytherapy. None have been observed to date, although the long-term impact of the treatment is not known. BrachySil consists of tiny pockets made up of silicon microparticles. The pores or holes in the silicon pocket are the size of about 10 atoms. Radioactive phosphorus is bombarded into the structure. Because of its method of delivery of radiation doses, the treatment may well be applicable to a broader range of cancers than other forms of brachytherapy, which is currently limited to prostate and liver cancers. The clinical trial of BrachySil was undertaken at the Singapore General Hospital beginning in mid-2004. It involved eight patients suffering from primary liver cancer (where the tumours have not spread to a secondary site). They were given CT scans before and after the injection of BrachySil to determine the impact on the tumours and were monitored for possible side effects. After 12 weeks of the treatment, smaller tumours were completely eradicated. The most extraordinary finding, however, was that all tumours were reduced by an average of 80 percent-a result not seen in other treatments. After the trial results were announced, the company received a flood of inquiries and was forced to announce on its website that testing was still in its early stages. Worldwide, liver cancer is not one of the most prevalent cancers. Nevertheless, more than half a million new cases are diagnosed every year-some 45 percent of them in China. Causes of liver cancer include infection by parasites such as the Chinese liver fluke. Liver cancer can also be related to hepatitis, exposure to radiation and to the irritant Polyvinyl Chloride.
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How nanotechnology works?
Nanotechnology works in two different ways, the world of molecules and the world of atoms. the two are as small as one nanometer, which is one billionth of a meter. Nanotechnology was first mentioned in the 1860's by James Clerk Maxwell in a tiny experiment called "Maxwell Demons" that was able to handle individual molecules. Nanotechnology has also been used for cancer cures and research and water nanotechnology. Nanotechnology can be used in a classification system invented by Richard Adolf Zsigmondy. He also did the first observations and measurements on nanotechnology. This is the opinoin on how Nanotechnology works.
How is nanotechnology used in chemistry?
nanotechnology is used in chemistry to enter the human body and get rid of the desease it was programed to get rid of
Nanotechnology and its importance in Medical Sciences?
Nanotechnology is the manipulation of matter on an atomic and molecular scale. It has the potential to revolutionize many fields, including medicine. Importance of nanotechnology in medical sciences Nanotechnology has the potential to improve the diagnosis, treatment, and prevention of diseases in a number of ways. For example, nanoparticles can be used to: Deliver drugs more effectively. Nanoparticles can be engineered to target specific cells or tissues, which can reduce the side effects of drugs and improve their efficacy. For example, nanoparticles are being used to develop new treatments for cancer and other diseases. Improve imaging techniques. Nanoparticles can be used to create contrast agents that can improve the resolution and sensitivity of medical imaging techniques such as MRI and CT scans. This can help doctors to diagnose diseases earlier and more accurately. Develop new diagnostic tools. Nanoparticles can be used to develop new diagnostic tools that can detect diseases at an earlier stage. For example, nanoparticles are being developed to detect cancer cells in the bloodstream. Create new tissue engineering scaffolds. Nanoparticles can be used to create new scaffolds that can help to repair or regenerate damaged tissues. For example, nanoparticle-based scaffolds are being used to develop new treatments for spinal cord injuries and other conditions. Examples of nanotechnology applications in medical sciences Here are some specific examples of how nanotechnology is being used in medical sciences today: Nanoparticles are being used to deliver chemotherapy drugs to cancer cells. This can help to reduce the side effects of chemotherapy and improve its effectiveness. Nanoparticles are being used to create contrast agents for MRI scans. This can help doctors to diagnose cancer and other diseases earlier and more accurately. Nanoparticles are being developed to detect cancer cells in the bloodstream. This could lead to earlier diagnosis and treatment of cancer. Nanoparticle-based scaffolds are being used to develop new treatments for spinal cord injuries. These scaffolds can help to promote nerve regeneration and improve function. Nanoparticles are being used to develop new vaccines. Nanoparticles can help to deliver vaccines more effectively and improve their immune response. Future of nanotechnology in medical sciences Nanotechnology is still in its early stages of development, but it has the potential to revolutionize many aspects of medicine. In the future, we can expect to see nanotechnology used to develop new and more effective treatments for a wide range of diseases. Nanotechnology could also be used to develop new diagnostic tools and imaging techniques that can help doctors to diagnose diseases earlier and more accurately. Overall, nanotechnology has the potential to make a significant impact on human health and well-being.
Radiological and chemical are terms that are used to describe?
Oncologic (cancer) treatment, for one.
What is the difference between nanoparticles and nanotechnology?
nanoparticles are basicly microscopic particles. Nanotechnology is the technology used to manipulate these nonoparticles for human use.
Does Nanotechnology in Medicine e.g. Treatment of Cancer Cell use Artificial Intelligence if yes How?
Not presently.
Is there any cancer treatment?
radiation treatment of cancer or other kinds of treatments can be used for cancer.
How can nanotechnology help detect diseases?
Nanotechnology can use to develop bio indicators a type of molecules which will attached to infected cells, they also can be detected from scanning. let say nanotechnology can be used to develop a dye to indicate cancer cells and when a patient given that, the dye molecules will selectively attached to the cancer cells and the dye concentration will increase around the cancer. And once the scanning is done dye can be identified hence the cancer.
What treatment is used for cancer?
KEMO
How could herbal medicine be used in cancer treatment?
Herbal medicines is the natural treatment and for cancer it's one of the effective treatment from the centuries.Certain herbs are combined used for the major diseases like cancer.
Which noble gas is used for cancer treatment?
argon is the gas used in treatement of cancer
How does nanotechnology works?
Nanotechnology works in two different ways, the world of molecules and the world of atoms. the two are as small as one nanometer, which is one billionth of a meter. Nanotechnology was first mentioned in the 1860's by James Clerk Maxwell in a tiny experiment called "Maxwell Demons" that was able to handle individual molecules. Nanotechnology has also been used for cancer cures and research and water nanotechnology. Nanotechnology can be used in a classification system invented by Richard Adolf Zsigmondy. He also did the first observations and measurements on nanotechnology. This is the opinoin on how Nanotechnology works.
How nanotechnology works?
Nanotechnology works in two different ways, the world of molecules and the world of atoms. the two are as small as one nanometer, which is one billionth of a meter. Nanotechnology was first mentioned in the 1860's by James Clerk Maxwell in a tiny experiment called "Maxwell Demons" that was able to handle individual molecules. Nanotechnology has also been used for cancer cures and research and water nanotechnology. Nanotechnology can be used in a classification system invented by Richard Adolf Zsigmondy. He also did the first observations and measurements on nanotechnology. This is the opinoin on how Nanotechnology works.
Can antibiotics be used in the treatment of cancer?
No, antibiotics do not control cancer.
Can you catch the HIV by nanobots and can you destroy it by nanobots?
Today, and in foreseeable future - not at all.
Is foxglove a source of a cancer-treatment?
Foxglove is a source of digitalis, a medication used in the treatment of heart disease. It has no reported efficacy in the treatment of any cancer.
Is radioactive isotopes used to treat cancer.?
Yes, radioactive isotopes are largely used for the treatment of cancer.
