Superfast Laser Turns Virus Into Rubble

A physicist and his biologist son destroyed a common virus using a superfast pulsing laser, without harming healthy cells. The discovery could lead to new treatments for viruses like HIV that have no cure.

“We have demonstrated a technique of using a laser to excite vibrations on the shield of a virus and damage it, so that it’s no longer functional,” said Kong-Thon Tsen, a professor of physics at Arizona State University. “We’re testing it on HIV and hepatitis right now.”

Tsen and his son Shaw-Wei Tsen, a pathology student at Johns Hopkins University, came up with the idea while strolling in the park and discussing the need for antiviral treatments that go beyond vaccinations. Tsen senior has long experimented with ultrashort-pulse lasers (USPs), devices increasingly used outside of physics.

Raydiance, a USP laser manufacturer, signed a deal with the FDA in July to explore laser therapies. As Wired News reported earlier this year, an FDA official estimated there could be a hundred medical uses for USP lasers, from common laser eye treatments to cell-by-cell tumor ablation.

In the latest research, Tsen and his son demonstrated that their laser technique could shatter the protein shell, or capsid, of the tobacco mosaic virus, leaving behind only a harmless mucus-like mash of molecules.

The laser shattered the capsid at low energy: 40 times lower, in fact, than the energy level that harmed human T-cells. Other types of radiation, like ultraviolet light, kill microbes on produce, but would damage human cells.

The virus-deactivating laser works on a principle called forced resonance. The scientists tune the laser to the same frequency the virus vibrates on. Then they crank up the volume. Like a high-pitched sound shattering glass, the laser vibrates the virus until it breaks.

The USP laser releases energy in femtosecond pulses — one millionth of a nanosecond — at a time.

“The extreme brevity of these pulses is creating a physical effect that traditional lasers and other types of non-laser approaches can’t do,” said Scott Davison, president of the venture-backed USP laser company, Raydiance. “What we see is a new wave of exploration and discovery in applying USP in a whole bunch of industries and applications.”

Unlike lasers used to burn through flesh in surgery, USP lasers don’t generate a lot of heat. Tsen says the technology could provide immediate benefits for clearing viruses in blood stored in blood banks. Some viruses, like HIV, have a window during which they are very difficult to detect.

“This technique will be very useful to disinfect all the viruses, known or unknown,” Tsen said. “This will make blood transfusion very safe.”

The Tsens’ technology has seen success only in test tubes. It must be tested in animals and then humans. Treatments are still far in the future. But with more strolls in the park, anything seems possible.

(Source: http://www.wired.com/science/discoveries/news/2007/11/laser_virus)

I wonder how long will it take for big pharmaceutical co. To buy this invention and shelve it…

Friday, November 9, 2007 Posted by richardlalancette | Laser, New Technology | Leave a Comment

BACKWARD RESEARCH GOES FORWARD

University of Washington physicist (and science-fiction author) John Cramer is moving forward with his experiment in backward causality, thanks in part to tens of thousands of dollars in contributions sent in by his fans. Although Cramer emphasizes that his lab is looking at “nonlocal quantum communication” rather than backward time travel per se, the gadgetry he’s assembling could settle a controversy surrounding a seemingly faster-than-light effect that Albert Einstein thought was downright spooky.

Boiled down to its basics, the experiment involves splitting laser light into two beams, so that characteristics of one beam are reflected in the other beam as well. That’s an example of what physicists call quantum entanglement. Specifically, Cramer has been planning to fiddle with one of the entangled laser beams such that it takes on the property of waves or particles. If one beam behaves like particles, the entangled photons of light in the other beam should behave like particles, too.

So what happens when the beams go their separate ways, and you conduct a wave-vs.-particle measurement on one beam? When someone else checks the other beam, the same measurement should yield the same result. In fact, you could visualize using the wave-vs.-particle toggle as a means for communicating information, sort of like Morse code. Theoretically, you could check one beam to receive a message instantaneously from whoever is fiddling with the other beam – even if you’re separated from the receiver by millions of light-years.

That’s what Einstein considered “spooky action at a distance.” Such an effect could send information faster than light beams could travel, running counter to special relativity – and thus Einstein thought the effect was impossible to achieve. However, the evidence is mounting that quantum entanglement actually happens.

Cramer planned to start out by testing this kind of communication through quantum entanglement – that’s the “nonlocal communication” part of the experiment. If that worked, Cramer would go even further: He would send one of the entangled beams (call it Signal A) through a circuitous detour – say, a few miles of fiber-optic cable – then fiddle with it when it came out of the cable. If the principles behind nonlocal communication held true, the evidence of that fiddling should be detected at a corresponding place in the other entangled beam (call it Signal B).

Now brace yourself for the backward-causality part: Because Signal B followed a shorter route to its detector, the fiddling in Signal A could theoretically show up in Signal B before Cramer actually fiddles with Signal A. It would be as if Cramer’s actions had an effect that worked backward in time.

If Cramer detected that effect, the findings would raise the kinds of paradoxes you might see in science-fiction novels or “The Twilight Zone.” What if you detected a signal from the future, but then decided not to send the signal? (That’s called the “bilking paradox”). What if you received the text of a best-selling manuscript from yourself in the future, had it published, then saved a copy so you could send it to yourself in the past? (Cramer calls that the “immaculate conception paradox.”)

“Perhaps the fact that there are such paradoxes is nature’s way of telling us that our experiment isn’t going to work,” Cramer said.

Nevertheless, Cramer is anxious to find out whether it might work – and if not, why not. He suggested the framework for the experiment a year ago, and no one could come up with a reason why it should fail. Except for the money problem. …

For months, Cramer struggled to find the funding he needed to buy the equipment for the experiment, to no avail. Then an article about his plight came out in the Seattle Post-Intelligencer – and within weeks, thousands of dollars flowed in from foundations and private donors who, for one reason or another, wanted to find out what kind of answers Cramer could come up with.

Cramer said the fund now amounts to $40,000, and now that he’s back from a tour of duty at the Relativistic Heavy Ion Collider, he’s moving forward with the laser experiment. “If that laser holds out, then I think we’re in pretty good shape,” he told me today.

He’s hoping to complete the experiment by September, when the equipment he’s using will have to be moved someplace else to make room for remodeling. “It would be very nice if we could finish up by the 15th of September, but I don’t know if we’ll be able to do that or not,” he said.

Cramer is grateful for all the donations, but he admitted that he’s “a little uncomfortable” about the way things have gone so far. Usually, physicists work in obscurity, get some funding, conduct an experiment, publish the results – and only then does the publicity come, if the results are spectacular enough. The way Cramer sees it, there’s been a heck of a lot of publicity already about an experiment that has yet to be done.

“We seem to be doing it sort of backwards, in a sense,” he said. Then, realizing that he’s been talking about backward causality, he added with a chuckle that “it may be relevant to the experiment we’re trying to do.”

Cramer, who is the author of two science-fiction novels and a regular columnist for Analog magazine, said the experiment represents “a rare opportunity to push the envelope of quantum mechanics.” No matter how it turns out, the results will be put to good use, he said.

“If this experiment we’re doing works, then I will follow up and push it as hard as possible. And if it doesn’t work, I will write a science-fiction novel where it does work,” he said. “It’s a win-win situation.”

Feel free to add your thoughts about backward causality and time travel in the comments section below, or visit our discussion board. And if you’ve already come up with a solution for backward time travel, fill me in on the secret … yesterday.

Friday, July 20, 2007 Posted by richardlalancette | John Cramer, Laser, Quantum Entanglement, Quantum Physic | 1 Comment

Italians Build Atomic Laser

FLORENCE, Italy, July 6, 2007

Scientists have reported a way to achieve the so-called atomic laser, a breakthrough predicted by Albert Einstein in 1925, the Italian news agency ANSA reported today.

A Florence University research team led by Massimo Inguscio and Giovanni Modugno used potassium isotopes to build an “atomic condensate” squeezed into a harmonious whole by a magnetic field, similar to a theoretical model envisaged by Einstein and fellow physicist Satyendra Nath Bose, ANSA said.

“In this way, the interaction of atoms is virtually nonexistent,” Inguscio said.

Lasers are highly concentrated streams of light particles, or photons, with multiple uses in industry and medicine.

“Unlike photons, atoms bounce into one another so much that an atomic laser — eagerly awaited in the field of microelectronics – has proved impossible to achieve up to now,” ANSA reported.

(Source: http://www.photonics.com)

Saturday, July 14, 2007 Posted by richardlalancette | Laser, New Technology | Leave a Comment