Abstract

Within this proposal, we aim to investigate a novel concept of targeted cancer cell destruction by using magnetic vortices as mediators of cellular mechanotransduction. The importance of this work was recently highlighted by featuring our approach on the cover of Nature Materials. A unique material - lithographically defined, biocompatible, ferromagnetic microdisc - possessing a spin vortex ground state has been interfaced with cancer cells via incorporation of a tumor specific antibody. For GBM, our specific targeting of glioma cells was based on the selective expression of the IL13?2 receptor (IL13?2R) on malignant brain tumors. IL13?2R is expressed only on malignant glioma and not on normal, healthy astrocytes. In fact, the receptor is not expressed on other organ, with the exception of testis. Moreover, IL13?2R expression is associated with glial transformation and increased tumor grade. Our working hypothesis is that selective targeting of microdiscs conjugated with an antibody against IL13?2R will result in enhanced GBM cytotoxicity in the context of extremely low frequency and small amplitude magnetic field. The actuation of the magnetic vortices by an alternating magnetic field (AC) leads to oscillatory motion of the microdiscs and transduction of a magneto-mechanical stimulus directly to the cell membrane and into sub- cellular compartments. This results in membrane disturbance, and cellular signal transduction and amplification, causing initiation of cell death. Application of extraordinarily weak magnetic fields produces an extremely high degree of spin-vortex induced cytotoxicity. The concept, if successful, will open up the field for tremendous improvements in cancer therapy. Because the microdiscs target individual cells, the external power supplied to the cultures is at least ~100,000s times smaller than that employed by current best practice techniques for hyperthermia using superparamagnetic nanoparticles. The low operating field strength creates an opportunity for a multifunctional therapy platform with low cost, large working volume, and minimal invasiveness. Moreover, the most striking feature of this approach is that the energy is delivered directly to the individual cell. To further advance this strategy ito the preclinical setting, we now propose to complete the following specific aims:
Specific Aim 1 : Determine the in vivo therapeutic response of antibody conjugated ferromagnetic microdiscs in human xenograft murine glioma model as well as a transgenic model of murine glioma.
Specific Aim 2 : Evaluate the migration, engraftment, and long-term fate of antibody conjugated ferromagnetic microdiscs in animal models of glioma.
Specific Aim 3 : Examine the mechanism of cytotoxicity of microparticles and dynamics of triggered cell death.

Public Health Relevance

Glioblastoma multiforme (GBM) is the most common primary malignant tumor of the adult central nervous system (CNS). Recently, we have developed magnetic microdiscs which are capable of inducing high toxicity in the setting of this tumor. This proposal seeks to complete the preclinical and mechanistic studies necessary to advance this therapy to the clinical setting.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS077388-02
Application #
8423710
Study Section
Developmental Therapeutics Study Section (DT)
Program Officer
Fountain, Jane W
Project Start
2012-02-15
Project End
2016-12-31
Budget Start
2013-01-01
Budget End
2013-12-31
Support Year
2
Fiscal Year
2013
Total Cost
$513,562
Indirect Cost
$129,478

  Institution

Name
University of Chicago
Department
Surgery
Type
Schools of Medicine
DUNS #
005421136
City
Chicago
State
IL
Country
United States
Zip Code
60637

  Publications

Mansell, Rhodri; Vemulkar, Tarun; Petit, Dorothée C M C et al. (2017) Magnetic particles with perpendicular anisotropy for mechanical cancer cell destruction. Sci Rep 7:4257
Feng, Qishuai; Shen, Yajing; Fu, Yingjie et al. (2017) Self-Assembly of Gold Nanoparticles Shows Microenvironment-Mediated Dynamic Switching and Enhanced Brain Tumor Targeting. Theranostics 7:1875-1889
Shen, Yajing; Wu, Congyu; Uyeda, Taro Q P et al. (2017) Elongated Nanoparticle Aggregates in Cancer Cells for Mechanical Destruction with Low Frequency Rotating Magnetic Field. Theranostics 7:1735-1748
Panek, Wojciech K; Kane, J Robert; Young, Jacob S et al. (2017) Hitting the nail on the head: combining oncolytic adenovirus-mediated virotherapy and immunomodulation for the treatment of glioma. Oncotarget 8:89391-89405
Vemulkar, T; Welbourne, E N; Mansell, R et al. (2017) The mechanical response in a fluid of synthetic antiferromagnetic and ferrimagnetic microdiscs with perpendicular magnetic anisotropy. Appl Phys Lett 110:042402
Muroski, Megan E; Morshed, Ramin A; Cheng, Yu et al. (2016) Controlled Payload Release by Magnetic Field Triggered Neural Stem Cell Destruction for Malignant Glioma Treatment. PLoS One 11:e0145129
Morshed, Ramin A; Muroski, Megan E; Dai, Qing et al. (2016) Cell-Penetrating Peptide-Modified Gold Nanoparticles for the Delivery of Doxorubicin to Brain Metastatic Breast Cancer. Mol Pharm 13:1843-54
Cheng, Yu; Muroski, Megan E; Petit, Dorothée C M C et al. (2016) Rotating magnetic field induced oscillation of magnetic particles for in vivo mechanical destruction of malignant glioma. J Control Release 223:75-84
Dey, Mahua; Chang, Alan L; Miska, Jason et al. (2015) Dendritic Cell-Based Vaccines that Utilize Myeloid Rather than Plasmacytoid Cells Offer a Superior Survival Advantage in Malignant Glioma. J Immunol 195:367-76
Kanojia, Deepak; Morshed, Ramin A; Zhang, Lingjiao et al. (2015) ?III-Tubulin Regulates Breast Cancer Metastases to the Brain. Mol Cancer Ther 14:1152-61

Showing the most recent 10 out of 36 publications