Ultrasounds dance the 'moonwalk' in new metamaterial

Silicone beads embedded in a water-based gel (photograph is ~2 cm across). Credit: © CRPP

Metamaterials have extraordinary properties when it comes to diverting and controlling waves, especially sound and light: for instance, they can make an object invisible, or increase the resolving power of a lens. Now, researchers at the Centre de Recherche Paul Pascal (CNRS) and the Institut de Mécanique et d'Ingénierie de Bordeaux (CNRS/Université de Bordeaux/Bordeaux INP/Arts et Métiers ParisTech) have developed the first three-dimensional metamaterials by combining physico-chemical formulation and microfluidics technology. This is a new generation of soft metamaterials that are easier to shape. In their experiment, the researchers got ultrasonic oscillations to move backwards while the energy carried by the wave moved forwards. Their work opens up new prospects, especially for high-resolution imaging (ultrasonography). It is published on 15 December 2014 in the journal Nature Materials.

Since the 2000s, the international scientific community has seen interest in metamaterials and their extraordinary properties grow exponentially. A metamaterial is a medium in which the phase velocity of light or sound waves can be negative (the material is said to have a negative refractive index).. In such a medium, the phase of the wave (the successive oscillations) and the energy carried by this same wave move in opposite directions. This property is not found in any natural homogeneous medium.

To obtain a metamaterial, it is necessary to make a heterogeneous medium that contains a large number of inclusions (known as microresonators). The usual way is to use micromechanical methods (etching, deposition, etc) to machine solid supports that will have the properties of metamaterials in one or two dimensions. However, this method cannot be used to work with soft matter at the micrometer scales required for ultrasounds, and the materials obtained remain limited to one or two dimensions.

In this study, the researchers developed a new type of metamaterial, in the fluid phase, formed of porous silicone microbeads embedded in a water-based gel. This metafluid is the first three-dimensional metamaterial to work at ultrasonic frequencies. In addition, due to its fluid nature, it can be made using physico-chemical processes and microfluidics technologies, which are much easier to implement than micromechanical methods.

One of the properties of porous media is that sound travels through them at very low speed (a few tens of meters per second) compared to water (1500 meters per second). Due to this sharp contrast, the whole suspension has the properties of a metamaterial provided the bead concentration is sufficient: when the researchers studied the propagation of ultrasonic waves through this medium, they directly measured a negative refractive index. Within such a metafluid, the energy carried by the wave travels from the emitter to the receiver, as expected, whereas the oscillations appear to move backwards in the opposite direction, rather like a dancer doing the 'moonwalk'.

These results open the way to numerous applications ranging from high-resolution ultrasound imaging to sound insulation and stealth in underwater acoustics. In addition, the soft-matter physico-chemical techniques used to make this metamaterial makes it possible to produce fluid or flexible materials with adaptable shapes, potentially at the industrial scale.

Source: CNRS (Délégation Paris Michel-Ange)

Powerful imaging for optical point-of-care diagnostics

The new imaging system consists of a handheld probe (on the right), and an ultrasound scanning display system (on the left). It can be easily transported between rooms in a clinic. Credit: Pim van den Berg/ Khalid Daoudi

A new handheld probe developed by a team of university and industry researchers in the Netherlands and France could give doctors powerful new imaging capabilities right in the palms of their hands. The imaging system, which is described in a paper published in The Optical Society's (OSA) open-access journal Optics Express, shrinks a technology that once filled a whole lab bench down to a computer screen and a small probe about the size of a stapler.

The new device combines two imaging modalities: ultrasound and photoacoustics. Ultrasound is a well-established technology that analyzes how sound pulses echo off internal body parts. It is good at revealing anatomical structures and is, perhaps most familiarly, used to image a developing fetus in a mother's womb.

Photoacoustics is a relatively new imaging technique, still making its way toward widespread clinical applications. In photoacoustic imaging, short pulses of light heat up internal tissue. The slight temperature change leads to a change in pressure,
which in turn produces a wave of ultrasound that can be analyzed to reveal information about the body's internal workings. Since this technique ultimately produces ultrasound waves as well, existing technology can be used to analyze and display the images.

The advantage of photoacoustics is that it can reveal important medical information that other imaging techniques cannot, including the presence of molecules like hemoglobin and melanin and the sub-millimeter structure of networks of blood vessels several centimeters beneath the skin. When combined with spectroscopic measurements, photoacoustics can also quantify hemoglobin oxygen saturation within single vessels, providing metabolic information that could be helpful for monitoring tumor progression, for example.

Yet despite these benefits, the cost and size of most photoacoustic systems limit their widespread use, said Khalid Daoudi, a researcher in the Biomedical Photonic Imaging Group at the University of Twente in the Netherlands. Most systems on the market require costly and bulky lasers that make the systems impractical for point-of-care diagnostics. "Our research aimed to break through these hindering factors," Daoudi said.

The project started as collaboration between the University of Twente and three European companies: ESAOTE Europe, a maker of medical diagnostic systems, Quantel, a maker of solid state lasers, and SILIOS Technologies, a maker of optical components.

The team's key innovation, which allowed them to dramatically shrink the system, was the design of an ultra-compact laser based on an efficient and inexpensive laser diode. By stacking multiple diodes to increase the power and carefully designing optical elements to shape the laser beam, the team was able to generate laser pulses with energies higher than had ever been achieved before with diode technology.

Diode lasers can also provide many laser pulses per second, which in turn allows real time imaging, another advantage of the new system, Daoudi noted.

The researchers tested the imaging performance of the system in different types of phantoms -- materials designed to mimic a tissue's optical properties -- and in a healthy human finger joint.

The new compact probe and imaging system can be easily transported between rooms in a clinical setting, an attractive feature for future commercialization, the researchers said.

The team is currently working with a European consortium of industrial and academic partners to take the next steps from the research to the commercialization phase. The current system operates at a single wavelength in the near infrared, but the team has plans to expand the design to multi-wavelength imaging.

"Some applications targeted are rheumatoid arthritis in finger joints, oncology, cardiovascular disease and burn wounds," Daoudi said.

Source: The Optical Society