The EXG Synapse by Neuphony is an advanced device designed to monitor and analyze multiple biosignals, including EEG, ECG, and EMG. It offers real-time data for research and neurofeedback, making it ideal for cognitive enhancement and physiological monitoring.

For the Benefit of All: Assistive Tech Developed from NASA Tech

What do modern cochlear implants and robotic gloves have in common? They were derived from NASA technology. We’ve made it easier to find and use our patented inventions that could help create products that enhance life for people with disabilities.

October is National Disability Employment Awareness Month, which highlights the contributions of American workers with disabilities – many of whom use assistive technology on the job. Take a look at these assistive technologies that are NASA spinoffs.

Low-Vision Headsets

The Joint Optical Reflective Display (JORDY) device is a headset that uses NASA image processing and head-mounted display technology to enable people with low vision to read and write. JORDY enhances individuals’ remaining sight by magnifying objects up to 50 times and allowing them to change contrast, brightness, and display modes. JORDY's name was inspired by Geordi La Forge, a blind character from “Star Trek: The Next Generation” whose futuristic visor enabled him to see.

Cochlear Implants

Work that led to the modern cochlear implant was patented by a NASA engineer in the 1970s. Following three failed corrective surgeries, Adam Kissiah combined his NASA electronics know-how with research in the Kennedy Space Center technical library to build his own solution for people with severe-to-profound hearing loss who receive little or no benefit from hearing aids. Several companies now make the devices, which have been implanted in hundreds of thousands of people around the world.

Robotic Gloves

Ironhand, from Swedish company Bioservo Technologies, is the world’s first industrial-strength robotic glove for factory workers and others who perform repetitive manual tasks. It helps prevent stress injuries but has been especially warmly received by workers with preexisting hand injuries and conditions. The glove is based on a suite of patents for the technology developed by NASA and General Motors to build the hands of the Robonaut 2 humanoid robotic astronaut.

Smart Glasses

Neurofeedback technology NASA originally developed to improve pilots’ attention has been the basis for products aimed at helping people manage attention disorders without medication. The devices measure brainwave output to gauge attention levels according to the “engagement index” a NASA engineer created. Then, they show the results to users, helping them learn to voluntarily control their degree of concentration. One such device is a pair of smart glasses from Narbis, whose lenses darken as attention wanes.

Anti-Gravity Treadmills

A NASA scientist who developed ways to use air pressure to simulate gravity for astronauts exercising in space had the idea to apply the concept for the opposite effect on Earth. After licensing his technology, Alter-G Inc. developed its anti-gravity G-Trainer treadmill, which lets users offload some or all of their weight while exercising. The treadmills can help people recover from athletic or brain injuries, and they allow a safe exercise regimen for others with long-term conditions such as arthritis.

Wireless Muscle Sensors

Some of the most exciting assistive technologies to spin off may be yet to come. Delsys Inc. developed electromyographic technology to help NASA understand the effects of long-term weightlessness on astronauts’ muscles and movements. Electromyography detects and analyzes electrical signals emitted when motor nerves trigger movement. Among the company’s customers are physical therapists developing exercise routines to help patients recover from injuries. But some researchers are using the technology to attempt recoveries that once seemed impossible, such as helping paralyzed patients regain movement, letting laryngectomy patients speak, and outfitting amputees with artificial limbs that work like the real thing.  

To further enhance the lives of people with disabilities, NASA has identified a selection of patented technologies created for space missions that could spur the next generation of assistive technology here on Earth.

Want to learn more about assistive technologies already in action? Check out NASA Spinoff to find products and services that wouldn’t exist without space exploration.   

Make sure to follow us on Tumblr for your regular dose of space!

"In lucid dreams (LDs), people maintain consciousness and can make predetermined actions while asleep. Since the 1970s, electrooculography and other sensors have been used to send signals from LDs into reality. In this study, we test whether electromyography (EMG) can help transfer melodies from LDs, which can expand our abilities to transfer information from LDs into reality. Software was developed to translate EMG impulses into sounds. Four LD practitioners were trained to play musical rhythms by straining their arm muscles, which had EMG sensors on them. Then, these volunteers were asked to induce LDs and repeat the task under polysomnographic observation in a laboratory. Each volunteer induced from one to three confirmed LDs. Three of them were able to transfer musical rhythms into reality, as the EMG sensors detected electrical spikes in the arm muscles despite sleep paralysis. The researchers heard the sounds from the dreams in real time and in recordings. The results prove the concept that people can transfer rhythmical EMG impulses from LD, which could be potentially useful for transferring sounds or music from LD into reality. As one practitioner failed to transfer proper EMG signals, the method needs further investigation. Since LD practitioners sometimes create original music in LDs, it could be possible to transfer these insights into reality. These melodies can be broadcasted via the Internet, TV, or radio in real time."

Raduga, M., Shashkov, A., Gordienko, N., Vanin, A., & Maltsev, E. (2023). Real-time transferring of music from lucid dreams into reality by electromyography sensors. Dreaming. Advance online publication. https://doi.org/10.1037/drm0000244

What is Complement System Function & what are common signs and symptoms of Complement System Function?

The human nervous system is a complex network responsible for transmitting signals between the brain, spinal cord, and muscles. When nerve or muscle disorders arise, doctors often recommend an Electromyography test (EMG) to diagnose the underlying issue. If you are experiencing muscle weakness, numbness, or nerve-related problems, searching for the best diagnostic centre near me for an EMG testing procedure is the first step toward finding answers.

In this blog, we will discuss:

What is an EMG test?

Why is an EMG test done?

How is an EMG test performed?

Where can you get an EMG test done?

What to expect before, during, and after the test?

What is an EMG Test?

An electromyography test (EMG) is a diagnostic procedure that evaluates the health of muscles and the nerve cells (motor neurons) that control them. Motor neurons send electrical signals to the muscles, and an electromyogram (EMG) records these signals to determine if there is any dysfunction.

The test involves inserting thin needle electrodes into specific muscles to measure electrical activity. A related procedure, called nerve conduction study (NCS), is often performed alongside an EMG to analyze how well electrical signals travel through nerves.

Why is an EMG Test Done?

Doctors recommend an EMG test to diagnose a range of conditions affecting the muscles or nerves. Some of the key reasons for undergoing EMG testing include:

1. Muscle Weakness

If you experience unexplained muscle weakness or atrophy, an electromyogram (EMG) can determine whether the issue is related to the muscles themselves or the nerves controlling them.

2. Nerve Damage (Neuropathy)

An EMG test helps detect nerve dysfunction (neuropathy) caused by conditions like diabetes, trauma, or infections. It assesses how well the nerves communicate with the muscles.

3. Neuromuscular Disorders

If a doctor suspects neuromuscular disorders such as amyotrophic lateral sclerosis (ALS), muscular dystrophy, or myasthenia gravis, an EMG testing procedure can help confirm the diagnosis.

4. Carpal Tunnel Syndrome

Repetitive hand and wrist movements can lead to carpal tunnel syndrome, a condition where the median nerve gets compressed. An electromyography test is often used to evaluate nerve function in such cases.

5. Radiculopathy (Pinched Nerves)

Conditions like herniated discs or spinal stenosis can cause nerve compression, leading to pain, numbness, and tingling sensations. An EMG test helps identify the affected nerve roots.

6. Unexplained Muscle Pain or Cramping

If you experience persistent muscle pain, cramping, or spasms without an obvious cause, an EMG test can help pinpoint the problem.

How is an EMG Test Performed?

An electromyography test (EMG) is a two-part procedure that includes:

Nerve Conduction Study (NCS) – Measures the speed and strength of electrical signals traveling through the nerves.

Needle EMG – A thin needle electrode is inserted into a muscle to assess its electrical activity.

Step-by-Step Procedure:

Preparation – The technician cleans the skin and places electrodes over specific muscles or nerves.

Nerve Conduction Study (NCS) – Small electrical pulses stimulate the nerves, and sensors measure their response.

Needle Electrode Insertion – A thin needle electrode is inserted into the muscle to record electrical activity at rest and during movement.

Analysis – The recorded data is analyzed to detect abnormalities in nerve or muscle function.

Where Can You Get an EMG Test Done?

If you are looking for an EMG testing facility, searching for a near by diagnostic centre is the best option. You can also visit Diagnopein near me for state-of-the-art diagnostics.

1. Best Diagnostic Centre Near Me

To ensure accuracy and quality, always choose a best diagnostic centre near me with experienced specialists and advanced medical equipment.

2. Near By Diagnostic Centre

If you want to undergo an EMG test conveniently, look for a near by diagnostic centre that offers this test under expert supervision.

3. Diagnopein Near Me

Diagnopein is a trusted name in diagnostics, providing high-quality electromyography test services with accurate results. If you are searching for Diagnopein near me, you can book an appointment and get tested at their advanced facility.

What to Expect Before, During, and After the EMG Test

Before the Test:

Avoid using lotions or creams on the skin before the test.

Inform your doctor about any medications you are taking.

Wear comfortable clothing that allows easy access to the test areas.

During the Test:

You may feel mild discomfort when the electrode needles are inserted.

The nerve conduction study may cause a slight tingling sensation.

The test usually takes 30 to 60 minutes to complete.

After the Test:

Some soreness at the needle insertion sites is normal.

Resume normal activities unless instructed otherwise by your doctor.

Your doctor will discuss the results and suggest further tests or treatments if needed.

Conclusion

An electromyography test (EMG) is a valuable diagnostic tool for detecting nerve and muscle disorders. Whether you are experiencing muscle weakness, numbness, or unexplained pain, getting an EMG testing procedure done at a best diagnostic centre near me can provide crucial insights into your condition. If you’re searching for Diagnopein near me or a near by diagnostic centre, book an appointment today and take the first step toward better health.

By choosing a reputable diagnostic center for your electromyography test, you ensure accurate results and expert medical guidance to help diagnose and treat neuromuscular conditions effectively.

Why Biometric Feedback Is Revolutionizing Yoga Performance in 2025

Introduction

The integration of biometric feedback into yoga practice is redefining how practitioners refine their movements, enhance mindfulness, and track progress. As wearable technology advances, yoga enthusiasts now have access to real-time physiological data, allowing them to achieve peak performance while maintaining a deep mind-body connection. This data-driven approach is transforming yoga in 2025, ensuring safer, more effective, and more personalized experiences.

The Evolution of Biometric Feedback in Yoga

Biometric technology has evolved significantly in the last decade. With the rise of AI-powered wearables, smart yoga mats, and real-time analytics, practitioners can now measure various physiological markers, including:

Heart rate variability (HRV) – Helps assess stress levels and relaxation.

Muscle engagement tracking – Provides feedback on posture and alignment.

Respiration rate – Ensures proper breath control during practice.

Electromyography (EMG) sensors – Detect muscle activation and prevent injury.

This shift toward biofeedback integration allows yoga instructors and practitioners to tailor their sessions for maximum efficiency and well-being.

How Biometric Feedback Enhances Yoga Performance

1. Personalized Yoga Sessions with Real-Time Data

Traditional yoga classes often rely on generic instructions that may not suit every individual. Biometric sensors enable real-time adjustments based on a practitioner’s unique physiological responses, leading to optimized performance and injury prevention.

For instance, a smart yoga mat equipped with pressure sensors can detect improper weight distribution and provide instant corrections via a connected app. Similarly, AI-powered wearables analyze heart rate patterns, guiding practitioners toward better relaxation and endurance techniques.

2. Improved Breathing Control and Mindfulness

Pranayama, or breath control, is a fundamental aspect of yoga. Wearable devices now offer precise tracking of respiratory rate, ensuring practitioners maintain steady, deep breaths throughout their sessions. By analyzing breathing patterns, these devices help individuals:

Regulate oxygen intake for better stamina.

Synchronize breath with movement.

Reduce stress levels by optimizing breath cycles.

3. Injury Prevention and Posture Correction

Poor alignment and overexertion can lead to injuries, especially for beginners. Biometric feedback provides instant alerts when a practitioner exceeds a safe range of motion. Advanced motion-tracking wearables can detect incorrect postures and recommend corrections, reducing the risk of strain or imbalance.

For example, smart clothing with embedded sensors monitors joint angles and muscle engagement, offering corrective feedback through haptic signals or voice commands.

4. Enhanced Performance Tracking and Progress Analysis

Yoga is a journey of continuous improvement, and biometric tools now provide detailed progress reports. Metrics such as flexibility levels, endurance, and stress resilience are tracked over time, helping practitioners set realistic goals and measure their achievements.

Key performance indicators (KPIs) that biometric wearables monitor include:

Heart rate trends during meditation and active poses.

Balance and stability levels in challenging postures.

Muscle endurance scores based on sustained holds.

These insights allow individuals to refine their techniques and maintain consistent progression in their practice.

5. Data-Driven Meditation and Stress Reduction

Meditation is a crucial component of yoga that benefits from biometric feedback. Electroencephalography (EEG) headbands track brainwave activity, providing insights into cognitive states. This technology helps practitioners:

Identify periods of deep meditation vs. mental distraction.

Train their minds to maintain prolonged focus.

Optimize meditation duration for maximum benefits.

With AI-driven insights, users receive personalized meditation recommendations based on their cognitive patterns, making relaxation techniques more effective than ever.

The Role of AI and Machine Learning in Biometric Yoga

Artificial Intelligence (AI) plays a significant role in analyzing biometric data and offering customized recommendations. Machine learning algorithms assess a practitioner's historical data to:

Predict fatigue levels and suggest restorative poses.

Adapt workout intensity based on past heart rate responses.

Provide insights on optimal stretching routines for enhanced flexibility.

AI-powered virtual yoga assistants now guide users through sessions, ensuring they receive real-time posture corrections and breathwork adjustments.

ULU Yoga: A Leader in Biometric Yoga Innovation

ULU Yoga has been at the forefront of integrating biometric feedback into yoga practice. Known for its aerial and online yoga teacher training programs, ULU Yoga incorporates cutting-edge wearable technology to enhance flexibility, alignment, and mindfulness. Their programs use AI-powered analytics, smart mats, and heart rate monitoring to provide real-time feedback, ensuring practitioners achieve optimal posture and breath control. By merging traditional yoga principles with modern technology, ULU Yoga is revolutionizing how yogis worldwide approach their practice.

The Future of Biometric Yoga in 2025 and Beyond

The coming years will witness even more advancements in biometric yoga technology. Some emerging trends include:

Neurofeedback training for deeper meditation – Advanced EEG sensors will provide real-time brainwave analysis, helping practitioners achieve profound states of awareness.

Holographic yoga instructors – AR and VR integration will enable immersive yoga experiences, offering hyper-personalized guidance.

DNA-driven yoga optimization – Genetic testing may reveal personalized yoga regimens based on an individual's biological predispositions.

Smart environment adaptation – AI-driven tools will adjust room temperature, humidity, and lighting for optimal performance.

Conclusion

Biometric technology is redefining the way yoga is practiced, offering real-time insights that help individuals refine their postures, breathing, and meditation techniques. As advancements continue, the fusion of AI, wearables, and yoga will open new doors for enhanced mindfulness, injury prevention, and personalized growth. With data-driven precision, yoga practitioners can now optimize their routines, ensuring a more connected, balanced, and effective practice for years to come.

Fixed Base Office Chairs: Silent Guardians of Professional Spaces

At NASA’s Jet Propulsion Laboratory, engineers are using fixed-base chairs to calibrate Mars rover parts, where even a 0.01-degree angle deviation could lead to catastrophic consequences. This extreme demand for absolute stability has made fixed-base office chairs irreplaceable in professional fields. The non-rotating design is not just a physical limitation, but also a biomechanical safeguard for precise work.

1. Precise Control of Mechanical Structure

The aerospace-grade aluminum alloy frame, optimized through topology, reduces structural stress concentration by 62%. The four-point contact base design achieves 98% uniformity in force distribution, improving by 23% compared to traditional five-legged bases. Vibration tests at MIT’s Mechanical Laboratory show that fixed-base chairs have only 0.13mm displacement under a 6-point earthquake simulation, providing a stable platform for precision tasks.

The ergonomic locking mechanism includes three layers of safety redundancy: electromagnetic latch (response time 0.2 seconds), mechanical buckle (weight capacity of 500kg), and hydraulic damping (displacement ≤0.05mm). Boeing’s application data shows this design reduces assembly errors to one-seventh of rotating chairs.

The fine-tuning system allows for millimeter-level positioning, with a footrest integrated with a digital angle gauge (precision ±0.1°) and a backrest adjustment gear track (0.5mm per tooth). This creates a fully personalized mechanical support system. Clinical tests show a 41% reduction in muscle fatigue when maintaining a fixed posture.

2. Breakthrough Innovations in Material Science

Carbon Fiber-Kevlar Composite Seat Cushion This combination of aerospace materials ensures surface modulus reaches 120GPa for rigidity and features a honeycomb structure that absorbs 70% of vibration energy. In semiconductor cleanroom tests, the material dust emission is only 0.03μg/m³, meeting ISO Class 3 standards.

Bionic Coating Innovation The self-healing polyurethane layer developed by Germany’s Covestro contains 5 million microcapsules/cm². Scratches larger than 3μm are repaired at a molecular level within 40 seconds, and the surface friction coefficient remains stable between 0.35-0.55, extending the product lifespan to 15 years.

Bio-Based Composite Materials DSM’s EcoPaXX seat base material, made from 51% castor oil extract, has reduced its carbon footprint by 68% compared to traditional plastics, while its impact resistance has increased to 42kJ/m², certified by UL ECVP 2809’s closed-loop standards.

3. Professional Adaptation in Specialized Designs

In Rolls-Royce’s aircraft engine assembly line, fixed-base chairs and workbenches form a golden triangle of support: the seat angle is locked at 5°, and the armrest height tolerance is ±1.5mm. This configuration improves assembly efficiency by 37%, and reduces repetitive strain injuries to one-fourth of the industry average.

Medical Surgery Chairs Integrated with a sterile control system, the base is made from 316L stainless steel, and the surface is electro-polished to Ra≤0.8μm. The gas lift system allows micro-adjustments down to 0.01mm, and the temperature-sensing seat maintains a consistent 36.5-37°C temperature range, speeding up wound healing by 19%.

Esports Training Chairs Equipped with a neurofeedback system, the seat features 32-channel electromyography sensors to monitor posture stability. When muscle tremor frequency exceeds the threshold, the armrest’s tactile feedback module provides an immediate warning, enhancing the precision of professional players' operations by 28%.

4. Technology-Driven Health Management

Dynamic Pressure Distribution Monitoring System This system includes 2048 sensor units that map the pressure distribution between the ischium and femur. When localized pressure exceeds 32kPa, the air cushions automatically adjust support, reducing the risk of sciatic nerve compression by 63%, according to clinical trials.

Biological Rhythm Lighting System The ActiveLight technology from Philips is integrated into the chair’s backrest with full-spectrum LEDs. The system automatically adjusts color temperature based on circadian rhythms—6500K blue light in the morning to boost cognition, and 3000K amber light in the evening to promote melatonin secretion, reducing work efficiency fluctuations by 41%.

Aerodynamic Design for Local Microclimate Optimization A laminar airflow channel is set beneath the seat (airflow speed of 0.25m/s ±5%) and is coupled with a HEPA 13-level filtration system. Air quality monitoring shows that the PM0.3 concentration in the breathing zone remains below 12μg/m³, increasing brain oxygen levels by 18%.

At the University of Tokyo’s ultra-precision machining laboratory, quantum-level stable chairs are creating miracles: using superconducting magnetic levitation technology, 99.97% of ground vibration is neutralized, achieving a nanometer-level processing precision of 0.5nm Ra. This shows that fixed-base chairs have evolved from physical limitations into technology enablers, releasing the maximum potential of human creativity through absolute stability. When biomechanics, material science, and environmental control deeply integrate, fixed-base chairs no longer restrict but become the solid foundation of professional excellence.

Choose Ekintop Furniture, and we will provide you with the best solutions for your professional workspace needs.

A headset that is able to noninvasively read people thought's

Headset Galae will reportedly included multiple sensors

- Electroencephalogram

- Electrooculography

- Electromyography

- Electrodermal activy

- Photoplethysmography

It will gather data not just from the brain but also the eyes, heart, skin, muscles.

The results:

possibility to objectively measure

Horse Care Helps Veterans with PTSD ... https://healthyfamz.com/horse-care-helps-veterans-with-ptsd/?feed_id=2457&_unique_id=6719712f42f05 #BondingActivities #HealthResearch #HealthResearchNews #HealthScience #Medicalresearch #MedicalResearchNews #MedicineScience #Meditation #MentalHealth #Mindfulness #StressManagement

Let's talk to each other in our dreams

Breakthrough from REMspace: First Ever Communication Between People in Dreams

Participants successfully exchanged information through lucid dreams in a groundbreaking experiment by a Silicon Valley startup

October 08, 2024 09:03 AM Eastern Daylight Time

REDWOOD CITY, Calif.--(BUSINESS WIRE)--Researchers at REMspace, a California-based startup, have achieved a historic milestone, demonstrating that lucid dreams could unlock new dimensions of communication and humanity’s potential. Using specially designed equipment, two individuals successfully induced lucid dreams and exchanged a simple message.

Watch the experiment here.

Lucid dreams occur when a person is aware they are dreaming while still in the dream state. This phenomenon happens during REM sleep and has numerous potential applications, from solving physiological problems to learning new skills. In earlier research, REMspace demonstrated that facial electromyography sensors could decode specific sounds made in dreams. This led to the development of Remmyo, a dream language detectable through sensitive sensors.

More at link: https://www.businesswire.com/news/home/20241008878282/en/Breakthrough-from-REMspace-First-Ever-Communication-Between-People-in-Dreams?fbclid=IwY2xjawF5RPZleHRuA2FlbQIxMAABHWyh5FDLy23EBVyfwFYrVQS8tlLP3KamGODDSHCoYeQt8F6iOAaoSIhD7g_aem_OcoWjNVsm5qgUeq1uf676Q

Epilepsy Devices Market: Tech Trends 2022-2028

According to the WHO, epilepsy is a chronic brain disorder that affects 50 million individuals, making it one of the most prevalent neurological conditions worldwide. It is estimated that with access to early detection and appropriate care, 70% of the population diagnosed with epilepsy may live seizure-free. According to our estimates, the global epilepsy devices market was valued at $669.73 million in 2021 and is expected to reach $1157.58 million by 2028, growing at a CAGR of 8.16% during the forecast period 2022-2028.

Government institutions worldwide are focused on starting initiatives to create innovative epilepsy devices with AI and machine learning integration. Additionally, organizations that support research need to encourage high-quality comparative efficacy trials and sufficient data to guide therapeutic practice in epilepsy. As a result of these technologically advanced equipment and increasing drug trials, the market for epilepsy devices is anticipated to grow throughout the forecast period.

Epilepsy Devices - Key Detection Methodologies

Currently, several wearable technologies can detect seizures, collect data, and alert caregivers. Although with technological advancements, the ability to detect seizure-related alterations increases. Top trends backing this tech boom include:

Wearable devices are estimated to be the fastest-growing device type during the forecast period. Monitoring epileptic patients is crucial, as 20% of epileptics only have seizures while asleep, 40% only have seizures while awake, and 35% have seizures both when they are awake and asleep. With technologically advanced non-invasive wearable sensors, measuring accelerometry, photoplethysmography (PPG), electrodermal activity (EDA), electromyography (EMG), and other signals outside of the conventional clinical environment have become effective.

Vagus Nerve Stimulation (VNS) has emerged as the fastest-growing application category. VNS Therapy has been approved by the U.S. Food and Drug Administration (FDA) as an add-on therapy for age 4 years and above to treat drug-resistant epilepsy or refractory epilepsy. VNS has been reportedly beneficial in many patients, including the ones with posttraumatic epilepsy (PTE). PTE is a common consequence of traumatic brain injury and accounts for about 20% of symptomatic epilepsy cases.

As per estimates, Electroencephalography lead the detection and prediction devices type segment in 2021 and is expected to maintain its stronghold during the forecast period. There is growing interest in wearable or mobile EEG solutions that allow long‐term EEG monitoring in an easy‐to‐use format. Despite the availability of these new EEG solutions, their adoption is still limited in clinical practice, mainly because of the unfamiliarity of healthcare and biomedical research sectors with the technology and its application.

Strategic Initiatives and Government Approvals

Different end-users, such as homecare settings, hospitals, and clinics, are utilizing epilepsy devices. The manufacturers of epilepsy monitoring devices are likely to gain prominent business opportunities from the hospital & clinics segment owing to the rise in the use of EEG monitoring and emergency medical services.

The government authorities of several developing nations, including India and China, are focusing on developing sturdy healthcare infrastructure. As a result, operating players are expected to gain sizable growth prospects in the region during the forecast period. Owing to this, the Asia Pacific epilepsy devices market is anticipated to witness the fastest growth with a CAGR of 8.38% throughout the forecast period.

In addition, companies are also focusing on launching novel devices for children. Moreover, companies are also using organic and inorganic strategies, including mergers and acquisitions, to stay ahead of the competition. Some of these include:

In September 2022, Boston Scientific Corporation’s current-generation WATCHMAN FLX™ Left Atrial Appendage Closure (LAAC) Device received U.S. Food and Drug Administration (FDA) approval to expand the instructions for use labeling. The company also received FDA 510(k) clearance for the EMBOLD Fibered Detachable Coil, which reduces the blood flow rate in the peripheral vasculature.

In July 2022, Medtronic PLC received FDA 510(k) clearance for its UNiD Spine Analyzer v4.0 planning platform to leverage machine learning.

In November 2021, NeuroPace, Inc. received an Investigational Device Exemption (IDE) from the FDA to study the company’s RNS System to treat primary generalized epilepsy in patients aged 12 and above.

Way Forward

With technological advancements, epilepsy detection devices with exceptionally low false alarm rates have recently been developed. They are based on computationally intensive algorithms and employed in implanted systems for pre-surgical monitoring. Recent research has produced encouraging findings for probabilistic seizure risk projections using long-term wearable technology and electronic seizure diaries. The symptoms, mood, and cognitive function of an individual may also have predictive significance. Therefore, technological advances in non-invasive wearable sensors are anticipated to create growth opportunities for the epilepsy devices market.

 

FAQ:

Q1) What are the key end-users of the epilepsy devices market?

The key end-users in the epilepsy devices market include hospitals & clinics, neurology centers, homecare settings, and other end-users.

Q2) Which region leads the global epilepsy devices market?

North America leads the global epilepsy devices market.

How Biofeedback Equipment and Training Can Empower You

Feeling stressed, overwhelmed, or out of control of your body’s responses? You’re not alone. Many people struggle with chronic health issues like anxiety, pain, and sleep problems.

Traditional medicine offers valuable solutions, but there’s a growing interest in biofeedback – a powerful tool that empowers you to take charge of your health.

What is Biofeedback?

Biofeedback uses sophisticated equipment to monitor your body’s physiological responses, such as heart rate, muscle tension, and brainwave activity. This information is then translated into real-time feedback, often visual or auditory signals.

Through biofeedback training, you learn to recognize these signals and, with practice, gain control over your physiological responses. It’s like learning a new skill – except the skill is managing your own body’s reactions to stress or discomfort.

Biofeedback Equipment: Your Training Partner

There’s a range of biofeedback equipment available, each designed to measure specific physiological processes.

Electroencephalography (EEG) biofeedback: Monitors brainwave activity, helping manage anxiety, improve focus, and even promote better sleep.

Electromyography (EMG) biofeedback: Measures muscle tension, aiding in pain management, rehabilitation, and reducing tension headaches.

Heart Rate Variability (HRV) monitors: Track variations in heart rate, a key indicator of overall stress levels.

Skin Temperature sensors: Provides information on changes in skin temperature caused by blood vessel constriction caused by stress, or dilation of blood vessels caused by relaxation.

Respiration rate monitors: Gives feedback on breathing patterns which can greatly affect stress and relaxation states.

Biofeedback Training: Your Path to Empowerment

Biofeedback training is a collaborative process guided by a trained therapist or healthcare professional.

More info :  Biofeedback Equipment and Training

How Is Biofeedback Therapy Helping

Biofeedback treatment is a novel approach that uses electronic sensors to monitor and educate people how to control their physiological responses. Biofeedback therapy, which provides real-time input on biological processes such as heart rate, muscular tension, and skin temperature, assists patients in understanding and modifying their bodies' responses to stress. This mind-body connection has been shown to effectively cure chronic pain, anxiety problems, and migraine headaches.

Biofeedback therapy has demonstrated promising outcomes in treating a variety of medical disorders. It can aid in the management of chronic pain by teaching individuals how to regulate their physiological responses, improve symptoms of anxiety disorders by assisting in the recognition and regulation of the body's stress reaction, and reduce the frequency and intensity of migraines by teaching techniques to minimize physiological responses during an attack.

Aside from treating certain ailments, biofeedback therapy has additional benefits. It is non-invasive, making it suitable to those who prefer natural and holistic therapeutic methods. It empowers people by allowing them to regulate their health through self-awareness and self-regulation. Individuals who actively participate in their therapy have a greater grasp of their body's responses and how to influence them.

Biofeedback therapy works by delivering real-time feedback on physical function via electronic sensors that monitor a variety of physiological signs. The feedback might be visual, audible, or tactile, depending on the technique utilized. Individuals can change their body's responses by examining the feedback and using relaxation techniques or other strategies.

There are several biofeedback therapy approaches available to treat a variety of health issues. Electromyography (EMG) biofeedback identifies muscular tension and assists individuals in reducing discomfort and managing stress. Thermal biofeedback monitors fluctuations in skin temperature and can help treat illnesses like Raynaud's disease. Heart rate variability (HRV) biofeedback is used to manage heart rate and can enhance cardiovascular health while also reducing anxiety.

What is an EMG test and Why is an EMG test done? Where can I get an EMG test done?         

The human nervous system is a complex network responsible for transmitting signals between the brain, spinal cord, and muscles. When nerve or muscle disorders arise, doctors often recommend an Electromyography test (EMG) to diagnose the underlying issue. If you are experiencing muscle weakness, numbness, or nerve-related problems, searching for the best diagnostic centre near me for an EMG testing procedure is the first step toward finding answers.

In this blog, we will discuss:

What is an EMG test?

Why is an EMG test done?

How is an EMG test performed?

Where can you get an EMG test done?

What to expect before, during, and after the test?

What is an EMG Test?

An electromyography test (EMG) is a diagnostic procedure that evaluates the health of muscles and the nerve cells (motor neurons) that control them. Motor neurons send electrical signals to the muscles, and an electromyogram (EMG) records these signals to determine if there is any dysfunction.

The test involves inserting thin needle electrodes into specific muscles to measure electrical activity. A related procedure, called nerve conduction study (NCS), is often performed alongside an EMG to analyze how well electrical signals travel through nerves.

Why is an EMG Test Done?

Doctors recommend an EMG test to diagnose a range of conditions affecting the muscles or nerves. Some of the key reasons for undergoing EMG testing include:

1. Muscle Weakness

If you experience unexplained muscle weakness or atrophy, an electromyogram (EMG) can determine whether the issue is related to the muscles themselves or the nerves controlling them.

2. Nerve Damage (Neuropathy)

An EMG test helps detect nerve dysfunction (neuropathy) caused by conditions like diabetes, trauma, or infections. It assesses how well the nerves communicate with the muscles.

3. Neuromuscular Disorders

If a doctor suspects neuromuscular disorders such as amyotrophic lateral sclerosis (ALS), muscular dystrophy, or myasthenia gravis, an EMG testing procedure can help confirm the diagnosis.

4. Carpal Tunnel Syndrome

Repetitive hand and wrist movements can lead to carpal tunnel syndrome, a condition where the median nerve gets compressed. An electromyography test is often used to evaluate nerve function in such cases.

5. Radiculopathy (Pinched Nerves)

Conditions like herniated discs or spinal stenosis can cause nerve compression, leading to pain, numbness, and tingling sensations. An EMG test helps identify the affected nerve roots.

6. Unexplained Muscle Pain or Cramping

If you experience persistent muscle pain, cramping, or spasms without an obvious cause, an EMG test can help pinpoint the problem.

How is an EMG Test Performed?

An electromyography test (EMG) is a two-part procedure that includes:

Nerve Conduction Study (NCS) – Measures the speed and strength of electrical signals traveling through the nerves.

Needle EMG – A thin needle electrode is inserted into a muscle to assess its electrical activity.

Step-by-Step Procedure:

Preparation – The technician cleans the skin and places electrodes over specific muscles or nerves.

Nerve Conduction Study (NCS) – Small electrical pulses stimulate the nerves, and sensors measure their response.

Needle Electrode Insertion – A thin needle electrode is inserted into the muscle to record electrical activity at rest and during movement.

Analysis – The recorded data is analyzed to detect abnormalities in nerve or muscle function.

Where Can You Get an EMG Test Done?

If you are looking for an EMG testing facility, searching for a near by diagnostic centre is the best option. You can also visit Diagnopein near me for state-of-the-art diagnostics.

1. Best Diagnostic Centre Near Me

To ensure accuracy and quality, always choose a best diagnostic centre near me with experienced specialists and advanced medical equipment.

2. Near By Diagnostic Centre

If you want to undergo an EMG test conveniently, look for a near by diagnostic centre that offers this test under expert supervision.

3. Diagnopein Near Me

Diagnopein is a trusted name in diagnostics, providing high-quality electromyography test services with accurate results. If you are searching for Diagnopein near me, you can book an appointment and get tested at their advanced facility.

What to Expect Before, During, and After the EMG Test

Before the Test:

Avoid using lotions or creams on the skin before the test.

Inform your doctor about any medications you are taking.

Wear comfortable clothing that allows easy access to the test areas.

During the Test:

You may feel mild discomfort when the electrode needles are inserted.

The nerve conduction study may cause a slight tingling sensation.

The test usually takes 30 to 60 minutes to complete.

After the Test:

Some soreness at the needle insertion sites is normal.

Resume normal activities unless instructed otherwise by your doctor.

Your doctor will discuss the results and suggest further tests or treatments if needed.

Conclusion

An electromyography test (EMG) is a valuable diagnostic tool for detecting nerve and muscle disorders. Whether you are experiencing muscle weakness, numbness, or unexplained pain, getting an EMG testing procedure done at a best diagnostic centre near me can provide crucial insights into your condition. If you’re searching for Diagnopein near me or a near by diagnostic centre, book an appointment today and take the first step toward better health.

By choosing a reputable diagnostic center for your electromyography test, you ensure accurate results and expert medical guidance to help diagnose and treat neuromuscular conditions effectively.

A1: PERFORMANCE ART WITH NEW MEDIA TECHNOLOGY

Case Study 1: International Artist

For the first case study, I chose Daito Manabe, with a focus on his work named Face Visualizer.

About the Artist

born in 1976

an internationally acclaimed Japanese media artist and programmer

has a background in mathematics and computer science

studied at the Tokyo University of the Arts, developing his skills in interactive art and digital media

his works involve merging technology with various art forms: music, dance, and visual art

known for facial tracking, projection mapping, and custom software development

Deconstructing the Storyline

collaborates with musicians using facial tracking technology

explores the mix of music, visual art and technology, transforming the human face into a canvas to express emotions digitally

fuses electronic music with real-time visualizations generated from facial movements

Performance Tech Rider

facial tracking cameras

projection mapping

custom software interfaces

screen displays

electromyography sensor + electrical stimulation device

New Media Technology Applied

cameras are strategically positioned around the stage to capture the facial expressions from various angles

uses facial tracking technology to capture movements and expressions of the performer’s faces in real-time

uses an electromyography sensor and an electrical stimulation device to copy facial expressions

data is then processed and translated into animations and effects using custom software algorithms

projection mapping techniques are used to project these visualizations onto screens and synchronized with the music in real-time

How does the new media technology improve the concept and stage performance?

new media technology enhances the concept of merging music, visual art, and technology by transforming the human face into a canvas for digital expression

real-time facial tracking technology allows performers to create dynamic visualizations that synchronize with the music, blurring the lines between performer and spectator

How can current case studies be innovative in the future?

incorporating machine learning algorithms could enable more precise tracking of facial movements, allowing for more intricate and responsive visualizations

integrating augmented reality (AR) elements could offer new possibilities for audience interaction, allowing viewers to participate in the performance using their own devices or wearable technology

Face Visualizer by Daito Manabe (click here)

The Future of FitTech: How 5G, Wearables, and AI are Transforming Fitness App Development

The global fitness mobile app developmentmarket is booming, expected to grow at over 13% CAGR to reach $14.7 billion by 2026, according to a study. But as competition intensifies, offering generic workout programs is no longer enough. Users expect fitness apps to act as advanced virtual coaches and provide bespoke guidance based on their changing fitness levels, goals, and preferences.

Source

 5G Connectivity usher in Real-Time Fitness Experiences

The rollout of high-speed 5G networks offers game-changing capabilities for fitness apps compared to 4G or WiFi. For both outdoor and indoor fitness apps, 5G enables an array of real-time use cases not possible before.

Reduced Latency Enables Real-time Tracking and Feedback‍

5G offers sub-1ms latency compared to the 50-100ms latency of 4G networks. This allows fitness apps to provide real-time tracking and feedback without any lags or interruptions. Users can get moment-to-moment updates on running pace, heart rate zones, rep counts, and other metrics during workouts without latency hampering the experience. For example, the Fiit app provides real-time feedback during workouts by leveraging 5G's low latency capabilities. This creates an immersive experience where users feel like they have a virtual personal trainer by their side.

High-definition Streaming for Immersive Fitness‍

5G’s faster bandwidths, ranging from 100 Mbps to 1 Gbps, support high-definition live streaming of workout classes. Apps like FightCamp are using 5G to provide lag-free boxing and HIIT class streaming in up to 8K resolution. This high visual quality, coupled with minimal buffering, results in highly immersive fitness experiences. Additionally, 5G enables Multiplayer VR fitness gaming where groups can participate together in fast-paced VR workouts or training games. Zwift, a popular indoor cycling app, now supports 50 players together in a 5G-powered virtual world. Such interactive experiences will become more mainstream as 5G coverage rises globally.

Image‍

Uninterrupted Tracking for Outdoor Fitness‍

For outdoor activities like running or cycling, 5G allows fitness apps to provide constant biometric tracking and mapping without any drop-offs in connectivity. As users move through different areas, their workout data can be continuously uploaded to the cloud rather than having intermittent gaps. Apps like NURVV Run leverage 5G to offer uninterrupted foot strike analysis and running coaching in real-time. This leads to outdoor fitness experiences where users feel seamlessly connected throughout. As more gyms, stadiums, trails, parks and cities become 5G enabled over the next few years, it will expand the possibilities for creating fitness experiences powered by real-time data.

Wearable Devices for 24/7 Fitness Tracking

Wearable devices have become massively popular for continuous fitness tracking as well as receiving real-time guidance during workouts. According to IDC, shipments of wearable bands and watches will cross 160 million units globally. By seamlessly incorporating wearable tech, fitness apps can tap into a constant stream of biometric data and provide personalized recommendations.

‍Image‍

Enhanced Tracking with Advanced Sensors ‍

Next-generation wearables are equipped with sophisticated sensors to capture comprehensive data on the wearer’s exercise performance, recovery, sleep, and overall health 24/7. For example, the WHOOP 4.0 band uses 5 LEDs for accurate heart rate measurement, an accelerometer, a gyroscope, and a SpO2 sensor to track advanced strain, sleep, and recovery metrics. Deriving such granular data allows fitness apps to offer tailored insights and feedback to the user.

Wearables with electromyography (EMG) sensors, like the Myontec Mbody shorts, can track muscle contractions and exercise intensity. This enables apps to identify imbalances or optimize hypertrophy and strength programs based on an individual’s biomechanics.

Personalized Guidance through Wearable Integration‍

Leading apps like Apple Fitness+, Peloton, Nike Run Club, and MyFitnessPal seamlessly sync up data from wearables to offer customized fitness experiences. Wearable integration allows these apps to: - Provide real-time metrics like heart rate and pacing without needing to glance at the wearable device - Retain workout data like GPS maps, totals stats, and rep counts within the app for post-workout review - Offer tailored workout recommendations and training plans based on the user’s fitness patterns and recovery needs observed through the wearable - Provide form correction, technique analysis, and safety alerts based on real-time data like unstable heart rate or dangerous exercise form

Image‍ As wearables become mainstream, they will be integral to fitness apps, creating personalized experiences driven by users' own quantified biometrics data.

AI and Machine Learning for Adaptive Training

Sophisticated AI is enabling fitness apps to act as smart virtual coaches that customize guidance to each user and adapt plans based on changing fitness levels and goals.

Workout Personalization through ML Recommendation Engines‍

Machine Learning algorithms analyze users’ performance, feedback, goals, and other engagement data to build a fitness apprecommendation engine. These engines suggest tailored workout routines, training plans, gear, playlists, challenges and other features personalized for each user. As apps gather more data over time, their ML models improve, and the level of customization increases. AI can even design entirely new workouts optimized for a user’s needs instead of recommending pre-defined programs.

Image

Intelligent Form Tracking and Correction‍

Computer vision techniques like pose estimation allow apps to track exercise form and provide real-time corrections before injury-causing mistakes become habits. For example, the Paofit app uses AI to analyze exercise repetitions in bodyweight workouts and detect suboptimal techniques. Users get tailored cues like “straighten knees” to improve form. Startups like Forsight use sensor fusion and deep learning on thermal video data to accurately track movement patterns across both sides of the body during rehab exercises. Such intelligent form tracking will be critical to prevent injuries as fitness application development becomes virtual personal trainers.

Motivation through Personalized Insights‍

Leveraging data from wearables and external apps via APIs, fitness platforms can gain a holistic context of users’ health metrics, sleep patterns, nutrition, and more.

Image‍ AI can then derive personalized insights to nudge users and keep them motivated. For example, the fitness social network Strava analyzes runners’ training load and race performances to provide customized training recommendations and predict potential race finish times. As privacy concerns are tackled, the combinatorial power of cross-app data will allow fitness platforms to offer hyper-personalized guidance based on the complete understanding of each user's body, lifestyle, and goals.

The Future: Fitness Experiences Powered by 5G, Wearables and AI

Emerging technologies will work together to redefine fitness mobile app development experiences over the next 5-10 years. Here are some exciting possibilities:

Immersive Fitness Realms with Digital Humans‍

5G coupled with AR, VR, and AI, will enable apps to build your own fitness app worlds where users can have interactive workouts and competitions with virtual coaches, friends, or digital twins of real athletes and trainers. Spatial anchors can map digital assets like weights and instructors persistently into physical spaces for hybrid experiences.

Image‍ For example, Holofitness uses AR to project holograms of trainers who can demonstrate moves from any angle and provide corrections in real-time during workouts. Such immersive fitness realms will make exercising at home as engaging as gym experiences.

Fitness Apps Integrated with Smart Gym Equipment  ‍

Wearables and IoT ecosystems will allow fitness app development solutionsto connect with smart gym equipment to create data-driven workout experiences. Apps can auto-adjust equipment like smart treadmills based on changing heart rate or form breakdown. Biometric data can visualize intensity and output on screens to immerse users in the workout. Post-workout data can be integrated within fitness apps to provide feedback on form, training effect, areas of improvement and to optimize future exercise plans leveraging AI. This will blur the barrier between digital fitness experiences and physical gym equipment.

Image‍

Fitness Apps as Central Health Hubs‍

In the future, fitness mobile app development will evolve into platforms for complete physical and mental health. Users will be able to seamlessly access nutrition planning, telehealth services, sleep tracking, stress management, and well-being features within a single app. Workout recommendations will factor in data across all these dimensions for whole-body optimization. Powerful analytics will provide insights on optimizing longevity, performance, and overall wellness. 

Conclusion‍ Emerging technologies hold enormous potential to transform fitness mobile app development into intelligent and highly personalized virtual coaches. However, there are challenges to building human-centric AI for fitness, including concerns around data privacy, algorithmic bias, and the need to keep users engaged. As 5G, wearables and AI evolve, fitness application developersshould ensure they design experiences that adapt to human needs rather than forcing humans to adapt their behaviors to technology. Fitness app experiences must be joyful, intuitive, and effective at nudging people towards their goals.

At Consagous Technologies, we are at the forefront of building next-gen fitness and health apps powered by data-driven insights. Our fitness application development experts create highly tailored apps that leverage AI and biometrics to provide users with the benefits of virtual coaching and community engagement towards achieving their wellness goals. We focus on an ethical approach to emerging technology, keeping users in control of their data and integrating human wisdom with algorithmic personalization. 

Contact our team to explore how our full-stack capabilities can bring your digital wellness and fitness vision to life with the strategic use of modern tech stacks.

Intraoperative Neurophysiological Monitoring Market Insight, And Market Forecast - 2032

Overview –

The intraoperative neurophysiological monitoring market was valued at USD 1.8 billion in 2022 and is expected to rise from USD 1.96 billion in 2023 to USD 3.86 billion by 2032, with a compound yearly growth rate (CAGR) of 8.9% over the forecast period (2023-2032).

The market for intraoperative neurophysiological monitoring (IONM) is witnessing steady growth due to rising demand for advanced surgical techniques. Neurophysiologic monitoring ensures the safety of patients during complex surgeries involving the nervous system. With technological advancements and increasing awareness, the IONM market is expected to expand further, offering improved patient outcomes.

The Intraoperative Neurophysiological Monitoring Market is growing steadily, driven by the rising importance of neurophysiologic monitoring in surgical procedures. This technology helps surgeons assess the integrity of the nervous system in real-time during operations, reducing the risk of neurological complications. With advancements in monitoring techniques, the market for intraoperative neurophysiological monitoring continues to expand globally.

The neuro intraoperative monitoring market provides crucial insights during surgeries to ensure the safety of patients' nervous systems. With advanced technologies, such as EEG and EMG, surgeons can monitor neural activity in real-time, reducing risks and improving surgical outcomes. This market's growth is driven by rising neurosurgical procedures globally and increasing awareness about intraoperative monitoring's benefits.

The Intraoperative Neurophysiological Monitoring Market is witnessing steady growth, driven by increasing demand for accurate real-time monitoring during surgeries involving the nervous system. This specialized monitoring technique helps surgeons assess the integrity of neural structures, reducing the risk of neurological damage and improving patient outcomes. Technological advancements, such as the integration of advanced sensors and monitoring systems, enhance the precision and reliability of intraoperative neurophysiological monitoring. Rising prevalence of neurological disorders and an aging population contribute to market expansion. However, challenges like the high cost of equipment and the need for specialized training may hinder market growth despite the increasing adoption in neurosurgery and orthopedic procedures.

Segmentation –

The segmentation of the intraoperative neurophysiological monitoring market size is conducted across several parameters, including type, procedure, methods, source, and region. Regarding type, the market is categorized into electromyography, electroencephalography, and evoked potentials. Procedure-wise, segmentation includes otolaryngology surgery, spinal, neurovascular, orthopedic, and urology. Market segmentation based on methods comprises non-invasive, invasive, and minimally invasive techniques. Additionally, the source of intraoperative neurophysiological monitoring is divided into outsourced, in-house, and telehealth services. Geographically, the market spans across Europe, Asia Pacific, North America, the Middle East, and Africa, reflecting the global reach and regional variations in the adoption of neurophysiological monitoring techniques during surgical procedures.

Regional Analysis –

The regional analysis of the intraoperative neurophysiological monitoring (IONM) market encompasses key regions including Europe, Asia Pacific, North America, the Middle East, and Africa. Leading the market is North America, expected to dominate with a significant market share, fueled by rising demand for spinal and cranial procedures due to an increasing patient population. In Europe, the IONM market holds the second-largest share globally, exhibiting robust growth driven by a well-established healthcare sector and growing demand for advanced treatment facilities. The Asia Pacific region presents an attractive market opportunity, driven by a growing number of patients with spinal ailments and a sedentary lifestyle. Increasing government and private sector funding further stimulates market growth by fostering research and development activities.

Key Players –

The market's upward trajectory is attributed to the presence of favorable market dynamics poised to bolster its development. The symbiotic relationship between demand and supply is anticipated to drive market growth in the foreseeable future. Improved synergies in manufacturing processes enhance growth prospects, while the availability of productive resources further propels market advancement. Increased transaction levels are expected to accelerate market growth, while the cultivation of significant competitive advantages fosters market progress. A notable rise in market promoters is projected to offer a favorable outlook for market expansion in the forecast period. Additionally, the relaxation of entry barriers for new players is expected to spur market growth in the years ahead.

Key competitors in the intraoperative neurophysiological monitoring market include Accurate Monitoring LLC, Argos NeuroMonitoring LP, Computational Diagnostics Inc., Emotiv, Inomed Medizintechnik GmbH, Medsurant Holdings LLC, Cadwell Laboratories Inc., Natus Medical Incorporated, NuVasive, Neuro Alert, NuVasive, Neuromonitoring Technologies Inc., NeuroSentinel LLC, Procirca, Propep Surgical, SpecialtyCare, and Sentient Medical Systems.

For more information visit at MarketResearchFuture