Brain MRF in Children, Adolescents and Young Adults With Acute Leukemia

Description

Acute leukemia (AL), including Acute Lymphoblastic Leukemia (ALL), Acute Myeloid Leukemia (AML) and myeloproliferative neoplasms (MPN) are among the most common childhood cancers, the 5-year overall survival of children with leukemia has significantly improved with the current treatment methods, and is now ~90 % for ALL participants and ~70 % for AML participants. There has been a remarkable shift in the treatment strategy for childhood acute leukemia to reduce the burden of therapy related complications. Most notably, the addition of central nervous system (CNS)-directed, intensified intravenous and intrathecal chemotherapy regimens for most standard risk participants has obviated the need for craniospinal radiation therapy (CRT), thus reserving CRT for high-risk participants. With the improved overall survival rates, there is an increasing focus on characterizing and mitigating the long-term effects of the disease and therapy that may affect the quality of life of these participants. The results of multiple studies have indicated that the long-term survivors of ALL and AML experience varying degrees of neurocognitive deficits including memory loss, poor concentration, deficits in executive functioning and personality changes5-9. Methotrexate which is an important chemotherapeutic agent in the treatment of acute leukemia is known to cause chemotherapy induced cognitive impairment (CICI), by causing complex glial dysfunction leading to disruption of activity-dependent myelination in the CNS.

Studies designed to characterize normal brain development in early childhood have not only contributed significantly to our understanding of healthy neurodevelopment, but have also helped to identify neurodevelopmental problems at an early stage, enabling the application of treatment interventions in a timely fashion. Although magnetic resonance imaging (MRI) has been used for this purpose, its application has been hampered by several limitations including the sensitivity to motion artifact, the length of time required to perform a scan, and the requirement for sedation for younger participants. These limitations can be overcome using a new technology known as magnetic resonance fingerprinting (MRF), which allows for rapid, efficient and simultaneous quantification of multiple tissue properties, and quantifies T1, T2 and Myelin Water Fraction (MWF) simultaneously. Sedation is not necessary since whole brain MRF imaging takes approximately 5 minutes to complete and is resistant to motion artifacts.

These properties position MRF for use to assess multiple tissue properties in both pediatric and AYA participants diagnosed with acute leukemia, before, during and after exposure to CNS directed chemotherapy. The investigator proposes to use MRF to monitor demyelination, which has been documented as an underlying mechanism contributing to the long-term neurocognitive deficits seen in participantsundergoing chemotherapy. The goal of using MRF in this context is that it might ultimately serve as a valuable imaging biomarker that would enable early detection of the participants that are at an increased risk of developing neurocognitive deficits due to exposure to anti-neoplastic chemotherapy, by detecting the myelin changes as defined by MRF quantification of myelin water fraction. The capacity for detection would facilitate development of early interventions for these high-risk participants, so that their quality of life can be preserved as much as possible.

The study will evaluate the feasibility of obtaining MRF imaging data along with assessments of neurocognitive function. Chanages/decline in neurocognitive function in pediatric participants undergoing treatment for acute leukemia have been tested, validated and reported by the Children’s Oncology Group using a battery of assessment developed by Cogstate®. The computerized cognitive tests are rapid, reliable, and have demonstrated sensitivity to drug related changes in cognition. The tests have been designed and validated to withstand operational challenges during the conduction of clinical trials. The data system is HIPAA compliant U.S. FDA Class II Exempt Digital Medical Device.