Ultrasound-Assisted Optical Imaging Could Replace Endoscopy
|
By MedImaging International staff writers Posted on 01 Aug 2019 |
|
Image: Ultrasound could soon be used to provide optical images of internal structures (Photo courtesy of Maysam Chamanzar/ CMU).
A new study suggests that ultrasound could be used to optically image internal organs, potentially eliminating the need for invasive visual exams using endoscopic cameras.
Developed by researchers at Carnegie Mellon University (CMU; Pittsburgh, PA, USA), the new technique uses ultrasonic wave patterns to change the local density of the tissues so as to create a graded refractive index pattern in the direction of light propagation, which modulates the phase front of light. Thus causes it to focus within the medium, effectively creating a virtual gradient index (GRIN) lens relay. The virtual GRIN lens can be moved around simply by reconfiguring the ultrasound wave patterns from outside the body, enabling the imaging of different target regions, all noninvasively.
The focal distance and the numerical aperture of the sculpted optical GRIN lens can also be tuned, by changing the ultrasonic wave parameters. The researchers demonstrate that the virtual GRIN lens can resolve small features (22 µm) even through a turbid medium (which is normally opaque), continuously scanning over a depth of 5.4 mm in the modulated medium. The researchers claim the technology could eventually be implemented in the form of a handheld device or wearable surface patch that images the brain or under the skin. The study was published on July 17, 2019, in Light: Science and Applications.
“Being able to relay images from organs such as the brain without the need to insert physical optical components will provide an important alternative to implanting invasive endoscopes in the body,” said co-lead author Maysam Chamanzar, PhD. “We used ultrasound waves to sculpt a virtual optical relay lens within a given target medium, which for example, can be biological tissue. Therefore, the tissue is turned into a lens that helps us capture and relay the images of deeper structures. This method can revolutionize the field of biomedical imaging.”
“Turbid media have always been considered obstacles for optical imaging, but we have shown that such media can be converted to allies to help light reach the desired target,” said co-lead author PhD student Matteo Giuseppe Scopelliti, MSc. “When we activate ultrasound with the proper pattern, the turbid medium becomes immediately transparent. It is exciting to think about the potential impact of this method on a wide range of fields, from biomedical applications to computer vision.”
GRIN lenses do not require an air gap to function since the operation of the lens is due to varying indices in the lens itself, rather than the difference in indices between the air and lens. Additionally, in a GRIN lens, all optical paths are the same due to the radially varying refractive index, in contrast to a spherical or aspheric lens.
Related Links:
Carnegie Mellon University
Developed by researchers at Carnegie Mellon University (CMU; Pittsburgh, PA, USA), the new technique uses ultrasonic wave patterns to change the local density of the tissues so as to create a graded refractive index pattern in the direction of light propagation, which modulates the phase front of light. Thus causes it to focus within the medium, effectively creating a virtual gradient index (GRIN) lens relay. The virtual GRIN lens can be moved around simply by reconfiguring the ultrasound wave patterns from outside the body, enabling the imaging of different target regions, all noninvasively.
The focal distance and the numerical aperture of the sculpted optical GRIN lens can also be tuned, by changing the ultrasonic wave parameters. The researchers demonstrate that the virtual GRIN lens can resolve small features (22 µm) even through a turbid medium (which is normally opaque), continuously scanning over a depth of 5.4 mm in the modulated medium. The researchers claim the technology could eventually be implemented in the form of a handheld device or wearable surface patch that images the brain or under the skin. The study was published on July 17, 2019, in Light: Science and Applications.
“Being able to relay images from organs such as the brain without the need to insert physical optical components will provide an important alternative to implanting invasive endoscopes in the body,” said co-lead author Maysam Chamanzar, PhD. “We used ultrasound waves to sculpt a virtual optical relay lens within a given target medium, which for example, can be biological tissue. Therefore, the tissue is turned into a lens that helps us capture and relay the images of deeper structures. This method can revolutionize the field of biomedical imaging.”
“Turbid media have always been considered obstacles for optical imaging, but we have shown that such media can be converted to allies to help light reach the desired target,” said co-lead author PhD student Matteo Giuseppe Scopelliti, MSc. “When we activate ultrasound with the proper pattern, the turbid medium becomes immediately transparent. It is exciting to think about the potential impact of this method on a wide range of fields, from biomedical applications to computer vision.”
GRIN lenses do not require an air gap to function since the operation of the lens is due to varying indices in the lens itself, rather than the difference in indices between the air and lens. Additionally, in a GRIN lens, all optical paths are the same due to the radially varying refractive index, in contrast to a spherical or aspheric lens.
Related Links:
Carnegie Mellon University
X-Ray Illuminator
X-Ray Viewbox Illuminators
New
HF Stationary X-Ray Machine
TR20G
Ultrasound Table
Women’s Ultrasound EA Table
Ultra-Flat DR Detector
meX+1717SCC
Latest Ultrasound News
- Tiny Magnetic Robot Takes 3D Scans from Deep Within Body
- High Resolution Ultrasound Speeds Up Prostate Cancer Diagnosis
- World's First Wireless, Handheld, Whole-Body Ultrasound with Single PZT Transducer Makes Imaging More Accessible
- Artificial Intelligence Detects Undiagnosed Liver Disease from Echocardiograms
- Ultrasound Imaging Non-Invasively Tracks Tumor Response to Radiation and Immunotherapy
- AI Improves Detection of Congenital Heart Defects on Routine Prenatal Ultrasounds
- AI Diagnoses Lung Diseases from Ultrasound Videos with 96.57% Accuracy
- New Contrast Agent for Ultrasound Imaging Ensures Affordable and Safer Medical Diagnostics
- Ultrasound-Directed Microbubbles Boost Immune Response Against Tumors
- POC Ultrasound Enhances Early Pregnancy Care and Cuts Emergency Visits
- AI-Based Models Outperform Human Experts at Identifying Ovarian Cancer in Ultrasound Images
- Automated Breast Ultrasound Provides Alternative to Mammography in Low-Resource Settings
- Transparent Ultrasound Transducer for Photoacoustic and Ultrasound Endoscopy to Improve Diagnostic Accuracy
- Wearable Ultrasound Patch Enables Continuous Blood Pressure Monitoring
- AI Image-Recognition Program Reads Echocardiograms Faster, Cuts Results Wait Time
- Ultrasound Device Non-Invasively Improves Blood Circulation in Lower Limbs
Channels
Radiography
view channel
AI-Powered Imaging Technique Shows Promise in Evaluating Patients for PCI
Percutaneous coronary intervention (PCI), also known as coronary angioplasty, is a minimally invasive procedure where small metal tubes called stents are inserted into partially blocked coronary arteries... Read more
Higher Chest X-Ray Usage Catches Lung Cancer Earlier and Improves Survival
Lung cancer continues to be the leading cause of cancer-related deaths worldwide. While advanced technologies like CT scanners play a crucial role in detecting lung cancer, more accessible and affordable... Read more
MRI
view channel
Ultra-Powerful MRI Scans Enable Life-Changing Surgery in Treatment-Resistant Epileptic Patients
Approximately 360,000 individuals in the UK suffer from focal epilepsy, a condition in which seizures spread from one part of the brain. Around a third of these patients experience persistent seizures... Read more
AI-Powered MRI Technology Improves Parkinson’s Diagnoses
Current research shows that the accuracy of diagnosing Parkinson’s disease typically ranges from 55% to 78% within the first five years of assessment. This is partly due to the similarities shared by Parkinson’s... Read more
Biparametric MRI Combined with AI Enhances Detection of Clinically Significant Prostate Cancer
Artificial intelligence (AI) technologies are transforming the way medical images are analyzed, offering unprecedented capabilities in quantitatively extracting features that go beyond traditional visual... Read more
First-Of-Its-Kind AI-Driven Brain Imaging Platform to Better Guide Stroke Treatment Options
Each year, approximately 800,000 people in the U.S. experience strokes, with marginalized and minoritized groups being disproportionately affected. Strokes vary in terms of size and location within the... Read moreNuclear Medicine
view channel
Novel PET Imaging Approach Offers Never-Before-Seen View of Neuroinflammation
COX-2, an enzyme that plays a key role in brain inflammation, can be significantly upregulated by inflammatory stimuli and neuroexcitation. Researchers suggest that COX-2 density in the brain could serve... Read more
Novel Radiotracer Identifies Biomarker for Triple-Negative Breast Cancer
Triple-negative breast cancer (TNBC), which represents 15-20% of all breast cancer cases, is one of the most aggressive subtypes, with a five-year survival rate of about 40%. Due to its significant heterogeneity... Read more
General/Advanced Imaging
view channel
AI-Powered Imaging System Improves Lung Cancer Diagnosis
Given the need to detect lung cancer at earlier stages, there is an increasing need for a definitive diagnostic pathway for patients with suspicious pulmonary nodules. However, obtaining tissue samples... Read more
AI Model Significantly Enhances Low-Dose CT Capabilities
Lung cancer remains one of the most challenging diseases, making early diagnosis vital for effective treatment. Fortunately, advancements in artificial intelligence (AI) are revolutionizing lung cancer... Read more
Imaging IT
view channel
New Google Cloud Medical Imaging Suite Makes Imaging Healthcare Data More Accessible
Medical imaging is a critical tool used to diagnose patients, and there are billions of medical images scanned globally each year. Imaging data accounts for about 90% of all healthcare data1 and, until... Read more
Global AI in Medical Diagnostics Market to Be Driven by Demand for Image Recognition in Radiology
The global artificial intelligence (AI) in medical diagnostics market is expanding with early disease detection being one of its key applications and image recognition becoming a compelling consumer proposition... Read more
Industry News
view channel
GE HealthCare and NVIDIA Collaboration to Reimagine Diagnostic Imaging
GE HealthCare (Chicago, IL, USA) has entered into a collaboration with NVIDIA (Santa Clara, CA, USA), expanding the existing relationship between the two companies to focus on pioneering innovation in... Read more
Patient-Specific 3D-Printed Phantoms Transform CT Imaging
New research has highlighted how anatomically precise, patient-specific 3D-printed phantoms are proving to be scalable, cost-effective, and efficient tools in the development of new CT scan algorithms... Read more
Siemens and Sectra Collaborate on Enhancing Radiology Workflows
Siemens Healthineers (Forchheim, Germany) and Sectra (Linköping, Sweden) have entered into a collaboration aimed at enhancing radiologists' diagnostic capabilities and, in turn, improving patient care... Read more