ALL PAST & FUTURE EVENTS AS WELL AS MASTERCLASSES WITH A SINGLE ANNUAL PASS
Wearable Sensors & Continuous Vital Signs Monitoring
13-14 October 2021
Virtual Event Platform
About the Event
The agenda will examine the latest developments in medical wearable sensors and continuous vital sign monitoring techniques. You will hear from leading players developing wearable or implantable continuous monitoring devices for neurons, blood pressure, heat rate, respiration, glucose, and beyond. Furthermore you will hear the latest about the progress in data science and AI in making sense of the data generated by wearable sensors. Finally, you will hear from the leading voices worldwide about the latest business and commercialization trends in the field. This event brings together OEMs to interesting start ups to leading academic voices.
The co-located agenda will be announced soon. It will likely include GE Heatlthcare, Siemens, Jabil, Microsoft, Williot, Ypsomed, Neurosoft, ZSK, Myant, DiPulse, Mas Holding, Sony, Trelleborg, Medtronics, Sony, Abbott, imec, Holst, Henkel, DuPont, Quad Industries, Wise SRL, Eastprint, Mekoprint, InnovationLab, Joanneum Research, Liquid Metal, nutromics, IDUN Technologies, Screentec, Loomia, Uni of California, University of Newcastle, Robert Sauvé Research Institute for Occupational Health and Safety, General Silicones Co., Ltd. , etc
Topics Covered
Wearables Sensors & Continuous Vital Signs | Electronic Skin Patches | Brain Computer Interfaces | Neuron Monitoring and Modulation | Invasive and Non-Invasive Continuous Glucose Monitoring | Implantables | Camera + AI based Monitoring | Voice as a Biomarker | Ultrasound | mmWave Radar + AI based Monitoring | Stretchable Electronics | Printed Sensors | E-Textiles | Liquid Metals
Explore our past & upcoming events on this topic
Leading global speakers include:
Full Agenda
The times below is Central European Times (CET).
On the platform the times will automatically be changed to your time zone
Coming Soon
13 October 2021
Nutromics
Continuous Molecular Monitoring (CMM) wearables are the next step in medical wearables after Continuous Glucose Monitoring (CGM) devices
Wednesday
1:10pm
More Details
Robert Batchelor
Head of Biosensors
There is a clinical need for continuous monitoring of vital molecular biomarkers and drug concentrations. However, with the exception of venous oxygen and glucose, these concentrations are currently determined via lab tests. Lab testing costs valuable time, which is relevant for transient biomarkers and critically sick patients. Additionally, lab testing is intermittent at best, and requires infrastructure, reagents, and skilled operators, which aren’t always available in remote locations.
Electrochemical aptamer-based (EAB) sensors, invented and developed by Prof. Kevin Plaxco at the University of California, Santa Barbara, can be adapted for multiple molecular targets, are reagent-free, and work in-vivo, thus enabling on-body wearable devices. Nutromics is integrating the EAB technology into a wearable ‘lab on the skin’ to meet the pressing clinical need of monitoring molecular biomarkers and drugs.
In this presentation I will discuss the EAB sensor technology, how it compares with continuous glucose monitors, the advantages and limitations of the technology, and finally, the potential of Continuous Molecular Monitoring (CMM) wearable devices using EAB sensors.
All, Wearables, Sensors
Continuous Molecular Monitoring (CMM) wearables are the next step in medical wearables after Continuous Glucose Monitoring (CGM) devices
More Details
1:10pm
There is a clinical need for continuous monitoring of vital molecular biomarkers and drug concentrations. However, with the exception of venous oxygen and glucose, these concentrations are currently determined via lab tests. Lab testing costs valuable time, which is relevant for transient biomarkers and critically sick patients. Additionally, lab testing is intermittent at best, and requires infrastructure, reagents, and skilled operators, which aren’t always available in remote locations.
Electrochemical aptamer-based (EAB) sensors, invented and developed by Prof. Kevin Plaxco at the University of California, Santa Barbara, can be adapted for multiple molecular targets, are reagent-free, and work in-vivo, thus enabling on-body wearable devices. Nutromics is integrating the EAB technology into a wearable ‘lab on the skin’ to meet the pressing clinical need of monitoring molecular biomarkers and drugs.
In this presentation I will discuss the EAB sensor technology, how it compares with continuous glucose monitors, the advantages and limitations of the technology, and finally, the potential of Continuous Molecular Monitoring (CMM) wearable devices using EAB sensors.
13 October 2021
Rouast Labs
Camera-based Vital Signs Measurement: From its Origins to the Deep Learning Era
Wednesday
1:10pm
More Details
Philipp Rouast
Researcher
Simple RGB video of the human face gives away physiological information through tiny changes in skin color and motion — imperceptible to the human eye, but measurable by the computer to produce estimates of vital signs such as heart rate and respiration rate. The technology that accomplishes this is know as remote photoplethysmography (rPPG), highlighting its major advantage of not requiring physical contact between subject and sensor.
First proposed in 2008, rPPG has yet to be widely commercialized. This is in part due to the difficulty in obtaining reliable measurements in challenging real-world conditions, especially regarding illumination conditions and subject movement. This talk will (i) introduce the basis for the signals obtained with camera sensors, (ii) walk through the technological improvements made by researchers since 2008, and (iii) summarize current issues and give an outlook on future applications.
All, Wearables, Sensors
Camera-based Vital Signs Measurement: From its Origins to the Deep Learning Era
More Details
1:10pm
Simple RGB video of the human face gives away physiological information through tiny changes in skin color and motion — imperceptible to the human eye, but measurable by the computer to produce estimates of vital signs such as heart rate and respiration rate. The technology that accomplishes this is know as remote photoplethysmography (rPPG), highlighting its major advantage of not requiring physical contact between subject and sensor.
First proposed in 2008, rPPG has yet to be widely commercialized. This is in part due to the difficulty in obtaining reliable measurements in challenging real-world conditions, especially regarding illumination conditions and subject movement. This talk will (i) introduce the basis for the signals obtained with camera sensors, (ii) walk through the technological improvements made by researchers since 2008, and (iii) summarize current issues and give an outlook on future applications.
13 October 2021
Atcor
Medical Reliable Cardiovascular Health Monitoring Using New Wearable Technology
Wednesday
1:33pm
More Details
Ahmad Qasem
Chief Science & Research Officer
Current wearable sensor technologies provide limited and less reliable health parameters based mainly on heart rate measurement. Any reliable cardiovascular health assessment requires blood pressure measurements. Many attempts had been made to provide blood pressure measurements using commercially available wearable sensors like in smart watches. However, all attempts failed in measuring blood pressure as required by medical standards. On the other hand, FDA cleared Cardiex\AtCor medical technology became the ‘gold standard’ in measuring non-invasively heart and arterial pressure parameters reflecting cardiac and arterial health.
The challenge is to adapt such medical technology into the wearable sensor devices. This involves examining different and new sensors. It also involve new methods of sensor signals based on cardiovascular physiology to extract clinically significant central arterial pressure parameters. This presentation will review current health wearable technologies, challenges in providing reliable cardiovascular health assessment, and Cardiex current development of medical wearable devices to provide clinical heart and arterial health assessments.
All, Wearables, Sensors
Medical Reliable Cardiovascular Health Monitoring Using New Wearable Technology
More Details
1:33pm
Current wearable sensor technologies provide limited and less reliable health parameters based mainly on heart rate measurement. Any reliable cardiovascular health assessment requires blood pressure measurements. Many attempts had been made to provide blood pressure measurements using commercially available wearable sensors like in smart watches. However, all attempts failed in measuring blood pressure as required by medical standards. On the other hand, FDA cleared Cardiex\AtCor medical technology became the ‘gold standard’ in measuring non-invasively heart and arterial pressure parameters reflecting cardiac and arterial health.
The challenge is to adapt such medical technology into the wearable sensor devices. This involves examining different and new sensors. It also involve new methods of sensor signals based on cardiovascular physiology to extract clinically significant central arterial pressure parameters. This presentation will review current health wearable technologies, challenges in providing reliable cardiovascular health assessment, and Cardiex current development of medical wearable devices to provide clinical heart and arterial health assessments.
13 October 2021
Karl Mayer Stoll R&D
TEXTILE-CIRCUIT - Warp knitted solutions for E-Textiles
Wednesday
1:33pm
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Sophia Krinner
New Business Development
This talk will illustrate possibilities for the field of e-textiles by warp knitted products.
Already today highly functional products in the fields of active & sportswear, lingerie, outerwear, automotive and agricultural fabrics are based on warp knitted materials.
During this highly productive production process fabrics can be functionalized, therefore warp knitted fabrics will enrich the chances of e-textiles and change the market.
In this presentation you will see different functional systems done by this technology including a coil for inductive charging and a sensor shirt to detect vital parameters.
All, Wearables, Sensors, eTextile
TEXTILE-CIRCUIT - Warp knitted solutions for E-Textiles
More Details
1:33pm
This talk will illustrate possibilities for the field of e-textiles by warp knitted products.
Already today highly functional products in the fields of active & sportswear, lingerie, outerwear, automotive and agricultural fabrics are based on warp knitted materials.
During this highly productive production process fabrics can be functionalized, therefore warp knitted fabrics will enrich the chances of e-textiles and change the market.
In this presentation you will see different functional systems done by this technology including a coil for inductive charging and a sensor shirt to detect vital parameters.
13 October 2021
FeetMe
Smart Insoles for Clinical Research : a Problem-Solving Approach to Deliver Value with Continuous Mobility Assessment
Wednesday
1:56pm
More Details
false
Alexis Mathieu
Co-Founder & CEO
Bringing a drug to market is long and difficult. Studies estimate that the clinical trial process lasts 9 years and costs $1.3B on average. Clinical trials are conducted in multiple phases, with cost and complexity increasing from Phase I to Phase III. Despite the time and capital invested in trials, only 1 in 10 drugs that enter Phase I of a clinical trial will be approved by the FDA.
There is Large medical need to evaluate to treat the physical deterioration of physical status. A growing number of patients with mobility impairments lacks accurate tools to diagnose, monitor expensive evolutive diseases and intervene efficiently.
Gait is the simplest and most actionable biomarker to monitor multiple diseases but vastly underutilized as a biomarker or outcome measure because gait analysis is often not high quality when assessed in the clinic.Clinical gait tests, today, are used to identify mobility disorders, measure the efficacy of a therapeutic treatment. This is done in a controlled setting at sites. However, the technologies or design used present strong limitations. Episodic assessments, sometimes observational, don't generate sufficient sensitive data to demonstrate subtle changes.
The FeetMe solution allows the collection of validated gait data at site with the Insoles, and in the same accurate way in the patients daily life allowing continuous recording of gait data.
All, Wearables, Sensors, eTextile
Smart Insoles for Clinical Research : a Problem-Solving Approach to Deliver Value with Continuous Mobility Assessment
More Details
1:56pm
Bringing a drug to market is long and difficult. Studies estimate that the clinical trial process lasts 9 years and costs $1.3B on average. Clinical trials are conducted in multiple phases, with cost and complexity increasing from Phase I to Phase III. Despite the time and capital invested in trials, only 1 in 10 drugs that enter Phase I of a clinical trial will be approved by the FDA.
There is Large medical need to evaluate to treat the physical deterioration of physical status. A growing number of patients with mobility impairments lacks accurate tools to diagnose, monitor expensive evolutive diseases and intervene efficiently.
Gait is the simplest and most actionable biomarker to monitor multiple diseases but vastly underutilized as a biomarker or outcome measure because gait analysis is often not high quality when assessed in the clinic.Clinical gait tests, today, are used to identify mobility disorders, measure the efficacy of a therapeutic treatment. This is done in a controlled setting at sites. However, the technologies or design used present strong limitations. Episodic assessments, sometimes observational, don't generate sufficient sensitive data to demonstrate subtle changes.
The FeetMe solution allows the collection of validated gait data at site with the Insoles, and in the same accurate way in the patients daily life allowing continuous recording of gait data.
13 October 2021
Sony
Improving trust for connected devices in remote monitoring, with security-by-design technology
Wednesday
1:56pm
More Details
Anders Strömberg
Head of Wearable Platform
In this talk, Anders Strömberg, Director, Head of Wearable Platform Division, Sony Network Communications Europe, will discuss the issue of trust in IoT devices for remote monitoring, the challenges and some possible solutions.
Care providers need to monitor the wellbeing of their patients. That means staying connected with them wherever they are, whatever they’re doing. Most of today’s remote monitoring applications require pairing with cell phones or smartwatches, using standard LTE connectivity.
Healthcare providers are continuously seeking to increase the quantity and quality of information available, and to offer end-users more practical, timely insights. How can they do this while also providing solutions that are as easy for all kinds of end-users to handle?
The answer lies in the convergence of new IoT, telecommunications and AI technologies which enable access to rich data and allow service providers to develop new solutions; solutions that, for example, improve adherence to prescriptions, enable early detection of conditions like diabetes and boost the users’ general health and wellbeing.
Both service providers and end users show a high level of acceptance and willingness to adopt these new technologies in the pursuit of better health and health services. However, there are some serious trust issues when it comes to IoT. Although the risks are not new, concerns have risen to a new level because of the vast number of IoT devices deployed in the field and the way in which they are being used.
Against this backdrop, Strömberg will discuss the balancing act required to bring trust and quality of service together to enable the future of healthcare and put forward some ideas about how to provide access to more, better and diverse data that enables greater insights and tailored services.
All, Wearables, Sensors
Improving trust for connected devices in remote monitoring, with security-by-design technology
More Details
1:56pm
In this talk, Anders Strömberg, Director, Head of Wearable Platform Division, Sony Network Communications Europe, will discuss the issue of trust in IoT devices for remote monitoring, the challenges and some possible solutions.
Care providers need to monitor the wellbeing of their patients. That means staying connected with them wherever they are, whatever they’re doing. Most of today’s remote monitoring applications require pairing with cell phones or smartwatches, using standard LTE connectivity.
Healthcare providers are continuously seeking to increase the quantity and quality of information available, and to offer end-users more practical, timely insights. How can they do this while also providing solutions that are as easy for all kinds of end-users to handle?
The answer lies in the convergence of new IoT, telecommunications and AI technologies which enable access to rich data and allow service providers to develop new solutions; solutions that, for example, improve adherence to prescriptions, enable early detection of conditions like diabetes and boost the users’ general health and wellbeing.
Both service providers and end users show a high level of acceptance and willingness to adopt these new technologies in the pursuit of better health and health services. However, there are some serious trust issues when it comes to IoT. Although the risks are not new, concerns have risen to a new level because of the vast number of IoT devices deployed in the field and the way in which they are being used.
Against this backdrop, Strömberg will discuss the balancing act required to bring trust and quality of service together to enable the future of healthcare and put forward some ideas about how to provide access to more, better and diverse data that enables greater insights and tailored services.
13 October 2021
DuPont Microcircuit Materials
Facilitating Wellness throughout the Human Life Cycle through Next Generation Wearables and Sensors
Wednesday
2.19pm
More Details
true
Russell Anderson
Technical Specialist
Ensuring health and wellness is crucial for quality of life and longevity. Join us in a discussion how wearable technology and sensors are being created to monitor and report health throughout the human life cycle. Facilitating the human story of health and wellness from womb to late adulthood.
All, Wearables, Sensors, eTextile, Stretchable Electronics
Facilitating Wellness throughout the Human Life Cycle through Next Generation Wearables and Sensors
More Details
2.19pm
13 October 2021
Holst Centre
Facilitating Wellness throughout the Human Life Cycle through Next Generation Wearables and Sensors
Wednesday
2:19pm
More Details
true
Ashok Sridhar
Technologist
Ensuring health and wellness is crucial for quality of life and longevity. Join us in a discussion how wearable technology and sensors are being created to monitor and report health throughout the human life cycle. Facilitating the human story of health and wellness from womb to late adulthood.
All, Wearables, Sensors, eTextile, Stretchable Electronics
Facilitating Wellness throughout the Human Life Cycle through Next Generation Wearables and Sensors
More Details
2:19pm
13 October 2021
Break
Exclusive Networking Break in Lounge
Wednesday
2:42pm
More Details
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
Exclusive Networking Break in Lounge
More Details
2:42pm
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
13 October 2021
Roche Diabetes Care Inc.
Innovative solutions for better diabetes care: Trends, hopes and realities
Wednesday
3:05pm
More Details
Horst Merkle
Director in the Chief Technology Office
Accurate measurement of actual blood glucose levels is the base for effective diabetes management. This presentation will provide a snap-shot of the latest trends in glucose testing including continuous glucose monitoring (CGM) and emerging non-invasive methodologies that receive a lot of attention. We will also talk about the role of artificial intelligence (AI) and machine learning (ML) in this context, their potential but also some of the realities associated with AI/ML. Last but not least we will discuss how freely available data generated by all these innovative solutions creates value and evaluate the status of interoperability in diabetes care.
All, Sensors, Wearables, Biosensors
Innovative solutions for better diabetes care: Trends, hopes and realities
More Details
3:05pm
Accurate measurement of actual blood glucose levels is the base for effective diabetes management. This presentation will provide a snap-shot of the latest trends in glucose testing including continuous glucose monitoring (CGM) and emerging non-invasive methodologies that receive a lot of attention. We will also talk about the role of artificial intelligence (AI) and machine learning (ML) in this context, their potential but also some of the realities associated with AI/ML. Last but not least we will discuss how freely available data generated by all these innovative solutions creates value and evaluate the status of interoperability in diabetes care.
13 October 2021
Accensors
Smart Health Patch 2.0 -
Enabling the next generation of multifunctional medical skin patches with printed electronics (joint talk)
Wednesday
3:28pm
More Details
true
Eike Kottkamp
CEO
Smart Healthcare demands smart medical devices.
Wearable skin patches allow for comprehensive patient monitoring at medical grade accuracy, improving patient care to become more individualized and connected. Printed Electronics technology is a key enabler to smart health patches - allowing the creation of thin, flexible and lightweight sensing components and full solutions that increase the comfort of wear while allowing long-term vital sight monitoring.
Throughout this presentation Henkel Printed Electronics and Accensors will showcase latest printed electronic materials and sensing technologies to shape the next generation of smart health patches.
All, Printed Electronics, Sensors, Wearables
Smart Health Patch 2.0 -
Enabling the next generation of multifunctional medical skin patches with printed electronics (joint talk)
More Details
3:28pm
Smart Healthcare demands smart medical devices.
Wearable skin patches allow for comprehensive patient monitoring at medical grade accuracy, improving patient care to become more individualized and connected. Printed Electronics technology is a key enabler to smart health patches - allowing the creation of thin, flexible and lightweight sensing components and full solutions that increase the comfort of wear while allowing long-term vital sight monitoring.
Throughout this presentation Henkel Printed Electronics and Accensors will showcase latest printed electronic materials and sensing technologies to shape the next generation of smart health patches.
13 October 2021
Henkel AG & Co. KGaA
Smart Health Patch 2.0 -
Enabling the next generation of multifunctional medical skin patches with printed electronics (joint talk)
Wednesday
3:28pm
More Details
true
Stijn Gillissen
Global Head of Printed Electronics
Smart Healthcare demands smart medical devices.
Wearable skin patches allow for comprehensive patient monitoring at medical grade accuracy, improving patient care to become more individualized and connected. Printed Electronics technology is a key enabler to smart health patches - allowing the creation of thin, flexible and lightweight sensing components and full solutions that increase the comfort of wear while allowing long-term vital sight monitoring.
Throughout this presentation Henkel Printed Electronics and Accensors will showcase latest printed electronic materials and sensing technologies to shape the next generation of smart health patches.
All, Printed Electronics, Sensors, Wearables
Smart Health Patch 2.0 -
Enabling the next generation of multifunctional medical skin patches with printed electronics (joint talk)
More Details
3:28pm
Smart Healthcare demands smart medical devices.
Wearable skin patches allow for comprehensive patient monitoring at medical grade accuracy, improving patient care to become more individualized and connected. Printed Electronics technology is a key enabler to smart health patches - allowing the creation of thin, flexible and lightweight sensing components and full solutions that increase the comfort of wear while allowing long-term vital sight monitoring.
Throughout this presentation Henkel Printed Electronics and Accensors will showcase latest printed electronic materials and sensing technologies to shape the next generation of smart health patches.
13 October 2021
Neteera
Remote Contactless Vital Sign Monitoring Using Sub-THz Radar & Advanced Algorithms
Wednesday
3:51pm
More Details
Shimon Steinberger
CTO
Neteera has designed and developed a contactless vital-signs monitoring product capable of detecting a variety of physiological parameters (Hear Rate, Hear Rate Variability, Respiration Rate, Respiration Depth, Inhale/Exhale ratio, Sleep Apnea, etc.), based on an on-chip sub-THz (116-123 GHz) micro-radar and advanced signal processing and AI algorithms. The Vital Sign parameters are monitored continuously and presented in real time on a monitor and/or stored in the cloud for offline analysis. The Product is targeted to both Remote Patient Monitoring (RPM) at home, Elderly care monitoring, Chronic diseases patients, relevant Hospital wards, etc.
Neteera’s novel micro radar-based solution enables measuring only the micro-motions of the skin (BCG-Ballistocardiograph) remotely, in real-time, non-invasive, and non-contact manner, through non-metallic materials such as furniture and clothing at a high resolution.
Neteera 130H product is based on the following key elements:
1. High-frequency (116-123 GHz), micro-radar on chip (with an on-package antenna).
2. Vital sign monitor algorithms, based on proprietary signal processing algorithms, that are designed to track the relevant vital signs metrics.
3. Cloud Cluster for data collection (including raw, processed, reference) and analysis.
All, Wearables, Sensors
Remote Contactless Vital Sign Monitoring Using Sub-THz Radar & Advanced Algorithms
More Details
3:51pm
Neteera has designed and developed a contactless vital-signs monitoring product capable of detecting a variety of physiological parameters (Hear Rate, Hear Rate Variability, Respiration Rate, Respiration Depth, Inhale/Exhale ratio, Sleep Apnea, etc.), based on an on-chip sub-THz (116-123 GHz) micro-radar and advanced signal processing and AI algorithms. The Vital Sign parameters are monitored continuously and presented in real time on a monitor and/or stored in the cloud for offline analysis. The Product is targeted to both Remote Patient Monitoring (RPM) at home, Elderly care monitoring, Chronic diseases patients, relevant Hospital wards, etc.
Neteera’s novel micro radar-based solution enables measuring only the micro-motions of the skin (BCG-Ballistocardiograph) remotely, in real-time, non-invasive, and non-contact manner, through non-metallic materials such as furniture and clothing at a high resolution.
Neteera 130H product is based on the following key elements:
1. High-frequency (116-123 GHz), micro-radar on chip (with an on-package antenna).
2. Vital sign monitor algorithms, based on proprietary signal processing algorithms, that are designed to track the relevant vital signs metrics.
3. Cloud Cluster for data collection (including raw, processed, reference) and analysis.
13 October 2021
Quad Ind
Printed Electronics - a technology platform enabling wearable health solutions
Wednesday
4:14pm
More Details
Arne Casteleyn
Managing Director
This presentation will provide insights in how Quad Industries uses printed electronics as a platform technology to create wearable sensors and skin patches.
Printed circuit foils have been used for many years inside, amongst others, membrane switches and capacitive touch sensors, but one of the biggest opportunities in the field of printed electronics, lies in newly emerging applications, such as wearable health.
Quad Industries is a leading innovator in this field, and by means of S2S and R2R screen-printing techniques, the company integrates smart functionality on a wide range of materials, such as flexible and stretchable films.
This presentation highlights some of the recent developments in the development and manufacturing of electronic skin patches.
All, Printed Electronics, Sensors, Wearables, Human Machine Interface
Printed Electronics - a technology platform enabling wearable health solutions
More Details
4:14pm
This presentation will provide insights in how Quad Industries uses printed electronics as a platform technology to create wearable sensors and skin patches.
Printed circuit foils have been used for many years inside, amongst others, membrane switches and capacitive touch sensors, but one of the biggest opportunities in the field of printed electronics, lies in newly emerging applications, such as wearable health.
Quad Industries is a leading innovator in this field, and by means of S2S and R2R screen-printing techniques, the company integrates smart functionality on a wide range of materials, such as flexible and stretchable films.
This presentation highlights some of the recent developments in the development and manufacturing of electronic skin patches.
13 October 2021
Break
Exclusive Networking Break in Lounge
Wednesday
4:37pm
More Details
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
Exclusive Networking Break in Lounge
More Details
4:37pm
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
13 October 2021
Eastprint
Mass Producing Wearable Biosensors: Success Stories and Case Studies
Wednesday
5:00pm
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Mass Producing Wearable Biosensors: Success Stories and Case Studies
More Details
5:00pm
13 October 2021
Jabil
How to Specify Your E-Textile Product
Wednesday
5:23pm
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Salwa Rasheed
Designer Engineer
The market share of the e-textile industry has seen an upward trend over the years. Rising awareness and the limitless possibilities to utilize the comfort and flexibility of textiles, combined with the intelligence of electronics has led to tremendous opportunities in the development and manufacture of e-textile and wearable products across various industry segments. The pandemic times have called for and accelerated the need for remote monitoring and opened new vistas of opportunities. With more investment by existing and emerging players in the research and development of such products, it is imperative for businesses to understand and clearly specify the e-textile product requirements. Each product being so unique in nature and function, makes it more critical to address their requirements in a comprehensive manner. This presentation will cover the key aspects to consider while specifying an e-textile product.
Stretchable Electronics, All, eTextile, Human Machine Interface
How to Specify Your E-Textile Product
More Details
5:23pm
The market share of the e-textile industry has seen an upward trend over the years. Rising awareness and the limitless possibilities to utilize the comfort and flexibility of textiles, combined with the intelligence of electronics has led to tremendous opportunities in the development and manufacture of e-textile and wearable products across various industry segments. The pandemic times have called for and accelerated the need for remote monitoring and opened new vistas of opportunities. With more investment by existing and emerging players in the research and development of such products, it is imperative for businesses to understand and clearly specify the e-textile product requirements. Each product being so unique in nature and function, makes it more critical to address their requirements in a comprehensive manner. This presentation will cover the key aspects to consider while specifying an e-textile product.
13 October 2021
Neurosoft Bioelectronics
Soft Implantable Electrodes to Interface with the Brain
Wednesday
5:23pm
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Ludovic Serex
COO & Co-Founder
Neural implants aim at restoring lost or impaired functions of the nervous system by electrical stimulation or recording of the brain. Current neural implants suffer from a mechanical mismatch compared to the soft host tissue, as they constrain mechanically the physiological motion of the central nervous system. This mismatch causes poor electrode-tissue contact, leading to unspecific stimulation or recording, as well as chronic scarring. At Neurosoft Bioelectronics, we overcome these fundamental limitations by developing soft neural electrodes, using more compliant materials, that seamlessly interface with the brain, promoting the long-term bio-integration of the devices and reducing surgical risks.
All, Wearables, Sensors, Stretchable Electronics, Human Machine Interface
Soft Implantable Electrodes to Interface with the Brain
More Details
5:23pm
Neural implants aim at restoring lost or impaired functions of the nervous system by electrical stimulation or recording of the brain. Current neural implants suffer from a mechanical mismatch compared to the soft host tissue, as they constrain mechanically the physiological motion of the central nervous system. This mismatch causes poor electrode-tissue contact, leading to unspecific stimulation or recording, as well as chronic scarring. At Neurosoft Bioelectronics, we overcome these fundamental limitations by developing soft neural electrodes, using more compliant materials, that seamlessly interface with the brain, promoting the long-term bio-integration of the devices and reducing surgical risks.
13 October 2021
Liquid Wire
Manufacturing Stretchable Sensors and Electronics for Wearability in On-body Medical Devices
Wednesday
5:46pm
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Manufacturing Stretchable Sensors and Electronics for Wearability in On-body Medical Devices
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5:46pm
13 October 2021
ZSK TECHNICAL EMBROIDERY SYSTEMS
Embroidered E-Textiles – Embroidery as your Technology for Prototyping and Mass Production
Wednesday
6:09pm
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Melanie Hoerr
Manager of Technical Embroidery Applications & Smart Textiles
Melanie’s presentation gives an overview of conductive yarn embroidery and its applications for E-Textiles. Applications such as textile electrodes, touch, capacity, and proximity sensors, conductive paths, and pads will be presented as well as the electrical connection of LED sequins and the ZSK-E-Tex-Board on a ZSK embroidery machine. The electrical connections between electronic parts and textiles are automatically stitched by the embroidery machine.
Due to the high level of automatization of the embroidery technology, it can be used for the mass production of E-Textiles but already during the early stage of the development of prototypes.
All, Wearables, Stretchable Electronics, eTextile
Embroidered E-Textiles – Embroidery as your Technology for Prototyping and Mass Production
More Details
6:09pm
Melanie’s presentation gives an overview of conductive yarn embroidery and its applications for E-Textiles. Applications such as textile electrodes, touch, capacity, and proximity sensors, conductive paths, and pads will be presented as well as the electrical connection of LED sequins and the ZSK-E-Tex-Board on a ZSK embroidery machine. The electrical connections between electronic parts and textiles are automatically stitched by the embroidery machine.
Due to the high level of automatization of the embroidery technology, it can be used for the mass production of E-Textiles but already during the early stage of the development of prototypes.
13 October 2021
Break
Exclusive Networking Break in Lounge
Wednesday
6:32pm
More Details
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
Exclusive Networking Break in Lounge
More Details
6:32pm
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
13 October 2021
IDUN Technologies
Ubiquitous Brain Computer Interfaces Based on Ear EEG Electrodes
Wednesday
6:55pm
More Details
Mark Melnykowycz
Product/Application Lead
Brain computer interface (BCI) designs have traditionally focused on the use of electrodes located on the scalp of a person to measure their brain activity using Electroencephalography (EEG) brain imaging techniques. Scalp EEG traditionally utilized metal electrodes placed over the scalp with conductive gel between the electrode and the skin to improve electrical contact. Dry contact electrodes were then developed to make the process more user-friendly and to reduce the time to setup EEG systems before conducting experiments. This made EEG more accessible outside of research and medical laboratories and led to the release of BCI products onto the consumer market. Despite the recent advances in invasive BCI’s based on implants, dry electrode EEG offers a greater ability to develop EEG products for daily use. One of the most important product challenges to over-come is the design of BCI’s which fit into existing societal trends. Scalp-focused BCI designs are difficult to scale beyond niche user communities since they represent another device for users to integrate into their lives. Ear EEG offers a way to design BCI products that integrate into users’ lives similar to the way that earbuds have seen wide adoption across different cultures and markets throughout the world.
IDUN Technologies has developed electrodes for biopotential measurements since 2017. The IDUN Guardian Development Kit BCI relies on ear EEG electrodes in an earbud form-factor to facilitate the research of ear EEG for applications from sleep and wellness to acoustic attention. The IDUN ear EEG electrodes are based on a conductive polymer formed into traditional earbud shapes. The combination of electrical conductivity and mechanical deformability allow the electrodes to provide secure contact to the surface of the ear canal resulting in good signal quality for EEG measurements. Performance of the system has been evaluated with electrical impedance as well as EEG paradigm measurements. The mean in-ear skin-contact impedances of the ear electrodes tested in humans at 10 Hz ranged from 11 kΩ to 190 kΩ with a mean of 75 kΩ for cleaned and of 110 kΩ for uncleaned ears. EEG paradigm validation has been conducted included Acoustic Steady State Response (ASSR), Alpha excitation and sleep features includes slow waves and spindles.
All, Wearables, Sensors
Ubiquitous Brain Computer Interfaces Based on Ear EEG Electrodes
More Details
6:55pm
Brain computer interface (BCI) designs have traditionally focused on the use of electrodes located on the scalp of a person to measure their brain activity using Electroencephalography (EEG) brain imaging techniques. Scalp EEG traditionally utilized metal electrodes placed over the scalp with conductive gel between the electrode and the skin to improve electrical contact. Dry contact electrodes were then developed to make the process more user-friendly and to reduce the time to setup EEG systems before conducting experiments. This made EEG more accessible outside of research and medical laboratories and led to the release of BCI products onto the consumer market. Despite the recent advances in invasive BCI’s based on implants, dry electrode EEG offers a greater ability to develop EEG products for daily use. One of the most important product challenges to over-come is the design of BCI’s which fit into existing societal trends. Scalp-focused BCI designs are difficult to scale beyond niche user communities since they represent another device for users to integrate into their lives. Ear EEG offers a way to design BCI products that integrate into users’ lives similar to the way that earbuds have seen wide adoption across different cultures and markets throughout the world.
IDUN Technologies has developed electrodes for biopotential measurements since 2017. The IDUN Guardian Development Kit BCI relies on ear EEG electrodes in an earbud form-factor to facilitate the research of ear EEG for applications from sleep and wellness to acoustic attention. The IDUN ear EEG electrodes are based on a conductive polymer formed into traditional earbud shapes. The combination of electrical conductivity and mechanical deformability allow the electrodes to provide secure contact to the surface of the ear canal resulting in good signal quality for EEG measurements. Performance of the system has been evaluated with electrical impedance as well as EEG paradigm measurements. The mean in-ear skin-contact impedances of the ear electrodes tested in humans at 10 Hz ranged from 11 kΩ to 190 kΩ with a mean of 75 kΩ for cleaned and of 110 kΩ for uncleaned ears. EEG paradigm validation has been conducted included Acoustic Steady State Response (ASSR), Alpha excitation and sleep features includes slow waves and spindles.
13 October 2021
NMES Group
Smart wearables and the closed loop system. A new approach to biofeedback based performance training (joint talk)
Wednesday
6:55pm
More Details
true
Victoria Sparkes
Managing Director, Medical Business Unit
The smart wearables industry has expanded with many companies committed to generating data acquired from external factors (altitude, speed, goniometry) and more recently, internal measurements such as temperature, blood oxygen and the constituents of human sweat. Data is analyzed in accordance with human performance – monitoring the execution of elite sports activities, or assessing normal function for those otherwise restricted, and it’s here that the majority of wearables, reach their functional limits. The ability to affect change within the individual human body, through a smart wearable device, and in response to data generated is not yet a fully commercialized offer.
What if the future of smart wearables is equally focused on affect as well as effect? If the data generated from motion, thermal or heart rate sensors can trigger an instantaneous change within the body? NMES Group began its journey in neuromuscular electrical stimulation, offering a wholly innovative system to deliver electrical current through the skin to produce muscle contractions. The subsequent development of unique stimulation programs for a multitude of sport, fitness, occupational health and medical uses was a natural progression. However, pioneering innovation in stimulation programs has enabled NMES Group to think outside of the box, and revolutionize the technology through enhanced haptics in gaming and military applications – and this is just the beginning. The next phase lies firmly in a closed loop system – the intelligent application of muscle stimulation in response to real-time data generated through smart sensors, providing a platform for multiple diverse industry applications.
All, Wearables, Stretchable Electronics, eTextile
Smart wearables and the closed loop system. A new approach to biofeedback based performance training (joint talk)
More Details
6:55pm
The smart wearables industry has expanded with many companies committed to generating data acquired from external factors (altitude, speed, goniometry) and more recently, internal measurements such as temperature, blood oxygen and the constituents of human sweat. Data is analyzed in accordance with human performance – monitoring the execution of elite sports activities, or assessing normal function for those otherwise restricted, and it’s here that the majority of wearables, reach their functional limits. The ability to affect change within the individual human body, through a smart wearable device, and in response to data generated is not yet a fully commercialized offer.
What if the future of smart wearables is equally focused on affect as well as effect? If the data generated from motion, thermal or heart rate sensors can trigger an instantaneous change within the body? NMES Group began its journey in neuromuscular electrical stimulation, offering a wholly innovative system to deliver electrical current through the skin to produce muscle contractions. The subsequent development of unique stimulation programs for a multitude of sport, fitness, occupational health and medical uses was a natural progression. However, pioneering innovation in stimulation programs has enabled NMES Group to think outside of the box, and revolutionize the technology through enhanced haptics in gaming and military applications – and this is just the beginning. The next phase lies firmly in a closed loop system – the intelligent application of muscle stimulation in response to real-time data generated through smart sensors, providing a platform for multiple diverse industry applications.
13 October 2021
NMES Group
Smart wearables and the closed loop system. A new approach to biofeedback based performance training (joint talk)
Wednesday
6:55pm
More Details
true
Vincent Tellenbach
CTO
The smart wearables industry has expanded with many companies committed to generating data acquired from external factors (altitude, speed, goniometry) and more recently, internal measurements such as temperature, blood oxygen and the constituents of human sweat. Data is analyzed in accordance with human performance – monitoring the execution of elite sports activities, or assessing normal function for those otherwise restricted, and it’s here that the majority of wearables, reach their functional limits. The ability to affect change within the individual human body, through a smart wearable device, and in response to data generated is not yet a fully commercialized offer.
What if the future of smart wearables is equally focused on affect as well as effect? If the data generated from motion, thermal or heart rate sensors can trigger an instantaneous change within the body? NMES Group began its journey in neuromuscular electrical stimulation, offering a wholly innovative system to deliver electrical current through the skin to produce muscle contractions. The subsequent development of unique stimulation programs for a multitude of sport, fitness, occupational health and medical uses was a natural progression. However, pioneering innovation in stimulation programs has enabled NMES Group to think outside of the box, and revolutionize the technology through enhanced haptics in gaming and military applications – and this is just the beginning. The next phase lies firmly in a closed loop system – the intelligent application of muscle stimulation in response to real-time data generated through smart sensors, providing a platform for multiple diverse industry applications.
All, Wearables, Sensors, eTextile
Smart wearables and the closed loop system. A new approach to biofeedback based performance training (joint talk)
More Details
6:55pm
The smart wearables industry has expanded with many companies committed to generating data acquired from external factors (altitude, speed, goniometry) and more recently, internal measurements such as temperature, blood oxygen and the constituents of human sweat. Data is analyzed in accordance with human performance – monitoring the execution of elite sports activities, or assessing normal function for those otherwise restricted, and it’s here that the majority of wearables, reach their functional limits. The ability to affect change within the individual human body, through a smart wearable device, and in response to data generated is not yet a fully commercialized offer.
What if the future of smart wearables is equally focused on affect as well as effect? If the data generated from motion, thermal or heart rate sensors can trigger an instantaneous change within the body? NMES Group began its journey in neuromuscular electrical stimulation, offering a wholly innovative system to deliver electrical current through the skin to produce muscle contractions. The subsequent development of unique stimulation programs for a multitude of sport, fitness, occupational health and medical uses was a natural progression. However, pioneering innovation in stimulation programs has enabled NMES Group to think outside of the box, and revolutionize the technology through enhanced haptics in gaming and military applications – and this is just the beginning. The next phase lies firmly in a closed loop system – the intelligent application of muscle stimulation in response to real-time data generated through smart sensors, providing a platform for multiple diverse industry applications.
13 October 2021
Microsoft
A Vision for the Future of Wearables: Smart Textiles, New Sensing Techniques, and Key Application Areas
Wednesday
7:18pm
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Teddy Seyed
Senior Researcher
The most profound technologies are those that disappear. They weave themselves into the fabric of everyday life until they are indistinguishable from it." Mark Weiser's seminal work in Ubiquitous Computing captures a key goal of the smart textile space: to become a part of our everyday clothing (among other objects), thus transforming them into wearables. In this talk, I describe how we are pushing towards our vision for a Future of Wearables, how we are enabling it through the creation of smart fabrics and new sensing techniques that use machine learning, as well as application areas of interest.
All, Sensors, Printed Electronics, eTextile
A Vision for the Future of Wearables: Smart Textiles, New Sensing Techniques, and Key Application Areas
More Details
7:18pm
The most profound technologies are those that disappear. They weave themselves into the fabric of everyday life until they are indistinguishable from it." Mark Weiser's seminal work in Ubiquitous Computing captures a key goal of the smart textile space: to become a part of our everyday clothing (among other objects), thus transforming them into wearables. In this talk, I describe how we are pushing towards our vision for a Future of Wearables, how we are enabling it through the creation of smart fabrics and new sensing techniques that use machine learning, as well as application areas of interest.
13 October 2021
VieLight
Photobiomodulation in Wearable Brain Stimulation
Wednesday
7:18pm
More Details
false
Lew Lim
Founder & CEO
The brain can be guided to perform better when it receives light of certain parameters in a process called Photobiomodulation (PBM). This is often done through light emitting or laser diodes. Today, this process is delivered through portable devices. Literature has shown PBM to be promising in the treatment of Alzheimer’s disease, Parkinson’s disease, traumatic brain injury and other neurological conditions, some of which are being tested with major clinical trials.
Dr Lew Lim and his team at Vielight conducts cutting-edge research in brain PBM and are also involved in several of the major clinical trials. The team also seeks new ways for the technology to improve the cognition of normal people, sports performance as well as even achieve bliss states in meditation.
In his presentation, Dr Lim will discuss foundational understanding of PBM. He will also show how one can improve one’s life by applying PBM in wearable devices for brain stimulation.
All, Wearables, Sensors
Photobiomodulation in Wearable Brain Stimulation
More Details
7:18pm
The brain can be guided to perform better when it receives light of certain parameters in a process called Photobiomodulation (PBM). This is often done through light emitting or laser diodes. Today, this process is delivered through portable devices. Literature has shown PBM to be promising in the treatment of Alzheimer’s disease, Parkinson’s disease, traumatic brain injury and other neurological conditions, some of which are being tested with major clinical trials.
Dr Lew Lim and his team at Vielight conducts cutting-edge research in brain PBM and are also involved in several of the major clinical trials. The team also seeks new ways for the technology to improve the cognition of normal people, sports performance as well as even achieve bliss states in meditation.
In his presentation, Dr Lim will discuss foundational understanding of PBM. He will also show how one can improve one’s life by applying PBM in wearable devices for brain stimulation.
13 October 2021
University of California San Diego
Soft Ultrasonic Technologies for Continuous Monitoring of Deep Tissues
Wednesday
7:41pm
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Sheng Xu
Assistant Professor
Soft wearable devices that can noninvasively and continuously acquire physiological signals from the human body represent an important trend for healthcare. Existing soft devices can monitor various signals from the human body, but those signals are limited to either the surface or very shallow (< 8 mm) below the skin. There are a lot more activities in deep tissues that have a stronger and faster correlation with the diseases and symptoms of the human body. In this presentation, I will demonstrate a wearable ultrasonic technology that allows noninvasively and continuously monitoring events 14 cm below the skin surface. Continuous blood pressure waveforms and blood flow spectra in central arteries and veins, and dynamic motions of heart chamber walls are exemplary use cases of the soft ultrasonic technology. This enabling platform effectively adds a new third-dimension to the detection range of existing wearable devices, and thus holds profound implications for a wide range of applications in consumer electronics, defense medicine, and clinical practices.
All, Wearables, Sensors, eTextile
Soft Ultrasonic Technologies for Continuous Monitoring of Deep Tissues
More Details
7:41pm
Soft wearable devices that can noninvasively and continuously acquire physiological signals from the human body represent an important trend for healthcare. Existing soft devices can monitor various signals from the human body, but those signals are limited to either the surface or very shallow (< 8 mm) below the skin. There are a lot more activities in deep tissues that have a stronger and faster correlation with the diseases and symptoms of the human body. In this presentation, I will demonstrate a wearable ultrasonic technology that allows noninvasively and continuously monitoring events 14 cm below the skin surface. Continuous blood pressure waveforms and blood flow spectra in central arteries and veins, and dynamic motions of heart chamber walls are exemplary use cases of the soft ultrasonic technology. This enabling platform effectively adds a new third-dimension to the detection range of existing wearable devices, and thus holds profound implications for a wide range of applications in consumer electronics, defense medicine, and clinical practices.
13 October 2021
Sonde Health
Inevitability of Voice as a Biomarker
Wednesday
8:04pm
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Anya Gupta
VP Business Development
Leveraging over 1 million voice samples from 80,000+ individuals, Sonde Health’s proprietary voice-based technology platform detects changes in user health - like mental fitness and respiratory disease - from changes in voice. Using advanced audio signal processing and machine learning, Sonde senses and analyzes subtle vocal changes due to changes in a person’s physiology to provide early health detection and monitoring. Sonde One, its health screening app, helps large organizations to execute a daily population screening regimen that helps reduce the spread of COVID-19, comply with government mandates, and return to work safely. Sonde has also leveraged its SurveyLex platform to enable rapid voice data collection for large clinical research organizations like UCB Pharma, Biogen, Massachusetts General Hospital, Beth Israel Deaconess Medical Center, Pear Therapeutics etc. and thereafter also enable voice-based health-detection models. Anya Gupta, Sonde's VP of Business Development, will describe the process Sonde has used since inception to develop their vocal biomarker platform.
All, Wearables, Sensors
Inevitability of Voice as a Biomarker
More Details
8:04pm
Leveraging over 1 million voice samples from 80,000+ individuals, Sonde Health’s proprietary voice-based technology platform detects changes in user health - like mental fitness and respiratory disease - from changes in voice. Using advanced audio signal processing and machine learning, Sonde senses and analyzes subtle vocal changes due to changes in a person’s physiology to provide early health detection and monitoring. Sonde One, its health screening app, helps large organizations to execute a daily population screening regimen that helps reduce the spread of COVID-19, comply with government mandates, and return to work safely. Sonde has also leveraged its SurveyLex platform to enable rapid voice data collection for large clinical research organizations like UCB Pharma, Biogen, Massachusetts General Hospital, Beth Israel Deaconess Medical Center, Pear Therapeutics etc. and thereafter also enable voice-based health-detection models. Anya Gupta, Sonde's VP of Business Development, will describe the process Sonde has used since inception to develop their vocal biomarker platform.
13 October 2021
WISE Srl
Stretchable Conductors Based on SCBI Technology on Silicones for Implantable Medical Devices
Wednesday
8.04pm
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Sandro Ferrari
Director of Operations
Soft conductive materials give significant advantages in neuro-electronic interfaces since they are able to comply and closely adhere to the soft neural tissues. Nevertheless not only is far from trivial to make soft conductive materials with appropriate performances, but it is a further challenge to interface them with hard electronic devices on one side and to achieve the required compliance to use in implantable medical devices on the other. Wise over the last decade managed to travel this route and to reach the market with its neuromonitoring devices based on the proprietary SCBI technology. The milestones of this journey and the opportunities opened by the technology will be presented.
All, Wearables, Strechable Sensors, Sensors, AR/VR, eTextile, Stretchable Electronics
Stretchable Conductors Based on SCBI Technology on Silicones for Implantable Medical Devices
More Details
8.04pm
Soft conductive materials give significant advantages in neuro-electronic interfaces since they are able to comply and closely adhere to the soft neural tissues. Nevertheless not only is far from trivial to make soft conductive materials with appropriate performances, but it is a further challenge to interface them with hard electronic devices on one side and to achieve the required compliance to use in implantable medical devices on the other. Wise over the last decade managed to travel this route and to reach the market with its neuromonitoring devices based on the proprietary SCBI technology. The milestones of this journey and the opportunities opened by the technology will be presented.
13 October 2021
Moderncraft by MAS
Cultivating Change while Enhancing the Necessary and Creating the Unexpected with Textile Technologies
Wednesday
8:27pm
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true
Cultivating Change while Enhancing the Necessary and Creating the Unexpected with Textile Technologies
More Details
8:27pm
13 October 2021
Moderncraft by MAS
Cultivating Change while Enhancing the Necessary and Creating the Unexpected with Textile Technologies
Wednesday
8:27pm
More Details
true
Praneeth Weerasekara
Program Manager
Patented ingenuity and science enable Moderncraft by MAS -Firefly illumination intelligence and Phoenix active heating technology to be embedded directly into fabric.
Firefly is a next-‐to-‐skin, washable, visibility solution on the market for any low-‐light or late-night conditions. The technology has been tested for visibility up to 450 feet.
With a breakthrough in fabric-based heating technology proven to be both durable and flexible - Phoenix is the most advanced active heating technology on the market, giving wearers full control of their personal micro-climate without added, bulky layers.
Both technologies offer not just design freedom to be creative, but also an innovative solution with the ability to manufacture affordably and quickly through a globally integrated supply chain.
All, Wearables, Sensors, Strechable Sensors, Stretchable Electronics, eTextile
Cultivating Change while Enhancing the Necessary and Creating the Unexpected with Textile Technologies
More Details
8:27pm
Patented ingenuity and science enable Moderncraft by MAS -Firefly illumination intelligence and Phoenix active heating technology to be embedded directly into fabric.
Firefly is a next-‐to-‐skin, washable, visibility solution on the market for any low-‐light or late-night conditions. The technology has been tested for visibility up to 450 feet.
With a breakthrough in fabric-based heating technology proven to be both durable and flexible - Phoenix is the most advanced active heating technology on the market, giving wearers full control of their personal micro-climate without added, bulky layers.
Both technologies offer not just design freedom to be creative, but also an innovative solution with the ability to manufacture affordably and quickly through a globally integrated supply chain.
13 October 2021
Nanoleq
Soft and Stretchable Electronics for Integration with Textiles
Wednesday
8:27pm
More Details
Niclas Granqvist
CTO
Nanoleq is a spinoff of the university of Zurich founded in 2017 focusing on stretchable and soft electronics integrated into textiles (smart textiles, e-textiles). The sensing technology is based on dry electrodes developed by ETH, Zurich, and Nanoleq that are sticky/adhesive (Electroskin (TM)) to reduce motion artifacts. Current generation of dry electrodes used in commercial heart rate sensor has a strap that needs to be firmly attached and you feel squeeze. The technology supports use cases from multiple verticals such as sport & fitness, wellness, rehabilitation, workwear and medical. Customers have integrated 2-20 electrodes. A high electrode count allows studying the heart vector in unprecedented detail. The soft electrodes are very suitable for children. I would like to present a few typical signal traces.
Elastic conductive tape (Phantomtape) connected to the electrodes and runs to the Phantomlink bridge that forms the interface between the textile and attached electronics. The PhantomLink connector solution is compatible with analogue and digital signals in e-textiles for ECG, EMG, EEG or for electrostimulation The Nanoleq solution is unique because not only has Nanoleq developed the technology but also the associated testing protocols for validation which is equally important.
I will discuss the integration of the components and how to make a shirt. As a last step I will elaborate over the design of analogue electronics outlining a complete hardware stack.
All, Wearables, Stretchable Electronics, Sensors
Soft and Stretchable Electronics for Integration with Textiles
More Details
8:27pm
Nanoleq is a spinoff of the university of Zurich founded in 2017 focusing on stretchable and soft electronics integrated into textiles (smart textiles, e-textiles). The sensing technology is based on dry electrodes developed by ETH, Zurich, and Nanoleq that are sticky/adhesive (Electroskin (TM)) to reduce motion artifacts. Current generation of dry electrodes used in commercial heart rate sensor has a strap that needs to be firmly attached and you feel squeeze. The technology supports use cases from multiple verticals such as sport & fitness, wellness, rehabilitation, workwear and medical. Customers have integrated 2-20 electrodes. A high electrode count allows studying the heart vector in unprecedented detail. The soft electrodes are very suitable for children. I would like to present a few typical signal traces.
Elastic conductive tape (Phantomtape) connected to the electrodes and runs to the Phantomlink bridge that forms the interface between the textile and attached electronics. The PhantomLink connector solution is compatible with analogue and digital signals in e-textiles for ECG, EMG, EEG or for electrostimulation The Nanoleq solution is unique because not only has Nanoleq developed the technology but also the associated testing protocols for validation which is equally important.
I will discuss the integration of the components and how to make a shirt. As a last step I will elaborate over the design of analogue electronics outlining a complete hardware stack.
13 October 2021
Panasonic Electronic Materials
The Development of a Unique High Temperature Substrate for Stretchable Printed Electronics.
Wednesday
8:50pm
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Takatoshi Abe
Technology Development Manager
Conventional electronic assembly processes like SMT reflow require high temperature resistant materials. However, conventional pliable and stretchable polymer films like thermoplastic polyurethane (TPU) normally used for printed and flexible hybrid electronics exhibit poor temperature resistance creating challenges in the printing and curing of functional materials like conductive pastes, surface mount assembly and end-use durability.
The technology development center of Panasonic Electronics Materials in Osaka, Japan has been developing materials for FHE/PE applications specifically to address these challenges. Through various experiments and use-case devices, we have demonstrated that these new stretchable materials have the durability and heat resistance to be compatible with traditional SMT assembly processes. This presentation will explain the substrate technology in detail and introduce some use-case demonstration parts made using these materials.
All, Sensors, Printed Electronics, Stretchable Electronics
The Development of a Unique High Temperature Substrate for Stretchable Printed Electronics.
More Details
8:50pm
Conventional electronic assembly processes like SMT reflow require high temperature resistant materials. However, conventional pliable and stretchable polymer films like thermoplastic polyurethane (TPU) normally used for printed and flexible hybrid electronics exhibit poor temperature resistance creating challenges in the printing and curing of functional materials like conductive pastes, surface mount assembly and end-use durability.
The technology development center of Panasonic Electronics Materials in Osaka, Japan has been developing materials for FHE/PE applications specifically to address these challenges. Through various experiments and use-case devices, we have demonstrated that these new stretchable materials have the durability and heat resistance to be compatible with traditional SMT assembly processes. This presentation will explain the substrate technology in detail and introduce some use-case demonstration parts made using these materials.
14 October 2021
Forciot Oy
Hands on Detection (HOD) functionality for Advanced Driver Assistance Systems (ADAS) enabled by stretchable electronics
Thursday
1:10pm
More Details
true
Pekka Iso-Ketola
Engineering Director, Stretchable Electronics, Co-Founder
The automotive industry is changing extremely fast, and there are opportunities that the stretchable electronics brings to address the challenges that the automotive industry is facing today and in the future.
In this presentation, Forciot and Gentherm, will elaborate on how they see stretchable electronics revolutionizing the automotive interior business and solutions by explaining the benefits from the steering wheel Hands on Detection (HOD) solution perspective.
Forciot’s advanced sensor technology can be integrated into vehicle interiors. With Gentherm, Forciot is cooperating on a solution relating to steering wheel HOD functionality for Advanced Driver Assistance Systems (ADAS).
All, Printed Electronics, Sensors, Wearables
Hands on Detection (HOD) functionality for Advanced Driver Assistance Systems (ADAS) enabled by stretchable electronics
More Details
1:10pm
The automotive industry is changing extremely fast, and there are opportunities that the stretchable electronics brings to address the challenges that the automotive industry is facing today and in the future.
In this presentation, Forciot and Gentherm, will elaborate on how they see stretchable electronics revolutionizing the automotive interior business and solutions by explaining the benefits from the steering wheel Hands on Detection (HOD) solution perspective.
Forciot’s advanced sensor technology can be integrated into vehicle interiors. With Gentherm, Forciot is cooperating on a solution relating to steering wheel HOD functionality for Advanced Driver Assistance Systems (ADAS).
14 October 2021
Gentherm
Hands on Detection (HOD) functionality for Advanced Driver Assistance Systems (ADAS) enabled by stretchable electronics
Thursday
1.10pm
More Details
true
Dusko Petrovski
Director Electronics Product Development
The automotive industry is changing extremely fast, and there are opportunities that the stretchable electronics brings to address the challenges that the automotive industry is facing today and in the future.
In this presentation, Forciot and Gentherm, will elaborate on how they see stretchable electronics revolutionizing the automotive interior business and solutions by explaining the benefits from the steering wheel Hands on Detection (HOD) solution perspective.
Forciot’s advanced sensor technology can be integrated into vehicle interiors. With Gentherm, Forciot is cooperating on a solution relating to steering wheel HOD functionality for Advanced Driver Assistance Systems (ADAS).
All, Sensors, Printed Electronics, Wearables
Hands on Detection (HOD) functionality for Advanced Driver Assistance Systems (ADAS) enabled by stretchable electronics
More Details
1.10pm
The automotive industry is changing extremely fast, and there are opportunities that the stretchable electronics brings to address the challenges that the automotive industry is facing today and in the future.
In this presentation, Forciot and Gentherm, will elaborate on how they see stretchable electronics revolutionizing the automotive interior business and solutions by explaining the benefits from the steering wheel Hands on Detection (HOD) solution perspective.
Forciot’s advanced sensor technology can be integrated into vehicle interiors. With Gentherm, Forciot is cooperating on a solution relating to steering wheel HOD functionality for Advanced Driver Assistance Systems (ADAS).
14 October 2021
Joanneum Research
Economical, Customizable & Simple - Printed Piezos For Wearables & Vital Parameter Monitoring
Thursday
1:33pm
More Details
Jonas Groten
Research
The measurement of physiological signals using skin attached sensors have raised a lot of interest in the recent years. The printing of electronics on stretchable patch substrates in combination with low power wireless data transmission allows the continuous recording of medical data in everyday environments and thus represents a significant improvement for patient monitoring compared to medical laboratories or hospitals. A successful realization of such skin patches depends on many factors such as wearing comfort, reliability of the stretchable electronics and sensors, low power consumption as well as sensitivity and selectivity of the applied sensor materials. In this presentation, the possibilities of the printable piezoelectric polymer P(VDF-TrFE) for recording various physiological parameters (respiratory rate, pulse, blood pressure) are presented. I will show that the piezoelectric materials can also be used for energy self-sufficient monitoring thanks to piezoelectric energy harvesting. In addition, the realization of sensors and energy harvesters on ultrathin substrates and the development of a low-cost and reliable stretchable silver ink further improves the wearing comfort and commercial attractiveness of the presented sensor patches.
All, Printed Electronics, Sensors
Economical, Customizable & Simple - Printed Piezos For Wearables & Vital Parameter Monitoring
More Details
1:33pm
The measurement of physiological signals using skin attached sensors have raised a lot of interest in the recent years. The printing of electronics on stretchable patch substrates in combination with low power wireless data transmission allows the continuous recording of medical data in everyday environments and thus represents a significant improvement for patient monitoring compared to medical laboratories or hospitals. A successful realization of such skin patches depends on many factors such as wearing comfort, reliability of the stretchable electronics and sensors, low power consumption as well as sensitivity and selectivity of the applied sensor materials. In this presentation, the possibilities of the printable piezoelectric polymer P(VDF-TrFE) for recording various physiological parameters (respiratory rate, pulse, blood pressure) are presented. I will show that the piezoelectric materials can also be used for energy self-sufficient monitoring thanks to piezoelectric energy harvesting. In addition, the realization of sensors and energy harvesters on ultrathin substrates and the development of a low-cost and reliable stretchable silver ink further improves the wearing comfort and commercial attractiveness of the presented sensor patches.
14 October 2021
InnovationLab GmbH
R2R Printed Sensors Enabling Automated Stock Replenishment. (Joint Talk)
Thursday
1:56pm
More Details
true
Florian Ullrich
Business Development
Printed electronics is a promising emerging technology for various applications in wearables, medtech, automotive and logistics. However, even though the possibility to print sensors and sensor systems is well know for more than a decade, products based on printed components only slowly find their way into mass market. One main hurdle is a reliable high-volume production and the possibility of a smooth transition from prototyping over upscaling to industrial production.
With its shareholders SAP, BASF and Heidelberger Druckmaschinen AG, InnovationLab is able to bridge this gap and to provide a One-Stop Shop for Printed Electronics while even going beyond hard- and software production by providing AI and IoT services as well. In this talk, the Lab-2-Fab concept is explained and several examples for printed electronic applications will be highlighted.
One of the applications is an automated stock replenishment system based on printed pressure sensor foils. The case study is an IoT solution developed by Trelleborg Sealing Solutions for their customers.
All, Sensors, Printed Electronics
R2R Printed Sensors Enabling Automated Stock Replenishment. (Joint Talk)
More Details
1:56pm
Printed electronics is a promising emerging technology for various applications in wearables, medtech, automotive and logistics. However, even though the possibility to print sensors and sensor systems is well know for more than a decade, products based on printed components only slowly find their way into mass market. One main hurdle is a reliable high-volume production and the possibility of a smooth transition from prototyping over upscaling to industrial production.
With its shareholders SAP, BASF and Heidelberger Druckmaschinen AG, InnovationLab is able to bridge this gap and to provide a One-Stop Shop for Printed Electronics while even going beyond hard- and software production by providing AI and IoT services as well. In this talk, the Lab-2-Fab concept is explained and several examples for printed electronic applications will be highlighted.
One of the applications is an automated stock replenishment system based on printed pressure sensor foils. The case study is an IoT solution developed by Trelleborg Sealing Solutions for their customers.
14 October 2021
Trelleborg Sealing Solutions
R2R Printed Sensors Enabling Automated Stock Replenishment.(Joint Talk)
Thursday
1:56pm
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true
Domenico Tucci
Team Lead IoT Client Solutions
Printed electronics is a promising emerging technology for various applications in wearables, medtech, automotive and logistics. However, even though the possibility to print sensors and sensor systems is well know for more than a decade, products based on printed components only slowly find their way into mass market. One main hurdle is a reliable high-volume production and the possibility of a smooth transition from prototyping over upscaling to industrial production.
With its shareholders SAP, BASF and Heidelberger Druckmaschinen AG, InnovationLab is able to bridge this gap and to provide a One-Stop Shop for Printed Electronics while even going beyond hard- and software production by providing AI and IoT services as well. In this talk, the Lab-2-Fab concept is explained and several examples for printed electronic applications will be highlighted.
One of the applications is an automated stock replenishment system based on printed pressure sensor foils. The case study is an IoT solution developed by Trelleborg Sealing Solutions for their customers.
All, Sensors, Printed Electronics
R2R Printed Sensors Enabling Automated Stock Replenishment.(Joint Talk)
More Details
1:56pm
Printed electronics is a promising emerging technology for various applications in wearables, medtech, automotive and logistics. However, even though the possibility to print sensors and sensor systems is well know for more than a decade, products based on printed components only slowly find their way into mass market. One main hurdle is a reliable high-volume production and the possibility of a smooth transition from prototyping over upscaling to industrial production.
With its shareholders SAP, BASF and Heidelberger Druckmaschinen AG, InnovationLab is able to bridge this gap and to provide a One-Stop Shop for Printed Electronics while even going beyond hard- and software production by providing AI and IoT services as well. In this talk, the Lab-2-Fab concept is explained and several examples for printed electronic applications will be highlighted.
One of the applications is an automated stock replenishment system based on printed pressure sensor foils. The case study is an IoT solution developed by Trelleborg Sealing Solutions for their customers.
14 October 2021
RISE
Screen Printed Sensors on Flexible Substrates for use in Everyday Applications
Thursday
2:19pm
More Details
Kathrin Hübscher
Development Engineer
With the advance of digitalisation, the constant digital monitoring of our surroundings is becoming increasingly important. Complex sensor and feedback systems are required to meet the demand for increased interaction with the world around us. Especially in the field of personalised healthcare and well-being, the need for flexible or even stretchable devices is a major challenge.
At RISE AB in Norrköping, we are experts in screen printing and integration of electronic components. We design and develop sensors that can detect everything from temperature, pressure, touch, strain, corrosion to electrical signals. Screen printing allows the use of a wide range of printing materials as well as flexible and stretchable substrates. This talk will give an insight into the possibilities of flexible sensors produced by screen printing at RISE and their applications.
All, Printed Electronics, Sensors
Screen Printed Sensors on Flexible Substrates for use in Everyday Applications
More Details
2:19pm
With the advance of digitalisation, the constant digital monitoring of our surroundings is becoming increasingly important. Complex sensor and feedback systems are required to meet the demand for increased interaction with the world around us. Especially in the field of personalised healthcare and well-being, the need for flexible or even stretchable devices is a major challenge.
At RISE AB in Norrköping, we are experts in screen printing and integration of electronic components. We design and develop sensors that can detect everything from temperature, pressure, touch, strain, corrosion to electrical signals. Screen printing allows the use of a wide range of printing materials as well as flexible and stretchable substrates. This talk will give an insight into the possibilities of flexible sensors produced by screen printing at RISE and their applications.
14 October 2021
Break
Exclusive Networking Break in Lounge
Thursday
2:42pm
More Details
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
Exclusive Networking Break in Lounge
More Details
2:42pm
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
14 October 2021
ScreenTec
Custom Disposable Medical Electrodes: fast Prototyping and Efficient Upscaling (joint talk)
Thursday
3:05pm
More Details
true
Roelof Aalpoel
Sales
The development and production of a disposable sensor can be a time consuming and difficult process. Indeed, the cradle-to-market timeline for any medical device can be long and arduous, due to regulations, standards and gathering evidence.
When embarking on such a journey, it is important to be well prepared, to know where potential pitfalls lie and to waste as little time and resources along the way. Whilst certain steps cannot be rushed, such as gathering clinical evidence, it is certainly possible to optimise other areas.
Design and production are some of the key areas where time and resources can be saved. Rapid prototyping and testing, as well as prototyping with mass production in mind, can save time as well as money.
In this talk we will be highlighting some of the key areas of how pitfalls can be avoided, as well as how to make the eventual mass production more efficient
All, Printed Electronics, Sensors, Wearables, Wearable
Custom Disposable Medical Electrodes: fast Prototyping and Efficient Upscaling (joint talk)
More Details
3:05pm
The development and production of a disposable sensor can be a time consuming and difficult process. Indeed, the cradle-to-market timeline for any medical device can be long and arduous, due to regulations, standards and gathering evidence.
When embarking on such a journey, it is important to be well prepared, to know where potential pitfalls lie and to waste as little time and resources along the way. Whilst certain steps cannot be rushed, such as gathering clinical evidence, it is certainly possible to optimise other areas.
Design and production are some of the key areas where time and resources can be saved. Rapid prototyping and testing, as well as prototyping with mass production in mind, can save time as well as money.
In this talk we will be highlighting some of the key areas of how pitfalls can be avoided, as well as how to make the eventual mass production more efficient
14 October 2021
Suunto OY
Custom Disposable Medical Electrodes: fast Prototyping and Efficient Upscaling (joint talk)
Thursday
3:05pm
More Details
true
Terho Lahtinen
Senior Manager, Future Concepts
The development and production of a disposable sensor can be a time consuming and difficult process. Indeed, the cradle-to-market timeline for any medical device can be long and arduous, due to regulations, standards and gathering evidence.
When embarking on such a journey, it is important to be well prepared, to know where potential pitfalls lie and to waste as little time and resources along the way. Whilst certain steps cannot be rushed, such as gathering clinical evidence, it is certainly possible to optimise other areas.
Design and production are some of the key areas where time and resources can be saved. Rapid prototyping and testing, as well as prototyping with mass production in mind, can save time as well as money.
In this talk we will be highlighting some of the key areas of how pitfalls can be avoided, as well as how to make the eventual mass production more efficient
All, Printed Electronics, Sensors
Custom Disposable Medical Electrodes: fast Prototyping and Efficient Upscaling (joint talk)
More Details
3:05pm
The development and production of a disposable sensor can be a time consuming and difficult process. Indeed, the cradle-to-market timeline for any medical device can be long and arduous, due to regulations, standards and gathering evidence.
When embarking on such a journey, it is important to be well prepared, to know where potential pitfalls lie and to waste as little time and resources along the way. Whilst certain steps cannot be rushed, such as gathering clinical evidence, it is certainly possible to optimise other areas.
Design and production are some of the key areas where time and resources can be saved. Rapid prototyping and testing, as well as prototyping with mass production in mind, can save time as well as money.
In this talk we will be highlighting some of the key areas of how pitfalls can be avoided, as well as how to make the eventual mass production more efficient
14 October 2021
Hamamatsu
Trust in your Laser-Sintering Process – with Active Laser Power Adjustment and Real-Time Temperature Monitoring
Thursday
3:28pm
More Details
Alexander Goerk
Senior Sales Engineer
Finding and especially keeping the right recipe for your thermal laser process (e.g. for manufacturing of printed RFID antennas or printed circuits) is all about a strong trust in constant material parameters.
The new semiconductor laser T-SMILS® from Hamamatsu Photonics offers the possibility to achieve a highly efficient and reliable laser sintering process for metal nano inks through real-time temperature monitoring and active laser power adjustment.
All, Sensors, Printed Electronics
Trust in your Laser-Sintering Process – with Active Laser Power Adjustment and Real-Time Temperature Monitoring
More Details
3:28pm
Finding and especially keeping the right recipe for your thermal laser process (e.g. for manufacturing of printed RFID antennas or printed circuits) is all about a strong trust in constant material parameters.
The new semiconductor laser T-SMILS® from Hamamatsu Photonics offers the possibility to achieve a highly efficient and reliable laser sintering process for metal nano inks through real-time temperature monitoring and active laser power adjustment.
14 October 2021
ASADA MESH CO., LTD
Understanding Surface Treatments for PET Substrates.
Thursday
3:51pm
More Details
Fernando Zicarelli
Business Manager
This initial study compared Print Resolution, Adhesion and Electrical Resistance of different PET substrate manufacturers. We looked at how each company applies their surface treatment and how it impacts the aforementioned variables.
All, Printed Electronics, Sensors
Understanding Surface Treatments for PET Substrates.
More Details
3:51pm
14 October 2021
Mekoprint
Stretchable Printed Sensors for Digital Health Care Solutions in Mass Production
Thursday
4:14pm
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Tobias Holmgaard Stær
Head of Printed Electronics
Printed stretchable sensors can assist in bringing electronics closer to the body. The sensors are more than just pliable and flexible circuits. They introduce a new dimension to flexibility as the sensors can stretch without losing function and thus can be placed in close proximity to- or directly on the human skin. In a 3-way partnership between Danish incontinence diaper manufacturer ABENA, Silicon Valley based Medisens Wireless, and Mekoprint, the worlds most advanced digital disposable incontinence product has been a made a reality. A disposable product with built-in sensor and a small discrete clip attached. The sensor registers when the product is wet and a notification is send to the caregivers’ smartphones or tablets.
All, Strechable Sensors, Wearables, Sensors
Stretchable Printed Sensors for Digital Health Care Solutions in Mass Production
More Details
4:14pm
Printed stretchable sensors can assist in bringing electronics closer to the body. The sensors are more than just pliable and flexible circuits. They introduce a new dimension to flexibility as the sensors can stretch without losing function and thus can be placed in close proximity to- or directly on the human skin. In a 3-way partnership between Danish incontinence diaper manufacturer ABENA, Silicon Valley based Medisens Wireless, and Mekoprint, the worlds most advanced digital disposable incontinence product has been a made a reality. A disposable product with built-in sensor and a small discrete clip attached. The sensor registers when the product is wet and a notification is send to the caregivers’ smartphones or tablets.
14 October 2021
Break
Exclusive Networking Break in Lounge
Thursday
4:37pm
More Details
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
Exclusive Networking Break in Lounge
More Details
4:37pm
Join us in the Spatial Chat lounge and network with fellow members and speakers. This is the ultimate in-person virtual experience giving you the opportunity not only to see but also chat with colleagues and new business contacts. Previous attendees have said:
"The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling." and
"I really loved networking lounge you have! Never seen anything like it".
Grab and drink and join us, we look forward to meeting you there.
14 October 2021
Ypsomed
Printed/Flexible Electronics for Drug Delivery Devices - Drivers & Tradeoffs
Thursday
5:00pm
More Details
Christoph Berger
Innovation Officer
After a brief overview of the Ypsomed product spectrum, we will explain some of the drivers for the use of electronics and in particular printed / flexible electronics in drug delivery devices. We'll also discuss the tradeoffs that result from partially contradicting requirements around device usability, sustainability, cost, etc.
All, Sensors, Printed Electronics
Printed/Flexible Electronics for Drug Delivery Devices - Drivers & Tradeoffs
More Details
5:00pm
After a brief overview of the Ypsomed product spectrum, we will explain some of the drivers for the use of electronics and in particular printed / flexible electronics in drug delivery devices. We'll also discuss the tradeoffs that result from partially contradicting requirements around device usability, sustainability, cost, etc.
14 October 2021
Ravensburger
Printed Electronics in the Board Game Industry
Thursday
5:23pm
More Details
Clemens Türck
Technical Innovation Manager
Clemens Tuerck from Ravensburger will show past examples of combining paper board games with electronic components. He will talk about recent tries to use printed electronics in new game products and explain why they failed and what hindered Ravensburger to use printed electronics. And finally, Clemens will present which future use cases could be interesting for the toy industry.
All, Printed Electronics, Sensors
Printed Electronics in the Board Game Industry
More Details
5:23pm
Clemens Tuerck from Ravensburger will show past examples of combining paper board games with electronic components. He will talk about recent tries to use printed electronics in new game products and explain why they failed and what hindered Ravensburger to use printed electronics. And finally, Clemens will present which future use cases could be interesting for the toy industry.
14 October 2021
Siemens Healthcare
Perovskites: The Emergence of a New Era for High-Resolving and Ultra-Sensitive Flat Panel X-Ray Detectors
Thursday
6.32pm
More Details
Sandro Francesco Tedde
Key Expert Research Scientist
The fabrication of medical and industrial X-ray imaging detectors that combine minimum fabrication costs and high performances is the major challenge since decades. Due to their strong X-ray absorption, high carrier diffusion lengths and mobility-lifetime (μτ) product hybrid inorganic-organic perovskites like Methylammonium Lead Triiodide (MAPbI3) are highly recommended as novel X-ray converting materials. Here we present a two-step manufacturing process of a microcrystalline MAPbI3 based imaging X-ray detector which decouples the fabrication of the several hundred micrometer thick absorber layer and its integration on the pixelated backplane. Microcrystalline MAPbI3 devices show an excellent sensitivity of 9300 µC/(Gyaircm²) with a μτ-product of 4E-4 cm²/V. The resulting X-ray imaging detector with 640x480 pixels, reveals a high-resolution capability of 6 line-pairs (lp)/mm simultaneous with an outstanding low detection limit of 0.22 nGyair/frame. Our findings stress the great potential of this material class for X-ray detector applications.
All, Printed Electronics, Perovskite, Perovskite, Organic, CIGS and Other Photovoltaics, Perovskite, Organic, CIGS, and Other Photovoltaics, Advanced Materials
Perovskites: The Emergence of a New Era for High-Resolving and Ultra-Sensitive Flat Panel X-Ray Detectors
More Details
6.32pm
The fabrication of medical and industrial X-ray imaging detectors that combine minimum fabrication costs and high performances is the major challenge since decades. Due to their strong X-ray absorption, high carrier diffusion lengths and mobility-lifetime (μτ) product hybrid inorganic-organic perovskites like Methylammonium Lead Triiodide (MAPbI3) are highly recommended as novel X-ray converting materials. Here we present a two-step manufacturing process of a microcrystalline MAPbI3 based imaging X-ray detector which decouples the fabrication of the several hundred micrometer thick absorber layer and its integration on the pixelated backplane. Microcrystalline MAPbI3 devices show an excellent sensitivity of 9300 µC/(Gyaircm²) with a μτ-product of 4E-4 cm²/V. The resulting X-ray imaging detector with 640x480 pixels, reveals a high-resolution capability of 6 line-pairs (lp)/mm simultaneous with an outstanding low detection limit of 0.22 nGyair/frame. Our findings stress the great potential of this material class for X-ray detector applications.
14 October 2021
Wiliot
How to Scale the IoT to Trillions – Sensing as a Service with Sticker Sized Computers
Thursday
7:41pm
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Steve Statler
SVP Marketing
After 4+ years of R&D, working with some of the largest pharma, CPG, retail and logistics companies, Wiliot has leant a lot of lessons about brining intelligence and connectivity to new classes of everyday things. Hear the latest on how the technology behind these self-powered compute devices is evolving, the applications that will be impacted and the implications for the ecosystem of brands and IoT companies that are engaged in this new area.
All, Printed Electronics, Sensors
How to Scale the IoT to Trillions – Sensing as a Service with Sticker Sized Computers
More Details
7:41pm
After 4+ years of R&D, working with some of the largest pharma, CPG, retail and logistics companies, Wiliot has leant a lot of lessons about brining intelligence and connectivity to new classes of everyday things. Hear the latest on how the technology behind these self-powered compute devices is evolving, the applications that will be impacted and the implications for the ecosystem of brands and IoT companies that are engaged in this new area.
14 October 2021
General Silicones
A Sustainable Industrial Solution for High Volume Production of Wearable, e- skin and Smart Surface HMI Automotive Applications.
Thursday
8.04pm
More Details
Anupam Mukherjee
Technical Director
Transition from linear to circular economy is now prevailing in almost every sector including Flexible Hybrid Electronics. Governments and stakeholders are in a continuous endeavour to explore sustainable solutions to support circular economy. Keeping this as utmost importance, General Silicones with its decades of experience, developed a sustainable silicone based novel material as well as circular platform that not only possess excellent chemical and mechanical properties but also removing the drawback of low surface energy of silicone, it can act as innovative sustainable platform to design printed and flexible electronics with unmet possibilities.
Along with high durability, sustainability, bio-compatibility, this wonder material has a range of tuneable properties like color (transparent, translucent, or any), the hardness (25-80 shore A), thickness (customized), tensile strength (30-100 Kgf/cm2), tear strength (10-30 Kgf/cm), and elongation (200-800 %). It can have soft touch and feel, provide different friction levels, and embossments can mimic surface patterns of other materials. Overcoming silicone adhesion, bonding and printing issues, Compo-SiL® offers a sustainable roll to roll industrial solution of printable, flexible, stretchable silicone films for high volume production of wearable, e-skin electronics & HMI automotive applications allowing more functionality and unprecedented freedom in design.
All, Wearables, Sensors, Stretchable Electronics
A Sustainable Industrial Solution for High Volume Production of Wearable, e- skin and Smart Surface HMI Automotive Applications.
More Details
8.04pm
Transition from linear to circular economy is now prevailing in almost every sector including Flexible Hybrid Electronics. Governments and stakeholders are in a continuous endeavour to explore sustainable solutions to support circular economy. Keeping this as utmost importance, General Silicones with its decades of experience, developed a sustainable silicone based novel material as well as circular platform that not only possess excellent chemical and mechanical properties but also removing the drawback of low surface energy of silicone, it can act as innovative sustainable platform to design printed and flexible electronics with unmet possibilities.
Along with high durability, sustainability, bio-compatibility, this wonder material has a range of tuneable properties like color (transparent, translucent, or any), the hardness (25-80 shore A), thickness (customized), tensile strength (30-100 Kgf/cm2), tear strength (10-30 Kgf/cm), and elongation (200-800 %). It can have soft touch and feel, provide different friction levels, and embossments can mimic surface patterns of other materials. Overcoming silicone adhesion, bonding and printing issues, Compo-SiL® offers a sustainable roll to roll industrial solution of printable, flexible, stretchable silicone films for high volume production of wearable, e-skin electronics & HMI automotive applications allowing more functionality and unprecedented freedom in design.
14 October 2021
Robert Sauvé Research Institute for Occupational Health and Safety
Smart Protective Equipment
Thursday
8.04pm
More Details
Alireza Saidi
Professional Researcher
Driven by the constant search for improved workplace safety solutions, smart protective equipment equipped with sensors, actuators and connected technologies has grown considerably in recent years.
Electronic devices integrated into protective equipment offer unprecedented opportunities to better protect the most vulnerable areas of the body during work. Interconnected sensors and actuators react, interact and communicate with the wearer or their supervisors to provide increased safety and comfort. The capabilities of smart protective equipment can help reduce errors, the number and severity of accidents and injuries in the workplace, and therefore promote improved performance, efficiency and productivity.
The information, data and communications collected by smart protective equipment can also identify patterns of risk situations and potential hazards in order to establish better practices and work methods. Through a presentation, we will discuss the different possibilities in terms of smart protective equipment using flexible electronics and electronic textiles.
All, Wearables, Stretchable Electronics, eTextile
Smart Protective Equipment
More Details
8.04pm
Driven by the constant search for improved workplace safety solutions, smart protective equipment equipped with sensors, actuators and connected technologies has grown considerably in recent years.
Electronic devices integrated into protective equipment offer unprecedented opportunities to better protect the most vulnerable areas of the body during work. Interconnected sensors and actuators react, interact and communicate with the wearer or their supervisors to provide increased safety and comfort. The capabilities of smart protective equipment can help reduce errors, the number and severity of accidents and injuries in the workplace, and therefore promote improved performance, efficiency and productivity.
The information, data and communications collected by smart protective equipment can also identify patterns of risk situations and potential hazards in order to establish better practices and work methods. Through a presentation, we will discuss the different possibilities in terms of smart protective equipment using flexible electronics and electronic textiles.
Customer Feedback
This TechBlick virtual platform has huge potential to grow up and have a lot of capabilities to build up a perfect ecosystem surrounding the social and technological innovative trends together with like minded people & organisations under one umbrella.
General Silicones
RKS
Very good. Your virtual conference platform is top notch!
Roche Diabetes Care Inc
Another worthwhile Techblick virtual event: excellent speakers presenting compelling content combined with terrific networking opportunities
Panasonic Electronic Materials
I am really impressed with what you put together. The breakout room works really well, almost better than in real world.
IP Group plc
The networking lounge functionality is fantastic! For me, the best I've seen so far in virtual events, the closest you can get to a real feeling
IMEC
Far the best digital interaction I have experienced. Both during ‘speed dating’ and lounge sessions it was straight forward to connect with people.
Epishine AB
The event was awesome, TechBlick is a great platform.
Applied Materials
I really love the idea of the networking lounge you have! Never seen anything like it
Teledyne
Techblick is the success story in virtual conferencing and we are looking forward to the next event
Coatema
The on-line networking/exhibition session was very similar to off-line networking/exhibition.
LG Electronics
I loved the Techblick online experience. It was really immersive and compared to other digital events it had a real trade show feel
e2ip
One of the best virtual exhibit platforms I have seen so far.
Nano OPS, Inc.
TechBlick made virtual interaction real
Evonik
TechBlick was a fantastic experience! Not only were the speakers excellent and the topics interesting, but also the virtual platform was easy to use and greatly facilitated our networking efforts. We look forward to participating in the next event!"
Brilliant Matters
The TechBlick event on Printed Electronics has been a true success. One of the best virtual events - that I have ever attended. Great talks and networking opportunities
Swarovski
Techblick is the only online event in the field of printed and hybrid electronics which gives the feeling of real live events so far.
Kundish GmbH
It was very good, topics were relevant for me. Very good fucntion to watch on demand. I still continue enjoying it.
CEA
Techblick stands out as the most convenient platform for online conferences in our field: A real way to interact online – online both, speed dating, virtual lounge, and many relevant participants. The analytics available has a great value to us as a presented and yields an excellent ROI. Moreover, it is a year-round activity that enables extra interactions and exposure
Copprint
Excellent event and presentations.
Kimoto
The conference was very intriguing and I look forward to the next month!
Lamar Advertising
I was skeptical at how effective the online events would work but was pleasantly surprised at how easy and effective the interface was. I attended I made three relevant contacts that could be potential collaborators
Neudrive
It was very well organized
Metamaterials
It was very good, topics were relevant for me. Very good funtion to watch on demand. I still continue enjoying it.
CEA-LETI
A quick answer to international technological and commercial exchange during and after pandemic
Smooth & Sharp
The networking session last week was very interesting! The virtual venue made me feel like having real conversation, it accelerated interactive communication with people. I really hope to join again next time
JX Nippon Mining & Metals Corporation
I can't say enough good things about the LIVE exhibit and networking session. You and The Techblick Team did an excellent job in creating and putting this show on! I'm glad I joined the Techblick membership!
S&K Electronics Inc
Very easy to navigate with useful content
Solvay
The event was excellent. Great content
Namics
I am honoured to be an exhibitor at the event and we cannot wait to go virtual with our cooperation. Great idea, this will be the place to meet in the coming years.
Coatema