ECHOGENIC LIPOSOMES FOR NITRIC OXIDE DELIVERY AND BREAST CANCER TREATMENT

Liposomes, also known as nontoxic, biodegradable, and non-immunogenic therapeutic delivery vehicles, have been proposed as a carrier for drugs and antitumor agents in cancer chemotherapy. Echogenic liposomes (ELIP) have the potential to entrap air or bioactive gas to enhance acoustic reflectivity in ultrasound and are used as a contrast agent. The innovative part of this study is based on a novel concept to encapsulate nitric oxide (NO) gas into ELIP, deliver it to breast cancer cells, and control its release via direct ultrasound exposure. Studies on the effect of NO in tumor biology have shown that a high levels of NO (> 300 nM) leads to cytostasis or apoptosis by decreasing the translation of several cell cycle proteins and stimulating cancer cell death by activating the p53 pathway. The central hypothesis is that NO gas can be packaged and delivered through a delivery methodology to breast cancer cells to facilitate tumor regression with minimal systemic toxicity. The primary goal of this thesis is to develop an echogenic liposomal solution that has the ability to encapsulate NO, to release NO locally upon ultrasound exposure, and to induce breast cancer cell death. NO-containing echogenic liposomes (NO-ELIP) were prepared by the freezing-under-pressure method previously developed in our laboratory. It was necessary to evaluate stability of NO-ELIP and release of NO from NO-ELIP by measuring echogenicity using intravascular ultrasound images. Breast cancer cell lines, MDA-MB-231 and MDA-MB-468, were selected to investigate the cytotoxic effects of NO liberated from NO-ELIP and their response to NO concentration. Ultrasound-triggered NO release from NO-ELIP using ultrasound activation was studied. It was demonstrated that NO-ELIP remained stable for 5 hours in bovine serum albumin. Delivery of NO using NO-ELIP induced cytotoxicity and programmed cell death of MDA-MB-231 and MDA-MB-468 after 5 hours of incubation. Enhancement of the NO-ELIP effect for therapeutic application was observed with ultrasound activation. This work demonstrates that NO-ELIP can incorporate and deliver NO to breast cancer cells providing increased NO stability and ultrasound-controlled NO release. Improved therapeutic effect with the use of NO-ELIP is expected to be found for breast cancer treatment.

Role of entorhinal cortical plasticity in spatial and contextual memory

It is well accepted that the hippocampus (HIP) is important for spatial and contextual memories, however, it is not clear if the entorhinal cortex (EC), the main input/output structure for the hippocampus, is also necessary for memory storage. Damage to the EC in humans results in memory deficits. However, animal studies report conflicting results on whether the EC is necessary for spatial and contextual memory. Memory consolidation requires gene expression and protein synthesis, mediated by signaling cascades and transcription factors. Extracellular-signal regulated kinase (ERK) cascade activity is necessary for long-term memory in several tasks, including those that test spatial and contextual memory. In this work, we explore the role of ERK-mediated plasticity in the EC on spatial and contextual memory. ^ To evaluate this role, post-training infusions of reversible pharmacological inhibitors specific for the ERK cascade that do not affect normal neuronal activity were targeted directly to the EC of awake, behaving animals. This technique provides spatial and temporal control over the inhibition of the ERK cascade without affecting performance during training or testing. Using the Morris water maze to study spatial memory, we found that ERK inhibition in the EC resulted in long-term memory deficits consistent with a loss of spatial strategy information. When animals were allowed to learn and consolidate a spatial strategy for solving the task prior to training and ERK inhibition, the deficit was alleviated. To study contextual memory, we trained animals in a cued fear-conditioning task and saw an increase in the activation of ERK in the EC 90 minutes following training. ERK inhibition in the EC over this time point, but not at an earlier time point, resulted in increased freezing to the context, but not to the tone, during a 48-hour retention test. In addition, animals froze maximally at the time the shock was given during training; similar to naïve animals receiving additional training, suggesting that ERK-mediated plasticity in the EC normally suppresses the temporal nature of the freezing response. These findings demonstrate that plasticity in the EC is necessary for both spatial and contextual memory, specifically in the retention of behavioral strategies. ^