Mind-Controlled Robotic Arm Benefits Paralyzed Patients
By HospiMedica International staff writers Posted on 03 Jul 2019 |
Image: New research suggests mind-controlled robotics can aid the paralyzed (Photo courtesy of CMU).
A noninvasive brain-computer interface (BCI) allows a mind-controlled robotic arm to continuously track and follow a computer cursor, using only thoughts.
Developed by researchers at Carnegie Mellon University (CMU; Pittsburgh, PA, USA) and the University of Minnesota (UMN; Minneapolis, USA), the new BCI facilitates real-time continuous robotic device control by increasing user engagement and spatial resolution of noninvasive neural data through electroencephalogram (EEG) source imaging, accompanied by a continuous pursuit task and an associated training paradigm. In all, the framework enhanced BCI learning by nearly 60% for traditional center-out tasks, and by more than 500% in the more realistic continuous pursuit task.
The researchers further demonstrated an additional enhancement in BCI control of almost 10% by using online noninvasive neuroimaging. The framework was also deployed in a physical task, demonstrating a near-seamless transition from the control of an unconstrained virtual cursor to the real-time control of a robotic arm. The researchers claim that combining advances in the quality of neural decoding with the accessibility of noninvasive robotic arm control will have a major role in the future development and implementation of neurorobotics. The study was published on June 19, 2019, in Science Robotics.
“There have been major advances in mind controlled robotic devices using brain implants. It's excellent science, but noninvasive is the ultimate goal,” said senior author Professor Bin He, PhD, head of the department of biomedical engineering at CMU. “This work represents an important step in noninvasive brain-computer interfaces, a technology which someday may become a pervasive assistive technology aiding everyone, like smartphones.”
Direct electrical stimulation and recording of brain activity requires invasive procedures, such as the removal of a portion of the skull or the drilling of a burr hole. Also, electrode implantation into tissue can cause inflammatory tissue responses and brain trauma, and lead to device failure. A noninvasive counterpart requiring less intervention could profoundly improve the integration of BCIs into the clinical and home setting.
Related Links:
Carnegie Mellon University
University of Minnesota
Developed by researchers at Carnegie Mellon University (CMU; Pittsburgh, PA, USA) and the University of Minnesota (UMN; Minneapolis, USA), the new BCI facilitates real-time continuous robotic device control by increasing user engagement and spatial resolution of noninvasive neural data through electroencephalogram (EEG) source imaging, accompanied by a continuous pursuit task and an associated training paradigm. In all, the framework enhanced BCI learning by nearly 60% for traditional center-out tasks, and by more than 500% in the more realistic continuous pursuit task.
The researchers further demonstrated an additional enhancement in BCI control of almost 10% by using online noninvasive neuroimaging. The framework was also deployed in a physical task, demonstrating a near-seamless transition from the control of an unconstrained virtual cursor to the real-time control of a robotic arm. The researchers claim that combining advances in the quality of neural decoding with the accessibility of noninvasive robotic arm control will have a major role in the future development and implementation of neurorobotics. The study was published on June 19, 2019, in Science Robotics.
“There have been major advances in mind controlled robotic devices using brain implants. It's excellent science, but noninvasive is the ultimate goal,” said senior author Professor Bin He, PhD, head of the department of biomedical engineering at CMU. “This work represents an important step in noninvasive brain-computer interfaces, a technology which someday may become a pervasive assistive technology aiding everyone, like smartphones.”
Direct electrical stimulation and recording of brain activity requires invasive procedures, such as the removal of a portion of the skull or the drilling of a burr hole. Also, electrode implantation into tissue can cause inflammatory tissue responses and brain trauma, and lead to device failure. A noninvasive counterpart requiring less intervention could profoundly improve the integration of BCIs into the clinical and home setting.
Related Links:
Carnegie Mellon University
University of Minnesota
SARS‑CoV‑2/Flu A/Flu B/RSV Sample-To-Answer Test
SARS‑CoV‑2/Flu A/Flu B/RSV Cartridge (CE-IVD)
Latest Patient Care News
- First-Of-Its-Kind Portable Germicidal Light Technology Disinfects High-Touch Clinical Surfaces in Seconds
- Surgical Capacity Optimization Solution Helps Hospitals Boost OR Utilization
- Game-Changing Innovation in Surgical Instrument Sterilization Significantly Improves OR Throughput
- Next Gen ICU Bed to Help Address Complex Critical Care Needs
- Groundbreaking AI-Powered UV-C Disinfection Technology Redefines Infection Control Landscape
- Clean Hospitals Can Reduce Antibiotic Resistance, Save Lives
- Smart Hospital Beds Improve Accuracy of Medical Diagnosis
- New Fast Endoscope Drying System Improves Productivity and Traceability
- World’s First Automated Endoscope Cleaner Fights Antimicrobial Resistance
- Portable High-Capacity Digital Stretcher Scales Provide Precision Weighing for Patients in ER
- Portable Clinical Scale with Remote Indicator Allows for Flexible Patient Weighing Use
- Innovative and Highly Customizable Medical Carts Offer Unlimited Configuration Possibilities
- Biomolecular Wound Healing Film Adheres to Sensitive Tissue and Releases Active Ingredients
- Wearable Health Tech Could Measure Gases Released From Skin to Monitor Metabolic Diseases
- Wearable Cardioverter Defibrillator System Protects Patients at Risk of Sudden Cardiac Arrest
- World's First AI-Ready Infrasound Stethoscope Listens to Bodily Sounds Not Audible to Human Ear