Sound could replace lasers in surgery
Moving from HOT to HAT, a dazzling new acoustic technology.
- Scientists announce the ability to simultaneously manipulate individual levitated objects.
- Using high-frequency sound waves may provide a safer alternative to laser microsurgery.
- Video of the research looks like a cartoon, but it's all real.
For a while now, scientists have presented demonstrations of sound's ability to levitate and move suspended particles. It's pretty cool stuff, and you can find lots of amazing videos showing intriguing patterns made with acoustic waves. Now, though, mechanical engineers Asier Marzo of Spain's Universidad Publica De Navarra and Bruce Drinkwater of the UK's University of Bristol have published research in which they demonstrate, for the first time, the ability to independently move particles in 3D space using ultrasonic sound waves. This technology has the potential to one day offer a less-invasive and destructive alternative to the lasers current employed in surgery suites. As Drinkwater tells University of Bristol News, "Optical tweezers are a fantastic technology, but always dangerously close to killing the cells being moved. With acoustics we're applying the same sort of forces but with way less energy associated. There's lots of applications that require cellular manipulation and acoustic systems are perfect for them."
HAT, not HOT
Marzo and Drinkwater call their invention "Holographic Acoustic Tweezers" (HOT), or simply "acoustic tweezers" in conversation. The HOT acronym differentiates the method from Holographic Optical Tweezers (HAT), the laser-based technology it hopes to supplant. The technique's medical applications do seem plausible: The scientists have already shown that they can connect polystyrene spheres with thread and use HAT to sew fabric.
Since moving polystyrene balls in the air is hardly the same as manipulating tiny objects in the body, the current breakthrough is seen as just a first step. Marzo and Drinkwater hope to demonstrate the system working in water in about a year, and from there move on to getting it going in biological tissue. Marzo says, "The flexibility of ultrasonic sound waves will allow us to operate at micrometre scales to position cells within 3D printed assemblies or living tissue. Or on a larger scale, to levitate tangible pixels that form a physical hologram in mid-air."
Sergio Larripa, Asier Marzo, Bruce Drinkwater
Working in the HAT array
How HAT works
Even in its current form, the HAT technology is impressive, to say the least.
"We applied a novel algorithm that controls an array of 256 small loudspeakers," says Marzo, "and that is what allows us to create the intricate, tweezer-like, acoustic fields." The speakers emit very high-frequency sound waves, in the 40 kHz range — human hearing is said to top out at just above 20 kHz, though there's some debate about its upper limits.
The HAT demonstration takes place inside a box-like array with the 256 single-centimeter speakers arranged on walls opposite each other over a reflective base. The "particles" they're moving are styrofoam balls from 1-3 millimeters in diameter, and HAT is currently capable of moving up to 25 of them at a time.
The future of HAT
Marzo describes his vision for HAT's future, saying, "The flexibility of ultrasonic sound waves will allow us to operate at micrometer scales to position cells within 3D printed assemblies or living tissue. Or on a larger scale, to levitate tangible pixels that form a physical hologram in mid-air." He describes another tantalizing use to Agencia Sync: "At micrometric scales," "Marzo says, it could allow "the manipulation of 3D cells to create structures beyond a simple culture in a two-dimensional Petri dish."
- Acoustic tweezers levitate single cells using sound waves ›
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- These sound waves can levitate and move particles in new ways ... ›
- Acoustic tweezers moves cells in three dimensions, builds structures ›
What can 3D printing do for medicine? The "sky is the limit," says Northwell Health researcher Dr. Todd Goldstein.
- Medical professionals are currently using 3D printers to create prosthetics and patient-specific organ models that doctors can use to prepare for surgery.
- Eventually, scientists hope to print patient-specific organs that can be transplanted safely into the human body.
- Northwell Health, New York State's largest health care provider, is pioneering 3D printing in medicine in three key ways.
New computing theory allows artificial intelligences to store memories.
- To become autonomous, robots need to perceive the world around them and move at the same time.
- Researchers create a theory of hyperdimensional computing to help store robot movement in high-dimensional vectors.
- This improvement in perception will allow artificial intelligences to create memories.
If you don't want to know anything about your death, consider this your spoiler warning.
- For centuries cultures have personified death to give this terrifying mystery a familiar face.
- Modern science has demystified death by divulging its biological processes, yet many questions remain.
- Studying death is not meant to be a morbid reminder of a cruel fate, but a way to improve the lives of the living.
Riots may ensue as more poor Americans recognize their "miserable" long-term prospects.
- How bad is wealth inequality in the United States? About 1 percent of Americans hold 80 percent of the money.
- In the United States, the correlation between the income of parents and the income of their children when they grow up is higher than in any other country in the world.
- One of the big underlying reasons for poverty is receiving a crummy education, which in turn leads to crummy jobs. When people recognize their miserable long-term prospects, they are more likely to partake in riots.
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