Biocompatible inkjet resistive sensors for biomedical applications

Dionisi, Alessandro; Borghetti, Michela; Sardini, Emilio; Serpelloni, Mauro

doi:10.1109/i2mtc.2014.6861021

Cited by 5 publications

(1 citation statement)

References 14 publications

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“…For direct attachment of the sensor to the skin, it is critical for the printer to be able to print sensors patterns on biocompatible substrates such as Kapton [63][64][65][66]. Biocompatible materials can be used in wearable sensors/systems which can measure physiological signals from respiration rate, heart rate, EEG and body movements etc.…”

Section: Inkjet-printed Strain Sensorsmentioning

confidence: 99%

Strain Sensors in Wearable Devices

Farooq

Sazonov

2015

Smart Sensors, Measurement and Instrumentation

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Abstract. This chapter discusses the use of strain sensors in wearable devices. Strain sensors are used to monitor deformation under applied load. Various techniques for the fabrication of strain sensors are discussed and some example applications are presented. Special focus is placed on textile based and inkjet-printed strain sensors. Textile based strain sensors open new frontiers for wearable systems by integrating sensors into garments which can be used for extended periods of time. Inkjet printing along with conductive inkjet inks provides low cost, efficient, and rapid prototyping solution for implementation of strain sensors in wearable devices. Applications in the area of remote monitoring of physiological signals, vital signs, and human activity are presented.

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Section: Inkjet-printed Strain Sensorsmentioning

confidence: 99%

Strain Sensors in Wearable Devices

Farooq

Sazonov

2015

Smart Sensors, Measurement and Instrumentation

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Fabrication Approaches for Conducting Polymer Devices

Koutsouras

Bihar

Fairfield

et al. 2017

Green Materials for Electronics

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Hybrid Systems-in-Foil

Elsobky

Burghartz

2021

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Hybrid Systems-in-Foil (HySiF) is a concept that extends the potential of conventional More-than-More Systems-in/on-Package (SiPs and SoPs) to the flexible electronics world. In HySiF, an economical implementation of flexible electronic systems is possible by integrating a minimum number of embedded silicon chips and a maximum number of on-foil components. Here, the complementary characteristics of CMOS SoCs and larger area organic and printed electronics are combined in a HySiF-compatible polymeric substrate. Within the HySiF scope, the fabrication process steps and the integration design rules with all the accompanying boundary conditions concerning material compatibility, surface properties, and thermal budget, are defined. This Element serves as an introduction to the HySiF concept. A summary of recent ultra-thin chip fabrication and flexible packaging techniques is provided. Several bendable electronic components are presented demonstrating the benefits of HySiF. Finally, prototypes of flexible wireless sensor systems that adopt the HySiF concept are demonstrated.

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Biocompatible inkjet resistive sensors for biomedical applications

Cited by 5 publications

References 14 publications

Strain Sensors in Wearable Devices

Strain Sensors in Wearable Devices

Fabrication Approaches for Conducting Polymer Devices

Hybrid Systems-in-Foil

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