A new report by MRS Research Group on Smart Contact Lenses market studies the intense structure of the Smart Contact Lenses market. The report breaks down the business from a 360-degree point of view from the essential market information and moving to various critical aspects which empowers the user to gain details of the ecosystem of the Smart Contact Lenses market. This report provides a full prediction of global Smart Contact Lenses market based on CAGR which offered report in terms of % for the forecasted period. This will help the users to make definite decisions based on prediction chart, reports Industry Updates.

This report evaluates the growth drivers, restraining factors, and opportunities at length. The examination of the prominent trends, driving forces, and the challenges assist the market participants and stakeholders to understand the issues they will have to face while operating in the worldwide market for Smart Contact Lens in the long run.

The report values Global Smart Contact Lenses market at USD XX million in 2016 and is expected to reach USD XX million by the end of 2022, growing at a CAGR of XX% between 2016 and 2022.

The key players covered in this study – Sensimed AG, Google, Samsung, Sony, PEGL, Research Institute, KAIST, Ghent University, Belgium.

Read more Imec, UGent and SEED Develop Hydrogel-Based Smart Contact Lens

Geographically, this report is segmented into several key Regions, with production, consumption, revenue (million USD), market share and growth rate of Smart Contact Lenses in these regions, from 2012 to 2022 (forecast), covering:

• North America
• Europe
• China
• Japan
• Southeast Asia
• India

On the basis of product, this report displays the production, revenue, price, market share and growth rate of each type, primarily split into

• Disposable Type
• Frequent Replacement Type

On the basis on the end users/applications, this report focuses on the status and outlook for major applications/end users, consumption (sales), market share and growth rate of Smart Contact Lenses for each application, including

• Medical Field
• Military Field
• Social Entertainment
• Others

Additionally, the Smart Contact Lenses report provide insights on the existing laws, policies, along with guidelines which makes the document useful for managers, analysts, business consultants and different key individuals to study and understand market trends, drivers and market challenges.

What if Amazon Alexa or Google Assistant could read your mind and act according to what you are thinking? That may soon be possible with a new gadget called AlterEgo, created by MIT Media Lab graduate student Arnav Kapur. The device could help a person with speech impediment or be used to dictate words for a computer to read out.

Read more Kenyan Invents Smart Gloves that Turn Sign Language Gestures into Audio Speech

“Our idea was: could we have a computing platform that’s more internal, that melds human and machine in some ways and that feels like an internal extension of our own cognition?”, said Kapur.

Kapur’s device resembles a jawbone hooked around the ear and attached to the user’s face between lip and chin. AlterEgo Uses a bone conduction system to hear and respond to the wearer’s internal voice via electrodes attached to the skin.

Although it doesn’t actually read the electrical signals from your brain, AlterEgo lets you silently ask questions, and then either have the answer fed back to you via bone-conduction technology. For a person with a speech impediment, it could also be used to dictate words for a computer to read out, reports Digital Trends.

Kapur envisions it as a new form of computer, which can be used in a way that is less demanding of your attention than tapping and swiping on a smartphone and more intimate than giving commands at Alexa. Though the device is still just a prototype, he imagines it being helpful in our everyday life.

Read more EyeControl AI powered Headset for Locked-In Syndrome Patients Available on NHS Supply Chain

“Throughout the history of personal computing, computers have always been external systems or entities that we interact with: desktops, smartphones, artificial intelligence tools, and even robots,” Kapur told Digital Trends. “Could we flip this paradigm? Could we augment and extend human abilities and weave the powers of computing and machine intelligence as an intrinsic human cognitive ability.”

What if Amazon Alexa or Google Assistant could read your mind and act according to what you are thinking? That may soon be possible with a new gadget called AlterEgo, created by MIT Media Lab graduate student Arnav Kapur. The device could help a person with speech impediment or be used to dictate words for a computer to read out.

Read more Kenyan Invents Smart Gloves that Turn Sign Language Gestures into Audio Speech

“Our idea was: could we have a computing platform that’s more internal, that melds human and machine in some ways and that feels like an internal extension of our own cognition?”, said Kapur.

Kapur’s device resembles a jawbone hooked around the ear and attached to the user’s face between lip and chin. AlterEgo Uses a bone conduction system to hear and respond to the wearer’s internal voice via electrodes attached to the skin.

Although it doesn’t actually read the electrical signals from your brain, AlterEgo lets you silently ask questions, and then either have the answer fed back to you via bone-conduction technology. For a person with a speech impediment, it could also be used to dictate words for a computer to read out, reports Digital Trends.

‍

Kapur envisions it as a new form of computer, which can be used in a way that is less demanding of your attention than tapping and swiping on a smartphone and more intimate than giving commands at Alexa. Though the device is still just a prototype, he imagines it being helpful in our everyday life.

Read more EyeControl AI powered Headset for Locked-In Syndrome Patients Available on NHS Supply Chain

“Throughout the history of personal computing, computers have always been external systems or entities that we interact with: desktops, smartphones, artificial intelligence tools, and even robots,” Kapur told Digital Trends. “Could we flip this paradigm? Could we augment and extend human abilities and weave the powers of computing and machine intelligence as an intrinsic human cognitive ability.”

‍

A new report by MRS Research Group on Smart Contact Lenses market studies the intense structure of the Smart Contact Lenses market. The report breaks down the business from a 360-degree point of view from the essential market information and moving to various critical aspects which empowers the user to gain details of the ecosystem of the Smart Contact Lenses market. This report provides a full prediction of global Smart Contact Lenses market based on CAGR which offered report in terms of % for the forecasted period. This will help the users to make definite decisions based on prediction chart, reports Industry Updates.

This report evaluates the growth drivers, restraining factors, and opportunities at length. The examination of the prominent trends, driving forces, and the challenges assist the market participants and stakeholders to understand the issues they will have to face while operating in the worldwide market for Smart Contact Lens in the long run.

The report values Global Smart Contact Lenses market at USD XX million in 2016 and is expected to reach USD XX million by the end of 2022, growing at a CAGR of XX% between 2016 and 2022.

The key players covered in this study – Sensimed AG, Google, Samsung, Sony, PEGL, Research Institute, KAIST, Ghent University, Belgium.

Read more Imec, UGent and SEED Develop Hydrogel-Based Smart Contact Lens

‍

Geographically, this report is segmented into several key Regions, with production, consumption, revenue (million USD), market share and growth rate of Smart Contact Lenses in these regions, from 2012 to 2022 (forecast), covering:

• North America
• Europe
• China
• Japan
• Southeast Asia
• India

On the basis of product, this report displays the production, revenue, price, market share and growth rate of each type, primarily split into

• Disposable Type
• Frequent Replacement Type

On the basis on the end users/applications, this report focuses on the status and outlook for major applications/end users, consumption (sales), market share and growth rate of Smart Contact Lenses for each application, including

• Medical Field
• Military Field
• Social Entertainment
• Others

Additionally, the Smart Contact Lenses report provide insights on the existing laws, policies, along with guidelines which makes the document useful for managers, analysts, business consultants and different key individuals to study and understand market trends, drivers and market challenges.

‍

Continuous, long-term monitoring of health is important for treatment process; it provides doctors with subtle information about the patient’s health. However, children, elderly, and people with various conditions often have difficulty wearing body-worn sensors. Scientists at Georgia Tech have developed a wireless wearable device that can be worn on the body for long-term to measure a range of physiological signals.

Related Wireless, Soft, Flexible Sensors Show Promise in Monitoring Premature Babies

The soft and conformable monitor can measure electrocardiogram (ECG), heart rate, respiratory rate and motion activity data as much as 15 meters to a portable recording device such as a smartphone or tablet computer. The electronics are mounted on a stretchable substrate and connected to gold, skin-like electrodes through printed connectors that can stretch with the medical film in which they are embedded, reports Georgia Tech News Center.

“This health monitor has a key advantage for young children who are always moving, since the soft conformal device can accommodate that activity with a gentle integration onto the skin,” said Woon-Hong Yeo, an assistant professor in the George W. Woodruff School of Mechanical Engineering and Wallace H. Coulter Department of Biomedical Engineering at the Georgia Institute of Technology. “This is designed to meet the electronic health monitoring needs of people whose sensitive skin may be harmed by conventional monitors.”

Because the device conforms to the skin, it avoids signal issues that can be created by the motion of the typical metal-gel electrodes across the skin. The device can even obtain accurate signals from a person who is walking, running or climbing stairs.

“When you put a conventional electrode on the chest, movement from sitting up or walking creates motion artifacts that are challenging to separate from the signals you want to measure,” he said. “Because our device is soft and conformal, it moves with the skin and provides information that cannot be seen with the motion artifacts of conventional sensors.”

The monitor uses three gold electrodes embedded in the film that also contains the electronic processing equipment. The entire health monitor is just three inches in diameter, and a more advanced version under development will be half that size. The wireless monitor is now powered by a small rechargeable battery, but future versions may replace the battery with an external radio-frequency charging system.

“The monitor could be worn for multiple days, perhaps for as long as two weeks,” Yeo said. “The membrane is waterproof, so an adult could take a shower while wearing it. After use, the electronic components can be recycled.”

Related UC-Berkeley Researchers Develop Flexible Sensor to Map Blood-Oxygen Levels Across the Body

The researchers developed two versions of the monitor. One is based on medical tape and designed for short-term use in a hospital or other care facility, while the other uses a soft elastomer medical film approved for use in wound care. The latter can remain on the skin longer, the Georgia Tech report said.

“The devices are completely dry and do not require a gel to pick up signals from the skin,” Yeo explained. “There is nothing between the skin and the ultrathin sensor, so it is comfortable to wear.”

Fossil’s new Gen 5 Smartwatch comes with an updated spec sheet and new battery modes which promise increased autonomy. The watches are powered by Snapdragon Wear 3100 chipset and runs Wear OS.

Related Fossil Launches Sport Smartwatch on Snapdragon Wear 3100 platform and Wear OS

The new smartwatch is set to integrate Cardiogram, an app that uses deep neural network technology to detect various heart conditions, preinstalled. The Cardiogram platform has been tested to detect sleep apnea, diabetes, hypertension and atrial fibrillation, reports MobiHealthNews.

“For several years, the health and wellness industry has been converging with smartwatch technology — and Fossil knew there was a tremendous opportunity to provide a connected option for the design-conscious consumer looking to bring style to their wrist,” Steve Evans, EVP of Fossil Group, said in a statement.

The Gen 5 Touchscreen Smartwatch has a 44-millimeter case size with a 1.3-inch digital display. It follows the brands’ design strategy that focuses on merging new tech with classic watch design.

The watches come in six color variants, which range from a sleek black to rose gold.

The watches come equipped with 1GB of RAM and 8GB of storage, both about twice the usual allotment.

The Gen 5 smartwatches also feature an extended battery life, voice calling, swim-proof speakers, increased storage and the heart rate tracking feature Cardiogram’s platform will rely on. They’ve also got NFC for Google Pay, Wi-Fi, GPS, 30-meter water-proofing, and a speaker.

Related Google Agrees to Buy Fossil’s Secret Smartwatch Tech for $40 Million

This is the first time Fossil is adding a speaker to its smartwatches. The speaker will allow you to hear answers from the Google Assistant, receive sound alerts and even play music. It’s paired with an onboard microphone. The speaker is swim proof up to three atmospheres, so it should be OK for a quick dip and rain.

The watches are on sale, starting at $295 from Fossil’s online store. Amazon won’t ship them until early next month, but you can pre-order now.

Fossil’s new Gen 5 Smartwatch comes with an updated spec sheet and new battery modes which promise increased autonomy. The watches are powered by Snapdragon Wear 3100 chipset and runs Wear OS.

Related Fossil Launches Sport Smartwatch on Snapdragon Wear 3100 platform and Wear OS

The new smartwatch is set to integrate Cardiogram, an app that uses deep neural network technology to detect various heart conditions, preinstalled. The Cardiogram platform has been tested to detect sleep apnea, diabetes, hypertension and atrial fibrillation, reports MobiHealthNews.

“For several years, the health and wellness industry has been converging with smartwatch technology — and Fossil knew there was a tremendous opportunity to provide a connected option for the design-conscious consumer looking to bring style to their wrist,” Steve Evans, EVP of Fossil Group, said in a statement.

The Gen 5 Touchscreen Smartwatch has a 44-millimeter case size with a 1.3-inch digital display. It follows the brands' design strategy that focuses on merging new tech with classic watch design.

‍

‍

The watches come in six color variants, which range from a sleek black to rose gold.

The watches come equipped with 1GB of RAM and 8GB of storage, both about twice the usual allotment.

The Gen 5 smartwatches also feature an extended battery life, voice calling, swim-proof speakers, increased storage and the heart rate tracking feature Cardiogram's platform will rely on. They’ve also got NFC for Google Pay, Wi-Fi, GPS, 30-meter water-proofing, and a speaker.

Related Google Agrees to Buy Fossil’s Secret Smartwatch Tech for $40 Million

This is the first time Fossil is adding a speaker to its smartwatches. The speaker will allow you to hear answers from the Google Assistant, receive sound alerts and even play music. It's paired with an onboard microphone. The speaker is swim proof up to three atmospheres, so it should be OK for a quick dip and rain.

The watches are on sale, starting at $295 from Fossil’s online store. Amazon won’t ship them until early next month, but you can pre-order now.

‍

Continuous, long-term monitoring of health is important for treatment process; it provides doctors with subtle information about the patient’s health. However, children, elderly, and people with various conditions often have difficulty wearing body-worn sensors. Scientists at Georgia Tech have developed a wireless wearable device that can be worn on the body for long-term to measure a range of physiological signals.

Related Wireless, Soft, Flexible Sensors Show Promise in Monitoring Premature Babies

The soft and conformable monitor can measure electrocardiogram (ECG), heart rate, respiratory rate and motion activity data as much as 15 meters to a portable recording device such as a smartphone or tablet computer. The electronics are mounted on a stretchable substrate and connected to gold, skin-like electrodes through printed connectors that can stretch with the medical film in which they are embedded, reports Georgia Tech News Center.

“This health monitor has a key advantage for young children who are always moving, since the soft conformal device can accommodate that activity with a gentle integration onto the skin,” said Woon-Hong Yeo, an assistant professor in the George W. Woodruff School of Mechanical Engineering and Wallace H. Coulter Department of Biomedical Engineering at the Georgia Institute of Technology. “This is designed to meet the electronic health monitoring needs of people whose sensitive skin may be harmed by conventional monitors.”

Because the device conforms to the skin, it avoids signal issues that can be created by the motion of the typical metal-gel electrodes across the skin. The device can even obtain accurate signals from a person who is walking, running or climbing stairs.

“When you put a conventional electrode on the chest, movement from sitting up or walking creates motion artifacts that are challenging to separate from the signals you want to measure,” he said. “Because our device is soft and conformal, it moves with the skin and provides information that cannot be seen with the motion artifacts of conventional sensors.”

‍

‍

The monitor uses three gold electrodes embedded in the film that also contains the electronic processing equipment. The entire health monitor is just three inches in diameter, and a more advanced version under development will be half that size. The wireless monitor is now powered by a small rechargeable battery, but future versions may replace the battery with an external radio-frequency charging system.

“The monitor could be worn for multiple days, perhaps for as long as two weeks,” Yeo said. “The membrane is waterproof, so an adult could take a shower while wearing it. After use, the electronic components can be recycled.”

Related UC-Berkeley Researchers Develop Flexible Sensor to Map Blood-Oxygen Levels Across the Body

The researchers developed two versions of the monitor. One is based on medical tape and designed for short-term use in a hospital or other care facility, while the other uses a soft elastomer medical film approved for use in wound care. The latter can remain on the skin longer, the Georgia Tech report said.

“The devices are completely dry and do not require a gel to pick up signals from the skin,” Yeo explained. “There is nothing between the skin and the ultrathin sensor, so it is comfortable to wear.”

‍

The demand for wearable devices, including smartwatches, fitness bands and smart patches is increasing rapidly. These devices require high-performance sensors on surfaces of various shapes and types.

Now, researchers at the Korea Institute of Science and Technology have developed a transfer-printing technology that uses hydrogel and nano ink to easily create high-performance flexible sensors of diverse shapes and structures. These sensors can be used in smartwatches, fitness trackers and medical wearables.

Read more KIST Develops 3D Soft Robots That Look Like Living Creatures

Hydrogel is a three-dimensional hydrophilic polymer network that absorbs large amounts of water.

Transfer-printing is a procedure for creating electrical gadgets through which electrodes are imprinted on a transfer mold and then transferred to a final substrate.

The research team was led by Dr. Hyunjung Yi of the Post-Silicon Semiconductor Institute.

Transfer printing works in a way similar to that of a tattoo sticker: just as sticking the tattoo sticker onto the skin and then removing the paper section leaves the image on the skin, this process creates a structure on one surface and then transfers it onto another. The technology doesn’t melt the hydrogel, maintaining its desired characteristics.

Using the porous and hydrophilic nature of hydrogels, the KIST team inkjet-printed an aqueous solution-based nano ink onto a hydrogel layer (which was solidified onto a topographic surface).

To prove their technology in practice, the researchers transferred nanoelectrodes directly onto a glove to create a modified sensor that can immediately detect finger movements. It also created a flexible, high-performance pressure sensor that can measure the pulse in the wrist.

Read more Maxim’s Health Sensors are Ultra-Small, Use Low Power and Deliver Clinical-Grade Accuracy for Next-Gen Wearables

“The outcome of this study is a new and easy method for creating flexible, high-performance sensors on surfaces with diverse characteristics and structures. We expect that this study will be utilized in the many areas that require the application of high-performance materials onto flexible and/or non-traditional substrates, including digital healthcare, intelligent human-machine interfaces, medical engineering, and next-generation electrical materials,” said Yi.

Parkinson's disease is a progressive nervous system disorder that affects movement. Symptoms include muscle rigidity, tremors, and changes in speech and gait. After diagnosis, treatments can help relieve symptoms, but there is no cure.

Related Abbott, Medtronic Driving Deep Brain Stimulation Innovation for Parkinson’s Disease

The established treatment for this condition is high-frequency brain stimulation. However, the therapy is imprecise because stimulators can only be programmed clinically and are not adaptable to the fluctuating symptoms of the disease. The key to improving the technology is biomarkers.

Now, researchers at the University of Houston have found neuro biomarkers for Parkinson’s disease that can help create the next generation of “smart” deep brain stimulators, able to respond to specific needs of Parkinson’s disease patients, reports Laurie Fickman of University of Houston.

“We can now make the closed-loop stimulator adaptive to sense a patient’s symptoms, so it can make the adjustments to the fluctuations in real time, and the patient no longer has to wait for weeks or months until the doctor can adjust the device,” said Nuri Ince, associate professor of biomedical engineering. He and doctoral student Musa Ozturk, lead author of the paper, published their findings in Movement Disorders journal.

The researchers also report a new understanding of the electrophysiology of Parkinson’s disease after examining cross frequency coupling in the subthalamic nucleus of patients with Parkinson’s disease both in the OFF state (before medication) and the ON state (after medication). Coupling, the interaction between the brain waves, has been reported in the past, but its significance and functional role have not been well understood.

Related Graphene to Protect Implantable Neurostimulators in People with Neurological Disorders

“Previous research showed coupling only existed in the basal ganglia of untreated patients and assumed to block the brain from functioning properly,” said Ozturk. “We found that strong coupling also exists in treated patients, though at different frequencies, so in effect we have ‘cleared coupling’s name’ and showed the frequencies involved in coupling impacts whether its effects are negative or positive.”

Parkinson's disease is a progressive nervous system disorder that affects movement. Symptoms include muscle rigidity, tremors, and changes in speech and gait. After diagnosis, treatments can help relieve symptoms, but there is no cure.

Related Abbott, Medtronic Driving Deep Brain Stimulation Innovation for Parkinson’s Disease

The established treatment for this condition is high-frequency brain stimulation. However, the therapy is imprecise because stimulators can only be programmed clinically and are not adaptable to the fluctuating symptoms of the disease. The key to improving the technology is biomarkers.

Now, researchers at the University of Houston have found neuro biomarkers for Parkinson’s disease that can help create the next generation of “smart” deep brain stimulators, able to respond to specific needs of Parkinson’s disease patients, reports Laurie Fickman of University of Houston.

“We can now make the closed-loop stimulator adaptive to sense a patient’s symptoms, so it can make the adjustments to the fluctuations in real time, and the patient no longer has to wait for weeks or months until the doctor can adjust the device,” said Nuri Ince, associate professor of biomedical engineering. He and doctoral student Musa Ozturk, lead author of the paper, published their findings in Movement Disorders journal.

‍

‍

The researchers also report a new understanding of the electrophysiology of Parkinson’s disease after examining cross frequency coupling in the subthalamic nucleus of patients with Parkinson’s disease both in the OFF state (before medication) and the ON state (after medication). Coupling, the interaction between the brain waves, has been reported in the past, but its significance and functional role have not been well understood.

Related Graphene to Protect Implantable Neurostimulators in People with Neurological Disorders

“Previous research showed coupling only existed in the basal ganglia of untreated patients and assumed to block the brain from functioning properly,” said Ozturk. “We found that strong coupling also exists in treated patients, though at different frequencies, so in effect we have ‘cleared coupling’s name’ and showed the frequencies involved in coupling impacts whether its effects are negative or positive.”

The demand for wearable devices, including smartwatches, fitness bands and smart patches is increasing rapidly. These devices require high-performance sensors on surfaces of various shapes and types.

Now, researchers at the Korea Institute of Science and Technology have developed a transfer-printing technology that uses hydrogel and nano ink to easily create high-performance flexible sensors of diverse shapes and structures. These sensors can be used in smartwatches, fitness trackers and medical wearables.

Read more KIST Develops 3D Soft Robots That Look Like Living Creatures

Hydrogel is a three-dimensional hydrophilic polymer network that absorbs large amounts of water.

Transfer-printing is a procedure for creating electrical gadgets through which electrodes are imprinted on a transfer mold and then transferred to a final substrate.

The research team was led by Dr. Hyunjung Yi of the Post-Silicon Semiconductor Institute.

‍

‍

Transfer printing works in a way similar to that of a tattoo sticker: just as sticking the tattoo sticker onto the skin and then removing the paper section leaves the image on the skin, this process creates a structure on one surface and then transfers it onto another. The technology doesn’t melt the hydrogel, maintaining its desired characteristics.

Using the porous and hydrophilic nature of hydrogels, the KIST team inkjet-printed an aqueous solution-based nano ink onto a hydrogel layer (which was solidified onto a topographic surface).

To prove their technology in practice, the researchers transferred nanoelectrodes directly onto a glove to create a modified sensor that can immediately detect finger movements. It also created a flexible, high-performance pressure sensor that can measure the pulse in the wrist.

Read more Maxim’s Health Sensors are Ultra-Small, Use Low Power and Deliver Clinical-Grade Accuracy for Next-Gen Wearables

“The outcome of this study is a new and easy method for creating flexible, high-performance sensors on surfaces with diverse characteristics and structures. We expect that this study will be utilized in the many areas that require the application of high-performance materials onto flexible and/or non-traditional substrates, including digital healthcare, intelligent human-machine interfaces, medical engineering, and next-generation electrical materials,” said Yi.

In the United States, more than 130 people die after overdosing on opioids every day. Devastating consequences of the opioid epidemic include increases in opioid misuse and related overdoses, as well as the rising incidence of newborns experiencing withdrawal syndrome due to opioid use and misuse during pregnancy, according to the U.S. Dept. of Health and Human Services.

Related Carnegie Mellon Researchers Develop Wearable Opioid Overdose Detector

A drug called Narcan is used as an antidote for opioid overdose, but it’s difficult for a patient to administer it by themselves. Researchers from Purdue University have decided to tackle this problem with a wearable system that will release the antidote automatically, reports MobiHealthNews.

“A lot of time patients who overdoes are found alone and are incapacitated to inject the life-saving drug themselves,” Hyowon “Hugh” Lee, an assistant professor of biomedical engineering at Purdue, said in a university video. “We are trying to come up with a closed loop solution that can automatically deliver an antidote.”

An overdose occurs when opioids adhere to brain receptors that control breathing, causing individuals to hypoventilate and die.

The wearable device can detect the point at which the respiration rate of a person decreases to a certain level – changed from electrocardiography (EKG) signals – and subsequently releases the drug. This drug blocks the opioid from adhering to brain receptors.

Just like an insulin pump, the proof of concept device is worn as an armband that fastens to a magnetic field generator, linked to a portable battery worn at the hip.

“The idea is to be able to measure the rate of respiration using some sort of wearable sensor, and then to be able to use that as some form of threshold to trigger the release of the antidote that will be implanted under the skin so you will have an antidote with you just in case you have some sort of an accident,” Lee said. “Then when the system texts that you are having respiratory failure the drug will be released automatically to give you extra time to get medical attention.”

An EKG sensor is adhered on the chest. When it detects a respiration that’s too low, it triggers the magnetic field generator to warm up a drug capsule within the body and discharges the antidote in 10 seconds.

Related DyAnsys Gets FDA Clearance For Its Wearable Device to Treat Opioid Addiction

The scientists believe the drug capsule can be pre-injected within the skin in an outpatient setting. The device therefore would be able to automatically release the drug to the patient in case of an overdose. That would give emergency services an extra hour to get the patient to the hospital, Lee said.

PhysIQ, a company known for applying Artificial Intelligence (AI) in wearable sensor data, received FDA 510(k) clearance for an algorithm facilitating cloud-based analysis of patients’ continuous ambulatory respiration rates. This regulatory clearance adds to the company’s expanding portfolio of FDA-cleared cloud-based analytics, which also include QRS detection, heart rate, heart rate variability, atrial fibrillation detection, and their personalized physiology change detection analytic.

Read more Omron and physIQ Collaborate to Improve Cardiovascular Patient Care

PhysIQ’s algorithms collect raw telemetry from the device and uploads it to the cloud where FDA-cleared analytics use the raw biosignals to produce vital signs. With this approach physIQ is able to provide vital sign analytics that benefit from the superior computing power of the cloud and fuel the higher-level analytics that further characterize dimensions of human physiology, reports Business Wire.

“In a real-world environment, respiration rate is a tough vital sign to accurately and consistently measure given high levels of motion artifact,” said Matt Pipke, co-founder and CTO of physIQ. “Given these challenges, it is ideal to be able to capitalize on the vast processing power and memory in the cloud to iron out the edge cases and outliers.”

Wearable sensors have enormous potential to transform how we understand and manage human health. However, these on-body sensors are collecting data in a noisy environment and, without sophisticated methods to manage signal noise, the resulting output is compromised.

Read more Netherlands-Based Haga Teaching Hospital Partners with physIQ and VitalConnect for Continuous Monitoring of Cancer Patients

“Accurate and precise vital signs are an essential component of a clinical grade remote intelligence solution but, ultimately, these vital signs are an input into the higher-level AI-based analytics for which physIQ is known,” said Gary Conkright, chairman and CEO of physIQ. “We are encouraged by the successful clearance of respiration as a core dimension of human cardiopulmonary physiology which will accelerate our development of further AI analytics.”

PhysIQ, a company known for applying Artificial Intelligence (AI) in wearable sensor data, received FDA 510(k) clearance for an algorithm facilitating cloud-based analysis of patients’ continuous ambulatory respiration rates. This regulatory clearance adds to the company’s expanding portfolio of FDA-cleared cloud-based analytics, which also include QRS detection, heart rate, heart rate variability, atrial fibrillation detection, and their personalized physiology change detection analytic.

Read more Omron and physIQ Collaborate to Improve Cardiovascular Patient Care

PhysIQ’s algorithms collect raw telemetry from the device and uploads it to the cloud where FDA-cleared analytics use the raw biosignals to produce vital signs. With this approach physIQ is able to provide vital sign analytics that benefit from the superior computing power of the cloud and fuel the higher-level analytics that further characterize dimensions of human physiology, reports Business Wire.

“In a real-world environment, respiration rate is a tough vital sign to accurately and consistently measure given high levels of motion artifact,” said Matt Pipke, co-founder and CTO of physIQ. “Given these challenges, it is ideal to be able to capitalize on the vast processing power and memory in the cloud to iron out the edge cases and outliers.”

‍

‍

Wearable sensors have enormous potential to transform how we understand and manage human health. However, these on-body sensors are collecting data in a noisy environment and, without sophisticated methods to manage signal noise, the resulting output is compromised.

Read more Netherlands-Based Haga Teaching Hospital Partners with physIQ and VitalConnect for Continuous Monitoring of Cancer Patients

“Accurate and precise vital signs are an essential component of a clinical grade remote intelligence solution but, ultimately, these vital signs are an input into the higher-level AI-based analytics for which physIQ is known,” said Gary Conkright, chairman and CEO of physIQ. “We are encouraged by the successful clearance of respiration as a core dimension of human cardiopulmonary physiology which will accelerate our development of further AI analytics.”

‍

In the United States, more than 130 people die after overdosing on opioids every day. Devastating consequences of the opioid epidemic include increases in opioid misuse and related overdoses, as well as the rising incidence of newborns experiencing withdrawal syndrome due to opioid use and misuse during pregnancy, according to the U.S. Dept. of Health and Human Services.

Related Carnegie Mellon Researchers Develop Wearable Opioid Overdose Detector

A drug called Narcan is used as an antidote for opioid overdose, but it’s difficult for a patient to administer it by themselves. Researchers from Purdue University have decided to tackle this problem with a wearable system that will release the antidote automatically, reports MobiHealthNews.

“A lot of time patients who overdoes are found alone and are incapacitated to inject the life-saving drug themselves,” Hyowon “Hugh” Lee, an assistant professor of biomedical engineering at Purdue, said in a university video. “We are trying to come up with a closed loop solution that can automatically deliver an antidote.”

An overdose occurs when opioids adhere to brain receptors that control breathing, causing individuals to hypoventilate and die.

The wearable device can detect the point at which the respiration rate of a person decreases to a certain level – changed from electrocardiography (EKG) signals – and subsequently releases the drug. This drug blocks the opioid from adhering to brain receptors.

‍

‍

Just like an insulin pump, the proof of concept device is worn as an armband that fastens to a magnetic field generator, linked to a portable battery worn at the hip.

“The idea is to be able to measure the rate of respiration using some sort of wearable sensor, and then to be able to use that as some form of threshold to trigger the release of the antidote that will be implanted under the skin so you will have an antidote with you just in case you have some sort of an accident," Lee said. "Then when the system texts that you are having respiratory failure the drug will be released automatically to give you extra time to get medical attention.”

An EKG sensor is adhered on the chest. When it detects a respiration that’s too low, it triggers the magnetic field generator to warm up a drug capsule within the body and discharges the antidote in 10 seconds.

Related DyAnsys Gets FDA Clearance For Its Wearable Device to Treat Opioid Addiction

The scientists believe the drug capsule can be pre-injected within the skin in an outpatient setting. The device therefore would be able to automatically release the drug to the patient in case of an overdose. That would give emergency services an extra hour to get the patient to the hospital, Lee said.

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Energous Corporation, a leader in next generation of wireless charging better known for its wireless charging solution WattUp®, received Federal Communications Commission (FCC) certification of a GaN-based WattUp Near Field wireless charging transmitter. The advanced transmitter is designed to deliver higher power with improved efficiency, enabling fast charging for hearables, wearables, medical sensors and more. To be deemed fully compliant with all regulatory requirements including RF, EMC and RF safety, the NF330 had to undergo rigorous testing by Underwriters Laboratory (UL), says a press release.

“The FCC certification of the NF330 transmitter is another step forward in the roll-out of Wireless Charging 2.0,” said Stephen R. Rizzone, president and CEO of Energous Corporation. “This GaN-based transmitter delivers five times more charging power, while almost doubling system efficiency compared to our CMOS-based transmitter solution, expanding charging options for consumers and manufacturers.”

Read more Batfree Power Strap Provides Longer Battery Life and Wireless Charging for Apple Watches

WattUp is the only technology that supports both contact-based and at-a-distance wireless charging, as well as the ability to charge multiple devices simultaneously. WattUp is a scalable, RF-based wireless charging technology that offers substantial improvements in contact-based charging efficiency, foreign object detection, orientation freedom and thermal performance compared to older, coil-based charging technologies. Similar to Wi-Fi, the WattUp ecosystem ensures interoperability between receivers and transmitters, regardless of manufacturer, making the entire ecosystem flexible and accessible for consumers and manufacturers.

Read more PlusUs Introduces First-Ever Flexible Wireless Charging Pad Made of Eco-Friendly Materials

About Energous

Energous Corporation is leading the next generation of wireless charging – Wireless Charging 2.0 – with its award-winning WattUp® technology, which supports fast, efficient contact-based charging, as well as charging over-the-air. The technology can be designed into many different sized electronic devices for the home and office, as well as the medical, industrial, retail and automotive industries, and it ensures interoperability across products. As a systems solutions company, Energous develops silicon-based wireless power transfer (WPT) technologies and customizable reference designs. These include innovative silicon chips, antennas and software, for a large variety of applications, such as smartphones, fitness trackers, hearables, medical sensors and more.

It seems like Microsoft is trying to get back in the health wearable space after abandoning the Microsoft Band in 2016. Neowin reports on a new patent filing by Microsoft, which says the tech giant has filed a patent for a multidimensional optical sensor which could detect heart rate, pulse wave velocity, blood and tissue oxygenation, and even blood pressure.

Read more Microsoft Files Patent for Eyeglasses That Measure Blood Pressure

“A rather interesting new wearables-related technology has been patented by the Redmond firm – a device containing a multi-dimensional optical sensor to generate and output data regarding hemodynamics of users. Notably, the device is stated to be incorporable with wearables,” Neowin said in the report.

According to Neowin, Microsoft believes that one-dimensional optical sensors found in currently available wearable devices may not accurately measure health data and are quite limiting. For example, the sensor may report inaccurate data while the person is walking. Moreover, these sensors fail to deliver accurate data on other fitness-related matters which are essential to the wearer’s health, the report said.

For the reasons, the advanced sensor proposed by Microsoft aims to not only address the inaccuracies in measurement, but also measure new hemodynamics – the dynamics of blood flow. The sensor will be able to detect and then display include arterial heart rate, arterial blood oxygenation, pulse waveform, tissue pulse, arterial stiffness, rate, tissue oxygenation, and many more.

Read more Trimble Announces New Hard Hat Compatible Mixed Reality Device with Microsoft HoloLens 2

The design is reportedly more accurate than existing optical sensors found in wearables, and also less invasive than clinical measuring tools.

The sensor could be incorporated into various wearable devices including devices such as smartwatches and fitness trackers or devices worn on arm and leg. One of the patent images shows a sensor built into a pair of glasses, over the wearer’s temple, reports MobiHealthNews.

It seems like Microsoft is trying to get back in the health wearable space after abandoning the Microsoft Band in 2016. Neowin reports on a new patent filing by Microsoft, which says the tech giant has filed a patent for a multidimensional optical sensor which could detect heart rate, pulse wave velocity, blood and tissue oxygenation, and even blood pressure.

Read more Microsoft Files Patent for Eyeglasses That Measure Blood Pressure

“A rather interesting new wearables-related technology has been patented by the Redmond firm - a device containing a multi-dimensional optical sensor to generate and output data regarding hemodynamics of users. Notably, the device is stated to be incorporable with wearables,” Neowin said in the report.

According to Neowin, Microsoft believes that one-dimensional optical sensors found in currently available wearable devices may not accurately measure health data and are quite limiting. For example, the sensor may report inaccurate data while the person is walking. Moreover, these sensors fail to deliver accurate data on other fitness-related matters which are essential to the wearer’s health, the report said.

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For the reasons, the advanced sensor proposed by Microsoft aims to not only address the inaccuracies in measurement, but also measure new hemodynamics – the dynamics of blood flow. The sensor will be able to detect and then display include arterial heart rate, arterial blood oxygenation, pulse waveform, tissue pulse, arterial stiffness, rate, tissue oxygenation, and many more.

Read more Trimble Announces New Hard Hat Compatible Mixed Reality Device with Microsoft HoloLens 2

The design is reportedly more accurate than existing optical sensors found in wearables, and also less invasive than clinical measuring tools.

The sensor could be incorporated into various wearable devices including devices such as smartwatches and fitness trackers or devices worn on arm and leg. One of the patent images shows a sensor built into a pair of glasses, over the wearer’s temple, reports MobiHealthNews.

‍

Energous Corporation, a leader in next generation of wireless charging better known for its wireless charging solution WattUp®, received Federal Communications Commission (FCC) certification of a GaN-based WattUp Near Field wireless charging transmitter. The advanced transmitter is designed to deliver higher power with improved efficiency, enabling fast charging for hearables, wearables, medical sensors and more. To be deemed fully compliant with all regulatory requirements including RF, EMC and RF safety, the NF330 had to undergo rigorous testing by Underwriters Laboratory (UL), says a press release.

“The FCC certification of the NF330 transmitter is another step forward in the roll-out of Wireless Charging 2.0,” said Stephen R. Rizzone, president and CEO of Energous Corporation. “This GaN-based transmitter delivers five times more charging power, while almost doubling system efficiency compared to our CMOS-based transmitter solution, expanding charging options for consumers and manufacturers.”

Read more Batfree Power Strap Provides Longer Battery Life and Wireless Charging for Apple Watches

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WattUp is the only technology that supports both contact-based and at-a-distance wireless charging, as well as the ability to charge multiple devices simultaneously. WattUp is a scalable, RF-based wireless charging technology that offers substantial improvements in contact-based charging efficiency, foreign object detection, orientation freedom and thermal performance compared to older, coil-based charging technologies. Similar to Wi-Fi, the WattUp ecosystem ensures interoperability between receivers and transmitters, regardless of manufacturer, making the entire ecosystem flexible and accessible for consumers and manufacturers.

Read more PlusUs Introduces First-Ever Flexible Wireless Charging Pad Made of Eco-Friendly Materials

About Energous

Energous Corporation is leading the next generation of wireless charging - Wireless Charging 2.0 - with its award-winning WattUp® technology, which supports fast, efficient contact-based charging, as well as charging over-the-air. The technology can be designed into many different sized electronic devices for the home and office, as well as the medical, industrial, retail and automotive industries, and it ensures interoperability across products. As a systems solutions company, Energous develops silicon-based wireless power transfer (WPT) technologies and customizable reference designs. These include innovative silicon chips, antennas and software, for a large variety of applications, such as smartphones, fitness trackers, hearables, medical sensors and more.

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