Double-Contrast MRI Technique Identifies Small Tumors
|
By MedImaging International staff writers Posted on 17 Jun 2020 |
|
A new study shows how two-way magnetic resonance tuning (TMRET) can help explore a variety of biological processes via magnetic resonance imaging (MRI).
Developed by researchers at Shanghai Jiaotong University (China), the University of California Davis (UCD; USA), Stanford University (CA, USA), and other institutions, the TMRET nanoprobe contains nanoparticles of superparamagnetic iron oxide (SPIO) and pheophorbide a-paramagnetic manganese (P-Mn), packaged together in a lipid envelope. Both SPIO and P-Mn give strong, separate signals on MRI, but as long as they are physically close together those signals tend to cancel each other out. When the particles enter tumor tissue, the fatty envelope breaks down, SPIO and P-Mn separate, and both signals appear.
When coupled with a dual-contrast enhanced subtraction imaging (DESI) algorithm, the integrated platform achieves substantially improved contrast enhancement (as compared to fluorescence-based Förster resonance energy transfer). The researchers tested the method in cultures of brain and prostate cancer cells and in mice. With the aid of the TMRET nanoprobe, they achieved a tumor-to-normal ratio as high as 10, which is almost five-fold higher than current methods. The study was published on May 25, 2020, in Nature Nanotechnology.
“This integrated platform achieves a substantially improved contrast enhancement with minimal background signal and can be used to quantitatively image molecular targets in tumors and to sensitively detect very small intracranial brain tumors in patient-derived xenograft models,” said senior author biochemist Yuanpei Li, PhD, of UCD. “The high tumor-to-normal tissue ratio offered by TMRET, in combination with DESSI, provides new opportunities for molecular diagnostics and image-guided biomedical applications.”
Distance-dependent magnetic resonance tuning (MRET) technology enables sensing and quantitative imaging of biological targets in vivo, with the advantage of deep tissue penetration and fewer interactions with the surroundings tissues. However, applications of MRET technology in vivo are currently limited by the moderate contrast enhancement and stability of T1-based MRET probes.
Related Links:
Shanghai Jiaotong University
University of California Davis
Stanford University
Developed by researchers at Shanghai Jiaotong University (China), the University of California Davis (UCD; USA), Stanford University (CA, USA), and other institutions, the TMRET nanoprobe contains nanoparticles of superparamagnetic iron oxide (SPIO) and pheophorbide a-paramagnetic manganese (P-Mn), packaged together in a lipid envelope. Both SPIO and P-Mn give strong, separate signals on MRI, but as long as they are physically close together those signals tend to cancel each other out. When the particles enter tumor tissue, the fatty envelope breaks down, SPIO and P-Mn separate, and both signals appear.
When coupled with a dual-contrast enhanced subtraction imaging (DESI) algorithm, the integrated platform achieves substantially improved contrast enhancement (as compared to fluorescence-based Förster resonance energy transfer). The researchers tested the method in cultures of brain and prostate cancer cells and in mice. With the aid of the TMRET nanoprobe, they achieved a tumor-to-normal ratio as high as 10, which is almost five-fold higher than current methods. The study was published on May 25, 2020, in Nature Nanotechnology.
“This integrated platform achieves a substantially improved contrast enhancement with minimal background signal and can be used to quantitatively image molecular targets in tumors and to sensitively detect very small intracranial brain tumors in patient-derived xenograft models,” said senior author biochemist Yuanpei Li, PhD, of UCD. “The high tumor-to-normal tissue ratio offered by TMRET, in combination with DESSI, provides new opportunities for molecular diagnostics and image-guided biomedical applications.”
Distance-dependent magnetic resonance tuning (MRET) technology enables sensing and quantitative imaging of biological targets in vivo, with the advantage of deep tissue penetration and fewer interactions with the surroundings tissues. However, applications of MRET technology in vivo are currently limited by the moderate contrast enhancement and stability of T1-based MRET probes.
Related Links:
Shanghai Jiaotong University
University of California Davis
Stanford University
Wall Fixtures
MRI SERIES
Portable Color Doppler Ultrasound Scanner
DCU10
Portable X-ray Unit
AJEX140H
Portable Color Doppler Ultrasound System
S5000
Latest MRI News
- AI Tool Tracks Effectiveness of Multiple Sclerosis Treatments Using Brain MRI Scans
- Ultra-Powerful MRI Scans Enable Life-Changing Surgery in Treatment-Resistant Epileptic Patients
- AI-Powered MRI Technology Improves Parkinson’s Diagnoses
- Biparametric MRI Combined with AI Enhances Detection of Clinically Significant Prostate Cancer
- First-Of-Its-Kind AI-Driven Brain Imaging Platform to Better Guide Stroke Treatment Options
- New Model Improves Comparison of MRIs Taken at Different Institutions
- Groundbreaking New Scanner Sees 'Previously Undetectable' Cancer Spread
- First-Of-Its-Kind Tool Analyzes MRI Scans to Measure Brain Aging
- AI-Enhanced MRI Images Make Cancerous Breast Tissue Glow
- AI Model Automatically Segments MRI Images
- New Research Supports Routine Brain MRI Screening in Asymptomatic Late-Stage Breast Cancer Patients
- Revolutionary Portable Device Performs Rapid MRI-Based Stroke Imaging at Patient's Bedside
- AI Predicts After-Effects of Brain Tumor Surgery from MRI Scans
- MRI-First Strategy for Prostate Cancer Detection Proven Safe
- First-Of-Its-Kind 10' x 48' Mobile MRI Scanner Transforms User and Patient Experience
- New Model Makes MRI More Accurate and Reliable
Channels
Radiography
view channel
World's Largest Class Single Crystal Diamond Radiation Detector Opens New Possibilities for Diagnostic Imaging
Diamonds possess ideal physical properties for radiation detection, such as exceptional thermal and chemical stability along with a quick response time. Made of carbon with an atomic number of six, diamonds... Read more
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
Ultrasound
view channel
AI Identifies Heart Valve Disease from Common Imaging Test
Tricuspid regurgitation is a condition where the heart's tricuspid valve does not close completely during contraction, leading to backward blood flow, which can result in heart failure. A new artificial... Read more
Novel Imaging Method Enables Early Diagnosis and Treatment Monitoring of Type 2 Diabetes
Type 2 diabetes is recognized as an autoimmune inflammatory disease, where chronic inflammation leads to alterations in pancreatic islet microvasculature, a key factor in β-cell dysfunction.... Read more
Nuclear 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