Glioblastoma multiforme (GBM) is the most common and aggressive primary brain tumor, with an extremely poor prognosis. Standard therapies fail to eradicate residual or infiltrating cells that reside adjacent to and infiltrate normal brain tisue. Stem cells are emerging as feasible delivery vehicles to therapeutically target primary and invasive tumor cells. One shortcoming of this approach of using stem cells as therapeutic vehicles is that in addition to migrating towards tumors, stem cells are additionally attracted towards normal areas in the body that may be harmed if they non-selectively express highly toxic therapies. Therefore, the objective of our application is to create a remote-controllable stem cell-based strategy that will allow us to non-invasively activate stem cell therapeutic production at the time and place of our choosing. The central hypothesis to be tested is that image-guided high intensity focused ultrasound (HIFU) can be used in an innovative way to mildly heat tumor tissue at the depth of our choosing and induce therapeutic production controlled by the HSP70 promoter. Of translational relevance, technology that delivers HIFU through the human skull to a depth of the operator's choosing is already being used in clinic for other applications. Another major limitation of cell-based therapy is the number of cells that successfully navigate to the tumor site. We propose to use HIFU to drive the production of a pro-migratory factor, which should further increase stem cell trafficking and accumulation at the tumor site. This process, the controlled amplification of stem-cell trafficking (CAST), may be repeated to serially amplify the effect. Since CAST is controlled by physical rather than biological stimuli, it can avoid the tumor immuno-suppression that cripples traditional cell therapy. Our remote controlled expression platform can also be leveraged to assist in locally opening up the blood brain barrier for facilitated drug delivery. The opening of the BBB will be limited to where selected factors will be secreted secondary to HIFU activation, which is in the vicinity of the engineered stem cells. As a result even though a much larger volume will be heated by HIFU the blood brain barrier opening will be much more focused to where the stem cells are located. If successful, this degree of spatial and temporal precision in controlling the blood brain barrier opening will be unprecedented and can have great potential in applications even outside of brain tumor therapy. To test our hypothesis we will pursue three specific aims: (1) To demonstrate that image-guided HIFU-mediated remote heat-activation of engineered stem cells can non-invasively activate expression of reporter genes; (2) To demonstrate the feasibility of using image-guided pHIFU to induce anti-GBM therapeutics under control of the HSP70 promoter; and (3) To determine the feasibility of using image-guided HIFU to temporally induce cytokine expression (under control of HSP70 promoter) for the purpose of attracting a second amplified wave of therapeutic stem cells to the target site and focally permeabilizing the Blood Brain Barrier (BBB).

Public Health Relevance

The objective of this project is to create a remote-controllable stem cell-based strategy to treat brain tumors that will allow us to non-invasively activate stem cell therapeutic production at the time and place of our choosing. This should allow us to increase efficacy and decrease toxicity of brain tumor therapy. This novel treatment paradigm utilizing image guided focused ultrasound can potentially be applied to other diseases that affect the central nervous system and have impact outside of cancer.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA184091-02
Application #
8893033
Study Section
Special Emphasis Panel (ZRG1-SBIB-Z (58))
Program Officer
Farahani, Keyvan
Project Start
2014-08-01
Project End
2019-07-31
Budget Start
2015-08-01
Budget End
2016-07-31
Support Year
2
Fiscal Year
2015
Total Cost
$321,625
Indirect Cost
$114,125
Name
Wake Forest University Health Sciences
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
937727907
City
Winston-Salem
State
NC
Country
United States
Zip Code
27157
Sun, Yao; Xiong, Xiaobing; Pandya, Darpan et al. (2017) Enhancing tissue permeability with MRI guided preclinical focused ultrasound system in rabbit muscle: From normal tissue to VX2 tumor. J Control Release 256:1-8
Birbrair, Alexander; Sattiraju, Anirudh; Zhu, Dongqin et al. (2017) Novel Peripherally Derived Neural-Like Stem Cells as Therapeutic Carriers for Treating Glioblastomas. Stem Cells Transl Med 6:471-481
Sai, Kiran Kumar Solingapuram; Sattiraju, Anirudh; Almaguel, Frankis G et al. (2017) Peptide-based PET imaging of the tumor restricted IL13RA2 biomarker. Oncotarget 8:50997-51007
Sattiraju, Anirudh; Xiong, Xiaobing; Pandya, Darpan N et al. (2017) Alpha Particle Enhanced Blood Brain/Tumor Barrier Permeabilization in Glioblastomas Using Integrin Alpha-v Beta-3-Targeted Liposomes. Mol Cancer Ther 16:2191-2200
Xiong, Xiaobing; Sun, Yao; Sattiraju, Anirudh et al. (2015) Remote spatiotemporally controlled and biologically selective permeabilization of blood-brain barrier. J Control Release 217:113-20