Wearable and low-stress ambulatory blood pressure monitoring technology for hypertension diagnosis.

We propose a highly wearable, upper-arm type, oscillometric-based blood pressure monitoring technology with low-stress. The low-stress is realized by new developments in the hardware and software design. In the hardware design, conventional armband; cuff, is almost halved in volume thanks to a flexible plastic core and a liquid bag which enhances the fitness and pressure uniformity over the arm. Reduced air bag volume enables smaller motor pump size and battery leading to a thinner, more compact and more wearable unified device. In the software design, a new prediction algorithm enabled to apply less stress (and less pain) on arm of the patient. Proof-of-concept experiments on volunteers show a high accuracy on both technologies. This paper mainly introduces hardware developments. The system is promising for less-painful and less-stressful 24-hour blood pressure monitoring in hypertension managements and related healthcare solutions.

Intracellular Ca2+ imaging for micropatterned cardiac myocytes.

The patterning of cardiac myocytes on a micron scale ( approximately 5 microm) was achieved by microcontact printing of fibronectin onto a hydrophobically pretreated glass substrate. The patterned cardiac myocytes conjugated with each other by forming a gap junction, as judged from the synchronized Ca(2+) transition over the pattern, and thus simultaneously contracted. The dynamic change of the Ca(2+) concentration within the patterned tissue was analyzed quantitatively during successive contraction and relaxation using a Nipkow-type high-speed confocal microscope.