A Spectral Editing Technique Based on Optimized Control of Nuclear Spin to Realize Lactate Signal Selection

A Spectral Editing Technique Based on Optimized Control of Nuclear Spin to Realize Lactate Signal Selection

Lactate can provide a large amount of energy to the body to maintain the stability of the cellular nervous system. In medicine, lactate is often used as a signaling molecule to monitor the health level of the body in a timely manner. Accurately and efficiently detecting changes in the content of lac...

Full description

Saved in:
Bibliographic Details
Main Authors: SHAO Zhengze, WANG Xingle, YANG Xue, XIN Jiaxiang, WEI Daxiu, YAO Yefeng
Format: Article
Language:zho
Published: Science Press 2025-03-01
Series:Chinese Journal of Magnetic Resonance
Subjects:
magnetic resonance spectroscopy
optimal control pulse
spectral editing
lactate
Online Access:http://121.43.60.238/bpxzz/article/2025/1000-4556/1000-4556-42-1-1.shtml
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Lactate can provide a large amount of energy to the body to maintain the stability of the cellular nervous system. In medicine, lactate is often used as a signaling molecule to monitor the health level of the body in a timely manner. Accurately and efficiently detecting changes in the content of lactate in living tissues can provide important information about the physiological functions and health status of the organism, and also has certain significance for the early diagnosis of diseases. Several methods for detecting lactate using magnetic resonance spectroscopy techniques have been reported in literature, including long TE filtering technology and multiple quantum filtering technology, which have certain limitations in signal selectivity and efficiency. Here we propose a new method for selectively filtering lactate signals, which uses optimized control pulses to specifically transform the four hydrogen protons on the methyl and methine of lactate molecules into a two-spin Zeeman order, achieving efficient and highly selective detection of the methyl signal of lactate. Using this pulse sequence method, we have successively achieved selective detection of the signals of lactate or similar chemical groups in mixtures and polymer samples. This study provides new ideas and methods for efficiently selecting the signals of lactate in complex systems.
ISSN:1000-4556

Similar Items