Tuesday, October 31, 2006

More on Fields-NanoArt 2006


The deadline is 12/31/06.

Will the Philippines be able to buy a scanneling tunneling microscope? We can call ourselves part of the Philippine-American Nanotechnology Initiative.


I talked with Cris Orfescu today. I told him that I do not think we should alloy nanocomposites with Pb, Cd, Hg, As, Be and Cr.

I also told him that STM has negligible radiation; SEM has more than STM but still negligible. I realized Light Microscopy does not have any radiation whatsoever.

comments? ideas?

I will color my websites later on. Geocities or something else. Google, Blogger, Free Blog does not have color.













Monday, October 30, 2006

More on the different fields of nanotechnology



Robert Freitas, Jr.

Nanotech News

Headline: UCLA Engineering awarded grant from the NIH to establish Nanomedicine Development Center

News source: Medical News Today

An interdisciplinary team of scientists from the UCLA Henry Samueli School of Engineering and Applied Science, the David Geffen School of Medicine at UCLA and UC Berkeley's College of Engineering has secured a prestigious federal grant from the National Institutes of Health Roadmap for Medical Research initiative aimed at improving nanomedical research. Their discoveries could enhance methods of curing diseases like cancer as well as viral infections at the molecular scale.

The nanomedicine grant, with a proposed budget of $7 million, will support the new NIH Nanomedicine Development Center for Cell Control, to be led by UCLA Engineering professor Chih-Ming Ho.

Nanomedicine Centers in the USA funded by NIH


GA Tech Research Corp
Purdue U
U of Cal, LA
U of Cal, LBL
Baylor College of Medicine
U of Illinois-Urbana Champaign
U of Cal, SF
Columiba U, NY Morningside






The late Nobel Prize winning Physicist Richard P Feynman in 1959 proposed using machine tools to make smaller machine tools, which in turn, would be used to make still smaller machine tools, and so on, all the way down to the molecular level. Such nanomachines, nanorobots and nanodevices ultimately could be used to develop a wide range of atomically precise microscopic instrumentation and manufacturing tools. Attempts are going on at present to produce molecular computer components using molecular parts at the nanometer (10-9 meter or 1 billionth of a meter) scale.

Nanotechnology will have future medical applications leading to the emergence of nanomedicine and nanodentistry. Nanodentistry will make it possible to maintain a near perfect oral health through the use of nanomaterials, biotechnology, including tissue engineering and nanorobotics. The nanorobotic functions may be controlled by an onboard nanocomputer that executes preprogrammed instructions in response to local sensor stimuli.

Local anaesthesia: In the era of nanodentistry, to induce local anaesthesia, dental professional will instill a colloidal suspension containing millions of active analgesic micrometer sized dental nanorobot particles on the patient’s gingivae. After contacting the surface of the crown or mucosa, the ambulating nanorobots reach the dentin by migrating into the gingival sulcus and passing painlessly through the lamina propria or the 1-3 micrometer thick layer of loose tissue at the cemento dentinal junction.

On reaching the dentin, the nanorobots enter dentinal tubule holes that are 1-4 micrometers in diameter and proceed toward the pulp, guided by a combination of chemical gradients, temperature differentials and even positional navigation, all under the control of the onboard nanocomputer, as directed by the dentist.

Orthodontic treatment: Orthodontic nanorobots could directly manipulate the periodontal tissues (gingiva, periodontal ligament, cementum and alveolar bone), allowing rapid and painless tooth straightening, rotating and vertical repositioning within minutes to hours.

Natural tooth maintenance: The appearance and durability of tooth may be improved by replacing upper enamel layers with covalently bonded artificial materials such as sapphire or diamond, which have 20 to 100 times the hardness and strength of natural enamel.

A subocclusal dwelling nanorobotic dentifrice delivered by mouthwash or toothpaste could patrol all supragingival and sub gingival surfaces at least once a day, metabolizing trapped organic matter into harmless and odorless vapors and performing continuous calculus debridement.

Dentirobots could identify and destroy pathogenic bacteria residing in the plaque and elsewhere, while allowing the 500 or so species of harmless oral micro flora to be maintained in a healthy ecosystem. With this kind of daily dental care available from an early age, conventional tooth decay and gingival disease will disappear.

Ref: JADA Oct.2000

Department of Health and Human Services
National Institutes of Health
Building the Tooth: Bridging Biology and Material Sciences. (Limited Competition)[U54]

Can someone(s) pick it up from here?

We better get more people and institutions...

One of the questions in my questionnaire for the Philippine American Academy of Science and Engineering is do we include
Medicine in the title and Dentistry as well or do we lump Medicine and Dentistry together as Medicine?

Fields in Nanotechnology





Nanochemistry: a Chemical Approach to Nanomaterials


Nanobiology and Nanomedicine



Cancer Nanotechnology

Office of Technology & Industrial Relations
National Cancer Institute
Building 31, Room 10A49
31 Center Drive, MSC 2580
Bethesda, MD 20892-2580
Phone: (301) 496-1550
Fax: (301) 496-7807
E-mail: otir@mail.nih.gov
Website: http://otir.nci.nih.gov/index.html