1. Thermosensitive Liposomes for Gemcitabine Delivery to Pancreatic Ductal Adenocarcinoma.
- Author
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Aparicio-Lopez, Cesar B., Timmerman, Sarah, Lorino, Gabriella, Rogers, Tatiana, Pyle, Marla, Shrestha, Tej B., and Basel, Matthew T.
- Subjects
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ADENOCARCINOMA , *PHOSPHOLIPIDS , *RESEARCH funding , *FEVER , *DESCRIPTIVE statistics , *PANCREATIC tumors , *CANCER chemotherapy , *POLYETHYLENE glycol , *GEMCITABINE , *DUCTAL carcinoma , *MICROSCOPY - Abstract
Simple Summary: Pancreatic cancer is one of the most deadly forms of cancer. Current treatment options often fail because too little of the chemotherapy gets into the cancer. Hyperthermia, or heat treatment, has shown some promise in treating pancreatic cancer and may make it more likely for the chemotherapy to enter into the cancer. This study aims to design liposomes that can increase the amount of chemotherapy reaching pancreatic cancer by targeting the liposomes with hyperthermia. Treatment of pancreatic ductal adenocarcinoma with gemcitabine is limited by an increased desmoplasia, poor vascularization, and short plasma half-life. Heat-sensitive liposomes modified by polyethylene glycol (PEG; PEGylated liposomes) can increase plasma stability, reduce clearance, and decrease side effects. Nevertheless, translation of heat-sensitive liposomes to the clinic has been hindered by the low loading efficiency of gemcitabine and by the difficulty of inducing hyperthermia in vivo. This study was designed to investigate the effect of phospholipid content on the stability of liposomes at 37 °C and their release under hyperthermia conditions; this was accomplished by employing a two-stage heating approach. First the liposomes were heated at a fast rate, then they were transferred to a holding bath. Thermosensitive liposomes formulated with DPPC: DSPC: PEG2k (80:15:5, mole%) exhibited minimal release of carboxyfluorescein at 37 °C over 30 min, indicating stability under physiological conditions. However, upon exposure to hyperthermic conditions (43 °C and 45 °C), these liposomes demonstrated a rapid and significant release of their encapsulated content. The encapsulation efficiency for gemcitabine was calculated at 16.9%. Additionally, fluorescent analysis during the removal of unencapsulated gemcitabine revealed an increase in pH. In vitro tests with BxPC3 and KPC cell models showed that these thermosensitive liposomes induced a heat-dependent cytotoxic effect comparable to free gemcitabine at temperatures above 41 °C. This study highlights the effectiveness of the heating mechanism and cell models in understanding the current challenges in developing gemcitabine-loaded heat-sensitive liposomes. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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