Systemically administered glioblastoma (GBM) therapeutics reach the brain in very low concentrations due to the presence of both the blood brain barrier (BBB) and the nanoporous electrostatically charged extracellular matrix, denoted here as the brain-tissue barrier. New delivery strategies, capable of providing higher local concentrations and more uniform dispersion in the brain, are critically needed. This need extends to the delivery of agents designed to inhibit or restore the expression of recently identified master regulatory miRNAs. These miRNAs regulate multiple oncogenic and tumor suppressive pathways in GBM, and therefore represent promising new targets for therapy. To achieve this goal, we will implement innovative miRNA and anti-miRNA delivery approaches that couple magnetic resonance image (MRI)-guided BBB opening via focused ultrasound (FUS) and microbubbles (MBs) with miRNA-expression modifying nanoparticles (BPN) that have been engineered to rapidly penetrate the brain-tissue barrier. The collaborative efforts of Co-PIs Price and Hanes have generated ample pilot data supporting our concept for miRNA/anti-miRNA BPN delivery. Our central hypothesis is that therapeutic molecules designed to modify the expression of master regulatory miRNAs will exhibit markedly enhanced efficacy when they are packaged in BPN and delivered to GBM with MRI-guided FUS and MBs. This proposal consists of 3 specific aims.
Aim 1 will be to engineer BPN that effectively modify master regulatory miRNA expression in intracranial GBM xenografts in mice. BPN comprised of various core polymers will be fabricated using previously determined surface PEG chemistries. The ability of these therapeutic BPN to penetrate brain tumor tissue, as well as inhibit oncogenic miRNAs and/or restore tumor-suppressive miRNAs identified by Co-Investigators Abounader and Purow, will be tested. BPN with the most promising characteristics will be advanced to experimental therapeutic testing in Aim 3. Meanwhile, Aim 2 will be to develop MRI-guided approaches for the safe and effective delivery of these miRNA BPN to GBM using FUS and MBs. We will define FUS pressure thresholds for safe and reversible BBB opening and use them as boundaries in determining effective FUS and MB parameters for delivering BPN formulations. Studies for Aim 3 will first determine maximum tolerated dose and the pharmacokinetic profile of candidate miRNA/anti-miRNA BPN formulations. Next, the experimental therapeutic efficacy achieved by delivering miRNA/anti-miRNA BPN via MR-guided FUS and MBs will be examined. Controls will include non-penetrating nanoparticles and intravenously injected miRNA BPN formulations without FUS-mediated delivery. Efficacy will also be compared to that achieved using an established, yet highly invasive, convective enhanced delivery approach. Once completed, we believe these findings will establish miRNAs/anti-miRNA BPN as effective GBM therapeutics when delivered across the BBB using MRI-guided FUS and MBs.

Public Health Relevance

Therapeutic nanoparticles capable of modifying the expression of 'master regulatory' miRNAs hold great promise for the treatment of glioblastoma. However, targeting the delivery of these nanoparticles across the blood-brain barrier and through tumor tissue is extremely challenging. This proposal will utilize MR image- guided focused ultrasound, in conjunction with microbubbles, to open the blood-brain barrier in and around glioblastomas to both target the delivery of specially-engineered miRNA/anti-miRNA nanoparticles and determine the experimental therapeutic efficacy of this approach.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
5R01EB020147-04
Application #
9438525
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
King, Randy Lee
Project Start
2015-05-01
Project End
2019-02-28
Budget Start
2018-03-01
Budget End
2019-02-28
Support Year
4
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of Virginia
Department
Biomedical Engineering
Type
Biomed Engr/Col Engr/Engr Sta
DUNS #
065391526
City
Charlottesville
State
VA
Country
United States
Zip Code
22904
Heuslein, Joshua L; McDonnell, Stephanie P; Song, Ji et al. (2018) MicroRNA-146a Regulates Perfusion Recovery in Response to Arterial Occlusion via Arteriogenesis. Front Bioeng Biotechnol 6:1
Heuslein, Joshua L; Gorick, Catherine M; McDonnell, Stephanie P et al. (2018) Exposure of Endothelium to Biomimetic Flow Waveforms Yields Identification of miR-199a-5p as a Potent Regulator of Arteriogenesis. Mol Ther Nucleic Acids 12:829-844
Mastorakos, Panagiotis; Zhang, Clark; Song, Eric et al. (2017) Biodegradable brain-penetrating DNA nanocomplexes and their use to treat malignant brain tumors. J Control Release 262:37-46
Curley, Colleen T; Sheybani, Natasha D; Bullock, Timothy N et al. (2017) Focused Ultrasound Immunotherapy for Central Nervous System Pathologies: Challenges and Opportunities. Theranostics 7:3608-3623
Mead, Brian P; Kim, Namho; Miller, G Wilson et al. (2017) Novel Focused Ultrasound Gene Therapy Approach Noninvasively Restores Dopaminergic Neuron Function in a Rat Parkinson's Disease Model. Nano Lett 17:3533-3542
Heuslein, Joshua L; Gorick, Catherine M; Song, Ji et al. (2017) DNA Methyltransferase 1-Dependent DNA Hypermethylation Constrains Arteriogenesis by Augmenting Shear Stress Set Point. J Am Heart Assoc 6:
Zhang, Clark; Nance, Elizabeth A; Mastorakos, Panagiotis et al. (2017) Convection enhanced delivery of cisplatin-loaded brain penetrating nanoparticles cures malignant glioma in rats. J Control Release 263:112-119
Zhang, Clark; Mastorakos, Panagiotis; Sobral, Miguel et al. (2017) Strategies to enhance the distribution of nanotherapeutics in the brain. J Control Release 267:232-239
Timbie, Kelsie F; Afzal, Umara; Date, Abhijit et al. (2017) MR image-guided delivery of cisplatin-loaded brain-penetrating nanoparticles to invasive glioma with focused ultrasound. J Control Release 263:120-131
Mastorakos, Panagiotis; Song, Eric; Zhang, Clark et al. (2016) Biodegradable DNA Nanoparticles that Provide Widespread Gene Delivery in the Brain. Small 12:678-85

Showing the most recent 10 out of 17 publications