Lung cancer is currently the first major cancer that causes the human death. A lung, containing many alveolus, has a very low proton density, so it can not be imaged using the traditional proton MRI. CT and X-ray can be used to image the lungs, however, these techniques are radioactive and can only obtain the structure information of the lungs.
As an inert gas, 129Xe is endowed with high selectivity by functionalized cage molecular, which bridges the ultra high sensitivity of optically-pumped NMR technique to the MRI molecular imaging. We are focused on the broadening of the application range of the Xenon based molecular sensor and even higher NMR sensitivity by further modification of the sensor and development of new NMR/MRI pulse method.
The 129Xe hyperpolarizer can produce hyperpolarized 129Xe gas by the way of spin-exchange optical pumping with high polarization (~3-5 orders of magnitude than the thermal polarization) and high productivity (>0.6 L/h). Hyperpolarized 129Xe gas should be used in the lung and brain MRI for the human and other animals. Based on its special feature, the gas also can be developed in the biosensor.
At present, NMR spectrometers use the radiofrequency (RF) coils for detecting NMR signals. Due to Faraday's law of electromagnetic induction, this method's sensitivity depends badly on the frequency of NMR signal, and it has a poor efficiency of conversion from RF energy to the current or voltage signals in RF coils...
Multimodal molecular imaging can offer a synergistic improvement of diagnostic ability over a single imaging modality. A combination of multifunctional molecular probes such as biomolecules, polymers, and nanoparticles continue to increase functionality for in vivo multimodal imaging and therapeutic agents.
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Venturing into the Summit of Science and Technology!
Six pioneering achievements from the Innovation Academy for Precision Measurement Science and Technology, including the human lung gas MRI system, were presented to the General Secretary Xi for review. President Xin Zhou reported to the General Secretary Xi on site and received his instructions!
The human lung multi-nuclei magnetic resonance imaging technology made significant breakthroughs, winning the Second Prize of the 2023 National Technical Invention Award
Recently, the project "Development of Multi-nuclei Magnetic Resonance Imaging (MRI) Equipment" completed by the group led by Professor Xin Zhou won the second prize of the National Technological Invention Award in 2023.
Topics in Focus: Aspire high and commit to innovation!
Accelerate the achievement of high-level technological self-reliance and self-improvement — Professor Xin Zhou, recipient of the second prize of the 2023 national technical invention award, accepted an interview.
"Facing People's Life and Health" - Hyperpolarized Gas MRI
To carry out the aim of General Secretary Xi "facing people's life and health", group lead by Professor Xin Zhou has made breakthrough in the field of hyperpolarized gas MRI, and made contributions to the development of MR technology in China.
Hyperpolarized Gas MRI of Human Lung
Ultrasensitive Magnetic Resonance Research Group
Our research program involves:
1.Methodologies and techniques of hyperpolarized MRI signal enhancement.
2.Human multi-nuclear MRI instrument development and applications in biomedicine.3.Artificial intelligence enabled ultrasensitive molecular imaging in vivo.
4. Atomic magnetometer and portable MRI.Our group has eight professors, eleven associate professors, four research finance assistants, seven postdoctors.
Innovation Academy for Precision Measurement Science and Technology, CAS.
West No.30 Xiao Hong Shan, Wuhan 430071 China
Tel:+86-27-8719-8631 Fax:+86-27-8719-9291
Email:hanyeqing@wipm.ac.cn
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