Abstract
A highly flexible, stretchable, and mechanically robust low-cost soft composite consisting of silicone polymers and water (or hydrogels) is reported. When combined with conventional acoustic transducers, the materials reported enable high performance real-time monitoring of heart and respiratory patterns over layers of clothing (or furry skin of animals) without the need for direct contact with the skin. The approach enables an entirely new method of fabrication that involves encapsulation of water and hydrogels with silicones and exploits the ability of sound waves to travel through the body. The system proposed outperforms commercial, metal-based stethoscopes for the auscultation of the heart when worn over clothing and is less susceptible to motion artefacts. The system both with human and furry animal subjects (i.e., dogs), primarily focusing on monitoring the heart, is tested; however, initial results on monitoring breathing are also presented. This work is especially important because it is the first demonstration of a stretchable sensor that is suitable for use with furry animals and does not require shaving of the animal for data acquisition.
Highlights
A highly flexible, stretchable, and mechanically robust low-cost soft comsolutions.[4]
The approach enables an entirely new method of fabrication that involves encapsulation of water and hydrogels with (Opto)electronic sensors integrated into flexible/stretchable materials,[13,14] with a wearable form factor, offer an accurate yet inexpensive method to monitor vital signs of health noninsilicones and exploits the ability of sound waves to travel through the body
The system proposed outperforms commercial, metal-based stethoscopes for the auscultation of the heart when worn over clothing and is less susceptible to motion artefacts
Summary
In this scheme, i) a polylactic acid (PLA)-based polymer mold is 3D printed to cast the bottom-outer layer of the silicone membrane (2 mm in thickness). Ii) The silicone membrane produced is filled with deionized water (or hydrogels) and, iii) uncured silicone is poured directly on top of the water to fully encapsulate it (see Video S1 of the Supporting Information for the production of water–silicone composite transducer) During this process, the silicone introduced naturally spreads itself over the water added inside the bottom-outer silicone membrane (i.e., does not mix) and forms another thinner membrane (20–100 μm) which covers the entire top-surface and is highly stretchable and flexible (Figure S1, Supporting Information). The final system produced can be worn over the chest and conforms to the curvature of the body, allowing acquisition of acoustic signals from the subject
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