ABSTRACT
The stability of a new insulin formulation (lyophilized U100 insulin, Organon) was investigated in vitro in conditions reproducing those of in vivo implanted devices, i.e., constant horizontal agitation at 37 degrees C for 4 wk in various containers and 8 wk in different solvents. Physical stability was assessed by ultraviolet absorption, chemical stability by HPLC, and biological stability by hypoglycemia tests in mice. Insulin precipitated in glass vials but remained clear and active in polyethylene reservoirs and after passage through catheter and pumps in motion, although only 83-90% of insulin was delivered chemically intact. In acidic solvent, insulin showed a major gradual transformation into deamidized derivatives (up to 78% after 8 wk), although still fully active and clear, as expected from previously published excellent in vivo results with acidic insulins. Heparin addition to neutral insulin solution (500 IU/ml) did not alter the properties of the two compounds and might thus be tried to prevent in vivo catheter obstruction due to fibrin deposition.
Subject(s)
Insulin Infusion Systems , Insulin , Chromatography, High Pressure Liquid , Drug Incompatibility , Drug Packaging , Drug Stability , Freeze Drying , Heparin , Hydrogen-Ion Concentration , Nephelometry and Turbidimetry , SolventsABSTRACT
The bioavailability of rapid-acting insulin administered as a nasal spray was studied in 6 type 1 (insulin-dependent) diabetic patients. They received long-acting bovine insulin (Ultratardum 40 U/ml, Organon) as basal treatment at 8 a.m. Rapid-acting insulin was also administered at 8 a.m., then at noon and 6 p.m, subcutaneously on day 1 as a 100 U/ml solution and intranasally by aerosol spray as a 100 U/ml and 500 U/ml with 1% (w/v) 9 lauryl ether solution on day 2 and day 3 respectively. On days 2 and 3, the dose of insulin was at least nine times higher than the subcutaneous dose on day 1. Free and total plasma insulin concentrations were assayed after the noon insulin administration. The peaks of the free and total plasma insulin levels were reached earlier and the return to basal levels was obtained earlier after nasal insulin administration than after insulin injected subcutaneously. The bioavailability of nasal spray insulin versus subcutaneous insulin with a 100 U/ml insulin solution was similar to that with a 500 U/ml insulin solution: 5.14 +/- 0.38% (m +/- SEM) and 4.64 +/- 0.46% according to the total plasma insulin level. This study suggests that the bioavailability of nasal spray insulin is not increased by increasing insulin concentration in our experimental conditions.