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Doctor of Philosophy with a Major in Bioengineering

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https://hdl.handle.net/1853/72221
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search.filters.applied.f.advisor: Bellamkonda, Ravi V. ×

Publication Search Results

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    Novel nanocarriers for invasive glioma
    (Georgia Institute of Technology, 2011-07-08) Munson, Jennifer Megan
    The invasive nature of glioblastoma (GBM) represents a significant challenge to the standard of care and contributes to poor clinical outcomes. Invasion of tumors into healthy brain restricts chemotherapeutic access and complicates surgical resection. The central hypothesis of the thesis is that an effective anti-invasive agent can enhance the standard chemotherapeutic response in invasive brain tumors. Through a screen of novel compounds, a new anti-invasive small molecule, Imipramine Blue (IB), was identified. This triphenylmethane compound inhibits invasion of highly invasive glioma in vitro and in vivo. To elicit a response in vivo, Imipramine Blue was liposomally encapsulated to yield better delivery to tumor. Using this formulation, it is shown that IB attenuates invasion of glioma in vivo leading to a more compact tumor in an aggressively invasive rodent glioma model. Further, it is shown that this novel compound binds NADPH oxidases and alters expression of actin regulatory elements to elicit this anti-invasive activity. To test our hypothesis that anti-invasive therapy coupled with chemotherapy will enhance efficacy, nano-IB therapy was followed by liposomally encapsulated doxorubicin (DXR) chemotherapy. Additionally, a co-encapsulated formulation of IB and DXR was developed and tested in vivo. This combination therapy significantly enhanced survival compared to IB or DXR alone, resulting in long-term survival in the syngeneic invasive rat astrocytoma model RT2. It was seen that sequential treatment was more effective than the co-encapsulated treatment indicating a benefit of pre-treating the tumor with the anti-invasive. This thesis demonstrates that novel anti-invasive IB mediated 'containment' of diffuse glioma significantly enhances the efficacy of DXR chemotherapy compared to chemotherapy or anti-invasive therapy alone.
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    Nanocarrier mediated therapies for the gliomas of the brain.
    (Georgia Institute of Technology, 2011-01-21) Agarwal, Abhiruchi
    Existing methods of treating glioma are not effective for eradicating the disease. Therefore, new and innovative methods of treatment alone or in combination with existing therapies are necessary. Delivery of therapeutic agents through delivery carriers such as liposomes diminishes the harmful effects of the agent in healthy tissues and allows increased accumulation in the tumor. In addition, targeted chemotherapy using liposomes provides the opportunity for further increase in drug accumulation in tumor. However, the current targeting strategies suffer accelerated plasma clearance and are not advantageous in improving efficacy. The search for new tumor targets, novel ligands, new strategies for targeting, and particle stabilization will advance our ability to improve delivery at the tumor level while decreasing toxicity to normal tissues. The global objective of this thesis was to improve the status of current liposomal therapy to achieve higher efficacy in tumors. Here, we show a novel mechanism to increase targeting to tumor while uncompromising on the long circulation of stealth liposomes. Long circulation is essential for passive accumulation of the nanocarriers due to EPR effect, in order to see benefits of targeting. Using phage display technique, a variety of tumor specific peptides were identified for use as targeting moieties. One potential advantage of the approach proposed here is the rapid identification of patient tumor specific peptide that evades the RES. This could lead to the development of a nanocarrier system with high avidity and selectivity for tumors. Therefore, tumor accumulation of the targeted formulations will be higher than that of non‐targeted liposomes due to increased drug retention at the tumor site and uncompromised blood residence time.In addition, it has been shown that the distribution of nanocarriers, spatially within the tumor, is limited that might further hinder the distribution of the encapsulated drug, thereby limiting efficacy. It is necessary to release the drug from within the nanocarrier to promote increased efficacy. Here, we were able to address the problem of drug diffusion within the tumor interstitium using a combination therapy employing a remotely triggered thermosensitive liposomal chemotherapeutic. We fabricated a thermosensitive liposomal nanocarrier that maintained its stability at physiological temperature to minimize toxicity to healthy cells. We, then, showed a remote triggering mechanism mediated by gold nanorods heated via NIR can help in achieving precise control over the desired site for drug release. These strategies enabled increased drug availability at the tumor site and contributed to tumor retardation. Additionally, we show that the synergistic therapy employing gold nanorods and thermosensitive liposomes may have great potential to be translated to the clinic.