Cloudtag and imec, the nanoelectronics research center, today presented the first results of their collaboration on accurate frictionless wearable health solutions. Cloudtag Track, a new wearable fitness tracker, that was launched today at CES 2016, combines fitness and health monitoring with design, to pave the way to innovation in fitness wearables as well as in the care, cure and prevention cycle by providing immediate access to accurate medical data and personalized feedback.

Within the framework of their collaboration, imec develops algorithms for CloudTag’s wearable sensor devices that enable accurate monitoring of physiological parameters. At CES 2016, CloudTag has launched the Cloudtag Track, its first wearable multisensor device. The Cloudtag Track stands out among other wearable devices due to its unique combination of high user comfort with unparalleled data quality. The light and ultra-small device integrates imec’s proprietary algorithm that retrieves physiological parameters with an exceptionally high level of accuracy. Imec’s algorithm accurately recognizes activity, measures energy expenditure, heart rate and other physiological data.

Cloudtag Track can be tailored to match different needs and blends reliable technology with frictionless usabilityto improve the user experience and to help increase adoption. Cloudtag Track gives immediate, accurate and personalized feedback on one’s lifestyle, enabling the individual to put unhealthy habits into perspective while persuading lifestyle changes to adopt healthier diet and activity habits.

“Imec and Holst Centre develop ultra-small low-power, high-quality sensors and specialized algorithms that turn data into valuable knowledge, paving the way to next generation wearables that offer medical quality data monitoring in a frictionless way. These sophisticated wearables can support doctors in diagnosis and follow-up of illnesses, and they offer a huge opportunity in illness prevention by serving as a virtual personal coach,” stated Chris Van Hoof, program director of imec’s wearable health program. “Our collaboration with Cloudtag is an exciting example of how imec’s technology can support the industry in realizing the next generation of wearable devices.”

“I am extremely pleased with this collaboration with imec, as I believe this firmly validates the joint work we are doing and the future of our relationship,” commented Amit Ben-Haim, CloudTag CEO. “This is underscored by the results of the collaboration, and in particular, the accuracy of imec’s algorithms to retrieve physiological parameters which provides us with a unique selling point. I look forward to our continued collaboration and to future product development.”

Teams of researchers from the University of Illinois at Urbana-Champaign (UIUC) have demonstrated a biosensor capable of counting the blood cells electrically using only a drop of blood. The blood cell count is among the most ubiquitous diagnostic tests in primary health care. The gold standard routinely used in hospitals and testing laboratories is a hematology analyzer, which is large and expensive equipment, and requires trained technicians and physical sample transportation. It slows turn-around time, limits throughput in hospitals, and limits accessibility in resource-limited settings. Bashir and his team have developed a biosensor to count red blood cell, platelet, and white blood cell counts, and its 3-part differential at the point-of-care while using only 11 microL of blood.

(a) Schematic of the biosensor used for total leukocyte and its differential counts. The inset shows the micro-fabricated coplanar electrodes aligned with the cell counting aperture of cross-section 15 µm x 15 µm. (b) Representative voltage pulses generated as the individual cells pass over the electrodes. (c) The pulse amplitude histogram shows the distinct populations of lymphocytes and granulocytes + monocytes. CREDIT: TECHNOLOGY

The microfluidic device can electrically count the different types of blood cells based on their size and membrane properties. To count leukocyte and its differentials, red blood cells are selectively lysed and the remaining white blood cells were individually counted. The specific cells like neutrophils were counted using multi-frequency analysis, which probe the membrane properties of the cells. However, for red blood cells and platelets, 1 microL of whole blood is diluted with PBS on-chip and the cells are counted electrically. The total time for measurement is under 20 minutes. The report appears in the December 2015 issue of the journal TECHNOLOGY.

“Our biosensor exhibits the potential to improve patient care in a spectrum of settings. One of the compelling is in resource-limited settings where laboratory tests are often inaccessible due to cost, poor prevalence of laboratory facilities, and the difficulty of follow-up upon receiving results that take days to process,” says Professor Rashid Bashir of the University of Illinois at Urbana-Champaign and Principal Investigator on the paper.

There exists a huge potential to translate our biosensor commercially for blood cell counts applications,” says Umer Hassan, Ph.D., the lead author on this paper. “The translation of our technology will result in minimal to no experience requirement for device operation. Even, patients can perform the test at the comfort of their home and share the results with their primary care physicians via electronic means too.” “The technology is scalable and in future, we plan to apply it to many other potential applications in the areas of animal diagnostics, blood transfusion analysis, ER/ICU applications and blood cell counting for chemotherapy management” says Professor Bashir. The clinical trials of the biosensor are done in collaboration with Carle Foundation Hospital, Urbana, IL.

The team from UIUC is working now to further develop a first portable prototype of the cell counter. “The cartridges will be disposable and the size of a credit card. The base unit or the reader will be portable and possibly hand-held. Our technology has the potential to reduce the cost of the test to less than $10 as compared to $100 or more currently charged,” says Umer.

At last week’s IEEE International Electron Devices Meeting 2015, nanoelectronics research center imec, KU Leuven, and Neuro-Electronics Research Flanders (NERF, set up by VIB/KU Leuven and imec) presented a set of silicon neural probes that combine 12 monolithically integrated optrodes using a CMOS compatible process. The probes enable optical stimulation and electronic detection of individual neurons, based on optogenetics techniques. They pave the way to a greater understanding of the brain and towards novel treatments for brain disorders such as Alzheimer’s, schizophrenia, autism, and epilepsy.

The enormous burden that brain disorders pose on affected individuals and health care systems calls for new ways to prevent, treat and cure these diseases. Currently available devices for recording neural activity to study the functioning of the brain typically have a limited number of electrical channels. Additionally, the brain is composed of many genetically and functionally distinct neuron types, and conventional probes cannot disambiguate recorded electrical signals with respect to their source. Imec’s and KU Leuven’s novel neural probes tackle these challenges, set a path towards greater understanding of the brain, and enable novel treatment options for brain disorders.

Imec’s and KU Leuven’s novel probes combine electronics and photonics to perform extremely sensitive measurements. The fully integrated implantable neural microsystems have advanced capabilities to detect, process and interpret neural data at a cellular scale. The systems feature a very high density of electrodes and nanophotonic circuits (optrodes). Such optrodes are used to optically stimulate single neurons using optogenetics, a technology in which neurons are genetically modified to make them light-sensitive and thus susceptible to stimulation through light pulses.

This research is supported by the Agency for Innovation by Science and Technology in Flanders (IWT) through the OptoBrain project.

Probe tip with activated light output