Articles tagged with Ultrasound
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Researchers created a miniaturized ultrasound system that can be used at home or in doctors' offices to scan people at high risk of breast cancer. The new system detects tumors earlier, increasing the chances of successful treatment.
Researchers have developed a natural solid gel pad made from tamarind seed gum, offering improved image quality and patient comfort compared to conventional liquid gel. The new gel pad's self-moisturizing property ensures stable acoustic coupling and enhanced ultrasound image quality.
Scientists have developed a new technique that combines rotational ultrasound tomography (RUST) with photoacoustic tomography (PAT) to create 3D color images of soft tissues and blood vessel function. This method has the potential to enhance breast tumor imaging, monitor nerve damage caused by diabetes, and brain imaging.
Steatotic liver disease can be precisely assessed using three-dimensional ultrafast vascular ultrasound. The technology visualizes subtle microvascular changes, enabling real-time monitoring of disease progression and therapeutic response.
Researchers developed an innovative noninvasive technique that combines ultrasound and photoacoustic imaging to capture images of both tissue and blood vessels. The technology has the potential to address current gaps in medical imaging, providing faster and more comprehensive imaging at meaningful depths.
Boston College researchers used piezoelectric nanoparticles to trigger macrophages, a key part of the body's immune response. The study suggests that this method could be used to activate immune cells specifically at an infection or tumor site, avoiding side effects associated with systemic administration of drugs.
Researchers propose a roadmap for using transcranial focused ultrasound to study consciousness, enabling precise manipulation of brain activity and determining cause-and-effect patterns. This technology may help address the hard problem of consciousness by probing neural circuits that generate sensations, thoughts, and feelings.
Researchers developed ultrasound-responsive in-situ antigen nanocatchers that efficiently capture tumor antigens, activating dendritic cell maturation and migration. This system achieved high primary tumor inhibition rates and complete distant tumor regression in a mouse model, providing a universal personalized immunotherapy platform.
The researchers created a new ultrasound technology that can clearly visualize blood vessels deep inside the human body in three dimensions without using contrast agents or radiation. This innovation is expected to significantly improve medical imaging safety and accessibility.
The research team developed 'ULM-Lite,' a new analysis method that retains essential information from ultrasound signals, significantly reducing data size and increasing processing speeds. This technology enables clear visualization of the entire brain non-invasively without requiring surgery or fluorescent materials.
A new study uses ultrasound to detect vascular complications from cosmetic fillers, such as absent blood flow to perforator vessels. Clinicians can now target exact areas for treatment, reducing the need for blind injections and minimizing complications like blindness and stroke.
The Mount Sinai Hospital is now using an FDA-approved AI tool that enhances fetal ultrasound screenings for congenital heart defects. The AI tool improved detection rates of suspicious findings to over 97%, while also reducing reading time and increasing confidence scores.
A new study found that hospitals with early ultrasound protocols detected 40% of major fetal anomalies before 16 weeks of pregnancy, compared to 28% in hospitals without such protocols. This suggests that systematic first trimester screening could improve the timeliness of anomaly detection across the population.
Researchers at Columbia University Irving Medical Center have successfully used focused ultrasound to open the blood-brain barrier in three children with diffuse midline glioma, a rare and aggressive brain cancer. The technique allowed chemotherapy drugs to reach tumors, leading to some improvement in patient mobility.
Researchers at Virginia Tech's Fralin Biomedical Research Institute are studying how fluid flow contributes to the spread of glioblastoma tumors. They will use focused ultrasound and advanced MRI techniques to build a map of fluid flow in the whole brain and test the effectiveness of drug delivery.
A new study aimed to standardize POCUS education, leading to more physician trainees learning the technique. The research found consensus on over 50 essential skills and teaching methods, promoting better patient care with faster diagnosis times.
A new report from Northwestern University offers six practical strategies to improve the doctor-patient bedside encounter in an era dominated by AI. By employing these strategies, clinicians can strengthen patient-physician relationships, combat inequities, and reduce burnout, ultimately leading to better patient outcomes.
A nonsurgical approach has been demonstrated to quiet a specific brain circuit in an animal model by delivering engineered gene therapy only to the targeted region. The method uses low-intensity focused ultrasound to open the blood-brain barrier, allowing precise control over brain activity without impacting off-target areas.
A study published in The New England Journal of Medicine found that nearly 4 million children and adolescents were at higher risk of developing blood cancers due to radiation exposure from medical imaging. The researchers estimated that up to 10% of pediatric blood and bone marrow cancers may be attributable to radiation exposure.
Researchers found that patients have more confidence in autonomous robotic ultrasound systems when an avatar guides them through the process. The virtual agent explains what it is doing and answers questions in any language.
A novel ultrasound method, SAVES, shows promise for safer vein access in critically ill patients by visualizing both the artery and vein simultaneously. This technique demonstrated a 100% success rate without serious complications.
A Rutgers and RWJBarnabas Health study found that portable ultrasounds can lead to better diagnoses, shorter hospital stays, and significant cost savings. The technology requires additional training and workflow integration to be widely adopted.
The research team has developed a velocity-constrained Kalman filtering algorithm that improves microbubble tracking accuracy, maps spatial distribution and movement direction of microvascular networks, and quantifies changes in blood flow speed. The technology also addresses challenges like motion compensation and low frame rates.
A new ultrasound-based tool has shown high accuracy in detecting suspected meningitis in newborns and infants, offering a non-invasive alternative to traditional lumbar puncture. The device can correctly classify 17 out of 18 meningitis cases and detect high white blood cell levels with approximately 94% sensitivity.
Studies have shown that emotional or psychological stress enhances pain responses, but the effects of social pain transmission remain elusive. Researchers found that ultrasonic vocalizations emitted by mice in response to pain stimuli can induce emotional transmission and hyperalgesia in other mice.
A new deep learning model enhances handheld 3D medical imaging by automatically tracking transducer motion without external sensors. The model produces more realistic 3D US images and can reconstruct blood vessel structures using ultrasound and photoacoustic data.
Scientists developed a method to use ultrasound to chemically activate drugs, selectively targeting tumors and stimulating immune cells. This approach achieved a 99% tumor suppression rate in colon cancer models without harming healthy tissues.
A new device created by USC biomedical engineers could help sufferers avoid the need for opioids. The UIWI stimulator is designed to provide real-time, personalized pain management through machine learning algorithms and wireless power supply.
A team of scientists from Colorado State University and the University of São Paulo have developed a seismological solution to improve the resolution of ultrasound images for lung monitoring. This breakthrough could lead to improved critical care for patients, including continuous lung monitoring at the bedside. The technique uses seis...
Researchers have developed a technique to create spin in liquid droplets using ultrasound waves, concentrating solid particles suspended in the liquid. This allows for the creation of novel technologies for biomedical applications and research on rotating systems.
Researchers at Mass General Brigham have pinpointed a 'sweet spot' for focused ultrasound treatment to provide significant relief from essential tremor. The study identified a specific subregion of the brain's thalamus that can result in optimal and long-lasting tremor improvements while reducing side effects. With this breakthrough, p...
Researchers have developed a technique for in vivo 3D printing of polymers using sound localization, which can be used for drug delivery, tissue repair, and internal wound sealing. The new method, called deep tissue in vivo sound printing (DISP), has been successfully tested in mice and shows promising results.
University of Virginia researcher Natasha D. Sheybani has received a $5.5 million grant to advance her research on focused ultrasound technology for breast cancer immunotherapy. Her work aims to enhance the safety, effectiveness, and precision of immunotherapy drugs.
A pioneering study demonstrated that an AI-powered lung ultrasound surpasses human experts by 9% in diagnosing pulmonary tuberculosis. The technology leverages deep learning algorithms to interpret lung ultrasound images in real-time, making it more accessible for TB triage, especially for minimally trained healthcare workers.
Natasha Diba Sheybani, a UVA researcher, has received a $5.5 million grant to develop safer and more precise breast cancer treatments using focused ultrasound technology. Her work aims to overcome key bottlenecks in current treatments and improve patient outcomes.
Researchers at Pohang University of Science & Technology and Jeonbuk National University successfully trapped mechanical waves within a single resonator, overcoming a century-old physics barrier. The discovery opens new possibilities for energy harvesting, ultra-sensitive sensors, and advanced communications.
Researchers used ULM to monitor pancreatic microvasculature in a rat model, tracking microbubble trajectories and quantifying vascular parameters. Anti-cytokine immunotherapy showed significant improvements in vascular structure and function, suggesting its potential to restore β-cell function.
A team of scientists has developed a new ultrasound technique called nonlinear sound sheet microscopy that images specifically labelled cells in 3D with ultrasound. This method allows for non-invasive imaging of whole organs and provides information about how cells behave in their natural environment.
Researchers at USC Viterbi have developed a new type of immune cell that can sense and destroy cancer cells for extended periods using focused ultrasound. This technology could overcome obstacles in treating tumors with immunotherapy while keeping healthy tissue safe.
The device uses AI technology to detect potential heart problems and provides real-time health insights. It has multiple points touching the skin near the heart, allowing for more accurate tracking even during movement.
Researchers developed a tiny magnetic robot that can take 3D scans from deep within the body, enabling 'virtual biopsies' for non-invasive cancer diagnosis and treatment. The device uses high-frequency imaging to create detailed 3D reconstructions, allowing clinicians to diagnose and treat colorectal cancer in a single procedure.
The study reveals that muscle fibers shorten as forces increase during fast hopping, allowing for faster motion. This counterintuitive behavior enhances leg stiffness, which could impact sports training, rehabilitation, and robotics.
A new study has shown that high-resolution ultrasound can diagnose prostate cancer as effectively as MRI, with improved resolution and lower costs. The technology, called micro-ultrasound, is expected to speed up diagnosis, reduce hospital visits, and make imaging more accessible, particularly in less developed healthcare systems.
A new study has developed CoLDiT, a conditional latent diffusion model capable of generating high-resolution breast ultrasound images. The model achieved comparable performance to real images in BI-RADS classification and realism evaluation, while safeguarding patient privacy through nearest neighbor analysis.
Flexible micromachined ultrasound transducers (MUTs) enable continuous monitoring and targeted stimulation due to their conforming ability, reducing diagnostic errors and operator variability. The study explores fabrication methods, performance benchmarks, and potential applications of these devices.
A new study by Rice University and Vanderbilt University researchers found that combining focused ultrasound with the existing protein therapy TRAIL can significantly reduce tumor size and burden in prostate cancer models. The therapy works by amplifying the anticancer effects of TRAIL via Piezo1 activation, which triggers cell death.
Increasing the spacing between integrin-ECM binding domains on the extracellular matrix can boost the efficiency of ultrasound treatment applied to kill cancer cells. A new study found that this increased spacing triggers myosin forces, pumps more calcium inside, and promotes cell death.
A new study found that babies show positive responses to the smell of foods they were exposed to in the womb after birth. Newborns whose mothers had taken carrot powder capsules reacted favourably to the smell of carrot, while those whose mothers had taken kale powder capsules reacted more positively to the scent of kale.
Researchers from The Mount Sinai Hospital analyzed an AI system to detect heart defects on fetal ultrasound exams, finding it significantly improved detection rates. The study aimed to improve prenatal detection of congenital heart defects, a leading cause of infant morbidity and mortality.
A new study suggests that AI can significantly improve a clinician's ability to detect cases suspicious for congenital heart defects, regardless of their experience or training. The AI system also increased confidence levels and reduced diagnosis time among clinicians.
A new algorithm proposes measuring quadriceps muscle mass for more accurate sarcopenia diagnosis, potentially leading to earlier detection and better treatment options. Ultrasound imaging is recommended as a cost-effective and practical solution for diagnosing sarcopenia in clinical settings.
A multicenter study shows trained health professionals with AI assistance can meet diagnostic standards for lung ultrasounds. This technology has the potential to increase access to lung ultrasound in areas without expert personnel.
Concordia researchers propose a novel method using ultrasound-guided microbubbles to stimulate critical cytokine secretion in T cells, potentially re-activating them and increasing the release of proteins needed to fight cancer. The approach could complement existing treatments and improve outcomes.
A University of Minnesota Medical School study found that implementing point-of-care ultrasounds in the first trimester enhances care for pregnant patients and reduces emergency visits. This integrated approach allows comprehensive care during a single visit, improving diagnosis and patient outcomes.
A new study published in Nature Medicine shows that AI-based models can accurately identify ovarian cancer in ultrasound images, achieving an accuracy rate of 86.3%. The models also reduce the need for expert referrals and misdiagnosis rates by 63% and 18%, respectively.
Researchers developed an ultra-compact transparent ultrasonic transducer for simultaneous high-resolution ultrasound and photoacoustic imaging. This technology improves diagnostic sensitivity by providing detailed information about tissue vasculature, thereby enhancing early cancer detection.
Artificial intelligence is enhancing breast cancer risk prediction through mammographic analysis, uncovering key features that predict breast cancer risk. These AI-generated features may inform personalized screening strategies, such as more frequent or less frequent screenings for women at high or low risk of breast cancer.
Engineers at USC Viterbi School of Engineering have developed a new CRISPR toolkit that allows for precise, remote-controlled genome editing using focused ultrasound. This breakthrough enables the treatment of various genetic disorders and diseases by activating or silencing specific genes with precision.
A new approach to first trimester obstetrical care combining point-of-care ultrasound and immediate multidisciplinary care has reduced emergency visits by 81%. This integration allows for timely diagnosis of abnormal pregnancies, improved education and support for all patients, including those experiencing miscarriage.
A team of researchers at the University of California San Diego has developed a clinically validated, wearable ultrasound patch for continuous and noninvasive blood pressure monitoring. The device offers precise, real-time readings of blood pressure deep within the body, providing detailed trends in blood pressure fluctuations.