Assessment of Aprotinin Loaded Microemulsion Formulations for Parenteral Drug Delivery: Preparation, Characterization, in vitro Release and Cytotoxicity Studies.

The object of the current study was to prepare novel microemulsion formulations of aprotinin for parenteral delivery and to compare in vitro characteristics and release behaviour of different Technetium-99m ((99m)Tc)-Aprotinin loaded microemulsion formulations. In addition, cytotoxicity of microemulsion formulation was evaluated with cell culture studies on human immortalized pancreatic duct epithelial-like cells. For this aim, firstly, pseudo-ternary phase diagrams were plotted to detect the formulation region and optimal microemulsions were characterized for their thermodynamic stability, conductivity, particle size, zeta potential, viscosity, pH and in vitro release properties. For in vitro release studies aprotinin was labelled with (99m)Tc and labelling efficiency, radiochemical purity and stability of the radiolabeled complex were determined by several chromatography techniques. Radiolabeling efficiency of (99m)Tc-Aprotinin was found over than 90% without any significant changes up to 6 hours after labelling at room temperature. After that, in vitro release studies of (99m)Tc-Aprotinin loaded microemulsions were performed with two different methods; dissolution from diffusion cells and dialysis bags. Both methods showed that release rate of (99m)Tc- Aprotinin from microemulsion could be controlled by microemulsion formulations. Drug release from the optimized microemulsion formulations was found lower compared to drug solution at the end of six hours. According to stability studies, the optimized formulation was found to be stable over a period of 12 months. Also, human immortalized pancreatic duct epithelial-like cells were used to evaluate the cytotoxicity of optimum formulation. Developed microemulsion did not reveal cytotoxicity. In conclusion the present study indicated that the M1-APT microemulsion is appropriate for intravenous application of aprotinin.

Characterization of solid lipid nanoparticles containing caffeic acid and determination of its effects on MCF-7 cells.

Many anticancer drugs that are currently used in cancer treatment are natural products or their analogues by structural modification. Caffeic acid (3, 4-dihydroxycinnamic acid; CA) is classified as hydroxycinnamic acid and has a variety of potential pharmacological effects, including antioxidant, immunomodulatory and anti-inflammatory activities. As a drug carrier, solid lipid nanoparticles (SLNs) introduced to improve stability, provide controlled drug release, avoid organic solvents and are obtained in small sizes. In this study, we developed solid lipid nanoparticles incorporating with caffeic acid using hot homogenization method. Caffeic acid loaded solid lipid nanoparticles were characterized regarding particle size, zeta potential, drug entrapment efficiency, drug release, scanning electron microscopy (SEM) and FT-IR. The effects of caffeic acid loaded solid lipid nanoparticles on MCF-7 cells were determined by 3-(4, 5-dimethylthiazol-2-yl)-2, 5-dimethyl tetrazolium bromide (MTT) test and Annexin V-PI analysis. As a result, solid lipid nanoparticles could potentially be used for the delivery of caffeic acid and solid lipid nanoparticles formulation enhanced the effects of caffeic acid on MCF-7 cells. Some relevant patents are also referred in this article.

Vitamin B12-loaded solid lipid nanoparticles as a drug carrier in cancer therapy.

Nanostructure-mediated drug delivery, a key technology for the realization of nanomedicine, has the potential to improve drug bioavailability, ameliorate release deviation of drug molecules and enable precision drug targeting. Due to their multifunctional properties, solid lipid nanoparticles (SLNs) have received great attention of scientists to find a solution to cancer. Vitamin supplements may contribute to a reduction in the risk of cancer. Vitamin B12 has several characteristics that make it an attractive entity for cancer treatment and possible therapeutic applications. The aim of this study was to produce B12-loaded SLNs (B12-SLNs) and determine the cytotoxic effects of B12-SLNs on H-Ras 5RP7 and NIH/3T3 control cell line. Results obtained by MTT assay, transmission electron and confocal microscopy showed that B12-loaded SLNs are more effective than free vitamin B12 on cancer cells. In addition, characterization studies indicate that while the average diameter of the B12 was about 650 nm, B12-SLNs were about 200 nm and the drug release efficiency of vit. B12 by means of SLNs increased up to 3 h. These observations point to the fact that B12-SLNs could be used as carrier systems due to the therapeutic effects on cancer.

Preparation and characterization of ascorbic acid loaded solid lipid nanoparticles and investigation of their apoptotic effects.

In this paper, ascorbic acid (Vitamin C, AA) known as an antioxidant was successfully incorporated in solid lipid nanoparticles (SLNs) by hot homogenization and efficient delivery of AA to cancer cells. The obtained SLN formulations were characterized by Nano Zetasizer ZS and HPLC with the particle size being less than 250nm. AA-SLNs exhibited sustained release and high entrapment efficiency. According to MTT test results, AA-SLNs showed high cytotoxic activity compared to the free AA against H-Ras 5RP7 cells without damaging NIH/3T3 control cells. These results were supported by the Annexin V-PI and caspase-3 assay. Furthermore, as compared to the AA, AA-SLNs exhibited more efficient cellular uptake, accumulated in the cytoplasm and induced apoptosis which was observed by confocal laser scanning microscopy (CLSM) and transmission electron microscopy (TEM). Thus, the results of this study suggest that SLNs can be a potential nanocarrier system for AA.

Preparation and characterization of nocodazole-loaded solid lipid nanoparticles.

Nocodazole (NCD) has more carcinogenic effect than similar drugs. Moreover, it has low drug release time and high particle size. Solid Lipid Nanoparticles (SLNs) have been evaluated for decrease in particle size and therefore increase in drug release time, for such drugs. In this study, NCD has been successfully incorporated into SLNs systems and remained stable for a period of 90 days. NCD structure related to the chemical nature of solid lipid is a key factor to decide whether anticarcinogenic agent will be incorporated in the long term and for a controlled optimization of active ingredient incorporation and loading, intensive characterization of the physical state of the lipid particles were highly essential. Thus, NMR, FT-IR, DSC (for thermal behavior) analyses were performed and the results did not indicate any problem on stability. Moreover, SLNs were decreased size of NCD in addition to increase in time of the drug release. After SLN preparation, particle size, polydispersity index, electrical conductivity and zeta potential were measured and drug release from NCD-loaded SLNs were performed. These values seem to be of the desired range.

Preparation and characterization of methotrexate-loaded microcapsules.

Methotrexate (MTX) has toxic effect to healthy tissues. Microencapsulation coats particles with a functional coat to optimize storage stability and to modulate release. In the present study, a new MTX encapsulated microcapsules were synthesized for controlling MTX release. Controlled drug release provides releasing of efficient dose and prevent drug side effect to tissues and also protects MTX from oxygen, pH and other interactions. MTX was encapsulated through biocompatible hyaluronic acid (HA) and sodium alginate (SA) with an encapsulation system to reduce its toxicity and for controlled release. The microcapsules prepared by vibrating nozzle were cross-linked with SA, HA and calcium chloride. Nozzle diameter and MTX concentration were changed according to loaded MTX and encapsulation efficiency were determined using HPLC. For the reliability of the data, validation studies of the HPLC method were performed. The precision of the method was demonstrated using intra- and inter-day assay relative standard deviation (RSD) values which are less than 2% in all instances. For the characterization of microcapsules, particle size, drug loading and in vitro drug release studies were performed. Diameters of MTX-loaded microcapsules were acquired approximately 160, 400 and 800 µm. Surface morphology of encapsulated microcapsules were displayed with light microscope. Eighty-nine percent MTX encapsulation efficiencies were achieved. Encapsulated MTX microcapsules showed controlled release when compared to pure MTX. While powder MTX dissolved completely in 10 min in the dissolution medium, MTX release from encapsulated MTX microcapsules became 40 h in 0.1 M PBS pH 7.4, including NaCl. MTX release from MTX-loaded microcapsules was reached to 79%. Moreover, drug efficiency was examined in vitro cell culture tests. Viability of 5RP7 cells were decreased to 88.5% for 96 h. When MTX was given directly to 5RP7 cells, viability of 5RP7 cells was decreased to 49.7% for 96 h. Flow cytometry studies also showed that, MTX microcapsules induced apoptosis. The goal of this study is to provide controlled release of MTX and to reduce the toxic effect of MTX.

Preparation and in vitro evaluation of controlled release hydrophilic matrix tablets of ketorolac tromethamine using factorial design.

Controlled release matrix tablets of ketorolac tromethamine (KT) were prepared by direct compression technique using cellulose derivatives as hydroxypropylmethyl cellulose (HPMC), hydroxyethyl cellulose (HEC), and carboxymethyl cellulose (CMC) in different concentrations (10-20%). The effect of polymer type and concentration was investigated on drug release by 2(3) factorial design. For the quality control of matrix tablets, weight deviation, hardness, friability, diameter-height ratio, content uniformity of KT, and in vitro dissolution technique were performed. UV Spectrophotometric method was used to detection of KT in matrix tablets. This method was validated. Dissolution profiles of the formulations were plotted and evaluated kinetically. An increase in polymer content resulted with a slow release rate of drug as was expected. According to the dissolution results, tablets prepared with HPMC + HEC + CMC (F1 and F8) were found to be the most suitable formulation for KT. About 99.27% KT was released from F8 in 7 h.