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Special gold nanoparticles show promise for 'cooking' cancer cells
March 23, 2009Researchers are describing a long-awaited advance toward applying the marvels of nanotechnology in the battle against cancer. They have developed the first hollow gold nanospheres - smaller than the finest flecks of dust - that search out and "cook" cancer cells. The cancer-destroying nanospheres show particular promise as a minimally invasive future treatment for malignant melanoma, the most serious form of skin cancer, the researchers say. Melanoma now causes more than 8,000 deaths annually in the United States alone and is on the increase globally.
The topic of a report presented here today at the American Chemical Society's 237th National Meeting, the hollow gold nanospheres are equipped with a special "peptide." That protein fragment draws the nanospheres directly to melanoma cells, while avoiding healthy skin cells. After collecting inside the cancer, the nanospheres heat up when exposed to near-infrared light, which penetrates deeply through the surface of the skin. In recent studies in mice, the hollow gold nanospheres did eight times more damage to skin tumors than the same nanospheres without the targeting peptides, the researchers say.
"This technique is very promising and exciting," explains study co-author Jin Zhang, Ph.D., a professor of chemistry and biochemistry at the University of California in Santa Cruz. "It's basically like putting a cancer cell in hot water and boiling it to death. The more heat the metal nanospheres generate, the better."
This form of cancer therapy is actually a variation of photothermal ablation, also known as photoablation therapy (PAT), a technique in which doctors use light to burn tumors. Since the technique can destroy healthy skin cells, doctors must carefully control the duration and intensity of treatment.
Researchers now know that PATs can be greatly enhanced by applying a light absorbing material, such as metal nanoparticles, to the tumor. Although researchers have developed various types of metal nanoparticles to help improve this technique, many materials show poor penetration into cancer cells and limited heat carrying-capacities. These particles include solid gold nanoparticles and nanorods that lack the desired combination of spherical shape and strong near-infrared light absorption for effective PAT, scientists say.
To develop more effective cancer-burning materials, Zhang and colleagues focused on hollow gold nanospheres - each about 1/50,000th the width of a single human hair. Previous studies by others suggest that gold "nanoshells" have the potential for strong near-infrared light absorption. However, scientists have been largely unable to produce them successfully in the lab, Zhang notes.
After years of research toward this goal, Zhang announced in 2006 that he had finally developed a nanoshell or hollow nanosphere with the "right stuff" for cancer therapy: Gold spheres with an optimal light absorption capacity in the near-infrared region, small size, and spherical shape, perfect for penetrating cancer cells and burning them up.
"Previously developed nanostructures such as nanorods were like chopsticks on the nanoscale," Zhang says. "They can go through the cell membrane, but only at certain angles. Our spheres allow a smoother, more efficient flow through the membranes."
The gold nanoshells, which are nearly perfect spheres, range in size from 30 to 50 nanometers - thousands of times smaller than the width of a human hair. The shells are also much smaller than other nanoparticles previously designed for photoablation therapy, he says. Another advantages is that gold is also safer and has fewer side effects in the body than other metal nanoparticles, Zhang notes.
In collaboration with Chun Li, Ph.D., a professor at the University of Texas M.D. Anderson Cancer Center in Houston, Zhang and his associates equipped the nanospheres with a peptide to a protein receptor that is abundant in melanoma cells, giving the nanospheres the ability to target and destroy skin cancer. In tests using mice, the resulting nanospheres were found to be significantly more effective than solid gold nanoparticles due to much stronger near infrared-light absorption of the hollow nanospheres, the researchers say.
The next step is to try the nanospheres in humans, Zhang says. This requires extensive preclinical toxicity studies. The mice study is the first step, and there is a long way to go before it can be put into clinical practice, Li says.
American Chemical Society
This form of cancer therapy is actually a variation of photothermal ablation, also known as photoablation therapy (PAT), a technique in which doctors use light to burn tumors. Since the technique can destroy healthy skin cells, doctors must carefully control the duration and intensity of treatment.
Researchers now know that PATs can be greatly enhanced by applying a light absorbing material, such as metal nanoparticles, to the tumor. Although researchers have developed various types of metal nanoparticles to help improve this technique, many materials show poor penetration into cancer cells and limited heat carrying-capacities. These particles include solid gold nanoparticles and nanorods that lack the desired combination of spherical shape and strong near-infrared light absorption for effective PAT, scientists say.
To develop more effective cancer-burning materials, Zhang and colleagues focused on hollow gold nanospheres - each about 1/50,000th the width of a single human hair. Previous studies by others suggest that gold "nanoshells" have the potential for strong near-infrared light absorption. However, scientists have been largely unable to produce them successfully in the lab, Zhang notes.
After years of research toward this goal, Zhang announced in 2006 that he had finally developed a nanoshell or hollow nanosphere with the "right stuff" for cancer therapy: Gold spheres with an optimal light absorption capacity in the near-infrared region, small size, and spherical shape, perfect for penetrating cancer cells and burning them up.
"Previously developed nanostructures such as nanorods were like chopsticks on the nanoscale," Zhang says. "They can go through the cell membrane, but only at certain angles. Our spheres allow a smoother, more efficient flow through the membranes."
The gold nanoshells, which are nearly perfect spheres, range in size from 30 to 50 nanometers - thousands of times smaller than the width of a human hair. The shells are also much smaller than other nanoparticles previously designed for photoablation therapy, he says. Another advantages is that gold is also safer and has fewer side effects in the body than other metal nanoparticles, Zhang notes.
In collaboration with Chun Li, Ph.D., a professor at the University of Texas M.D. Anderson Cancer Center in Houston, Zhang and his associates equipped the nanospheres with a peptide to a protein receptor that is abundant in melanoma cells, giving the nanospheres the ability to target and destroy skin cancer. In tests using mice, the resulting nanospheres were found to be significantly more effective than solid gold nanoparticles due to much stronger near infrared-light absorption of the hollow nanospheres, the researchers say.
The next step is to try the nanospheres in humans, Zhang says. This requires extensive preclinical toxicity studies. The mice study is the first step, and there is a long way to go before it can be put into clinical practice, Li says.
American Chemical Society
Nanospheres Current Events and Nanospheres News RSSHollow gold nanospheres show promise for biomedical and other applications
A new metal nanostructure developed by researchers at the University of California, Santa Cruz, has already shown promise in cancer therapy studies and could be used for chemical and biological sensors and other applications as well.
Targeted nanospheres find, penetrate, then fuel burning of melanoma
Hollow gold nanospheres equipped with a targeting peptide find melanoma cells, penetrate them deeply, and then cook the tumor when bathed with near-infrared light, a research team led by scientists at The University of Texas M. D. Anderson Cancer Center reported in the Feb. 1 issue of Clinical Cancer Research.
Engineering Nanoparticles for Maximum Strength
Because they are riddled with defects, bulk crystalline materials never achieve their ideal strength; nanocrystals, on the other hand, are so small there's no room for defects.
Gold nanostars outshine the competition
Novel nanoparticles being tested at the National Institute of Standards and Technology (NIST) have researchers seeing stars. In a recent paper, NIST scientists used surface-enhanced Raman spectroscopy (SERS) to demonstrate that gold nanostars exhibit optical qualities that make them superior for chemical and biological sensing and imaging.
New technique sees into tissue at greater depth, resolution
By coupling a kicked-up version of microscopy with miniscule particles of gold, Duke University scientists are now able to peer so deep into living tissue that they can see molecules interacting.
Turning Waste Material into Ethanol
Say the word "biofuels" and most people think of grain ethanol and biodiesel. But there's another, older technology called gasification that's getting a new look from researchers at the U.S. Department of Energy's Ames Laboratory and Iowa State University. By combining gasification with high-tech nanoscale porous catalysts, they hope to create ethanol from a wide range of biomass, including distiller's grain left over from ethanol production, corn stover from the field, grass, wood pulp, animal waste, and garbage.
Killer pulses help characterize special surfaces
Detecting deadly fumes in subways, toxic gases in chemical spills, and hidden explosives in baggage is becoming easier and more efficient with a measurement technique called surface-enhanced Raman scattering. To further improve the technique's sensitivity, scientists must design better scattering surfaces, and more effective ways of evaluating them.
Platinum nanocrystals boost catalytic activity for fuel oxidation, hydrogen production
A research team composed of electrochemists and materials scientists from two continents has produced a new form of the industrially-important metal platinum: 24-facet nanocrystals whose catalytic activity per unit area can be as much as four times higher than existing commercial platinum catalysts.
UC Davis researchers use heated nanoprobes to destroy breast cancer cells in mice
In experiments with laboratory mice that bear aggressive human breast cancers, UC Davis researchers have used hot nanoprobes to slow the growth of tumors — without damage to surrounding healthy tissue. The researchers describe their work in the March issue of the Journal of Nuclear Medicine.
Gold Nanorods May Make Safer Cancer Treatment
Researchers at the Georgia Institute of Technology and the University of California, San Francisco, have found an even more effective and safer way to detect and kill cancer cells.
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Ultrasound Creates Hollow Nanospheres.: An article from: High Tech Ceramics News by Business Communications Company, Inc. (Publisher) This digital document is an article from High Tech Ceramics News, published by Business Communications Company, Inc. on March 1, 2005. The length of the article is 350 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. Citation Details Title: Ultrasound Creates Hollow Nanospheres. Publication: High Tech Ceramics News (Newsletter) Date: March 1, 2005 Publisher: Business Communications Company, Inc. Volume: 16 Issue: 10 Page: NA Distributed by Thompson... | |
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Self-assembling gold nanoparticles on thiol-functionalized poly(styrene-co-acrylic acid) nanospheres for fabrication of a mediatorless biosensor [An article from: Analytica Chimica Acta] by S. Xu (Author), G. Tu (Author), B. Peng (Author), X. Han (Author) This digital document is a journal article from Analytica Chimica Acta, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: A novel strategy to construct a sensitive mediatorless sensor of H"2O"2 was described. At first, a cleaned gold electrode was immersed in thiol-functionalized poly(styrene-co-acrylic acid) (St-co-AA) nanosphere latex prepared by emulsifier-free emulsion polymerization St with AA and function with dithioglycol to assemble the nanospheres, then gold nanoparticles were chemisorbed onto the thiol groups and formed monolayers on the surface of poly(St-co-AA) nanospheres. Finally, horseradish peroxidase (HRP) was... |
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