Delivery of Cell-Specific Aptamers to the Arterial Wall with an Occlusion Perfusion Catheter.

Current strategies to prevent restenosis following endovascular treatment include the local delivery of anti-proliferative agents to inhibit vascular smooth muscle cell (VSMC) proliferation and migration. These agents, not specific to VSMCs, are deposited on the luminal surface and therefore target endothelial cells and delay vascular healing. Cell-targeted therapies, (e.g., RNA aptamers), can potentially overcome these safety concerns by specifically binding to VSMC and inhibiting proliferation and migration. The purpose of this study was to therefore demonstrate the ability of a perfusion catheter to deliver cell-specific RNA aptamer inhibitors directly to the vessel wall. RNA aptamers specific to VSMCs were developed using an in vitro cell-based systematic evolution of ligand by exponential enrichment selection process. Two aptamers (Apt01 and Apt14) were evaluated ex vivo using harvested pig arteries in a pulsatile flow bioreactor. Local drug delivery of the aptamers into the medial wall was accomplished using a novel perfusion catheter. We demonstrated the feasibility to deliver aptamer-based drugs directly to the medial layer of an artery using a perfusion catheter. Such cell-specific targeted therapeutic drugs provide a potentially safer and more effective treatment option for patients with vascular disease.

Smart thermosensitive liposomes for effective solid tumor therapy and in vivo imaging.

In numerous studies, liposomes have been used to deliver anticancer drugs such as doxorubicin to local heat-triggered tumor. Here, we investigate: (i) the ability of thermosensitive liposomal nanoparticle (TSLnp) as a delivery system to deliver poorly membrane-permeable anticancer drug, gemcitabine (Gem) to solid pancreatic tumor with the aid of local mild hyperthermia and, (ii) the possibility of using gadolinium (Magnevist®) loaded-TSLnps (Gd-TSLnps) to increase magnetic resonance imaging (MRI) contrast in solid tumor. In this study, we developed and tested gemcitabine-loaded thermosensitive liposomal nanoparticles (Gem-TSLnps) and gadolinium-loaded thermosensitive liposomal nanoparticles (Gd-TSLnps) both in in-vitro and in-vivo. The TSLnps exhibited temperature-dependent release of Gem, at 40-42°C, 65% of Gem was released within 10 min, whereas < 23% Gem leakage occurred at 37°C after a period of 2 h. The pharmacokinetic parameters and tissue distribution of both Gem-TSLnps and Gd-TSLnps were significantly greater compared with free Gem and Gd, while Gem-TSLnps plasma clearance was reduced by 17-fold and that of Gd-TSLpns was decreased by 2-fold. Area under the plasma concentration time curve (AUC) of Gem-TSLnps (35.17± 0.04 µghr/mL) was significantly higher than that of free Gem (2.09 ± 0.01 µghr/mL) whereas, AUC of Gd-TSLnps was higher than free Gd by 3.9 fold high. TSLnps showed significant Gem accumulation in heated tumor relative to free Gem. Similar trend of increased Gd-TSLnps accumulation was observed in non-heated tumor compared to that of free Gd; however, no significant difference in MRI contrast enhancement between free Gd and Gd-TSLnps ex-vivo tumor images was observed. Despite Gem-TSLnps dose being half of free Gem dose, antitumor efficacy of Gem-TSLnps was comparable to that of free Gem(Gem-TSLnps 10 mg Gem/kg compared with free Gem 20 mg/kg). Overall, the findings suggest that TSLnps may be used to improve Gem delivery and enhance its antitumor activity. However, the formulation of Gd-TSLnp needs to be fully optimized to significantly enhance MRI contrast in tumor.

Pharmacokinetic, biodistribution and therapeutic efficacy of 5-fluorouracil-loaded pH-sensitive PEGylated liposomal nanoparticles in HCT-116 tumor bearing mouse.

The objective of the study was to investigate the pharmacokinetics and efficacy of 5-FU entrapped pH-sensitive liposomal nanoparticles with surface-modified anti-epidermal growth factor receptor (EGFR) antibody (pHLNps-5-FU) delivery system. Cytotoxicity of 5-FU and pHLNps-5-FU was determined in vitro against HCT-116 cells. The biodistribution and pharmacokinetic parameters of the administered 5-FU and pHLNps-5-FU as well as efficacy of 5-FU and pHLNps-5-FU were determined in HCT-116 subcutaneous mouse model. Mean size of pHLNp-5-FU was 164.3 ± 8.4 nm with entrapment efficiency (E.E) of 54.17%. While cytotoxicity of 5-FU and pHLNps-5-FU showed a strong dose-dependent, pHLNps-5-FU proved to be more effective (2-3 fold high) than that of 5-FU against HCT-116 cells. Pharmacokinetic study showed a prolonged plasma circulation of pHLNps-5-FU and a more significant body exposure while accumulation of pHLNps-5-FU in tumor was significantly higher than that of free 5-FU. Further, the efficacy of pHLNps-5-FU, was greater than free 5-FU at equivalent 5-FU dose. The study suggests that pHLNps may be an effective drug delivery system to enhance the anticancer activity of 5-FU against colorectal tumor growth.

Cytotoxicity of gemcitabine-loaded thermosensitive liposomes in pancreatic cancer cell lines.

Gemcitabine (GEM) is currently the standard option for the treatment of pancreatic cancer but its short half-life and rapid metabolism has caused for new modality for delivery of GEM. The purpose of this study was to formulate GEM loaded PEGylated thermosensitive liposomal nanoparticles (GEM-TSLnps) to increase residence time and deliver high payload of GEM to pancreatic cancer cells using mild hyperthermia (mHT). The GEM-TSLnps were formulated by thin film hydration. The cytotoxic effects of GEM and GEM-TSLnps were evaluated against human pancreatic cancer cell lines. In vitro release of GEM by TSLnps was determined at temperatures from 26°C through to 50°C. Cell viability studies, clonogenic assay, flow cytometry and confocal imaging were performed on pancreatic cancer cell lines using GEM and GEM-TSLnps + mHT. The GEM-TSLnp size was determined to be 216.10 ± 0.57 nm with entrapment efficiency of 41.10 ± 2.0%. GEM release from TSLnps was sharply increased at 42°C (60%) than at 37°C (25%), (p<0.01). In vitro cytotoxicity of GEM-TSLnps + mHT treated pancreatic cancer cell lines was significantly higher than GEM treated. The IC50 values for PANC-1, MiaPaCa-2 and BxPC-3 cells GEM-TSLnps + mHT treated were 1.2 to 3.5 fold-higher than GEM treated. Among the cell lines, GEM-TSLnps + mHT treated PANC-1 and MiaPaCa-2 cells show significantly reduced reproductive viability compared with the GEM treated cells. Flow cytometric and confocal images revealed high Rho-TSLnps cellular uptake. Our findings suggest that GEMTSLnps+ mHT can significantly enhance cytotoxic effect of GEM and could serve as a new chemotherapy modality for delivering GEM.

In vitro and in vivo antitumor activity of gemcitabine loaded thermosensitive liposomal nanoparticles and mild hyperthermia in pancreatic cancer.

The study was designed to explore the feasibility of increasing the delivery of gemcitabine-HCL (Gem), a poor membrane permeable and short half-life drug, through PEGylated thermosensitive liposomal nanoparticles (TSLnps) delivery system followed by mild hyperthermia (mTH) at 42°C. In vitro release pattern of Gem-TSLnps showed a significant Gem release (60%, p<0.01) at 42°C compared to that released at 37°C (29%). Cell viability and clonogenic assay demonstrated significant inhibition of MiaPaCa-2 cells growth by Gem-TSLnps + mHT compared to Gem alone. Further, IC50 value of Gem treated cells was (0.077µM) 1.2 fold higher compared to that treated with Gem-TSLnps + mHT (0.063 µM). mHT treated cells showed moderate inhibition of cell growth compared to controls. For cellular uptake studies, flow cytometric analysis and confocal imaging revealed higher uptake of Rho-TSLnps compared to Rho-PE or untreated cells. Tumor volume of mice treated with Gem alone was 1.8 fold higher compared to the group treated with Gem-TSLnps + mHT. Further, tumor regression of Gem-TSLnps + mHT treated group was significantly higher (p<0.01) compared to Gem-TSLnps or Gem. No significant elevated liver enzymes were observed when serum alanine aminotransferase (ALT) or aspartate aminotransferase (AST) level of control group was compared to that of Gem or Gem-TSLnps+mHT treated groups. However, serum level of alkaline phosphatase (ALP) of Gem or Gem-TSLnps+ mHT treated group was significantly elevated (p<0.05) when compared to the control group. In conclusion, TSLnps increased the delivery of Gem to tumor cells and also enhanced significantly the antitumor activity of Gem when combined with heat.

Cytotoxicity of 5-fluorouracil-loaded pH-sensitive liposomal nanoparticles in colorectal cancer cell lines.

5-Fluorouracil (5-FU) is widely used in cancer therapy, either alone or in combination with other anti-cancer drugs. However, poor membrane permeability and a short half-life (5-20 min) due to rapid metabolism in the body necessitate the continuous administration of high doses of 5-FU to maintain the minimum therapeutic serum concentration. This is associated with significant side effects and a possibility of severe toxic effects. This study aimed to formulate 5-FU-loaded pH-sensitive liposomal nanoparticles (pHLNps-5-FU) and evaluate 5-FU release characteristics and anti-cancer effect of pHLNps-5-FU. Particle size and zeta potential were determined using a particle size analyzer. The release patterns of pHLNps-5-FU formulations were evaluated at 37°C at pH 3, 5, 6.5, and 7.4, while drug release kinetics of 5-FU from a pHLNp3-5-FU formulation were determined at pH 3 and 7.4 at different time points (37°C). Cell viability and clonogenic studies were conducted to evaluate the effectiveness of pHLNps-5-FU against HCT-116 and HT-29 cell lines while cellular uptake of rhodamine-labeled pHLNps-5-FU was determined by flow cytometry and confocal imaging. The average sizes of the pHLNp1-5-FU, pHLNp2-5-FU and pHLNp3-5-FU liposomes were 200nm ± 9.8nm, 181.9 nm ± 9.1 nm, and 164.3 nm ± 8.4 nm respectively. In vitro drug release of 5-FU from different pHLNps-5-FU formulations was the highest at pH 3.8. Both cell lines treated with pHLNps-5-FU exhibited reduced viability, two- or three-fold lower than that of 5-FU-treated cells. Flow cytometry and confocal imaging confirmed high uptake of rhodamine-labeled pHLNps-5-FU in both cell lines. The drug release profile of the chosen pHLNp3-5-FU formulation was optimal at pH 3 and had the poorest release profile at pH 7.4. The release profile of pHLNp3-5-FU showed that 5-FU release was two-fold higher at pH 3 than that at pH 7.4. This study demonstrates that pHLNp3-5-FU may be a potential candidate for the treatment of colorectal cancer.

Development of a novel approach to enhance the solubility of ftibamzone formulation.

Ftibamzone (FBZ) is known to be effective against herpes simplex virus that causes genital herpes but poor solubility of FBZ has reduced its therapeutic efficacy. We investigated water-soluble complexes of various nanoparticles with FBZ to improve its solubility as well as increase its absorption. Using phase-solubility technique, we measured formation constant (K1:1 and K1:2) values at room temperature in pH 7 buffer. Solubility was determined by dissolving FBZ or FBZ-entrapped nanoparticles in phosphate buffers and pH adjusted to different pH range (2-12). The solutions were then equilibrated for 24 hours and then filtered and analyzed using HPCL. Nanoparticles were formulated using nanoprecipitation technique and cellular uptake of nanoparticle was determined by confocal microscope. No significant FBZ solubility was observed from pH 2 to 10 however we did notice a rapid increase in solubility from pH of 10 to 12 with FBZ solubility of 950 µg/ml. Our log D against pH profile revealed that FBZ is characteristic of an acid drug since unionized group was dominant at low pH. FBZ interaction with methyl-ß-cyclodextrin (mßCD) complexation/nanoparticles showed a greater solubility of FBZ compared with FBZ alone while complexation constants were determined to be K1:1 and K1:2 were 7.06×10-3 and 8.98×10-8 mM-1 respectively. Only FBZ-chitosan nanoparticles were toxic against MDCK cells. Study demonstrates that FBZ-PLGA nanoparticles could significantly enhance the solubility and absorption of FBZ compared with FBZ alone and has the potential to be used as an effective delivery system for the treatment of genital herpes.