Experimental verification of a predicted, hitherto unseen separation selectivity pattern in the nonaqueous capillary electrophoretic separation of weak base enantiomers by octakis (2,3-diacetyl-6-sulfato)-gamma-cyclodextrin

The capillary electrophoretic separation of cationic enantiomers with single-isomer multivalent anionic resolving agents was reexamined with the help of the charged resolving agent migration model. Three general model parameters were identified that influence the shape of the separation selectivity and enantiomer mobility difference curves: parameter b, the binding selectivity (K(RCD)/K(SCD)), parameter s, the size selectivity (mu0(RCD)/mu0(SCD)), and parameter a, the complexation-induced alteration of the analyte's mobility (mu0(RCD)/mu0). In addition to the previously observed discontinuity in separation selectivity that occurs as mu(eff) of the less mobile enantiomer changes from cationic to anionic, a new feature, a separation selectivity maximum was predicted to occur in the resolving agent concentration range where both enantiomers migrate cationically provided that (i) K(RCD)/K(SCD) <1 and mu0(RCD)/mu0(SCD) >1 and (K(RCD)mu0(RCD))/(K(SCD)mu0(SCD)) > 1, or (ii) K(RCD)/K(SCD) >1 and mu0(RCD)/mu0(SCD) <1 and (K(RCD)mu0(RCD))/(K(SCD)mu0(SCD)) <1. This hitherto unseen separation selectivity pattern was experimentally verified during the nonaqueous capillary electrophoretic separation of the enantiomers of four weak base analytes in acidic methanol background electrolytes with octakis(2,3-diacetyl-6-sulfato)-gamma-cyclodextrin (ODAS-gammaCD) as resolving agent.

The physico-chemical properties of salmeterol and fluticasone propionate in different solvent environments

The physico-chemical properties of two anti-asthmatic drugs, salmeterol xinafoate and fluticasone propionate, have been studied in both aqueous and non-aqueous solvent environments. Ultraviolet-visible (UV-Vis) spectroscopy, fluorescence spectroscopy and electrospray ionisation mass spectrometry (ESI-MS) have been used to characterise the interaction of the drugs in 70:30 (v/v) methanol/water solutions. First derivative UV-Vis spectra measurements indicate that an interaction takes place between the two drugs in a binary solvent system. Fluorescence studies indicate that an increase in the concentration of fluticasone propionate results in a decrease in the fluorescence signal of the salmeterol for mixed solutions of the drugs. Analysis of a mixture of the two drug solutions using mass spectrometry also shows evidence of salmeterol-fluticasone propionate interaction and dimer formation with respect to both the salmeterol and the fluticasone propionate. Model metered dose inhalers (MDI) of both individual samples and mixtures of the drugs were formulated as suspensions in solvent CFC-113. The extent of deposition onto different inhaler components, such as the aluminium alloy canister, Teflon coated canister and the metering valve was evaluated by high-performance liquid chromatography (HPLC) of the methanol/water washings of the deposited drug(s). Changing the nature of the surface properties of the container resulted in a significant difference in the extent of deposition. The deposition of the individual drugs was found to increase as the dispersion concentration of the drug increases. However, the formulation based on a combination of the two drugs was found to show different deposition behaviour compared to the individual drug formulations. The deposition of the drugs, onto the aluminium alloy canister and the metering valve, decreases as the combined dispersion concentration of the two drug increases.

The influence of carrier morphology on drug delivery by dry powder inhalers

Alpha-lactose monohydrate was prepared to have different morphological features but with similar particle size. The crystal shape and surface smoothness of lactose were quantified by a number of shape descriptors and these were supported qualitatively by the visual examination of scanning electron (SE) micrographs of the crystals. All batches of lactose were subjected to a similar history of processing before blending separately with micronised salbutamol sulphate (SS) in a ratio of 67.5:1, w/w, using similar procedures. In vitro deposition of SS from these formulations was investigated after aerosolisation of the formulations at 60 l min(-1) via the Rotahaler and the Cyclohaler into a twin stage liquid impinger. The formulations prepared using the different batches of lactose produced different deposition profiles of SS. The fine particle (< 6.4 microm) fraction (FPF) of aerosolised SS varied from 12.6 +/- 2.4 to 25.6 +/- 1.5% after aerosolisation from the Cyclohaler whilst it changed from 15.0 +/- 2.2 to 24.4 +/- 0.8% after aerosolisation from the Rotahaler. The fine particle dose (FPD) and dispersibility of SS followed a similar trend to the change in the FPF of the drug. No significant difference (ANOVA P > 0.05) was observed for the deposition profiles of SS after aerosolisation from the Rotahaler and the Cyclohaler. The FPF and dispersibility of SS increased with either the surface smoothness (P < 0.01) or elongation ratio (P < 0.01) of lactose crystals. The t-ratio values of FPF and dispersibility of SS generated by changes in the surface smoothness were similar to those resulting from changes in elongation ratio. Increasing either the surface smoothness or the elongation ratio of lactose crystals will increase the potentially respirable fraction of SS from dry powder formulations for inhalation.

Analysis of salbutamol and related impurities by derivative spectrometry

Ultraviolet derivative spectrometry has been proposed for the analysis of salbutamol and related impurities. The assay of salbutamol aldehyde, 5-formyl-saligenin, and salbutamol ketone was performed in sodium hydroxide 0.1 mol/l solutions, using first and second derivative spectra. The method has been applied for the assay of related impurities of commercial samples of salbutamol sulfate.

Combining a positive expiratory pressure device with a metered-dose inhaler reservoir system using chlorofluorocarbon albuterol and hydrofluoroalkane albuterol: effect on dose and particle size distributions

BACKGROUND

Combining a positive expiratory pressure (PEP) device with inhalation of albuterol via metered dose inhaler (MDI) may improve drug delivery to the lung, but may also affect dose availability.

PURPOSE

Determine the effect of interposing a PEP device on dose availability of albuterol via MDI and reservoir with either a chlorofluorocarbon (CFC) or hydrofluoroalkane (HFA) propellant.

METHODS

MDI dose availability of CFC albuterol (Proventil) and HFA albuterol (Proventil HFA) using an Aerosol Cloud Enhancer (ACE) reservoir with and without a PEP device (TheraPEP) attached was determined. Drug availability was assessed using an Andersen 8-stage cascade impactor operated at 28.3 +/- 0.5 L/min. The PEP device was inserted between the reverse-firing ACE and the United States Pharmacopeia induction throat. Drug collected on impactor plates was analyzed spectrophotometrically at 276 nm, and the fine particle fraction was determined as the mass of drug < 4.7 microns.

RESULTS

With CFC albuterol, total dose and drug mass < 4.7 microns (means and standard deviations) for the MDI-ACE alone were 44.4 +/- 7.7 micrograms and 33.4 +/- 2.2 micrograms, respectively, and for the MDI-ACE with TheraPEP were 50.1 +/- 6.4 micrograms and 39.8 +/- 14.3 micrograms, respectively. With HFA-albuterol sulfate, total drug and drug mass < 4.7 microns for the MDI-ACE alone, expressed as base drug, were 41.7 +/- 4.2 micrograms and 35.2 +/- 6.3 micrograms, respectively, and for the MDI-ACE with TheraPEP were 48.9 +/- 8.0 micrograms and 44.2 +/- 6.2 micrograms, respectively. There was no significant difference in dose availability between the MDI-ACE alone and with the PEP device attached (Wilcoxon signed-rank test, p > 0.05), for either CFC or HFA albuterol.

CONCLUSION

Interposing the TheraPEP device at the MDI-ACE outlet does not change total dose, drug mass < 4.7 microns, or mass median aerodynamic diameter of MDI albuterol, with either CFC or HFA propellants.

Prodrug to probe solution HFA pMDI formulation and pulmonary esterase activity

A novel salbutamol prodrug was synthesised. Solubility in HFA-134a and susceptibility to rat lung homogenate, blood and plasma esterase enzymes were investigated. Whereas salbutamol had a very low solubility in HFA-134a, the prodrug was found to be miscible in all proportions. In lung homogenate, the prodrug hydrolysed with a half-life of 45 min, re-generating approximately 17% of expected salbutamol after 8 h incubation. The use of a solution pMDI for pulmonary delivery of the salbutamol prodrug is predicted to result in liberation of salbutamol in the lungs following in vivo hydrolysis by lung esterases.

A study of drug-carrier interactions in dry powder inhaler formulations using the Andersen cascade impactor, X-ray microanalysis and time of flight aerosol beam spectrometry (TOFABS)

The purpose of this study was to determine the in vitro deposition of both drug (albuterol sulfate) and carrier (lactose) particles in relation to each other from a dry powder inhaler formulation using an Andersen cascade impactor (ACI) and time of flight aerosol beam spectrometry (TOFABS). In addition, scanning electron microscopy (SEM) combined with X-ray microanalysis was employed to distinguish albuterol sulfate from lactose. Drug particles apparently penetrated deeper into the impactor than lactose particles contained in the formulation. In some certain stages of impactor, drug particles were separated from lactose particles. Although the TOFABS cannot distinguish between albuterol sulfate and lactose, the TOF spectra obtained from the Aerosizer would appear to be partly indicative of the interactions which exist between drug and carrier. One symmetrical TOF peak was obtained from drug or lactose alone. The TOF peak of the drug was always lower than the TOF of lactose. The times obtained for each powder between experiments were highly reproducible and typical of material and particle size. The use of SEM-X-ray microanalysis also allowed some qualitative characterization of shape and state of association of the two components.

Enantiomeric disposition of inhaled, intravenous and oral racemic-salbutamol in man--no evidence of enantioselective lung metabolism

Aims To establish whether enantioselective metabolism of racemic (rac )-salbutamol occurs in the lungs by determining its enantiomeric disposition following inhalation, in the absence and presence of oral charcoal, compared with that following the oral and intravenous routes. Methods Fifteen healthy subjects (eight male) were randomized into an open design, crossover study. Plasma and urine salbutamol enantiomer concentrations were measured for 24 h following oral (2 mg) with or without oral charcoal (to block oral absorption), inhaled (MDI; 1200 microg) with or without oral charcoal and intravenous (500 microg) rac-salbutamol. Systemic exposure (plasma AUC(0,infinity) and urinary excretion (Au24h ) of both enantiomers were calculated, and relative exposure to (R)-salbutamol both in plasma (AUC(R)-/AUC(S)- ) and urine (Au(R)-/Au(S)- ) was derived for each route. Relative exposure after the inhaled with charcoal and oral routes were compared with the intravenous route. Results AUC(R)-/AUC(S)- [geometric mean (95% CI)] was similar following the intravenous [0.32 (0.28, 0.36)] and inhaled with charcoal rates [0.29 (0.24, 0.36); P=0.046], but was far lower following oral dosing [0.05 (0.03, 0.07); P<0.001]. Similar results were found when relative exposure was analysed using Au24h. Conclusions These results show no evidence of significant enantioselective presystemic metabolism in the lungs, whilst confirming it in the gut and systemic circulation, indicating that the (R)- and (S)-enantiomers are present in similar quantities in the airways following inhaled rac-salbutamol.

New millennium bronchodilators for asthma: single-isomer beta agonists

Racemic beta2 agonists are composed of a 50:50 mixture of R and S isomers. The R isomer exhibits virtually all the bronchodilation, whereas the S isomers are generally considered inert. However, (S)-albuterol was shown to enhance bronchial reactivity to methacholine, eosinophil activation, and histamine-induced influx of fluid, proteins, and neutrophils into the airspaces. Actions such as these may compress the potency and foreshorten the duration of (R)-albuterol. Accordingly, pure (R)-albuterol provides bronchodilation at lower doses than racemate, allowing for fewer beta-adrenergic-mediated side effects. In addition, differential metabolism may allow for the progressive accumulation of (S)-albuterol. This logic is applicable to long-acting beta2 agonists: the therapeutically active (R,R)-formoterol is currently being developed in the United States, and preliminary results suggest rapid improvements in FEV1 with up to 24-hour duration of action. These combined observations with the R isomers of beta2 agonists suggest that potential improvements in therapeutic indices can be achieved with isomerically pure versions of existing racemic drugs.

Positive chemical ionization and tandem mass spectrometric fragmentation for the gas chromatographic analysis of beta-agonists using the ion trap technique

A procedure is described for the determination of three characteristic beta-agonists (clenbuterol, terbutalin and salbutamol) based on the formation of the corresponding protonated molecules and related collisional experiments. Quantification was carried out on selected collisional fragments and the reproducibility of the relative abundances of these fragments was estimated. The performance of the method was tested on bovine urine samples spiked at the lowest level of 0.2 ng ml(-1) in each of the chosen compounds.

Preferential pulmonary retention of (S)-albuterol after inhalation of racemic albuterol

The (R)-enantiomer of racemic albuterol produces bronchodilation, whereas the (S)-enantiomer may increase airway reactivity. After oral or intravenous administration of racemic albuterol, the (R)- enantiomer is metabolized several times faster than the (S)-enantiomer; however, enantiomer disposition after inhaling racemic albuterol with a metered-dose inhaler (MDI) is not known. Accordingly, 10 healthy subjects inhaled racemic albuterol with a MDI alone and with a MDI and holding chamber. We measured plasma levels of unchanged (R)- and (S)-albuterol before and up to 4 h after inhalation of racemic albuterol, and determined the unchanged R/S ratio in urine before and at 0.5, 4, 8, and 24 h later. The disposition of albuterol's enantiomers with a MDI and holding chamber was similar to that with a MDI alone. The area under the curve (AUC) of the plasma levels over time was significantly lower for the (S)- than for the (R)-enantiomer-395.5 +/- 141.0 (SE) versus 882.7 +/- 126.4 ng. ml(-)(1). min (p < 0.05)-indicating preferential retention of (S)-albuterol in the lung. The R/S ratio in urine at 0. 5 h after albuterol was > 1, reflecting the higher plasma level of the (R)-enantiomer. In conclusion, preferential retention of the (S)- compared with the (R)-enantiomer in the lung could lead to accumulation of the (S)-enantiomer after long-term use of racemic albuterol.

[Effect of separation characteristics between salbutamol sulfate (SS) particles and model carrier excipients on dry powder for inhalation]

Most often dry powder for inhalation are formulated as ordered mixtures of a carrier excipient and a micronized drug substance. In the present study, model powder blends were prepared from a mixture of lactose alpha-monohydrate, micro-crystalline cellulose pellets or synthesized sugar as carrier particles, and micronized salbutamol sulfate (SS). These ordered mixtures were aerosolized by the multidose JAGO dry powder inhaler (DPI) and their in vitro deposition properties were evaluated by a twin impinger (TI). The separation force between SS particles and carrier particles was investigated by the centrifuge method. In addition, the use of the air jet sieve (AJS) method was investigated to assess the separation behavior of drug particles from carrier excipient. Powder blends were sieved through a 325 mesh wire screen of an air jet sieve at an air pressure of 1500 Pa. The amount of drug deposited at the carrier surface was analysed before and after the sieving to calculate the percentage of the drug retained. A relationship was found between in vitro deposition properties (fine particle fraction, FPF) and the separation characteristics obtained by the centrifuge method and by the AJS method. The AJS method might be a suitable alternative for evaluating separation of a drug particle from carrier particles and hence can be used for the formulation screening of the dry powder inhalation.

The asthma-like pharmacology and toxicology of (S)-isomers of beta agonists

Beta(2 ) agonists were designed to emulate the bronchodilation and mast cell suppression effects of human adrenaline, an endogenous neuromediator. Endogenous adrenaline is produced exclusively as the single enantiomer or isomer, (R)-adrenaline, although all selective beta(2 ) agonists are marketed as racemic drugs, composed of a precise 50:50 mixture of R and S isomers. Isomers are compounds that are nonsuperimposable mirror images. The R isomers of beta agonists, essentially all congeners of (R)-adrenaline, exhibit the observed bronchodilation and clinical benefit of the racemate. The S isomers of the racemic beta agonists are devoid of clinical benefit, are assumed to be benign, and have not been studied until recently. In contradistinction to their assumed benign status, extensive studies with (S)-albuterol have shown that it opposes the bronchodilation effects of (R)-albuterol (levalbuterol), may be proinflammatory, and exhibits the potential to exacerbate airway reactivity to a variety of spasmogens by enhancing contractile responses. Clinically, (S)-albuterol can increase airway reactivity and, because of its slow metabolism, exists in higher and prolonged plasma concentrations than levalbuterol. The sustained presence of (S)-albuterol may help to explain why racemic beta agonists have not demonstrated a significant clinical anti-inflammatory potential. Furthermore, the adverse effects (S)-albuterol may contribute to paradoxic bronchospasm and the occurrence of severe reagenic-like reactions seen with racemic albuterol. These adverse effects of (S)-albuterol are completely avoided with single isomer version of (R)-albuterol (levalbuterol). The removal of (S)-albuterol increased the clinical potency of levalbuterol, such that bronchodilator efficacy is achieved at one-fourth the dose of racemic albuterol, but with marked reduction in side effects. Levalbuterol, a third generation beta agonist, retains the clinical benefit of racemic albuterol without the proinflammatory and potentially detrimental effects of (S)-albuterol.

Prospects for improved therapy in chronic obstructive pulmonary disease by the use of levalbuterol

Like asthma, chronic obstructive pulmonary disease (COPD) is a chronic disease, the most prominent symptom of which is airway obstruction. Airway inflammation may be pathogenomic in both diseases, but only in COPD does inflammation predominate as a determinant of symptoms to make obstruction largely refractory to treatment. Despite a more limited degree of reversibility than in asthma, beta(2 )-agonists are used extensively to reduce airway obstruction and to achieve symptomatic improvement, with racemic albuterol being widely favored. In asthma, bronchodilation and bronchoprotection largely account for symptomatic benefit. In COPD, the capacity of racemic albuterol to ameliorate these symptoms is more limited and suppression of edema and of infiltration and activation of leukocytes acquire greater significance. During regular use of racemic albuterol in asthma, bronchoprotection diminishes progressively as hyperresponsiveness becomes increasingly pronounced, a process that is associated with an infiltration and activation of eosinophils. These paradoxic effects of racemic albuterol may be attributed to pharmacologic actions of the distomer, (S)-albuterol. As would be expected, homochiral (R)-albuterol (levalbuterol) is more potent and effective in asthma and may have significant advantages if used in COPD. A substantial (4-8-fold) reduction in the dose of levalbuterol anticipates lesser side effects and diminished risk in patients with cardiovascular disease. Additionally, the increased potency and duration of bronchodilation observed in asthma may extend to COPD. Finally, removal of the proinflammatory actions of (S)-albuterol may eliminate the persisting obstruction and decrease elastance that are associated with enhanced inflammation and may allow levalbuterol to suppress edema and diminish leukocyte activation more effectively.

Contrasting properties of albuterol stereoisomers

Racemic albuterol is composed of an equimolar mixture of stereoisomers. For asthma therapy, (R)-albuterol is the eutomer and (S)-albuterol is the distomer. By interacting with beta(2 )-adrenoceptors, (R)-albuterol has bronchodilator, bronchoprotective, anti-edematous properties and inhibits activation of mast cells and eosinophils. (S)-albuterol does not activate beta(2 )-adrenoceptors and does not modify activation of beta(2 )-adrenoceptors by (R)-albuterol so that for many years it was presumed to be biologically inert. Recently, it has been established that regular and excessive use of racemic albuterol induces paradoxical reactions in some subjects with asthma. Because such effects cannot be accounted for by activation of beta(2 )-adrenoceptors, the pharmacologic profile of (S)-albuterol has been more carefully defined. (S)-albuterol has distinctive pharmacologic properties that are unrelated to activation of beta(2 )-adrenoceptors. Thus, (S)-albuterol intensifies bronchoconstrictor responses of sensitized guinea pigs and induces hypersensitivity of asthmatic airways; it also promotes the activation of human eosinophils in vitro. These actions of (S)-albuterol may explain why racemic albuterol can intensify allergic bronchospasm and promote eosinophil activation in asthmatic airways. The capacity of (S)-albuterol to elevate intracellular Ca(2+) would account for the paradox because this action will oppose, or even nullify, the consequences of adenylyl cyclase activation by (R)-albuterol. Because (S)-albuterol is metabolized more slowly than (R)-albuterol and is retained preferentially within the airways, paradoxical effects become more prominent during regular and excessive use of racemic albuterol. Because (S)-albuterol has detrimental effects in asthmatic airways, levalbuterol [homochiral (R)-albuterol] should have advantages over racemic albuterol in therapy for asthma.

Clinical experience with levalbuterol

Although racemic albuterol is an effective bronchodilator, regular use has been associated with some loss of bronchodilator potency, decreased protection against bronchoprovocation, increased sensitivity to allergen challenge, and increased sensitivity to some bronchoconstrictor stimuli. In experimental animals racemic albuterol has produced bronchial hyperresponsiveness, which could also be induced by administration of (S)-albuterol. These findings suggest that the pure or homochiral formulation of (R)-albuterol (levalbuterol) might be more effective as a bronchodilator than the racemic form. Single doses of levalbuterol provided more prolonged protection against methacholine challenge than the racemate, whereas (S)-albuterol significantly increased sensitivity to methacholine. In a 4-week study in adults, equivalent amounts of pure levalbuterol provided greater bronchodilation than did similar amounts of levalbuterol given as racemic mixtures. Furthermore, after 4 weeks, the baseline morning FEV(1 ) was lower in those receiving the racemate than in those receiving placebo or levalbuterol. In a single-dose study in children, the same conclusion regarding greater bronchodilation with pure levalbuterol compared with the same amount of levalbuterol in a racemic mixture was confirmed. These studies appear to confirm the greater efficacy of pure levalbuterol over a similar amount in a racemic mixture. This implies a deleterious effect of (S)-albuterol on both the acute bronchodilator response and baseline airway caliber, the exact mechanism of which will require further investigation.

Pharmaceutical dry powder aerosols: correlation of powder properties with dose delivery and implications for pharmacodynamic effect

PURPOSE

Efficient dispersion of bulk solids is critical for dry powder aerosol production which can be viewed as a sequence of events from stationary through dilated, flowing and finally dispersed particulates. The purpose of this study was to test the hypothesis that numerical descriptors of powder flow properties predict aerosol dispersion and pharmacodynamic effect.

METHODS

Drug and excipient particles were prepared in size ranges suitable for inhalation drug delivery, and their physico-chemical properties were evaluated. Novel techniques (chaos analysis of dynamic angle of repose and impact force separation) were developed and utilized to measure and characterize powder flow and particle detachment from solid surfaces, respectively. Dry powder aerosol dispersion was evaluated using inertial impaction. Pharmacodynamic evaluations of bronchodilation were performed in guinea pigs, for selected formulations.

RESULTS

We observed a direct correlation of powder flow with ease of particle separation (r2=0.9912) and aerosol dispersion (r2= 0.9741). In vivo evaluations indicated that formulations exhibiting a higher in vitro dose delivery resulted in a greater reduction in pulmonary inflation pressure.

CONCLUSIONS

These results integrate powder behavior at various levels and indicate that numerical descriptors of powder flow accurately predict dry powder aerosol dispersion. A proportionality between aerosol dispersion and pharmacodynamic effect was observed in preliminary in vivo evaluations, which demonstrates the potential of these techniques for correlation studies between in vitro powder properties and in vivo effect.

Stereoselective pharmacokinetics of S-salbutamol after administration of the racemate in healthy volunteers

Racemic R,S-salbutamol is taken to relieve bronchial constriction. Only the R-enantiomer has bronchodilating properties. The S-enantiomer has been proposed to cause in vitro bronchial hyperreactivity in guinea-pigs. Stereoselective elimination of salbutamol has been shown, with S-salbutamol being eliminated at a slower rate than R-salbutamol. This study questioned whether rates of stereoselective elimination were similar after oral or lung delivery, and whether the S:R ratio would increase after repeated inhalations in a situation resembling a common clinical use. Eighteen healthy volunteers received single-dose racemic salbutamol as a solution instilled in the trachea during anaesthesia, as inhaled micronized powder and/or as ingested tablets. Five volunteers inhaled repeated doses of racemic salbutamol. Concentrations in plasma and urine were measured using a technique which allowed chiral separation of samples with concentrations as low as 0.1 ng x mL(-1). The bioavailability of S-salbutamol was significantly higher than that of R-salbutamol after the different modes of administration. Stereoselective elimination was more pronounced after oral administration than after inhalation. Repeated inhalations resulted in successive increases in the S:R ratio as steady state was approached. In conclusion, the clinical consequences of increasing plasma concentrations of S-salbutamol need to be further assessed.

Effects of particle size and adding sequence of fine lactose on the deposition of salbutamol sulphate from a dry powder formulation

Ternary mixtures composed of coarse lactose (CL) (90.8 microm), salbutamol sulphate (SS) (5.8 microm) and either micronised lactose (ML) (5 microm) or intermediate sized lactose (IML) (15.9 microm) in a ratio of 66.5:1:1 w/w were prepared using different mixing sequences of the various components. In addition, a binary mixture composed of CL and SS (67.5:1 w/w) was also prepared as the control. The in vitro deposition of SS was measured using a twin stage impinger after aerosolisation at 60 and 90 l min-1 via a Rotahaler. The aerodynamic particle size distribution of both the aerosolised SS and lactose was further analysed using an Andersen cascade impactor at 60 l min-1. All ternary mixtures produced a significantly higher (analysis of variance, P<0.01) fine particle fraction (FPF) and fine particle dose (FPD) of SS than the control after aerosolisation at either 60 or 90 l min-1. Formulations containing the ML produced significantly (P<0.05) higher FPF and FPD of SS than those containing the IML at both aerosolisation flow rates. Different mixing sequences were also shown to result in different deposition profiles of both SS and lactose after aerosolisation of the ternary mixtures containing ML at 60 l min-1. The formulation prepared by first blending ML with CL before mixing with SS produced a higher FPF and FPD of SS but a lower FPF of lactose than the same formulation in terms of composition but prepared using different mixing orders of the three components. In contrast, the formulations containing IML produced a similar deposition profile to SS, regardless of the mixing sequences, and so did the formulations containing ML aerosolised at 90 l min-1. These results suggest that the effect of mixing sequences on drug deposition may become more prominent at lower aerosolisation flow rates and by reducing the size of any added fine lactose.

Utilizing vehicle imbibition by a microporous membrane and vehicle viscosity to control release rate of salbutamol

The possibility to control the release rate of salbutamol through the hydrophobic Celgard 2500 polypropylene membrane by varying the composition and the viscosity of hydrophilic drug vehicles was investigated. The use of the polypropylene membrane as a control membrane for reservoir-type drug delivery systems was envisaged and water, glycerol, isopropyl alcohol and ethanol, pure or as binary mixtures were studied as vehicles. With varying composition of the vehicle, a sharp change of its imbibition by the membrane from practically none to a complete filling of the membrane pores occurred, which coincided with a steep rise of the drug permeability for the membrane. From this was inferred that the vehicle-filled pores were the dominant permeation pathway, while when no vehicle was imbibed, transport took place by way of the polymer domain of the membrane. In case of imbibition, the permeation rate could be modulated in a predictable fashion by adjusting the viscosity of the vehicle. This demonstrated that drug release could be controlled by utilizing the in situ interaction of the vehicles with this membrane, leading to imbibition and establishment of a permeation pathway with pre-determined viscosity in the pores of the membrane.

Large porous particles for sustained protection from carbachol-induced bronchoconstriction in guinea pigs

PURPOSE

To determine whether a new formulated albuterol aerosol could sustain inhibition to bronchoconstriction for approximately one day in guinea pigs challenged with carbachol.

METHODS

Large and porous particles, comprising a combination of endogenous or FDA-approved excipients and albuterol sulfate, were prepared by spray drying using a NIRO portable spray drier. The anesthetized animals inhaled 5 mg of large porous or small nonporous particles by forced ventilation via cannulae inserted in the lumen of their exposed tracheae. At regular intervals over a period of 36 hours after drug delivery, airway resistance was determined in response to carbachol challenge dose.

RESULTS

Whereas inhalation of small nonporous albuterol particles protected from the carbachol-induced bronchoconstriction for up to 5 hours, inhalation of large porous albuterol particles produced a significant inhibition of carbachol-induced bronchoconstriction for at least 16 hours.

CONCLUSIONS

The absence of substantial side effects, verified over a period of 24 hours by evaluating cardio-respiratory parameters as well as pulmonary inflammation, supports the utility of large porous albuterol particles for sustained therapies in asthma and other types of lung disease.

Effect of the amphoteric properties of salbutamol on its release rate through a polypropylene control membrane

The permeation of salbutamol from aqueous vehicles with different pH values through the Celgard 2500 polypropylene membrane was studied, the goal being to assess the effect of the amphoteric properties of the drug on its release by the membrane. Permeation rates were generally low, which was related to the fact that purely aqueous vehicles were not imbibed into the pores of the membrane and therefore permeation took place through the amorphous polypropylene domains. Permeability coefficients were not proportional to the fraction of uncharged drug at different bulk pH values, indicating that either a pH gradient between the bulk and the membrane surface exists and/or charged drug species can permeate the hydrophobic membrane. Calculated hypothetical pH values of the membrane surface, assuming permeation of the uncharged drug only, failed to provide a consistent explanation of the experimental permeabilities. Permeability coefficients of the different ionization forms of the drug assuming no pH gradient were calculated from a system of linear equations, each one of them corresponding to a specific bulk pH. These were for the anionic and the cationic species one to two orders of magnitude smaller than for the combined uncharged and zwitterionic species. It is possible that both, a pH difference between bulk and membrane surface and permeation of ionized molecules were simultaneously responsible for the observed permeation rates.

Dry powder inhalers: the influence of device resistance and powder formulation on drug and lactose deposition in vitro

It is a principal in the formulation of a dry powder aerosol that the device should enable a high fine particle fraction (FPF) of drug to be delivered to the lung whilst any carrier, such as lactose, should remain in the upper airways. Both the device and the dry powder formulation itself contribute to the resultant FPF and few studies have considered the deposition of lactose carrier. It was the purpose of this study to determine the effect of the resistance of the device and the influence of powder formulation on the deposition of drug and carrier. Measurement of the pressure drop across the devices investigated in this study showed that the two types of Inhalator Ingelheim had the highest resistance, whilst lower pressure drops were found across the Diskhaler, Cyclohaler and Accuhaler devices. The lowest pressure drops were measured across the Rotahaler and Spinhaler devices. Employing Rotacaps 400 capsules as the formulated salbutamol product, the FPF of drug was greater from the high resistance devices, being in the order Inhalators Ingelheim>Cyclohaler>Rotahaler=Spinhaler. However, the Diskhaler, employing its own developed formulation, produced the highest FPF, approximately twice that from the Accuhaler. There was no statistical difference between the FPF of salbutamol (approximately 20% nominal dose) from the Rotacaps formulation when aerosolised using high resistance devices (Inhalators Ingelheim) operated at 30 l min-1, a medium resistance device (Cyclohaler) operated at 60 l min-1 and low resistance devices (Spinhaler and Rotahaler) operated at a flow-rate of 90 l min-1. The Ventolin Diskhaler using its own formulation operated at 60 l min-1 gave a FPF of 40.33%, but the FPF obtained was sensitive to flow, being only 25.65% of the nominal dose at 30 l min-1. Whereas no lactose was found in the FPF from the Accuhaler operated at 60 l min-1, 100, 400 and 3500 microg were obtained from the Diskhaler, Rotacaps and micronised lactose formulation, respectively, when operated at the same flow-rate. An in-house formulation comprising salbutamol sulphate blended with micronised lactose in a weight ratio of 1:67.5 and aerosolised from a Cyclohaler produced a similar FPF to the Diskhaler at 60 l min-1. When air flow was reduced to 30 l min-1, the FPF from the in-house formulation was reduced considerably less than that from the Diskhaler formulation.