Testing Tiles Designed for Ultrasound Treatment of Soft
Tissue Injuries
A new application could help improve the quality of
ultrasound treatment for soft tissue injuries such as ligament damage and muscle
strains.
Ultrasound is commonly used in physiotherapy to hasten
healing of tissue injuries. Ideally, the sound waves should be applied
uniformly tothe treatment site, but it is well known that this does not
occur typically in practice. This can affect quality of treatment and even cause damage.
The UK National Physical Laboratory (NPL; Teddington, UK; www.npl.co.uk)
has developed a way to quickly map the distribution and intensity of
ultrasound, allowing treatment heads to be used to administer the treatment
more effectively. The application will signal physiotherapists to sharp
“hot-spots,” allowing them to move the head to smooth the intensity or discard
it where it could cause more harm than good. It also has potential for
manufacturers, who could rapidly evaluate the effect that design alterations
have on the intensity distribution.
Piezoelectric-based treatment heads, during treatment,
transform electrical energy to mechanical energy, creating the vibrations needed
to produce the ultrasound waves. These are transmitted into the target tissue
with the aid of a thin layer of coupling gel. The treatment heads actually vibrate in a complex pattern, partly because of the
fact that they are extremely resonant devices. This leads to variations in acoustic pressure and acoustic intensity over the treated
region, resulting in “hot-spots,” which can cause over-heating and even damage
to the tissue. Without carrying out the complicated and time-consuming process
of mapping the acoustic field, it is very difficult to know precisely where the
acoustic energy is going.
NPL scientists have devised an answer to this hurdle by
developing a simple tool to help visualize the distribution and intensity of
the acoustic energy. The approach works by using crystals that are
thermochromic (in that they lose their color when heated up above a specific
trigger temperature). Importantly, the effect is reversible; the crystals
regain their original color on cooling.
The tool consists of two-layers; the bottom layer comprises
of the thermochromic crystals encapsulated in a polyurethane rubber matrix, which absorbs sound. The top layer is colorless and is
employed to capture the heat within the tile. The tile heat generated by the
acoustic energy is quickly and evenly trapped, and the crystals turn
white as they reach the trigger temperature. This then produces a pattern on
the tile, which represents the temperature distribution generated by the
treatment head, which in turn relates to the spatial distribution of the acoustic
intensity. The pattern can be clearly visible after only 10 seconds of exposure
to the ultrasound.
Bajram Zeqiri, an NPL science fellow who led the project,
described how you would test an ultrasound treatment head with the tiles. “In
clinical practice the new ‘imager’ tiles would be used in much the same way you
would treat a patient: by applying coupling gel to the treatment head, coupling
it to the tile, switching on for typically 10 seconds, and then removing and
observing the resulting image.”
The tiles can be used to quickly monitor for treatment head
damage, asymmetric beam-patterns (hot-spots), and more simply to validate
whether the devices are actually working at all. The capability to gain comparatively
complicated data from a simple and cost-effective device, in such a short
period of time, should help improve the quality of physiotherapy ultrasound
treatments.
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