The in Vitro Actions of Loxapine on Dopaminergic and Serotonergic Receptors. Time to Consider Atypical Classification of This Antipsychotic Drug?

Background: The denomination of typical antipsychotic for loxapine has poor relation to current knowledge of the molecule's relevant modes of action. Materials and Methods: Competition binding experiments were performed on expressed human recombinant receptors in CHO cells and HEK-293 cells for D1 to D5, 5-HT1A, 5-HT2A, 5-HT2C, 5-HT4, 5-HT6, and 5-HT7. In vitro autoradiographies using [11C]-Raclopride [18F]-Altanserin [18F]-MPPF [11C]-SB207145, and [18F]-2FNQ1P were measured in brain tissue of a male primate followed by addition of increasing doses of loxapine succinate. Results: In cell cultures, the measured Kb confirmed high affinity of loxapine for the D2; intermediate affinity for the D1, D4, D5, 5-HT2C receptorsl and a lack of affinity toward D3, 5-HT1A, 5-HT4, 5-HT6, and 5-HT7 receptors. In brain tissue, PET autoradiographies showed a radiopharmaceutical displacement at low concentrations of loxapine on D2 and 5-HT2A receptors. Conclusion: This preclinical study reveals that loxapine receptorial spectrum is close to an "atypical" profile (D2/5HT2A ratio, 1.14). Loxapine is rightly classified as a DS-RAn agent in the Neuroscience Based Nomenclature classification.

Success of tardive electroconvulsive therapy sessions after loxapine-induced malignant syndrome in the context of very poor metabolisation.

We report the success of tardive electroconvulsive therapy in a case of loxapine malignant syndrome with catatonia. Loxapine and its metabolites were measured in biological samples by liquid chromatography coupled to tandem mass spectrometry. Genes were studied by sequencing and quantitative polymerase chain reaction (PCR). Plasmatic drug concentrations showed a supratherapeutic concentration of loxapine with a very low 8-hydroxyloxapine/loxapine ratio (range from 0.32 to 0.66, normal value>2 for 100mg) and a very long elimination half-life of loxapine (half-life>140h, normal value from 1 to 4hours). We tried to explain this kinetics by exploring the main pharmacogenes implicated in the metabolism of loxapine. No genetic abnormality for CYP1A2 was observed. The study of associated treatments showed the potential contribution of valproate. Pharmacokinetics and pharmacogenetics investigations revealed a blockade of the CYP1A2 metabolic pathway without genetic abnormalities, probably due to valproate co-medication. Toxicological monitoring of loxapine and its metabolites helped to explain the persistence of symptoms and to adapt the therapeutic management.

Pharmacokinetics and Safety of Single-Dose Inhaled Loxapine in Children and Adolescents.

This multisite open-label study sought to characterize the pharmacokinetics and safety of a single dose of inhaled loxapine in children and adolescents. Loxapine powder for oral inhalation was administered via a single-use handheld drug device to children and adolescents (aged 10-17 years) with any condition warranting chronic antipsychotic use. Patients were dosed according to body weight and cohort (<50 kg [n = 15], 2.5 or 5 mg; ≥50 kg [n = 15], 5 or 10 mg); the first 6 patients (cohort 1) enrolled in each weight group received the lower dose. Patients were enrolled in the higher-dose group (cohort 2) after an interim pharmacokinetic and safety analysis of data from cohort 1. Blood samples were collected for 48 hours after dosing to determine the pharmacokinetic profile of loxapine and its metabolites. Safety was assessed using adverse event (AE), laboratory value, physical/neurologic examination, vital sign, electrocardiogram, suicidality, and extrapyramidal symptom assessment. Thirty patients were enrolled and evaluable for pharmacokinetics. Loxapine plasma concentrations peaked by 2 to 5 minutes in most patients; systemic exposure increased with dose in both weight subgroups. Loxapine terminal elimination half-life was ∼13 to 17 hours. The most common AEs were sedation and dysgeusia. Sedation was severe in 1 patient in the <50-kg group (2.5-mg dose) and 1 patient in the ≥50-kg group (5-mg dose). No AEs indicative of bronchospasm or other serious AEs were reported. Inhaled loxapine was rapidly absorbed and generally well tolerated in pediatric patients; no new safety signals were observed.

The Role of Inhaled Loxapine in the Treatment of Acute Agitation in Patients with Psychiatric Disorders: A Clinical Review.

Loxapine is a first generation antipsychotic, belonging to the dibenzoxazepine class. Recently, loxapine has been reformulated at a lower dose, producing an inhaled powder that can be directly administered to the lungs to treat the agitation associated with psychiatric disorders, such as schizophrenia and bipolar disorder. Thus, the aim of this narrative and clinical mini-review was to evaluate the efficacy and tolerability of inhaled loxapine in the treatment of acute agitation in patients with psychiatric disorders. The efficacy of inhaled loxapine has been evaluated in one Phase II trial on patients with schizophrenia, and in two Phase III trials in patients with schizophrenia and bipolar disorder. Moreover, there are two published case series on patients with borderline personality disorder and dual diagnosis patients. Inhaled loxapine has proven to be effective and generally well tolerated when administered to agitated patients with schizophrenia and bipolar disorder. Two case series have suggested that inhaled loxapine may also be useful to treat agitation in patients with borderline personality disorder and with dual diagnosis, but further studies are needed to clarify this point. However, the administration of inhaled loxapine requires at least some kind of patient collaboration, and is not recommended in the treatment of severe agitation in totally uncooperative patients. Moreover, the drug-related risk of bronchospasm must always be kept in mind when planning to use inhaled loxapine, leading to a careful patient assessment prior to, and after, administration. Also, the higher costs of inhaled loxapine, when compared to oral and intramuscular medications, should be taken into account when selecting it for the treatment of agitation.

Clinical Trial Simulations and Pharmacometric Analysis in Pediatrics: Application to Inhaled Loxapine in Children and Adolescents.

BACKGROUND AND OBJECTIVES: Loxapine for inhalation is a drug-device combination product approved in adults for the acute treatment of agitation associated with schizophrenia or bipolar I disorder. The primary objective of this study was to develop a clinical trial protocol to support a phase I pharmacokinetic study in children aged 10 years and older. In addition, this report details the results of the clinical study in relation to the predicted likelihood of achieving the target exposure associated with therapeutic effect in adults. METHODS: A nonlinear mixed-effects population pharmacokinetic model was developed using adult data and was adjusted for the targeted pediatric age groups by applying allometric scaling to account for body size effects. Based on this pediatric model, age-appropriate regimens to achieve loxapine exposures similar to the ones associated with therapeutic effect in the adult studies were identified via trial simulation. D-optimal design and power analysis were conducted to identify optimal pharmacokinetic sampling times and sample size, respectively. RESULTS: The developed clinical trial design formed the basis of a phase I study to assess the safety and pharmacokinetics of loxapine for inhalation in children aged 10 years and older (ClinicalTrials.gov ID: NCT02184767). CONCLUSION: The results of the study indicated that overall loxapine exposures were consistent with what had been predicted by the trial simulations. The presented approach illustrates how modeling and simulation can assist in the design of informative clinical trials to identify safe and effective doses and dose ranges in children and adolescents.

Simultaneous quantification of loxapine, loxapine N-oxide, amoxapine, 8-hydroxyloxapine and 7-hydroxyloxapine in human plasma using LC-MS/MS.

Loxapine is an antipsychotic medication used for the treatment of schizophrenia. In vivo, loxapine is metabolized to multiple metabolites. A high performance liquid chromatographic-tandem mass spectrometry (LC-MS/MS) method has been developed and validated for the determination of loxapine and 4 of its metabolites, loxapine N-oxide, amoxapine (N-desmethyl loxapine), 8-hydroxyloxapine and 7-hydroxyloxapine, in human plasma to support regulated clinical development. During method development, several technical challenges such as poor chromatography, separation of structural isomers, and inadequate sensitivity were met and overcome. The final method utilized micro-elution solid phase extraction (SPE) to extract plasma samples (100µL), and the resulting extracts were analyzed using reversed phase LC-MS/MS using a turbo-ionspray interface in positive ionization mode with selected reaction monitoring (SRM). The method was fully validated according to the current regulatory guidance for bioanalysis over the calibration curve range 0.0500-50.0ng/mL for all analytes using 1/x2-weighted linear regression analysis. Based on three separate runs, the between-run precision and inter-day precision for all five analytes at all concentrations, including the LLOQ (lower limit of quantitation) quality control at 0.0500ng/mL, varied from 0.0% to 13.8%, while the accuracy ranged from 86.4% to 109.3% of nominal. The extraction recoveries of loxapine and the four metabolites were above 80%. Various forms of short-term and long-term stability were established in both solutions and matrix, including the stability of loxapine and the four metabolites in human plasma for up to 260days of storage at -20°C. This method has been used to support a regulated clinical study, which included the successful execution of incurred sample reanalysis (ISR) testing. To the best of our knowledge, this is the first published methodology in which these five analytes were quantified with a single extraction and injection.

Inhaled loxapine for the urgent treatment of acute agitation associated with schizophrenia or bipolar disorder.

BACKGROUND: Acute agitation is a serious complication of schizophrenia and bipolar disorder, which may escalate quickly to aggressive behavior. Rapid treatment is therefore important to calm and stabilize the patient, reducing the potential for harm to the patient and others, and allowing further assessment. Current guidelines suggest that where pharmacologic intervention is indicated, medication should preferably be non-invasive, should have a rapid onset and should control aggressive behavior in the short term without compromising the physician-patient relationship in the long term. OBJECTIVES: This article presents an overview of a new inhaled formulation of the established antipsychotic loxapine, which aims to provide a more rapidly acting agent for the treatment of acute agitation without the disadvantages of intramuscular or intravenous injection. DISCUSSION: Inhaled loxapine is rapidly absorbed with intravenous-like pharmacokinetics, with a time to maximum plasma concentration of 2 minutes and a plasma half-life of approximately 6 hours. In phase III studies, loxapine reduced agitation within 10 minutes of inhalation; agitation was decreased at all subsequent assessments during a 24-hour evaluation period. Inhaled loxapine was generally well tolerated with no undue sedation. The most common adverse events were dysgeusia, mild sedation, and dizziness. Inhaled loxapine is contraindicated in patients with asthma, COPD or other pulmonary disease associated with bronchospasm. CONCLUSIONS: Inhaled loxapine rapidly reduces acute agitation in patients with schizophrenia or bipolar disorder and is generally well tolerated. The non-invasive route of delivery respects the patient's autonomy, reducing the perception of coercion or forced medication. Inhaled loxapine is therefore an effective and appropriate option for use in the emergency setting in patients with acute agitation.

A randomized, placebo-controlled repeat-dose thorough QT study of inhaled loxapine in healthy volunteers.

OBJECTIVE: This randomized, double-blind, active- and placebo-controlled, crossover, thorough QT study assessed the effect of two inhaled loxapine doses on cardiac repolarization as measured by corrected QT (QTc) interval in healthy subjects (ClinicalTrials.gov NCT01854710). METHODS: Subjects received two doses of inhaled loxapine (10 mg) 2 hours apart+oral placebo, two doses of inhaled placebo+oral placebo, or two doses of inhaled placebo+oral moxifloxacin (400 mg; positive control), with ≥3 days washout between treatments. Two-sided 90% confidence intervals (CIs) were calculated around least-squares mean predose placebo-subtracted individually corrected QT durations (ΔΔTcIs) at 12 time points throughout 24 hours after dosing. A ΔΔTcI 95% upper CI exceeding 10 msec was the threshold indicating QTc prolongation (primary endpoint). Secondary endpoints included Fridericia- and Bazett-corrected QT duration and QTcI outliers. Pharmacokinetics and adverse events (AEs) were also assessed. RESULTS: Of 60 subjects enrolled (mean age, 33.8 years; 52% male), 44 completed the study. Post loxapine dosing, no ΔΔTcI 95% upper CI exceeded 10 msec; the largest was 6.31 msec 5 minutes post dose 2. Methodology was validated by ΔΔTcI 95% lower CIs exceeding 5 msec at 9 of 12 time points after moxifloxacin dosing. Loxapine plasma concentrations increased rapidly (mean Cmax, 177 ng/mL; median tmax 2 minutes after dose 2, 2.03 hours after dose 1). There were no deaths, serious AEs, or AEs leading to discontinuation, and one severe AE. CONCLUSIONS: Primary and secondary endpoints indicated two therapeutic doses of inhaled loxapine did not cause threshold QTc prolongation in this study.

Multiple dose pharmacokinetics of inhaled loxapine in subjects on chronic, stable antipsychotic regimens.

This randomized, double-blind, placebo-controlled, parallel-group study was to determine the pharmacokinetic characteristics, safety, and tolerability of multiple doses of inhaled loxapine aerosol in subjects on a stable, oral, chronic antipsychotic regimen. Loxapine was delivered by means of a unique thermally generated aerosol comprising drug particles of a size designed for deep lung delivery and absorption. Thirty-two subjects were randomized 1:1:1:1 to receive inhaled loxapine (total doses of 15, 20, or 30 mg) or inhaled placebo administered in 3 divided doses, given 4 hours apart. Following inhalation, the median Tmax was 2 minutes, and concentrations declined to about half Cmax approximately 5 minutes later across the 3 dose levels. The dose proportionality across data from this study combined with data from the single-dose study showed a slope (90%CI) of log AUCinf versus log dose of 0.818 (0.762-0.875) across the 8 doses (n = 60 subjects) studied, indicating reasonable dose proportionality. The most common adverse events were cough (3 of 32, 9%), sedation (3 of 32, 9%), and dysgeusia (2 of 32, 6%). The inhalation of multiple doses of inhaled loxapine were well tolerated in study subjects and provided a safe, well-tolerated means for rapidly and reliably achieving therapeutic plasma concentrations of loxapine. ClinicalTrials.gov identifier: NCT00555412.

Effect of smoking on the pharmacokinetics of inhaled loxapine.

BACKGROUND: Loxapine inhalation powder delivered by a hand-held device as a thermally generated aerosol (ADASUVE) was recently approved in the United States and European Union for use in the acute treatment of agitation in patients with bipolar disorder or schizophrenia. As smokers comprise a large subpopulation of these patients, and many antipsychotic drugs require dose adjustments for smokers, the objective of this study was to compare the pharmacokinetics of inhaled loxapine administered to smokers and nonsmokers. METHODS: Pharmacokinetics and sedation pharmacodynamics using a visual analog scale were studied in 35 male and female adult subjects (18 nonsmokers and 17 smokers) following a single dose of 10 mg of inhaled loxapine. Blood samples were drawn at predose, 30 seconds, 1, 2, 3, 10, 30, and 60 minutes, and 2, 6, 12, and 24 hours after dosing. Loxapine and 8-OH-loxapine were analyzed using reverse-phase liquid chromatography coupled with a tandem mass spectrometer. Pharmacokinetic parameters assessed included Cmax, Tmax, AUCinf, and T1/2 for loxapine and 8-OH-loxapine. Geometric mean ratios (GMRs) were determined for smokers to nonsmokers. RESULTS: Loxapine Cmax was similar in smokers and nonsmokers with a GMR of 99.0%. The median loxapine Tmax was 1.88 and 1.01 minutes for nonsmokers and smokers, respectively. Loxapine AUCinf and AUClast values in nonsmokers were comparable with smokers (GMRs of 85.3% and 86.7%, respectively). A slight decrease in the observed mean terminal half-life values was observed for smokers (6.52 hours for smokers and 7.30 hours for nonsmokers). CONCLUSIONS: Sedation profiles and visual analog scale scores at each time point were similar for nonsmokers and smokers. It was concluded that inhaled loxapine does not require dosage adjustment based on smoking behavior.

Pharmacokinetic comparison between the long-term anesthetized, short-term anesthetized and conscious rat models in nasal drug delivery.

PURPOSE: To investigate the pharmacokinetic differences between the common nasal delivery models. METHODS: In three different rat models [long-term anesthetized (with nasal surgery), short-term anesthetized (without nasal surgery) and conscious models], tacrine and loxapine were administered via nasal, intravenous and oral routes, and the plasma pharmacokinetics were compared among different models. RESULTS: Systemic exposures of both drugs and their metabolites were consistently higher in long-term anesthetized model after all routes of administration in comparison to that of conscious model. Nasal bioavailabilities in long-term anesthetized model (tacrine 83%, loxapine 97%) were much higher than that in conscious model (tacrine 10%, loxapine 46%). Further studies on tacrine and its metabolites demonstrated no significant difference in t1/2 between short-term anesthetized and conscious models after all routes of administration; however, long-term anesthetized model showed significantly longer t1/2. Regarding the pharmacokinetic parameters (Cmax, Tmax, AUC, bioavailability) of tacrine and its metabolites, short-term anesthetized model resembled closer to conscious model than long-term anesthetized model. CONCLUSIONS: Plasma clearances of tacrine, loxapine, and their metabolites were much slower in the long-term anesthetized model of nasal delivery probably due to suppressed hepatic and renal clearances, while the short-term anesthetized model imposed less impact on tacrine pharmacokinetics and metabolism.

Loxapine delivered as a thermally generated aerosol does not prolong QTc in a thorough QT/QTc study in healthy subjects.

The objective of this study was to establish effects of inhaled loxapine on the QTc interval in this randomized, placebo-controlled, double-blind crossover study. Forty-eight healthy volunteers received a single inhaled placebo or 10 mg loxapine. Plasma concentrations of loxapine increased with a median Tmax of 1 minute and a mean Cmax of 312 ng/mL. After an initial rapid distribution phase, plasma concentrations of loxapine declined with a terminal half-life of 8 hours. Exposure to the active metabolite 7-OH-loxapine was 15% of the parent compound based on mean AUCinf and its terminal half-life was 12 hours. Inhaled loxapine did not increase QT intervals, as demonstrated by the upper bound of the 1-sided 95% CIs placed on the point estimate of the placebo-subtracted change of QTcI (ΔΔQTcI) being less than 10 milliseconds at all 11 post-dose times. The maximum ΔΔQTcI occurred at 1 hour post-dose (LSmean 5.42 milliseconds, upper confidence bound 7.75 milliseconds). The study outcome was validated by the demonstrated assay sensitivity using the positive control moxifloxacin maximum ΔΔQTcI occurred at 3 hour post-dose (LSmean 8.36 milliseconds, lower confidence bound 5.82 milliseconds). The analyses of QTc outliers, and the lack of emergent diagnostic findings for QTcI, QTcB, and QTcF; and simple mean placebo-subtracted changes of QTcI and QTcF supported the primary QT analysis conclusion that this is a negative finding and there is no apparent QT prolongation associated with the therapeutic dose of inhaled loxapine.

[Cesarean section and sismotherapy in a severe psychotic parturient: A case report]. / Césarienne et sismothérapie concomitante chez une patiente psychotique sévère : à propos d'un cas.

Psychiatric disorders may complicate the pregnancy and is one of the causes of maternal and fetal morbidity. We report the case of a patient with severe decompensated schizophrenia during her pregnancy that required prolonged hospitalization in psychiatric ward. The psychiatric status of the patient required the realization of a caesarean section at 36 weeks of amenorrhea. In our case, we decided to perform this cesarean section under general anaesthesia, since regional anaesthesia was not feasible in this patient in a state of uncontrolled agitation. Moreover, general anaesthesia permitted to combine cesarean section with a first session of electroconvulsive therapy, which had been declined during pregnancy. Given the huge amount of antipsychotic agents administered to the patient, we also studied their transplacental transfer and found a very high loxapine concentration in the fetus. Finally, this case raised several important ethical issues related to the management of the mother and her fetus in case of severe psychiatric disorders.

Brain disposition and catalepsy after intranasal delivery of loxapine: role of metabolism in PK/PD of intranasal CNS drugs.

PURPOSE: To elucidate the role of metabolism in the pharmacokinetics and pharmacodynamics of intranasal loxapine in conscious animals. METHODS: At pre-determined time points after intranasal or oral loxapine administration, levels of loxapine, loxapine metabolites, and neurotransmitters in rat brain were quantified after catalepsy assessments (block test and paw test). Cataleptogenicity of loxapine was also compared with its metabolites. RESULTS: Intranasally administered loxapine was efficiently absorbed into systemic circulation followed by entering brain, with tmax ≤15 min in all brain regions. Oral route delivered minimal amounts of loxapine to plasma and brain. Brain AUC0-240min values of 7-hydroxy-loxapine were similar after intranasal and oral administration. Intranasal loxapine tended to induce less catalepsy than oral loxapine, although statistical significance was not reached. The catalepsy score was positively and significantly correlated with the striatal concentration of 7-hydroxy-loxapine, but not with loxapine. 7-hydroxy-loxapine was more cataleptogenic than loxapine, while the presence of loxapine tended to reduce rather than intensify 7-hydroxy-loxapine-induced catalepsy. The increases in striatal dopamine turnover were comparable after intranasal and oral loxapine administration. CONCLUSIONS: The metabolite 7-hydroxy-loxapine, but not loxapine, was the main contributor to the catalepsy observed after intranasal and oral loxapine treatment. Intranasal route could effectively deliver loxapine to brain.

Inhaled loxapine: a new treatment for agitation in schizophrenia or bipolar disorder.

The treatment of acute agitation in psychiatric patients has traditionally involved the use of oral or intramuscular benzodiazepines, antipsychotics or their combination. However, oral medication may have too slow an onset and while the intramuscular route is faster, it carries an increased risk of adverse events and needle-stick injury. A new delivery modality has been devised using an inhalation-activated, thermally generated drug aerosol which can produce peak plasma concentrations in a few minutes. Using this delivery method, loxapine was assessed for its antiagitation effects in schizophrenia and bipolar I disorder patients. It produced a rapid calming effect without undue sedation. It was generally well tolerated, with dysgeusia being the most common adverse event.

Now take a deep breath: inhaled loxapine for the treatment of acute agitation.

Acute agitation in patients with schizophrenia or bipolar disorder is an important clinical management problem. Liquid concentrates, orally disintegrating tablets, and/or intramuscular formulations of several second-generation atypical antipsychotic drugs are available for treating acute agitation. Loxapine is an older first-generation antipsychotic drug that is approved for the treatment of schizophrenia. Staccato(®) loxapine is an investigational device system using a loxapine-coated heat source to administer loxapine by inhalation. Three multicenter, randomized, double-blind, placebo-controlled efficacy and safety studies of Staccato loxapine have been conducted in patients with acute agitation associated with schizophrenia or bipolar disorder. These studies found that inhaled loxapine was rapidly effective and generally well tolerated, although there are potential concerns about adverse pulmonary effects.

Investigation of the disposition of loxapine, amoxapine and their hydroxylated metabolites in different brain regions, CSF and plasma of rat by LC-MS/MS.

Loxapine represents an interesting example of old "new" drug and is recently drawing attention for its novel inhalation formulation for the treatment of both psychiatric and non-psychiatric disorders. It is extensively metabolized to several active metabolites with diverging pharmacological properties. To further pursue the contribution of metabolites to the overall outcome after loxapine administration, quantification of both loxapine and its active metabolites is essential. The current study developed a rapid liquid chromatography-tandem mass spectrometry (LC-MS/MS) method for the simultaneous quantification of loxapine and its five metabolites (amoxapine, 7-hydroxy-loxapine, 8-hydroxy-loxapine, 7-hydroxy-amoxapine and 8-hydroxy-amoxapine) in rat brain tissues, plasma and cerebrospinal fluid (CSF). By evaluating the effects of perchloric acid and methanol on analyte recovery, the extraction methods were optimized and only small amounts of sample (100 µl for plasma and less than 100mg for brain tissue) were required. The lower limits of quantification (LLOQs) in brain tissue were 3 ng/g for loxapine and amoxapine and 5 ng/g for the four hydroxylated metabolites of loxapine. The LLOQs were 1 ng/ml for loxapine and amoxapine and 2 ng/ml for the four hydroxylated metabolites in plasma, and 10 ng/ml for all analytes in CSF. The developed method was applied to a pharmacokinetic study on rats treated with a low-dose loxapine by oral administration. Four hours after loxapine dosing, high levels of 7-hydroxy-loxapine were found throughout the ten brain regions examined (68-124 ng/g), while only trace amount of loxapine was measured in brain (<5 ng/g) and plasma (<3 ng/ml). The method provides a useful tool for both preclinical and clinical investigations on the dispositions of loxapine and its metabolites, which would help to elucidate their roles in neurotherapeutics.

In vitro aerosol deposition in the oropharyngeal region for Staccato loxapine.

BACKGROUND: The Staccato system employs a thermal vaporization technology to generate pure drug aerosols with a particle size optimized for alveolar deposition, leading to rapid absorption of the drug into the systemic circulation. Unlike most traditional aerosol-generation techniques, the particle size of the thermally generated aerosols is significantly affected by the airflow rate going through the device. The objective of this study was to determine the effects of flow rate and other operating conditions on predicted oropharyngeal and lung deposition when using the Staccato system. METHODS: In vitro oropharyngeal deposition was measured at airflow rates of 15-80 L/min through the device. Oropharyngeal deposition was also measured for different inhalation profiles, different ambient temperatures and humidities, and device orientations. Deposition was measured using the Alberta geometry model, which was derived based on information available in the literature, CT scans of patients, and observations of living subjects. RESULTS AND CONCLUSIONS: Deposition in the oropharyngeal geometry was consistently approximately 11% of the emitted dose throughout the entire range of flow rates. Such consistency in deposition was due to the fact that mass median aerodynamic diameter (MMAD) varied inversely as the square root of the flow rate, resulting in an approximately constant value for the inertial deposition parameter. Thus, an increase in flow rate, which would increase the momentum of a fixed particle size and generally lead to higher oropharyngeal deposition, was almost exactly counterbalanced by the accompanying decrease in MMAD. Results also showed that deposition in the oropharyngeal region was unaffected by other potentially relevant factors such as different airflow ramp rates, inhalation time, ambient temperature and relative humidity, and device orientations.

Pharmacokinetics of loxapine following inhalation of a thermally generated aerosol in healthy volunteers.

The objective of this randomized, double-blind, placebo-controlled, dose escalation study was to determine the pharmacokinetic characteristics, safety, and tolerability of single doses of inhaled loxapine aerosol in healthy volunteers. Loxapine was delivered by means of a unique thermally generated aerosol comprising drug particles of a size designed for deep lung delivery and absorption. Fifty participants were randomized to receive 0.625, 1.25, 2.5, 5.0, or 10 mg of loxapine aerosol or placebo. Following inhalation, the t(max) median (25%, 75%) was 2 (1, 3) minutes. The loxapine AUC(infinity) was dose proportional across all doses with slope (90% confidence interval) of log AUC(infinity) versus log dose = 0.909 (0.832, 0.987). No clinically meaningful changes were noted in hematology results, blood chemistry, vital signs, or respiratory function. The most common adverse events were dizziness, somnolence, and bad taste. The inhalation of Staccato loxapine represents a safe, well-tolerated means for rapidly achieving therapeutic plasma concentrations of loxapine.