Ischemic stroke is a major health problem worldwide. In the United States, it is the fourth leading cause of death and the leading cause of major disability. It is estimated that more than 700,000 Americans experience new or recurrent stroke each year. Perfusion imaging plays an important role in virtually all stages of stroke and related cerebrovascular diseases. At present, most clinical perfusion imaging requires the use of contrast agents, e.g. gadolinium (Gd) in MRI. However, Gd perfusion MRI cannot be used or fails to be used in 10-20% of patients, due to a variety of reasons, such as allergic reactions, low glomerular filtration rate, difficulties in placing an intravenous line that is suitable for a rapid injection, or human errors in the timing of injection. Therefore, an alternative technique to Gd-perfusion will benefit a substantial number of patients in clinical practice. Arterial Spin Labeling (ASL) MRI allows for non-contrast evaluation of cerebral blood flow (CBF). However, in its current form, it cannot provide information equivalent to that obtained by contrast-agent-based perfusion imaging. This is because CBF is of limited value in stroke delineation. The most useful parameter in Gd- perfusion is Tmax or bolus-arrive-time (BAT), yet they cannot be measured reliably with current ASL methods. This application will develop a novel non-contrast perfusion technique that applies a new principle of MR fingerprinting (MRF) to ASL. The major strength of this technique is that it allows for simultaneous estimations of six parameters, CBF, BAT, T1, B1+, blood volume, and arterial travel time, in a single scan.
Aim 1 is the development of the MRF-ASL MRI technique. We will develop MRF-ASL sequence timing for efficient encoding of perfusion parameters. We will also develop k-space undersampling strategies to obtain high spatial resolution perfusion imaging without increasing echo-train length. We will conduct validation of the technique using Gd-based perfusion MRI.
Aim 2 of this project will develop a cloud-based ASL analysis platform that can provide researchers and clinicians with an installation-free, operating-system independent tool for ASL analysis (of MRF-ASL as well as all other types of ASL data). Our clinical team at Johns Hopkins has a long-standing interest in mechanistic and therapeutic studies of sub-acute stroke. Therefore, Aim 3 of the present project is to demonstrate the initial clinical utility of the technique in sub-acute stroke. Finally, it should be emphasized that, although the present project focuses on its clinical applications in cerebrovascular diseases, the method developed also has important utility in other brain diseases, such neurodegenerative diseases (e.g. Alzheimer?s, Parkinson?s, Huntington?s diseases), psychiatric diseases (e.g. schizophrenia, depression, autism, ADHD), and tumor (primary and metastatic brain tumor). Thus, this technique is expected to have a broad clinical impact.
Perfusion imaging plays a critical role in the diagnosis and treatment of brain vascular diseases such as stroke. The present application aims to develop a technique and associated analysis methods that allow accurate and convenient measurement of brain blood supply without injecting anything into the patient?s body. This technique is expected to have a range of clinical applications in neurological and psychiatric diseases.
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Hou, Xirui; Liu, Peiying; Gu, Hong et al. (2018) Estimation of brain functional connectivity from hypercapnia BOLD MRI data: Validation in a lifespan cohort of 170 subjects. Neuroimage 186:455-463 |