Making up just over 3% of all new cancer cases in the United States, pancreatic cancer is not inherently a common malignant disease. Yet, it continuously is shown to be one of the most lethal and common causes of cancer death. Early detection is critical among all cancer types. However, oncologists and researchers have struggled to find effective strategies or tests to detect cancer of the pancreas early on in development. Thus, the cancer is often found late stage and requires significant chemotherapy intervention. These multi-drug treatment cocktails have shown benefit, but only in added months and not years to a patient’s life. Significant adverse effects often limit the full effective doses of treatment. In order to limit these adverse effects, as well as increase the effectiveness of treatment, we have designed, optimized, and tested unique drug carriers known as polymersomes. Using characteristics of the localized environment surrounding pancreatic tumors and the cells found therein, we created targeted therapies that are responsive and relatively selective toward cancerous cells. Herein, are found two distinct polymersomes. The first, is a low oxygen reactive drug carrier with an additional small peptide molecule that is able to penetrate dense tumor tissue and has shown decreased tumor growth of as much as 260% as compared to control samples in an animal model of pancreatic cancer. The chemical make-up of this polymersome allows for extended circulation time and a high accumulation at the tumor site. A second design, uses an intracellular enzyme to destabilize the polymersomes’ structure, which in turn, releases a selected chemotherapy drug near its intended site of action. This strategy, has shown a 10 fold increase in potency of the chemotherapy drug, as compared to when the drug is given alone and showed decreased toxicity to non-cancerous cells. It is certain that thoughtful drug delivery strategies and not just drug molecule design will be instrumental in the paradigm shift of pancreatic cancer from likely death to survival. / NIH grant 1 R01GM 114080; Grand Challenge Initiative; Office of the Dean, College of Health Professions
Identifer | oai:union.ndltd.org:ndsu.edu/oai:library.ndsu.edu:10365/31354 |
Date | January 2020 |
Creators | Confeld, Matthew Ian |
Publisher | North Dakota State University |
Source Sets | North Dakota State University |
Detected Language | English |
Type | text/dissertation, movingimage/video |
Format | application/pdf, video/mp4 |
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