R01EB031008

Artificial Intelligence Boosted Evolution and Detection of Genetically Encoded Reporters for In Vivo Imaging - Project Summary

Magnetic Resonance (MR) reporter genes have the potential to monitor transgene expression non-invasively in real time at high resolution. These genes can be applied to interrogate the efficacy of gene therapy, to monitor viral therapeutics and viral gene delivery, to assess cellular differentiation, cell trafficking, and specific metabolic activity, and also assess changes in the microenvironment.

Efforts toward the development of MR reporter genes have been made for over a decade, but, despite these efforts, the field is still in its early developmental stage. This reflects the fact that there are numerous complications, caused by the low sensitivity of detection, the need for substrates with their associated undesirable pharmacokinetics, and/or the difficult and, in some cases, delayed interpretation of signal changes.

We have previously demonstrated that many of these challenges can be overcome with the use of a lysine-rich protein (LRP) reporter gene, that is detectable by chemical exchange saturation transfer (CEST) MRI. However, to mature the CEST reporter gene technology and bring it towards clinical translation, its sensitivity and specificity need to be improved. In particular, the LRP reporter gene specificity is limited by the fact that the lysine amide exchangeable protons of LRP have the same chemical shift as amide protons from endogenous proteins. It is therefore difficult to distinguish the reporter CEST contrast from the background CEST contrast, both of which may be changing with time. The specificity is further limited by the sensitivity of the CEST contrast to intracellular pH where the qualitative CEST contrast cannot distinguish between exchange rate and concentration effects. Finally, a decrease in cytosolic pH, observed in many disease pathologies, reduces the amide proton exchange rate and hence the CEST reporter sensitivity.

We therefore propose to develop improved MRI reporter genes and quantitative MRI detection methods that will facilitate the clinical translation of these methods for imaging biological therapeutics, such as oncolytic virotherapy. We hypothesize that CEST reporter genes with improved sensitivity and specificity along with improved quantitative CEST methods will enable viral infection and replication to be monitored longitudinally throughout OV tumor therapy. To test this hypothesis and establish the clinical potential of MRI reporter genes, we will capitalize on two transformative technologies developed in our labs: (Aim 1) an artificial intelligence-based genetic programming algorithm will be used for optimizing the sensitivity and specificity of the CEST reporter gene and (Aim 2) a CEST magnetic resonance fingerprinting (MRF) method will be used for the rapid quantification of both the reporter protein concentration and chemical exchange rate. (Aim 3) These methods will be validated for imaging oncolytic viral infection and replication in mouse glioblastoma tumor models.

The General Hospital Corporation

TO SUPPORT HYPOTHESIS-, DESIGN-, TECHNOLOGY-, OR DEVICE-DRIVEN RESEARCH RELATED TO THE DISCOVERY, DESIGN, DEVELOPMENT, VALIDATION, AND APPLICATION OF TECHNOLOGIES FOR BIOMEDICAL IMAGING AND BIOENGINEERING. THE PROGRAM INCLUDES BIOMATERIALS (BIOMIMETICS, BIOPROCESSING, ORGANOGENESIS, REHABILITATION, TISSUE ENGINEERING, IMPLANT SCIENCE, MATERIAL SCIENCE, INTERFACE SCIENCE, PHYSICS AND STRESS ENGINEERING, TECHNOLOGY ASSESSMENT OF MATERIALS/DEVICES), BIOSENSORS/BIOTRANSDUCERS (TECHNOLOGY DEVELOPMENT, TECHNOLOGY ASSESSMENT, DEVELOPMENT OF ALGORITHMS, TELEMETRY), NANOTECHNOLOGY (NANOSCIENCE, BIOMIMETICS, DRUG DELIVERY SYSTEMS, DRUG BIOAVAILABILITY, MICROARRAY/COMBINATORIAL TECHNOLOGY, GENETIC ENGINEERING, COMPUTER SCIENCE, TECHNOLOGY ASSESSMENT), BIOINFORMATICS (COMPUTER SCIENCE, INFORMATION SCIENCE, MATHEMATICS, BIOMECHANICS, COMPUTATIONAL MODELING AND SIMULATION, REMOTE DIAGNOSIS AND THERAPY), IMAGING DEVICE DEVELOPMENT, BIOMEDICAL IMAGING TECHNOLOGY DEVELOPMENT, IMAGE EXPLOITATION, CONTRAST AGENTS, INFORMATICS AND COMPUTER SCIENCES RELATED TO IMAGING, MOLECULAR AND CELLULAR IMAGING, BIOELECTRICS/BIOMAGNETICS, ORGAN AND WHOLE BODY IMAGING, SCREENING FOR DISEASES AND DISORDERS, AND IMAGING TECHNOLOGY ASSESSMENT AND SURGERY (TECHNIQUE DEVELOPMENT AND TECHNOLOGY DEVELOPMENT).

93.286 - Discovery and Applied Research for Technological Innovations to Improve Human Health

National Institute of Biomedical Imaging and Bioengineering (NIBIB) [HHS - NIH]

Charlestown, Massachusetts 02129 United States

Single Zip Code

NIH Research Project Grant (Parent R01 Clinical Trial Not Allowed) (PA-20-185)

Amendment Since initial award the End Date has been extended from 12/31/24 to 12/31/28 and the total obligations have increased 390% from $680,476 to $3,332,874.