Abstract
The fabrication of flexible and stretchable electronics is a critical requirement for the successful application of wearable healthcare devices. Although such flexible electronics have been commonly fabricated by microelectromechanical system (MEMS) technologies, they require a specialised equipment for vacuum deposition, photolithography, and wet and dry etching. A photolithography-free simple patterning method using a desktop plotter cutter has been proposed; however, the metal formation and electrode opening still rely on the MEMS technology. To address this issue, we demonstrate a simple, rapid, cost-effective, and a complete microfabrication process for flexible and stretchable sensor platforms encompassing conductor formation and patterning to encapsulate and open sensing windows, which only require an economic plotter cutter and readily available supplies. Despite its simplicity, the proposed process could stably create microscale features of 200 μm wide conductor lines and 1 mm window openings, which are in the useful range for various wearable applications. The feasibility of the simple fabrication of multi-functional sensors for various physiological monitoring applications was successfully demonstrated in electrochemical (glucose), electrical (electrocardiogram), mechanical (strain), and thermal (body temperature) modalities.
Highlights
The fabrication of flexible and stretchable electronics is a critical requirement for the successful application of wearable healthcare devices
The overall patch size was determined by the ECG electrode size (23 × 5 mm2) and spacing (35 mm) optimized for both compactness and signal quality based on literature[28,37,38]
The target substrate is not limited to PDMs, but can be readily transferred onto other soft materials widely used in biomedical applications such as polyethylene terephthalate (PET) and medical dressing as demonstrated in Supplementary Fig. S1
Summary
The fabrication of flexible and stretchable electronics is a critical requirement for the successful application of wearable healthcare devices. One of the successful examples, involves mechanical skin-like substrates integrated with multiple physiological sensors and wireless functionalities[8] Such epidermal electronics and typical state-ofthe-art wearable sensors are commonly fabricated based on standard microelectromechanical system (MEMS) technologies, including vacuum deposition, photolithography, and wet/dry etching. They are effective for a high patterning resolution and potential batch production, several challenges hinder further extension of the benefits of new technologies. Copper foils or copper-clad substrates have been employed for similar processes, for wireless functions[32,33]
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