Intrapulmonary and intravenous administrations of dihydroergotamine mesylate have similar cardiovascular effects in the conscious dog.

BACKGROUND AND PURPOSE: The effects of intrapulmonary artery (i.p.a.) administration of dihydroergotamine mesylate (DHE) were evaluated. EXPERIMENTAL APPROACH: Conscious beagle dogs (n=4) were given DHE via the i.p.a. or i.v. route as two 0.014 mg kg(-1) doses and a 0.14 mg kg(-1) dose given 60 min apart. A recovery period of > or =45 h occurred before crossover to the alternative route. Physiological parameters were monitored by telemetry or direct measurement, and venous blood samples were collected for pharmacokinetic assessments. KEY RESULTS: No meaningful differences between i.v. and i.p.a. treatments were observed for heart rate, systemic pressures and vascular pressures. Aortic resistance increased 8, 27 and 70%, respectively, following three doses of i.v. DHE compared with 11, 37 and 57%, respectively, with i.p.a. DHE. Carotid artery resistance increased 22, 40 and 87%, respectively, following three doses of i.v. DHE, compared with 17, 45 and 67%, respectively, following i.p.a. DHE. Increases in coronary artery resistance were of similar magnitude following i.v. and i.p.a. DHE administration. Increases in left ventricular systolic and diastolic pressures were seen following all doses of i.v. and i.p.a. DHE. Changes following DHE 0.014 mg kg(-1) were minimal and not clinically significant. With DHE 0.14 mg kg(-1) by either route, emesis was the most common adverse event. CONCLUSIONS AND IMPLICATIONS: DHE has comparable effects delivered via simulated deep inhalation (i.p.a.) or i.v. administration. The risk of cardiovascular complications is unlikely to be greater following inhalation of DHE.

Safety and pharmacokinetics of inhaled morphine delivered using the AERx system in patients with moderate-to-severe asthma.

OBJECTIVE: The safety and pharmacokinetics of inhaled morphine in asthmatic subjects were investigated using the AERx System, a novel aerosol system. METHODS: Twenty subjects with asthma received inhaled placebo and inhaled morphine sulfate, 2.2 mg, 4.4 mg and 8.8 mg, on separate days in a single-blind crossover study. Six of the subjects received an additional open-label dose of 17.6 mg on a separate day. Plasma morphine concentrations and safety evaluations including pulmonary function testing were performed. RESULTS: Mean tmax values were similar following all dose groups at approximately 1-2 minutes. Mean AUC(0-->1) values showed dose proportionality for the first 3 dose groups (6.3, 12.3 and 24.3 ng x h x ml(-1)), the mean AUC(0-->1) for the 17.6 mg dose group was 1.6x that of the 8.8 mg dose group. No statistically significant differences in forced expiratory volume in 1 sec (FEV1) were found for the 2.2 mg, 4.4 mg, or 8.8 mg dose groups; at 17.6 mg, a statistically significant but not clinically meaningful reduction in mean FEV1 (-8.18%) from baseline occurred at 10 minutes compared to placebo, spontaneously returning to baseline by 60 min. Four subjects experienced significant but reversible decreases in FEV1 of > or = 20% compared to baseline and across all dose levels including after placebo, but with no associated increase in dyspnea, wheezing or other adverse events. CONCLUSIONS: Inhaled morphine using the AERx System was absorbed rapidly and demonstrated dose-dependent plasma concentrations. It was well-tolerated and did not cause clinically significant bronchoconstriction in most subjects with moderate-to-severe asthma.

Compliance with inhaled insulin treatment using the AERx iDMS Insulin Diabetes Management System.

OBJECTIVE: The AERx Insulin Diabetes Management System [AERx iDMS, jointly developed by Novo Nordisk (Bagsvaerd, Denmark) and Aradigm Corp. (Hayward, CA)] provides insulin by pulmonary administration. This investigation was designed as a pilot trial to demonstrate the ability of patients to use the electronic device to deliver mealtime inhaled insulin doses and explore the impact on compliance. METHODS: AERx iDMS was evaluated in a substudy of a 12-week, multicenter open trial by adult patients with type 2 diabetes previously on any insulin regimen. The device was used for dosing fast-acting human insulin immediately before main meals, in combination with bedtime NPH insulin. The AERx iDMS device recorded the date and time of each insulin inhalation, insulin units used, and inhalation technique during aerosol delivery. Compliance was defined as the percentage of prescribed doses taken during the treatment period, dose timing, and the efficiency of dosing technique. RESULTS: Insulin dosing for 49 patients (age 59.1 +/- 7.7 years) using AERx iDMS was monitored for 78.9 +/- 10 days (range, 41-94 days) with 226 +/- 35 doses (range, 122-272 doses). Patients inhaled on average 2.9 +/- 0.3 doses of insulin daily, taking an average of 11.8 +/- 5.6 units per dose. Compliance with the prescribed regimen was 94.3 +/- 9.1% (range, 45-100%). Overall, 4.2 +/- 9.5% of prescribed doses were omitted. Hemoglobin A1c decreased 0.77 +/- 0.96% from baseline to the end of the study. Inhalation technique was excellent, with 97% of patients experiencing fewer than five inadequate doses. CONCLUSIONS: Excellent compliance with AERx iDMS dosing, timing, and inhalation technique showed that the device was well accepted by patients. The electronic monitoring feature could be used as an educational tool to help patients and clinicians manage insulin dosing.

Dose-response relation of liquid aerosol inhaled insulin in type I diabetic patients.

AIMS/HYPOTHESIS: The AERx insulin Diabetes Management system (AERx iDMS) is a liquid aerosol device that enables insulin to be administered to the peripheral parts of the lung. This study aimed to compare the pharmacokinetic and pharmacodynamic properties of insulin which is inhaled using AERx iDMS with insulin which is subcutaneously administered. METHODS: In total, 18 C-peptide negative patients with Type I (insulin-dependent) diabetes mellitus participated in this randomised, open-label, 5-period crossover trial. Human regular insulin was administered subcutaneously (0.12 U/kg body weight) or inhaled by means of the AERx iDMS (dosages 0.3, 0.6, 1.2, and 1.8 U/kg body weight). Thereafter plasma glucose was kept constant at 7.2 mmol/l for a 10-h period (glucose clamp technique). RESULTS: Inhaled insulin provided a dose-response relation that was close to linear for both pharmacokinetic (AUC-Ins(0-10 h); Cmax-Ins) and pharmacodynamic (AUC-GIR(0-10 h); GIRmax) parameters. Time to maximum insulin concentration (Tmax-Ins) and time to maximum glucose infusion rate (TGIRmax) were shorter with inhaled insulin than with subcutaneous administration. The pharmacodynamic system efficiency of inhaled insulin (AUC-GIR(0-6 h) was 12.7% (95% C.I.: 10.2-15.6). CONCLUSION/INTERPRETATION: The inhalation of soluble human insulin using the AERx iDMS is feasible and provides a clear dose response. Further long-term studies are required to investigate safety aspects, HbA1c values, incidence of hypoglycaemic events and the quality of life.

Comparison of in vitro and in vivo efficiencies of a novel unit-dose liquid aerosol generator and a pressurized metered dose inhaler.

Gamma scintigraphic imaging was employed in 10 healthy volunteers to compare the total and regional lung deposition of aerosols generated by two delivery platforms that permitted microprocessor-controlled actuation at an optimal point during inhalation. An aqueous solution containing 99mTc-DTPA was used to assess the deposition of aerosols delivered by inhalation from two successive unit-dosage forms (44 microl volume) using a prototype of a novel liquid aerosol system (AERx Pulmonary Delivery System). This was compared with aerosol deposition after inhalation of two 50 microl puffs of a 99mTc-HMPAO-labeled solution formulation from a pressurized metered dose inhaler (MDI). The in vitro size characteristics of the radiolabeled aerosols were determined by cascade impaction. For the AERx system, the predicted lung delivery efficiency based on the product of emitted dose (60.8%, coefficient of variation (CV)=12%) and fine particle fraction (% by mass of aerosol particles <5.7 microm in diameter) was 53.3% (CV=13%). For the solution MDI, the emitted dose was 62.9% (CV=13%) and the predicted lung dose was 44. 9% (CV=15%). The AERx system demonstrated efficient and reproducible dosing characteristics in vivo. Of the dose loaded into the device, the mean percent reaching the lungs was 53.3% (CV=10%), with only 6. 9% located in the oropharynx/stomach. In contrast, the lung deposition from the solution MDI was significantly less (21.7%) and more variable (CV=31%), with 42.0% of the radiolabel detected in the oropharynx/stomach. Analysis of the regional deposition of the radioaerosol indicated a homogeneous pattern of deposition after delivery from the AERx system. A predominantly central pattern of distribution occurred after MDI delivery, where the pattern of deposition was biased towards a central zone depicting the conducting airways. The AERx system, in contrast to MDIs, seems highly suited to the delivery of systemically active agents via pulmonary administration.

Pulmonary insulin administration using the AERx system: physiological and physicochemical factors influencing insulin effectiveness in healthy fasting subjects.

BACKGROUND: Orally inhaled insulin may provide a convenient and effective therapy for prandial glucose control in patients with diabetes. This study evaluated the influence of formulation pH and concentration and different respiratory maneuvers on pharmacokinetic and pharmacodynamic properties of inhaled insulin. METHODS: Three, open-label crossover studies in a total of 23 healthy subjects were conducted in which the safety, pharmacokinetics, and pharmacodynamics of insulin inhalation were compared to subcutaneous (SC) injection into the abdomen of commercially available regular insulin. A novel, aerosol generating system (AERx Diabetes Management System, Aradigm Corporation, Hayward, CA) was used to deliver aqueous insulin bolus aerosols to the lower respiratory tract from formulations at pH 3.5 or 7.4 and concentrations of U250 (250 U/mL) or U500 (500 U/mL). RESULTS: Time to maximum insulin concentration in serum (Tmax) after SC dosing occurred approximately 50-60 minutes with the time to minimum plasma glucose concentration (i.e., maximum hypoglycemic effect), (TGmin), occurring later, at around 100-120 minutes. In contrast, pulmonary delivery led to a significantly earlier Tmax (7-20 minutes) and TGmin (60-70 minutes), parameters that were shown to be largely unaffected by changing the pH or concentration of the insulin. However, investigation of changes in inhaled volume (achieved by different programming of the AERx system) for administration of the same sized aerosol bolus revealed significant effects. Significantly slower absorption and time to peak hypoglycemic activity occurred when aerosol delivery of insulin occurred during a shallow (approximately 40% vital capacity) as opposed to a deep (approximately 80% vital capacity) inspiration. In addition, it was shown that serum concentration of insulin increased immediately after a series of forced expiraratory maneuvers 30 minutes after inhaled delivery. CONCLUSIONS: Pulmonary delivery of aqueous bolus aerosols of insulin in healthy subjects resulted in rapid absorption with an associated hypoglycemic effect quicker than is achieved after subcutaneous dosing of regular insulin. Inhaled insulin pharmacokinetics and pharmacodynamics were independent of formulation variables (pH, concentration) but affected by certain respiratory maneuvers.

Morphine pharmacokinetics after pulmonary administration from a novel aerosol delivery system.

BACKGROUND: Successful pharmacotherapy of pain often depends on the mode of drug delivery. A novel, unit dose, aqueous aerosol delivery system (AERx Pulmonary Drug Delivery System) was used to examine the feasibility of the pulmonary route for the noninvasive systemic administration of morphine. METHODS: The study had two parts: (1) a dose-ranging study in four subjects with three consecutive aerosolized doses of 2.2, 4.4, and 8.8 mg (nominal) morphine sulfate pentahydrate at 40-minute intervals, and (2) a crossover study, on separate days, in six subjects with 4.4 mg (nominal) aerosolized morphine sulfate administered over 2.1 minutes on three occasions and intravenous infusions of 2 and 4 mg over 3 minutes. Subjects were healthy volunteers from 19 to 34 years old. Arterial blood was sampled for a total of 6 hours and plasma morphine concentrations were measured by gas chromatography-mass spectrometry. RESULTS: In part 1, plasma morphine concentrations were proportional to dose. In part 2, the mean +/- SD peak plasma concentration (Cmax) occurred at 2.7 +/- 0.8 minutes after the aerosol dose, with mean values for Cmax of 109 +/- 85, 165 +/- 22, and 273 +/- 114 ng/ml for the aerosol and 2 and 4 mg intravenous doses, respectively. The bioavailability [AUC(0-360 min)] of aerosol-delivered morphine was approximately 100% relative to intravenous infusion, with similar intersubject variability in AUC for both routes (coefficient of variation < 30%). CONCLUSION: The time courses of plasma morphine concentrations after pulmonary delivery by the AERx system and by intravenous infusions were similar. This shows the utility of the pulmonary route in providing a noninvasive method for the rapid and reproducible systemic administration of morphine if an appropriate aerosol drug delivery system is used.

Experience with a metered-dose inhaler with a spacer in the pediatric emergency department.

Studies of adults suggest that metered-dose inhalers with spacers are as effective as hand-held nebulizers for bronchodilator delivery. We studied 13 children with acute asthma. They received two puffs every 2 minutes from metered-dose inhalers with spacers (range, 4 to 14 puffs) titrated until improvement stopped. Peak expiratory flow increased 34% for metered-dose inhalers with spacers after the first 2 puffs and increased 87% for metered-dose inhalers with spacers after dose titration. After titration, respiratory rate decreased by 12%, heart rate increased by 2%, and breath sounds improved in 92% of the patients. We concluded that the metered-dose inhalers with spacers are an effective device for the treatment of asthma in the pediatric emergency department and that the use of metered-dose inhalers with spacers with titration can achieve significant bronchodilation in the treatment of patients with acute asthma.