The phenylephrine concentration-response relationship for blood pressure after nasal delivery in children.

BACKGROUND: Intranasal phenylephrine is commonly used to vasoconstrict the nasal mucosa, reducing bleeding associated with nasotracheal intubation or endoscopic sinus surgery. There are few data quantifying either absorption pharmacokinetics or phenylephrine concentration effect on blood pressure in children. METHODS: Published observations of plasma concentration and blood pressure changes after phenylephrine nasal administration (0.1 mL kg-1 , 0.25% or 0.5%) in children (n = 52, 2-12 years, 10-40 kg) were pooled with those in adults (23-81 years) given phenylephrine 2.5% (n = 10) and 10% (n = 10) eyedrops. Further pharmacokinetic (PK) data were available from healthy volunteers given oral phenylephrine 10 mg alone, with blood for concentration assay taken at 5, 15, 30, 45 minutes and 1, 2, 3, 6 hours (n = 28). Intravenous time-concentration data were available from four healthy volunteers given phenylephrine 1 mg and who had blood taken for assay on 17 occasions over the subsequent 4 hours. Data were analyzed using an integrated pharmacokinetic-pharmacodynamic (PK-PD) model using nonlinear mixed-effects models. Allometry, scaled to a 70-kg person, was used for PK size standardization. Effect was described using an EMAX model. RESULTS: A two-compartment model was used to fit PK data while an additional compartment, linked by an equilibration half-time (T1/2 keo), was used to describe effect. PK parameter estimates for the nasal formulation were clearance (CL) 160 L h-1 , central volume of distribution (V1) 13.3 L, intercompartment clearance (Q) 25.3 L h-1 , peripheral volume of distribution (V2) 225 L, absorption half-time (Tabs) 6.2 minutes, absorption lag time (Tlag) 1.5 minutes, and bioavailability (F) 0.183. Bioavailability and absorption of the ophthalmic solution were concentration dependent (F 0.13, Tabs 5.5 minutes for 2.5% solution; F 0.15, Tabs 9.6 minutes for 10% solution). Absorption of the oral formulation was slow (Tabs 48 minutes) with poor bioavailability (F 0.0128). The pediatric PD interrogation revealed a baseline mean arterial pressure of 60 mm Hg, a maximum effect (EMAX ) of 25 mm Hg, and an EC50 of 10.3 µg L-1 . The effect on vasculature was immediate and T1/2 keo was not estimable. CONCLUSION: Absorption of phenylephrine through the nasal mucosa was rapid and similar to the ophthalmic formulation. Bioavailability was also similar to the ophthalmic formulation. The maximum effect (EMAX ) in children was half that in adults (EMAX 50 mm Hg).

Hemodynamic responses and plasma phenylephrine concentrations associated with intranasal phenylephrine in children.

INTRODUCTION: Intranasal phenylephrine, an alpha-1 adrenergic agonist, causes vasoconstriction of the nasal mucosa and is used to reduce bleeding associated with nasotracheal intubation or endoscopic sinus surgery. The purpose of this study was to describe the hemodynamic effects associated with plasma phenylephrine concentrations following topical intranasal administration of 0.25% and 0.5% phenylephrine in children. METHODS: After Institutional Review Board and parental approval, 77 children between the ages of 2 and 12 years were studied in a prospective, double-blind manner and randomized into three groups. Group 1 received intranasal saline, while groups 2 and 3 received 0.1 mL/kg of 0.25% or 0.5% phenylephrine, respectively. All received the same anesthetic of halothane, N2 O, O2 , and vecuronium. After inhalation induction, endtidal halothane and PaCO2 were maintained at 1.5% and 35 mm Hg, respectively. Heart rate and rhythm, systolic, diastolic, and mean, noninvasive arterial blood pressures were recorded and venous blood was obtained for measurement of plasma phenylephrine concentration by high-performance liquid chromatography at baseline and at 2, 5, 10, and 20 minutes following intranasal spray application of the study drug. Nasotracheal intubation was performed immediately following the 5-minute measurements, and the presence of bleeding was assessed. Hemodynamic data were compared by analysis of variance for repeated measures. Bleeding and arrhythmia incidence among groups were analyzed using chi-squared tests. Phenylephrine levels were correlated with hemodynamic values via regression analysis. RESULTS: Fifty-two patients received intranasal phenylephrine. Increases in blood pressure correlated with increasing plasma phenylephrine concentration. Systolic blood pressure increased 8%, and mean blood pressure increased 14%, which were statistically significant but clinically insignificant. Heart rate did not change, and the incidence of arrhythmia was low and similar among groups. Bleeding following nasotracheal intubation was less frequent in Group 3 (11/27 subjects) than in Group 1 (17/25). Peak plasma phenylephrine concentrations were observed by 14±7 minutes following intranasal administration, and were highly variable among individuals (37.8±39.7 and 49.6±93.9 ng/mL [mean±SD] in Groups 2 and 3). DISCUSSION: Administration of intranasal phenylephrine, 0.25% and 0.50%, results in rapid but highly variable systemic absorption that is associated with mild increases of blood pressure that are clinically insignificant. Bleeding associated with nasotracheal intubation was less following administration of 0.5% intranasal phenylephrine than following intranasal saline.

Using the capnograph to confirm lung isolation when using a bronchial blocker.

The endotracheal tube and bronchial blocker combination is an accepted lung isolation technique used during thoracic surgery. A reliable and inexpensive method of confirming lung isolation that uses capnographic monitoring of the bronchial blocker central lumen is presented. As the bronchial blocker balloon is inflated, lung isolation is confirmed when the normal respiratory variation of carbon dioxide (CO(2)) is replaced by a persistent plateau CO(2) waveform.