<p class="title">MIT scientists have developed a new ultrasound technique that does not require contact with the body to see inside a patient, an advance that may help remotely image and assess health of infants, burn victims, and accident survivors in hard-to-reach places.</p>.<p class="bodytext">Conventional ultrasound does not expose patients to harmful radiation as X-ray and CT scanners do, and it is generally noninvasive.</p>.<p class="bodytext">However, it does require contact with a patient's body, and as such, may be limiting in situations where clinicians might want to image patients who don't tolerate the probe well.</p>.<p class="bodytext">Ultrasound probe contact induces significant image variability, which is a major challenge in modern ultrasound imaging, according to the researchers from the Massachusetts Institute of Technology (MIT) in the US.</p>.<p class="bodytext">The new laser ultrasound technique leverages an eye- and skin-safe laser system to remotely image the inside of a person.</p>.<p class="bodytext">When trained on a patient's skin, one laser remotely generates sound waves that bounce through the body, the researchers said.</p>.<p class="bodytext">A second laser remotely detects the reflected waves, which researchers then translate into an image similar to conventional ultrasound.</p>.<p class="bodytext">In the journal Light: Science and Applications, the team reports generating the first laser ultrasound images in humans.</p>.<p class="bodytext">The researchers scanned the forearms of several volunteers and observed common tissue features such as muscle, fat, and bone, down to about six centimetres below the skin.</p>.<p class="bodytext">"We're at the beginning of what we could do with laser ultrasound," said Brian W. Anthony, a principal research scientist at MIT.</p>.<p class="bodytext">"Imagine we get to a point where we can do everything ultrasound can do now, but at a distance. This gives you a whole new way of seeing organs inside the body and determining properties of deep tissue, without making contact with the patient," Anthony said.</p>.<p class="bodytext">The team selected 1,550-nanometre lasers, a wavelength which is highly absorbed by water, and is eye- and skin-safe.</p>.<p class="bodytext">As skin is essentially composed of water, the team reasoned that it should efficiently absorb this light, and heat up and expand in response.</p>.<p class="bodytext">As it oscillates back to its normal state, the skin itself should produce sound waves that propagate through the body, the researchers said.</p>.<p class="bodytext">They tested this idea with a laser setup, using one pulsed laser set at 1,550 nanometers to generate sound waves, and a second continuous laser, tuned to the same wavelength, to remotely detect reflected sound waves.</p>.<p class="bodytext">This second laser is a sensitive motion detector that measures vibrations on the skin surface caused by the sound waves bouncing off muscle, fat, and other tissues, the researchers said.</p>.<p class="bodytext">Skin surface motion, generated by the reflected sound waves, causes a change in the laser's frequency, which can be measured, they said.</p>.<p class="bodytext">By mechanically scanning the lasers over the body, scientists can acquire data at different locations and generate an image of the region. PTI SAR SAR</p>
<p class="title">MIT scientists have developed a new ultrasound technique that does not require contact with the body to see inside a patient, an advance that may help remotely image and assess health of infants, burn victims, and accident survivors in hard-to-reach places.</p>.<p class="bodytext">Conventional ultrasound does not expose patients to harmful radiation as X-ray and CT scanners do, and it is generally noninvasive.</p>.<p class="bodytext">However, it does require contact with a patient's body, and as such, may be limiting in situations where clinicians might want to image patients who don't tolerate the probe well.</p>.<p class="bodytext">Ultrasound probe contact induces significant image variability, which is a major challenge in modern ultrasound imaging, according to the researchers from the Massachusetts Institute of Technology (MIT) in the US.</p>.<p class="bodytext">The new laser ultrasound technique leverages an eye- and skin-safe laser system to remotely image the inside of a person.</p>.<p class="bodytext">When trained on a patient's skin, one laser remotely generates sound waves that bounce through the body, the researchers said.</p>.<p class="bodytext">A second laser remotely detects the reflected waves, which researchers then translate into an image similar to conventional ultrasound.</p>.<p class="bodytext">In the journal Light: Science and Applications, the team reports generating the first laser ultrasound images in humans.</p>.<p class="bodytext">The researchers scanned the forearms of several volunteers and observed common tissue features such as muscle, fat, and bone, down to about six centimetres below the skin.</p>.<p class="bodytext">"We're at the beginning of what we could do with laser ultrasound," said Brian W. Anthony, a principal research scientist at MIT.</p>.<p class="bodytext">"Imagine we get to a point where we can do everything ultrasound can do now, but at a distance. This gives you a whole new way of seeing organs inside the body and determining properties of deep tissue, without making contact with the patient," Anthony said.</p>.<p class="bodytext">The team selected 1,550-nanometre lasers, a wavelength which is highly absorbed by water, and is eye- and skin-safe.</p>.<p class="bodytext">As skin is essentially composed of water, the team reasoned that it should efficiently absorb this light, and heat up and expand in response.</p>.<p class="bodytext">As it oscillates back to its normal state, the skin itself should produce sound waves that propagate through the body, the researchers said.</p>.<p class="bodytext">They tested this idea with a laser setup, using one pulsed laser set at 1,550 nanometers to generate sound waves, and a second continuous laser, tuned to the same wavelength, to remotely detect reflected sound waves.</p>.<p class="bodytext">This second laser is a sensitive motion detector that measures vibrations on the skin surface caused by the sound waves bouncing off muscle, fat, and other tissues, the researchers said.</p>.<p class="bodytext">Skin surface motion, generated by the reflected sound waves, causes a change in the laser's frequency, which can be measured, they said.</p>.<p class="bodytext">By mechanically scanning the lasers over the body, scientists can acquire data at different locations and generate an image of the region. PTI SAR SAR</p>