Isotropic medium chain mono- and diglyceride systems : vehicles for subcutaneous injection in sheep

Sari, Peyami, n/a

January 2005

Purpose: To develop an approach to formulating an injectable solution containing both hydrophilic and lipophilic drugs for subcutaneous administration. Based on the literature survey, isotropic medium chain mono-and diglyceride (MCMDG) systems were chosen for study. For this purpose, analytical methods were developed and validated. In vitro assessments of the MCMDG systems, and in vitro release and in vivo studies were conducted. Methods: The phase diagrams of the isotropic MCMDG systems were constructed with systems comprising two and three components. The isotropic region was examined by visual inspection and confirmed using polarized light microscopy. Viscosities of formulations were measured. The validated HPLC assay methods were developed for determination of levamisole and abamectin in liquid formulations and in sheep plasma. The HPLC assay was capable of evaluating stability of abamectin and levamisole in liquid formulations. Solubilities of levamisole hydrochloride or levamisole phosphate and abamectin were determined in the isotropic MCMDG formulations using a HPLC assay method. Stabilities of levamisole phosphate and abamectin were conducted in the isotropic MCMDG formulations at 60�C for 10 days. In vitro release studies for levamisole phosphate were carried out for selected formulations using modified Franz diffusion cells. Based on stability and in vitro release studies, one formulation (MCMDG/propylene glycol (PG):glycerol formal (GF), 20/20:60 % w/w) was selected for a preliminary in vivo study. The selected MCMDG/PG:GF (20/20:60) formulation containing both levamisole phosphate and abamectin was injected subcutaneously into sheep, and the injection site was examined after subcutaneous injection. Pharmacokinetic profiles were determined. A correlation between in vitro fraction released (FR) and in vivo fraction absorbed (FA) for levamisole phosphate from the MCMDG/PG:GF (20/20:60) formulation was assessed. Results: The isotropic systems of the MCMDG systems containing two or three components were characterized through phase diagrams and viscosity. The solubility of the levamisole hydrochloride in the isotropic MCMDG/sesame oil/water formulations was higher in the absence of abamectin than in combination with abamectin. Solubility of levamisole phosphate was higher in the MCMDG system containing GF or PG compared to the MCMDG/SO/water system. The isotropic MCMDG/PG:GF systems allowed preparations of levamisole phosphate/abamectin solution dose forms containing more than the usual dosage of levamisole. Stability of both levamisole phosphate and abamectin in MCMDG/PG:GF formulations was higher compared with MCMDG/PG:GF/water formulations. Levamisole phosphate degraded in the presence or absence of abamectin in the MCMDG/PG:GF (20/20:60) formulation at 60�C for 10 days. Abamectin alone was found to be stable in the formulation at 60�C for 10 days. In vitro release of levamisole phosphate from water and the MCMDG formulations tested displayed first-order kinetics. Water from the receptor compartment was observed to pass through the membrane into the donor compartment. Therefore, an advancing layer of turbidity occurred in the donor phase. A highly significant decrease in release rate of levamisole phosphate was obtained in MCMDG/GP:GF (20/20:60) formulation compared to water and the other formulations. Pharmacokinetic studies of subcutaneous injection of MCMDG/PG:GF 20/20:60) formulation showed the tmax values of 2.2 h and 4.2 days for levamisole phosphate and abamectin, respectively. The Cmax was 0.94 [mu]g/ml for levamisole phosphate and 6.24 ng/ml for abamectin while the formulation displayed the AUC value was 5.2 [mu]g�h�ml⁻1 for levamisole phosphate and 84.7 ng�day�ml⁻1 for abamectin. No inflammatory reaction was observed at the injection site. Linear regression analysis showed that a significant relationship between the FR (in vitro) and FA for the subcutaneously injected formulation. Conclusion: The study carried out in this thesis introduces a new approach to formulating an injectable solution of the isotropic MCMDG/PG:GF systems containing both levamisole (hydrophilic drug) and abamectin (lipophilic drug) for subcutaneous administration, and presents the development of the HPLC assay methods for determination of levamisole and abamectin in liquid MCMDG formulations and plasma, in order to investigate in vitro and in vivo release from the isotropic MCMDG/PG:GF formulations. The MCMDG/PG:GF formulations may represent an alternative to the more traditional formulations for both lipophilic and hydrophilic drugs.

injections

solutions (pharmacy)

drugs administration

sheep as laboratory animals

Research into process validation in pharmaceutical companies, with specific reference to Roche, South Africa

Boca, Madalina Brindusa.

January 2009

Thesis (PhD(Anatomy, Faculty of Health Sciences))--University of Pretoria, 2006.

The relationship between length of time and contamination in open intravenous solutions a research report submitted in partial fulfillment ... /

Amonsen, Sharon. Gren, Janet.

January 1977

Thesis (M.S.)--University of Michigan, 1977.

A study of the effect of certain anionic surface active agents in suspensions of selected pharmaceutical powders

Groves, Gordon Arnold.

January 1958

Thesis (Ph. D.)--University of Wisconsin--Madison, 1958. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

The effect of triacetin on solubility of diazepam and phenytoin

Riley, Christine Marie, 1964-

January 1990

The effect of triacetin in combination with common cosolvents on the solubility of phenytoin and diazepam was studied. The cosolvents were PEG 400 and propylene glycol. In addition, the data were used to test the following model: UNFORMATTED EQUATION FOLLOWS: log Sᵈ(c,p,w) = log Sᵈ(w) + f(c)σᵈ(c) + [Sᵖ(w)10(f(c)σᵖ(c))/D(p)] σᵈ(p). UNFORMATTED EQUATION ENDS. The term on the left side of the equation is the solubility of a drug in the ternary system. This is related to the aqueous solubility of the drug, the solubility of the drug in a completely miscible organic solvent (CMOS), and the solubility of the partially miscible organic solvent (PMOS). This model was proposed by Gupta et al. (1989) and predicts the solubility of a ternary system composed of a CMOS and PMOS. The results indicate the triacetin does increase the solubility of the two poorly water-soluble drugs. There is good correlation between the observed and predicted increase in the solubility of the drugs.

Diazepam -- Solubility.

Phenytoin -- Solubility.

Drug carriers (Pharmacy)

Solubility -- Mathematical models.

Solutions (Pharmacy)

Compatibility and stability of 8% amino acids solution in combination with electrolytes, vitamins and antibiotics

Schuetz, David Harold

01 January 1973

For centuries, researchers have attempted to devise the ideal parenteral nutritional product readily amenable to physiological requirements. Hyperalimentation, intravenous alimentation, parenteral alimentation, parenteral feeding, and total parenteral nutrition are synonyms which refer to a method of complete intravenous nutrition reserved for patients demonstrating negative nitrogen balance. The nutrient solution appeared to accommodate levels of potassium phosphate, calcium gluconate, and magnesium sulfate well in excess of “usual” therapeutic concentrations. Similarly, commonly employed vitamin supplements and insulin were examined in combination with the hyperalimentation solution and failed to demonstrate signs of physical incompatibility. However, instrumental analysis, i.e., U.V. spectroscopy and thin-layer chromatography, suggested, in fact, there may have been chemical interaction of Solu B Forte and MVI once admixed with the amino acids/dextrose solution. Yet, results of thin-layer chromatography did not appear to substantiate chemical interaction between MVI and the amino acids solution. The investigator contends further study of multiple vitamin infusion stability be completed before definite conclusions are formulated regarding their compatibility in this nutritional infusate.

Amino acids

Electrolytes

Antibiotics

Vitamins

Solutions (Pharmacy)

Medicine and Health Sciences

Physical Sciences and Mathematics