Nanotechnology promises to impact medical treatment in multiple ways. First, advances in nanoscale particle design and fabrication provide new options for drug delivery and drug therapies. More than half of the new drugs developed each year are not water-soluble, which makes their delivery difficult. In the form of nanosized particles, however, these drugs are more readily transported to their destination, and they can be delivered in the conventional form of pills.
More important, nanotechnology may enable drugs to be delivered to precisely the right location in the body and to release drug doses on a predetermined schedule for optimal treatment. The general approach is to attach the drug to a nanosized carrier that will release the medicine in the body over an extended period of time or when specifically triggered to do so. In addition, the surfaces of these nanoscale carriers may be treated to seek out and become localized at a disease site—for example, attaching to cancerous tumours. One type of molecule of special interest for these applications is an organic dendrimer. A dendrimer is a special class of polymeric molecule that weaves in and out from a hollow central region. These spherical “fuzz balls” are about the size of a typical protein but cannot unfold like proteins. Interest in dendrimers derives from the ability to tailor their cavity sizes and chemical properties to hold different therapeutic agents. Researchers hope to design different dendrimers that can swell and release their drug on exposure to specifically recognized molecules that indicate a disease target. This same general approach to nanoparticle-directed drug delivery is being explored for other types of nanoparticles as well.
Another approach involves gold-coated nanoshells whose size can be adjusted to absorb light energy at different wavelengths. In particular, infrared light will pass through several centimetres of body tissue, allowing a delicate and precise heating of such capsules in order to release the therapeutic substance within. Furthermore, antibodies may be attached to the outer gold surface of the shells to cause them to bind specifically to certain tumour cells, thereby reducing the damage to surrounding healthy cells.
Examples-from-biological-and-mechanical-realms-illustrate-various-orders-ofExamples from biological and mechanical realms illustrate various “orders of magnitude” …[Credits : Encyclopædia Britannica, Inc.]
The-structure-of-buckminsterfullereneThe structure of buckminsterfullerene (C60).[Credits : Encyclopædia Britannica, Inc.]
Top-down-approaches-have-been-developed-for-building-structures-atTop-down approaches have been developed for building structures at the scale of the micrometre …[Credits : Encyclopædia Britannica, Inc.]
Phospholipid-molecules-composed-of-fatty-acid-tails-and-a-phosphatePhospholipid molecules, composed of fatty acid “tails” and a phosphate …[Credits : Encyclopædia Britannica, Inc.]
Coherent-X-ray-diffraction-patterns-such-as-the-one-shownCoherent X-ray diffraction patterns, such as the one shown here of a nanosized metal cube, can be …[Credits : Reprinted by permission from Macmillan Publishers Ltd.; Nature, July 6, 2006, vol. 442, …]
Link to this article and share the full text with the readers of your Web site or blog-post.
If you think a reference to this article on "nanotechnology" will enhance your Web site,
blog-post, or any other web-content, then feel free to link to this article,
and your readers will gain full access to the full article, even if they do not subscribe to our service.
You may want to use the HTML code fragment provided below.
We welcome your comments. Any revisions or updates suggested for this article will be reviewed by our editorial staff. Contact us here.
Regular users of Britannica may notice that this comments feature is less robust than in the past. This is only temporary, while we make the transition to a dramatically new and richer site. The functionality of the system will be restored soon.