Quantification of Chemical Exchange with Low Field T1rho Dispersion MRI

使用低场 T1rho 色散 MRI 定量化学交换

• 批准号: RGPIN-2020-05840
• 负责人: Rioux, James
• 金额: $ 2.11万
• 依托单位: Dalhousie University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=750815
• 关键词: Quantification; Chemical; Exchange; Low; Field

In addition to providing detailed images of anatomy, Magnetic Resonance Imaging (MRI) can also make quantitative maps which provide a more in-depth look at tissue composition, including signs of damage or disease. One physical phenomenon that can be imaged with MRI is chemical exchange between water and molecules such as proteins, which can be affected after a stroke, or during the development process of cancer, Alzheimer's, multiple sclerosis and other neurological disorders. Being able to reliably image such molecular and cellular changes could help improve our understanding of how these diseases appear or worsen over time. One well-established method for measuring chemical exchange is called Chemical Exchange Saturation Transfer, or CEST. CEST can examine exchange processes involving molecules such as proteins that are already in the body, or it can detect specially designed contrast agents that are injected before a scan. The quality of CEST data generally improves as the magnetic field strength increases, meaning that high field (above 3 Tesla) systems are much better suited to CEST than lower field systems (1.5T and below). However, such systems are expensive and rare; most commercial MRI scanners operate at 1.5T, making methods like CEST inaccessible to the majority of sites where it would be the most impactful. The proposed research program will explore an alternate MRI contrast mechanism known as T1? dispersion, to determine how it performs at low magnetic field strength and whether it might serve as a surrogate for CEST. It is already known that T1? dispersion measurements are sensitive to chemical exchange, but they have not been widely used at low field, where they may match or even outperform CEST. We will implement T1? dispersion methods on three different MRI scanners - a 3T clinical system, a 3T preclinical system, and a novel 0.5T scanner developed by Synaptive Medical, a Canadian company. We will then assess which method gives the most reliable information regarding chemical exchange, and which can be acquired in a reasonable amount of time to allow practical applications. The technological advances made possible through this research will benefit basic science throughout Canada and beyond by making chemical exchange contrast imaging more widely accessible. Currently, only those facilities with ultra-high field MRI scanners or access to specialized contrast agents can perform practical CEST imaging. If T1? dispersion can effectively provide the same information as CEST but is more feasible at lower field, this technique can then be deployed onto the hundreds of low-field scanners already in use across the country, as well as novel systems such as the Synaptive 0.5T. This would open up new avenues of research into the biomolecular and cellular underpinnings of malignant neurological processes that would not be limited to a handful of academic research centers but could be carried out on virtually any MRI scanner on the market.

除了提供详细的解剖图像外，磁共振成像(MRI)还可以制作定量地图，提供更深入的组织组成，包括损伤或疾病的迹象。一种可以用核磁共振成像的物理现象是水和蛋白质等分子之间的化学交换，这种交换可能会在中风后或癌症、阿尔茨海默氏症、多发性硬化症和其他神经疾病的发展过程中受到影响。能够可靠地成像这种分子和细胞变化可以帮助我们更好地理解这些疾病是如何随着时间的推移出现或恶化的。一种成熟的测量化学交换的方法被称为化学交换饱和转移，或CEST。CEST可以检查与已在体内的蛋白质等分子有关的交换过程，也可以检测扫描前注射的特殊设计的造影剂。CEST数据的质量通常随着磁场强度的增加而提高，这意味着高场(3特斯拉以上)系统比低场系统(1.5T及以下)更适合CEST。然而，这样的系统既昂贵又罕见；大多数商用核磁共振扫描仪的工作温度为1.5T，使得像CEST这样的方法无法在大多数影响最大的地点使用。拟议的研究计划将探索一种替代的MRI对比机制，称为T1？这项研究旨在确定它在低磁场强度下的表现，以及它是否可以作为CEST的替代品。已知T1？色散测量对化学交换很敏感，但在低场下还没有得到广泛的应用，在低场下它们可能与CEST持平，甚至超过CEST。我们将实施T1？在三种不同的MRI扫描仪上使用分散方法--3T临床系统、3T临床前系统和加拿大Synaptive Medical公司开发的新型0.5T扫描仪。然后，我们将评估哪种方法提供关于化学交换的最可靠信息，以及哪种方法可以在合理的时间内获得实际应用。通过这项研究实现的技术进步将使化学交换对比成像更广泛地获得，从而使整个加拿大乃至更远的地方的基础科学受益。目前，只有那些拥有超高场MRI扫描仪或获得专门造影剂的设施才能进行实用的CEST成像。如果是T1？弥散可以有效地提供与CEST相同的信息，但在低场更可行，这项技术随后可以部署到全国已在使用的数百台低场扫描仪以及诸如Synaptive 0.5T等新系统上。这将为研究恶性神经过程的生物分子和细胞基础开辟新的途径，这不会局限于少数几个学术研究中心，而是可以在市场上几乎任何一台核磁共振扫描仪上进行。