OBJECTIVE: The AERx insulin Diabetes Management System (AERx iDMS) (Aradigm, Hayward, CA) delivers an aerosol of liquid human insulin to the deep lung for systemic absorption. This study examined the effects on pulmonary function, pharmacokinetics, and pharmacodynamics of inhaled insulin in asthmatic and nonasthmatic subjects without diabetes. RESEARCH DESIGN AND METHODS: A total of 28 healthy and17 asthmatic (forced expiratory volume during the first second [ FEV(1)] 50-80% of predicted value) subjects were enrolled in a two-part, open-label trial. To assess insulin pharmacokinetics and pharmacodynamics, a single inhalation dose of 1.57 mg (45 IU) was given on each of the 2 dosing days in part 1. A dose of 4.7 mg (135 IU) of insulin was inhaled in part 2 to assess effects on pulmonary function. RESULTS:Inhaled insulin showed area under the curve (AUC)((0-360 min)) values that were significantly greater for healthy subjects than for asthmatic subjects (P = 0.013), whereas no difference was observed for maximum concentration (C(max)) in the two groups. A greater reduction of serum glucose as indicated by area over the curve (AOC)((0-360 min)) was observed in healthy subjects (P = 0.007). Asthmatic subjects had greater intrasubject variations in insulin AUC((0-360 min)) and C(max) values than healthy subjects, but similar variations in glucose AOC((0-360 min)). No significant changes in FEV(1), forced vital capacity (FVC), and FEV(1)/FVC were observed from pre- to postdose times, and there were no observed safety issues. CONCLUSIONS: After inhaling insulin using the AERx iDMS, asthmatic subjects absorbed less insulin than healthy subjects, resulting in less reduction of serum glucose. No effects on airway reactivity were observed. Diabetic patients with asthma may need to inhale more insulin than patients with normal respiratory function in order to achieve similar glycemic control.
RCT Entities:
OBJECTIVE: The AERx insulin Diabetes Management System (AERx iDMS) (Aradigm, Hayward, CA) delivers an aerosol of liquid humaninsulin to the deep lung for systemic absorption. This study examined the effects on pulmonary function, pharmacokinetics, and pharmacodynamics of inhaled insulin in asthmatic and nonasthmatic subjects without diabetes. RESEARCH DESIGN AND METHODS: A total of 28 healthy and 17 asthmatic (forced expiratory volume during the first second [ FEV(1)] 50-80% of predicted value) subjects were enrolled in a two-part, open-label trial. To assess insulin pharmacokinetics and pharmacodynamics, a single inhalation dose of 1.57 mg (45 IU) was given on each of the 2 dosing days in part 1. A dose of 4.7 mg (135 IU) of insulin was inhaled in part 2 to assess effects on pulmonary function. RESULTS: Inhaled insulin showed area under the curve (AUC)((0-360 min)) values that were significantly greater for healthy subjects than for asthmatic subjects (P = 0.013), whereas no difference was observed for maximum concentration (C(max)) in the two groups. A greater reduction of serum glucose as indicated by area over the curve (AOC)((0-360 min)) was observed in healthy subjects (P = 0.007). Asthmatic subjects had greater intrasubject variations in insulin AUC((0-360 min)) and C(max) values than healthy subjects, but similar variations in glucose AOC((0-360 min)). No significant changes in FEV(1), forced vital capacity (FVC), and FEV(1)/FVC were observed from pre- to postdose times, and there were no observed safety issues. CONCLUSIONS: After inhaling insulin using the AERx iDMS, asthmatic subjects absorbed less insulin than healthy subjects, resulting in less reduction of serum glucose. No effects on airway reactivity were observed. Diabeticpatients with asthma may need to inhale more insulin than patients with normal respiratory function in order to achieve similar glycemic control.
Authors: Astrid H Petersen; Stefan Korsatko; Gerd Köhler; Andrea Wutte; Horst Olschewski; Thomas Sparre; Jacob Råstam; Per Wollmer; Thomas R Pieber Journal: Br J Clin Pharmacol Date: 2010-03 Impact factor: 4.335