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New Light-Based Technique Could Transform Heart Tissue Repair

The AHA! Team — Wed, 05 Mar 2025 06:41:38 +0000

Mass General Brigham via News-Medical – Researchers from Mass General Brigham and collaborating institutions have developed a non-invasive approach to manipulate cardiac tissue activity by using light to stimulate an innovative ink incorporated into bioprinted tissue. Researchers from Mass General Brigham and collaborating institutions have developed a non-invasive approach to manipulate cardiac tissue activity by using light to stimulate an innovative ink incorporated into bioprinted tissue. Their goal is to develop a technique that can be used to repair the heart. Their findings in preclinical models, published in Science Advances, show the transformative potential of non-invasive therapeutic methods to control electrically active tissues. “We showed for the first time that with this optoelectronically active ink, we can print scaffolds that allow remote control of engineered heart tissues. This approach paves the way for non-invasive light stimulation, tissue regeneration, and host integration capabilities in cardiac therapy and beyond.” – Y. Shrike Zhang, PhD, co-corresponding author of the Division of Engineering in Medicine, Brigham and Women’s Hospital Three-dimensional bioprinted tissues composed of cells and other body-compatible materials are a powerful emerging tool to repair damaged heart tissue. But most bioprinted tissues cannot generate the necessary electrical activity for cellular function. They must instead rely on invasive wire and electrode placement to control heart activity, which can damage body tissues. Zhang and his colleagues addressed this limitation by infusing the bioprinted tissue with the “optoelectronically active” ink that can be remotely stimulated by light to generate electrical activity in these tissues. The authors also showed that these new, dynamic engineered tissues can synchronize with and accelerate the heart rate when stimulated by light in preclinical models. “Now that we have established the proof-of-concept for this technology, we are shifting our efforts towards understanding how it might promote long-term tissue regeneration and integrating it seamlessly within the heart’s biology,” said Zhang. Source: Mass General Brigham Journal reference: Ershad, F., et al. (2025) Bioprinted optoelectronically active cardiac tissues. Science Advances. doi.org/10.1126/sciadv.adt7210. To read the original article click here.

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Breakthrough UC San Diego Brain Recording Device Receives FDA Approval for a Clinical Trial

The AHA! Team — Fri, 02 Aug 2024 08:21:00 +0000

University of California San Diego via Newswise – The Federal Drug Administration approved a clinical trial to test the effectiveness of an electronic grid that records brain activity during surgery, developed by engineers at the University of California San Diego. The device with nanoscale sensors records electrical signals directly from the surface of the human brain in record-breaking detail. The grid’s breakthrough resolution could provide better guidance for planning and performing surgeries to remove brain tumors and treat drug-resistant epilepsy. The grid’s higher resolution for recording brain signals could improve neurosurgeons’ ability to minimize damage to healthy brain tissue. During epilepsy surgery, the novel grid could improve the ability to precisely identify the regions of the brain where epileptic seizures originate for safe and effective treatment. The new brain sensor array, known as platinum nanorod grid (PtNRGrid) features a densely packed grid of a record-breaking 1,024 embedded electrocorticography (ECoG) sensors. The device rests on the surface of the brain and is approximately 6 microns thin–smaller than one tenth of the human hair–and flexible. As a result, it can both adhere and conform to the surface of the brain, bending as the brain moves while providing high-quality, high-resolution recordings of brain activity. In contrast, the ECoG grids most commonly used in surgeries today typically have between 16 and 64 sensors. These grids are rigid, stiffer and more than 0.5 mm in thickness and do not conform to the curved surface of the brain. The PtNRGrid was invented by Shadi Dayeh, a Professor in the Department of Electrical and Computer Engineering at the University of California San Diego and members of his team. Over the years, the team developed the PtNRGrid technology in collaboration with neurosurgeons and medical researchers from UC San Diego, Massachusetts General Hospital (MGH) and Oregon Health & Science University (OHSU). “This accomplishment ushers in a new era of clinical neuroscience and neuromonitoring,” Dayeh said. “We are very excited to receive the FDA approval to apply our groundbreaking PtNRGrid in a clinical setting. It is a credit to the hard work of my team members who worked tirelessly to meet the quality criteria mandated by the FDA. I am also grateful to my clinical partners, the support of the NIH, and to the campus leadership that fostered an impactful ecosystem across engineering and medicine to transform the future of healthcare.” The FDA approved an investigational device exemption (IDE) for a “pivotal study [titled] “Systematic Evaluation of Platinum Nanorod Grids (PtNRGrids) for Intraoperative Mapping and Neurophysiological Monitoring (IONM) During Brain Surgeries.” Specifically, the clinical trial is designed to demonstrate the effectiveness of the PtNRGrid device to map both normal and pathological brain activity. During the trial, UC San Diego engineers will partner with clinician-scientists: Drs. Sharona Ben-Haim and Eric Halgren at UC San Diego, Dr. Sydney Cash at MGH, and Dr. Ahmed Raslan at OHSU. In a first phase, surgeons will implant the PtNRGrid in 20 patients, then measure and compare the grid’s performance with the present state-of-the-art. The PtNRGrid will be deployed in surgeries to remove brain tumors and to remove tissue that causes epileptic seizures. Record-breaking density Dayeh’s team has pioneered human brain and spinal cord mapping with thousands of channels since 2019, and has reported early safety and efficacy results in a series of articles published in Science Translational Medicine in 2022 in human subjects. PtNRGrid is the only device with thousands of channels to demonstrate in peer-reviewed publications that it can map motor and language brain activity, as well as epileptic discharges, by producing panoramic videos of brain waves over 10 square centimeters of the brain’s cortex while maintaining resolution at a microscopic level. Currently, Dayeh’s research group holds the world record of recording brain activity from a single cortical grid with 2,048 channels on the surface of the human brain published in Science Translational Medicine in 2022. The device was used in the operating room of Dr. Ahmed Raslan of the OHSU. Since then, the team has increased the number of recording channels to 4,096 and continues to work on increasing the number of channels in the grid to monitor brain activity in even higher resolution. Pending success of this staged trial, the team will transition to the next crucial step of making the PtNRGrid available for commercial use at scale. Demonstrating that ECoG grids with sensors in the thousands of channels record brain activity with high fidelity also opens new opportunities in neuroscience for uncovering a deeper understanding of how the human brain functions. Basic science advances, in turn, could lead to improved treatments grounded in enhanced understanding of brain function. “Our goal is to provide a new atlas for understanding and treating neurological disorders, working with a network of highly experienced clinical collaborators at UC San Diego, MGH, and OHSU,” Dayeh said. Dayeh’s work toward the FDA approval is supported by an NIH BRAIN® Initiative award # UG3NS123723. To read the original article click here.

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Electrical Stimulation Could Restore Vision in Blind People

AHA Publisher — Fri, 10 Jul 2020 07:00:40 +0000

University of Zurich via News-Medical Net – In a project under Horizon 2020, researchers from seven European organizations will examine how the vision of visually impaired people can be restored using electrical stimulation of the brain. The project is being coordinated by the University of Zurich and supported by the European Union with funding of 4 million euros. If a project receives funding from the European Union, it must involve excellent science in innovative and promising interdisciplinary research fields that provide new and relevant ideas for industry and society. The international Neural Active Visual Prosthetics for Restoring Function project meets all these criteria and has been awarded an EU research grant totaling 4 million euros over four years. The project will kick off on 1 September 2020 and is being coordinated by Prof. Shih-Chii Liu at the Institute of Neuroinformatics of the University of Zurich. Working in interdisciplinary teams from seven European universities and institutions with complementary expertise in computational, systems and clinical neuroscience, materials engineering, microsystems design, and deep learning, the project will develop technology to restore the vision of blind people through electrical stimulation of the brain. Close Interdisciplinary Cooperation The aim of the project is to develop a neuroprosthesis with thousands of electrodes driven by adaptive machine learning algorithms for a new brain-computer interfacing technology. “We want to create a novel neuroprosthesis system that is lightweight, robust and portable, and which will remain effective for decades,” explains Shih-Chii Liu. Current systems only stimulate a small set of neurons in the brain, and interfaces have longevity of only a few months. Liu is convinced that the project will succeed in its goals: “All the partners have long-time experience in their respective fields, so the required background knowledge is already in place. The breakthroughs will come with the planned larger-scale efforts and partner interactions in this project.” The challenge will be coordinating the expected breakthroughs across multiple disciplines. Establishing Innovation These breakthroughs include innovative approaches for stimulation with high-electrode-count interfacing with the visual cortex. For this, thin flexible probes are needed that cause minimal tissue damage as well as new electrode coatings and novel microchip methods. The researchers will also channel the stimulation currents to many thousands of electrodes and monitor neuronal activity in higher cortical areas. Breakthroughs are also expected when it comes to artificial neural networks trained by deep learning, which will only extract the most relevant visual information from a camera input to enable blind individuals to recognize objects and facial expressions and navigate through unfamiliar environments. These networks will transform the camera footage into stimulation patterns that drive the neurons in a way that the blind person can interpret. This is the only way that the signals can be processed and passed on. At the same time, eye tracking will be used to improve perception in a closed-loop approach. The Algorithm Translates Stimulation Patterns In addition to coordinating the project, the University of Zurich is also contributing to its technological expertise. The neuroinformatics team of Shih-Chii Liu and Tobi Delbruck will be working with consortium partners to develop power-efficient neuromorphic deep learning hardware and algorithms. The network implemented on the neuromorphic hardware will translate camera input into stimulation patterns to drive the stimulation electrodes. This research project is important because it lays ground-breaking work for constructing a new brain neuroprosthesis and brings added benefits to other neuroprosthesis research.” Shih-Chii Liu, Professor, Institute of Neuroinformatics, University of Zurich The involved researchers hope that the project will raise Europe’s still relatively low profile in this research field. To read the original article click here.

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