Nov 182017

NUS Engineering researchers developed a novel microfibre sensor for real-time healthcare monitoring and diagnosis. The sensor can be woven into a glove to monitor heart rate and blood pressure.

Wide-ranging applications include monitoring of vital signs and bandage pressure sensing

A research team from National University of Singapore (NUS) has developed a soft, flexible and stretchable microfibre sensor for real-time healthcare monitoring and diagnosis. The novel sensor is highly sensitive and ultra-thin with a diameter of a strand of human hair. It is also simple and cost-effective to mass produce.

Wearable and flexible technology has gained significant interest in recent years, leading to tremendous progress in soft and wearable sensors. In tandem with this trend, microfluidic devices using conductive liquid metals have been increasingly employed as wearable pressure and strain sensors. However, current devices have various limitations – for instance, they may not fit well on the skin or are uncomfortable to wear.

“Our novel microfibre sensor can hardly be felt on the skin and conforms extremely well to skin curvatures. Despite being soft and tiny, the sensor is highly sensitive and it also has excellent electrical conductivity and mechanical deformability. We have applied the sensor for real-time monitoring of pulse waveform and bandage pressure. The results are very promising,” said Professor Lim Chwee Teck from the Department of Biomedical Engineering at NUS Faculty of Engineering, who is the leader of the research team.

Real-time monitoring of pulse waveform

The smart microfibre sensor developed by the NUS Engineering team comprises a liquid metallic alloy, which serves as the sensing element, encapsulated within a soft silicone microtube. The sensor measures an individual’s pulse waveform in real-time, and the information can be used to determine one’s heart rate, blood pressure and stiffness in blood vessels.

“Currently, doctors will monitor vital signs like heart rate and blood pressure when patients visit clinics. This requires multiple equipment such as heart rate and blood pressure monitors, which are often bulky and may not provide instantaneous feedback. As our sensor functions like a conductive thread, it can be easily woven into a glove which can be worn by doctors to track vital signs of patients in real-time. This approach offers convenience and saves time for healthcare workers, while patients can enjoy greater comfort,” added Prof Lim.

The microfibre sensor could also be beneficial for patients suffering from atherosclerosis, which is the thickening and stiffening of the arteries caused by the accumulation of fatty streaks. Over time, these streaks accumulate into plaques which may completely block off blood flow or break apart, resulting in organ failure or may trigger a heart attack or stroke.

Existing methods of detecting plaque in blood vessels – such as computerised tomography scans and magnetic resonance imaging – would require expensive and bulky equipment. Such tests need to be done in hospitals by trained medical professionals.

As plaque will change the stiffness of the blood vessel and hence the pulse waveform, the novel sensor developed by the NUS Engineering team could be easily used to detect plaque before it accumulates to a size big enough to block or rupture the blood vessel.

Earlier this year, the NUS team published the development of the microfibre sensor and its application for pulse monitoring in scientific journals Proceedings of the National Academy of Sciences (PNAS) and Advanced Materials Technologies, respectively.

Bandage pressure monitoring

Another clinical application of the smart microfibre sensor is for the management of venous ulcers, which are caused by poor blood circulation. They occur when the veins in the legs could not push blood back to the heart as well as they should. As blood pools in the veins, there is increased pressure in the veins, causing progressive skin damage over time.

Compression therapy is a common treatment for venous ulcer. Depending on the severity of the ulcers, bandages with varying amount of pressure have to be applied on the legs of patients for months to even a year. If the bandage is too tight, it could result in tissue damage, but if the bandage is too loose, the healing could be ineffective. Currently, healthcare workers tend to estimate the pressure in the bandage at the point of application, based on training and experience.

As the pressure provided by the bandage could change over time due to movements by the patient, accurate and continuous measurement of the bandage pressure in real-time is therefore important to ensure that healing takes place effectively.

Being ultra-thin and highly flexible, the NUS Engineering team’s microfibre sensor can be easily woven into bandages to monitor the pressure that is being delivered and maintained. This could potentially improve the effectiveness of the treatment and reduce the time required for healing. In future, patients could also track the bandage pressure using an app, and the information could be shared with doctors who could remotely monitor the progress of the treatment.

The team is currently collaborating with the Singapore General Hospital to test the application of the microfibre sensor for bandage pressure monitoring.

Commercialisation and further research

“Our microfibre sensor is highly versatile, and could potentially be used for a wide range of applications, including healthcare monitoring, smart medical prosthetic devices and artificial skins. Uniquely designed to be durable and washable, our novel invention is highly attractive for promising applications in the emerging field of wearable electronics,” said Prof Lim.

The team has filed a patent for its smart microfibre sensor. Researchers are currently refining the sensor design and reducing the size of its accessories to improve the user-friendliness of the device. The NUS team had recently won the Most Innovative Award at the Engineering Medical Innovation Global Competition held in Taipei in September 2017.

While the NUS researchers continue to explore new applications of the microfibre sensor, they are also keen to work with commercial partners to bring their novel sensor to market.

Learn more: NUS researchers develop smart, ultra-thin microfibre sensor for real-time healthcare monitoring and diagnosis


The Latest on: Microfibre sensor
  • Extraordinary gadget gifts for the one-of-a-kinds on your list
    on November 29, 2017 at 11:26 am

    3-inch CMOS sensor producing 12-megapixel images ... with a 20 mm memory foam ear cushion, covered with a perforated microfibre fabric. An adjustable headband is constructed with solid aluminum and covered with leather outside and perforated microfibre ... […]

  • NUS Researchers Develop Smart, Ultra-Thin Microfibre Sensor for Real-Time Healthcare Monitoring and Diagnosis
    on November 15, 2017 at 4:00 pm

    A research team from National University of Singapore (NUS) has developed a soft, flexible and stretchable microfibre sensor for real-time healthcare monitoring and diagnosis. The novel sensor is highly sensitive and ultra-thin with a diameter of a strand ... […]

  • Shaft alignment tool benefits discussed
    on October 12, 2017 at 3:03 pm

    The 565 mm × 343 mm × 127 mm Fluke 830 laser alignment tool comprises a laser sensor, laser prism, a chain-type mounting bracket with 150 mm support posts, a microfibre cleaning cloth, sensor and PC cables, as well as a 64 MB USB drive and cable. […]

  • 10 of the best cases for keeping your new Google Pixel safe and sound
    on October 18, 2016 at 10:11 am

    The inside of the case is finished off with microfibre to keep your phone protected from scratches ... Cutouts for the camera lens and fingerprint sensor keep both easily accessible while also helping protect them from scratches, and the case has been ... […]

  • 8 of the best Google Pixel cases to buy right now
    on October 13, 2016 at 3:00 am

    Here are some of the best Google Pixel cases that will keep your phone intact ... as well as a polycarbonate core, and a soft microfibre interior. Fancy, right? Google has also built a second type of Pixel phone case, which is made from clear material. […]

  • PCR's guide to laptops and accessories
    on April 26, 2014 at 1:16 am

    A 6,400dpi 4G laser sensor is featured, and the mouse supports Razer’s ... Made for gaming on the move, the Kabuto is an ultra-thin gaming mouse mat made of microfibre material and backed with a natural rubber grip base. The 129x280x1.27mm mat can ... […]

  • Apple iPhone 5S with new A7 chip and fingerprint sensor announced
    on September 10, 2013 at 11:53 am

    To complement the iPhone 5S, Apple has designed premium leather cases in six colours with a matching microfibre lining. There are two LED flash units on the back now. The improved 8 megapixel iSight camera has a secondary True Tone flash, which improves ... […]

  • Best DSLR sensor cleaning kit: 6 tested
    on May 26, 2012 at 2:00 am

    These Photographic Solutions Sensor Swabs come in a variety of sizes to suit different sensors, with 17mm swabs being ideal for Canon APS-C format DSLRs. The lint-free microfibre fabric is bonded to the swab handle, so it can't slip off during cleaning ... […]

  • Road gear round-up: Look Keo Power pedals, Polar G5 GPS Sensor
    on November 28, 2011 at 4:00 pm

    Also from Polar is this G5 GPS sensor which straps to your arm during training ... is DMT's premier road shoe. It has a microfibre upper, dial closure and carbon sole, and weighs in at 646g a pair. These shoes are available now from UK distributors ... […]

via Google News and Bing News

Other Interesting Posts

Leave a Reply

%d bloggers like this: