Abstract
The aim of the present studies was to investigate the tolerability and activity of a novel mucolytic drug, Nacystelyn (NAL), for the treatment of cystic fibrosis (CF) lung disease.
In study 1, involving 10 CF patients, the main objective was to determine the tolerability and potential efficacy of a range of single doses of NAL in comparison to a placebo, in order to establish an optimal dose for further testing. On five consecutive scheduled treatment days, patients inhaled either from two (4 mg) to eight puffs (16 mg) of a single dose of NAL from the range, administered in an open-label fashion, or 12 puffs of active NAL (24 mg) versus 12 puffs of placebo, administered in a randomized double-blind fashion. Pulmonary function data were unaffected and clinically-adverse effects were limited to wheezing in some patients that inhaled 12 puffs of either placebo or active drug. Subsequent rheological analysis of their sputum showed a dose-dependent decrease in sputum viscoelasticity, accompanied by a decrease in sputum solids content and an increase in chloride and sodium concentrations.
In study 2, involving 12 CF patients, the clinical safety and mucolytic activity of a single dose of NAL was monitored over 24 h. On different scheduled treatment days, 7 days apart, patients inhaled a single dose of 12 puffs of active NAL (24 mg) or 12 puffs of placebo drug in a randomized, double-blind sequence, with sputum samples taken at intervals before and after inhalation. Mucus rigidity decreased following NAL inhalation, with the maximum effect observed at 4 h; the 1-, 2- and 4-h NAL rheology results were significantly different from placebo. No adverse effects were observed.
The drug was well tolerated in both studies. Sputum results were predictive of improved clearability by ciliary and cough transport mechanisms.
- airway clearance
- cystic fibrosis
- epithelial ion transport
- mucolytic therapy
- protease inhibitors
- sputum rheology
This study was supported by SMB & Galephar, and in part by the Canadian CF Foundation.
Cystic fibrosis (CF) is a chronic, progressive and generally fatal genetic disease caused by mutations in the gene that codes for the CF transmembrane regulator protein 1. The main physiological defect is related to abnormal transepithelial sodium and chloride transport. In most patients, this leads to raised levels of chloride in sweat (>60 mmol·L−1, with chloride higher than sodium) 2 and reduced chloride permeability in airway and intestinal epithelia. These factors cause most of the clinical problems, although the exact mechanisms are still unclear. In general, the exocrine glands are dysfunctional, resulting in viscous secretions of low water content. These viscous secretions are poorly cleared, especially in the lung 3, leading both to obstruction of the airways and recurrent and chronic lung infections. The cycle of chronic infection causes early-sustained and severe inflammatory reactions 4, leading to progressive lung damage, eventual respiratory failure and, ultimately, death.
Nacystelyn (NAL), a salt derivative of N-acetylcysteine (ACC) and lysine, is a mucoactive agent developed for the treatment of impaired mucociliary clearance and chronic mucus retention in CF. NAL has been shown to have direct mucolytic activity approximately equal to the sum of the activities of its two components, ACC and lysine 5. App et al. 6 and Dasgupta and King 7 found NAL to be effective in reducing the viscoelasticity of CF sputum in the 10−4 M range. Through use of spinnability as a rheological measure, Dasgupta and King 7 also found that NAL combined synergistically with recombinant human deoxyribonuclease (rhDNase; Pulmozyme®, Genentech Inc., San Francisco, CA, USA) in reducing the viscoelasticity of CF sputum. In addition to this direct mucolytic activity, NAL in vivo appears to increase the transepithelial potential difference, causing a stimulation of chloride transport, which induces water movement into the epithelial lining fluid and further enhances the fluidification of the mucus 8–10. This important additional effect of NAL in vivo is believed to be due to its lysine component 11.
The almost neutral pH of NAL (negative logarithm of the acid ionization constant (pKa)=6.2), in contrast to the high acidity of its parent molecule ACC (pKa=2.2), has eliminated the need for a buffering agent and has led to the development of a metered-dose inhaler (MDI), which does not produce an increase in airway responsiveness 12. Besides its mucolytic activity and chloride-transport stimulation, NAL appears to play a role in alleviating and/or preventing oxidative lung damage caused by an active inflammatory response 13–16 and in changing the protease-to-antiprotease balance in bronchial secretions to antiprotease 6, 17, 18.
On the basis of these observations, it appears that administration of NAL may be a promising therapeutic approach to the treatment of CF. The authors therefore decided to perform an initial pilot clinical study (study 1), with the main objective of determining the tolerability and potential efficacy of several different single doses of NAL in comparison to a placebo, in order to establish an optimal dose that could be be tested in further clinical studies. This study was carried out in CF patients with mild-to-moderate lung dysfunction. Evidence of activity of NAL was determined by observations of sputum rheology, consistent with a mucolytic effect.
In light of the favourable results from the dose-finding study, the highest single dose tested (i.e. 24 mg of NAL) was retained for further investigation. The main objective of the second pilot study (study 2) was to determine the duration of efficacy and tolerability of this single dose of NAL in comparison to a placebo in a group of patients with CF lung disease, in order to establish an optimal dosing schedule that could be tested in further clinical studies.
Methods
Study 1: dose-finding study
From those attending the CF Clinic of Erasmus Hospital, Brussels, Belgium, 10 CF patients (six males, four females) aged 15–31 yrs, were selected at a run-in visit, 1 week before entry into the study and according to the inclusion and exclusion criteria. They all signed an informed consent form, with the signature of a witness. The study was approved by the Ethical Committee of Erasmus University Hospital, Université Libre de Bruxelles (ULB) in Brussels, Belgium.
Patients were selected if they had CF with mild-to-moderate lung function impairment, were aged >7 yrs, and were diagnosed as having the disease from a combination of medical history, clinical examination, chest radiograph, and abnormal sweat test (by iontophoresis with pilocarpine). Patients were excluded from participation in the study if they: had severe respiratory disease (forced expiratory volume in one second (FEV1) <30% predicted); had a recent history of an acute respiratory episode within 2 weeks before the study; were unable to stop using antibiotics, bronchodilators, mucolytics or expectorant drugs within 1 week prior to their first intake of the study drug; had a history of allergy to ACC or related drugs; were unable to use an MDI correctly; were aged <7 yrs; or refused to give signed written consent. In addition, female patients who may have been pregnant, pregnant women and nursing mothers were all refused entry into the study.
Study design
The study was designed to look for an optimal single dose of NAL, which may be potentially active and well tolerated in mild-to-moderate CF patients.
NAL was administered by MDI (Armstrong Laboratories, part of Medeva Inc., West Roxbury, MA, USA). Inhalation was made via a Volumatic spacer (Allen & Hanburys, Uxbridge, Middlesex, UK), which delivers a respirable fraction (weight fraction of particles <4.7 µm) of about one-tenth the nominal dose 19. The doses were delivered to the patient puff-by-puff, using a deep inhalation technique, with the patient waiting ∼30 s between puffs.
The NAL and placebo metered-dose inhalants were supplied by Laboratoires SMB & Galephar S.A. (Brussels, Belgium). The placebo consisted of a surfactant, sorbitone trioleate, and a mixture of freons as propellants. The NAL inhalant contained the same ingredients as were in the placebo formulation, plus 6.7 mg of l-lysine ACC (Nacystelyn, Moehs SA, Rubi, Barcelona, Spain) per 100 mg of propellants. The MDI was designed to deliver 150 puffs per container, each puff containing 2 mg of active ingredient. In connection with the present study, the particle size distribution of NAL administered from the inhaler was measured using an Andersen Cascade Impactor (Andersen plc, Nottingham, UK), which was tested as described in the literature 20.
During the run-in visit, a complete medical history was taken, including the patient's genotype (when available), general physical health (including tiredness, appetite and weight) and dyspnoea evaluation (all rated on a numerical scale of 0–4 (0: best score, 4: worst score)), and concomitant medications. A physical exam, including a pulmonary and cardiological exam, was also performed. Pulmonary function tests (whole body plethysmography; Jaeger Instruments, Würzburg, Germany) including vital capacity (VC), FEV1, Tiffeneau ratio (FEV1/VC), specific airway resistance (sRaw), peak expiratory flow (PEF) and arterial oxygen saturation (Sa,O2; Ohmeda Biox 3700 pulse oximeter, Louisville, KY, USA) were all administered. A chest radiograph was also taken (if unavailable from the last 6 months) and scored from 0–25 according to the Brasfield scoring technique 21. A washout period of antibiotics, bronchodilators, mucolytics and expectorant drugs was enforced from 1 week prior to their first intake of study drug.
Patients then returned to the clinic to receive their study treatment over five visit days, which, in most instances, were consecutive. The study treatment consisted of a series of randomly-administered single doses of either 4 mg (two puffs), 8 mg (four puffs) or 16 mg (eight puffs) of active drug administered in an open-label fashion, or 24 mg (12 puffs) of active drug or 12 puffs of placebo drug administered in a randomized double-blind fashion.
The time interval between treatment doses was programmed to be ∼24 h; administration was always in the morning, at the same time each day. During each of the five study visits and ≥15 min before the inhalation of the study drug, the patient was questioned about general health and any change in concomitant medication. In addition, during each study visit ≥15 min before and ∼30 min after inhalation of the study drug, a dyspnoea evaluation, pulmonary function tests, Sa,O2 measurements, and a pulmonary and cardiological physical exam were performed on each patient. Any adverse events occurring after inhalation of the study drug were recorded by the clinical investigator.
Sputum samples were also collected, primarily in order to evaluate the rheology, but also to examine the electrolyte content and protease and antiprotease activity. Dental cotton was used on the orifices of salivary ducts to reduce saliva contamination 22. For each sputum sample collection, a specific technique was employed. The patient was directed to cough into a glass beaker under a physiotherapist's supervision. The first sample was collected ≥15 min before inhalation and the second sample ∼30 min after inhalation on each study day. The samples were transferred using tweezers into a 10 mL test tube and covered immediately with ∼0.5 mL of light paraffin oil (Fisher, Zürich, Switzerland). Each tube was then covered with a screw-top cap, labelled with an alcohol-based colour pen and the label covered with transparent tape. Within 30 min of collection, it was placed in a deep freezer for storage at −80°C. Once all the sputum samples were collected, they were placed in a styrofoam box filled with dry ice and shipped overnight to a specialized laboratory at the University of Grosshadern, Munich, Germany (GSF Hematologicum, E.M. App) for processing and analysis of sputum.
Study 2: 24-h monitoring study
Twelve CF patients (seven males, five females) ranging from 12–31 yrs were recruited for this study (six were from the Erasmus University Hospital, ULB and the other six were from the Academic Hospital, Vrije Universiteit Brussel (VUB), Brussels, Belgium). Patients (or guardians, if the patient was <18 yrs old) all signed an informed consent form. The study was approved by the respective ethics committees of both hospitals. Eligibility criteria were the same as for study 1.
Study design
The study was designed to look for the duration of activity and the tolerability of a single dose of NAL compared to a placebo in CF patients with mild-to-moderate pulmonary dysfunction. Both NAL and placebo were administered from an MDI (Armstrong Laboratories) identical to that used in study 1; inhalation was again made via a Volumatic spacer (Allen & Hanburys).
Run-in procedures were the same as in study 1, with the following additions or variations: rales found on pulmonary auscultation were evaluated on a numerical scale of 0–4 (0: best score, 4: worst score) and wheezing on a scale of 0–2 (0: best score, 2: worst score). A chest radiograph was also taken (if unavailable from 1 month prior to entry into the study) and scored 0–25 according to the Brasfield scoring method 21. A sputum sample was taken (if unavailable from 1 month prior to entry into the study) for semiquantitative bacterial analysis. A washout period of antibiotics (especially inhaled), bronchodilators, mucolytics and expectorant drugs was enforced from 72 h prior to their first intake of study drug.
In the hospital clinic, patients were then allocated to receive, on two separate days, a single morning dose of either 12 puffs (24 mg) of active drug or 12 puffs of placebo drug in a randomized, double-blind, two-way crossover design. The time interval between the two administrations was 7 days. The order of treatment was randomized and the time of day of therapy was the same for each administration. Each patient was closely monitored for side-effects over a period of 8 h after dosing and on the morning of the following day, 24 h after dosing. During each study visit, the patient was questioned about any change in concomitant medication.
Sputum samples were collected ≥15 min before inhalation of the dose and 1, 2, 4, 8 and 24 h afterwards in order to evaluate primarily the rheology, but also the electrolyte content and the protease and antiprotease activity. Placebo data were also examined for evidence of diurnal variability.
Sputum analysis
Sputum was examined for five properties: rigidity, spinnability, hydration, changes in electrolytes and protease-to-antiprotease activity.
Rheological properties of sputum aliquots were measured by magnetic microrheometry 23, 24. Approximately 2 µL aliquots of sputum were placed in the chamber of the magnetic microrheometer and the rigidity, G* (mechanical impedance=vector sum of viscosity and elasticity) and loss tangent (viscosity/elasticity) were determined at low (1 radian (rad)·s−1) and high (100 rad·s−1) frequencies. These measurement frequencies are used to simulate mucociliary and cough clearance conditions, and thus obtain relevant viscoelasticity. The measured viscoelastic data were expressed as log G* and tan δ, and were used to calculate a mucociliary clearability index as well as a cough clearability index from previously established relationships, based on model studies 25.
Spinnability measurements were performed in order to measure the gross elastic deformation capacity, which is important for an effective cough clearance in mucus hypersecretion such as in CF. Spinnability is the thread-forming ability of mucus under the influence of low-speed elastic deformation. The spinnability of CF sputum samples was measured using a filancemeter (Type 04, SEFAM, Nancy, France) 26, modified to accommodate small sample volumes, in which a 20–30-µL sputum sample is stretched at a distraction velocity of 10 mm·s−1. An electrical signal conducted through the mucus sample is interrupted at the point where the mucus thread is broken. The length of this thread is known as the mucus spinnability (measured in mm).
A gravimetric method was used to determine the solids content of the sputum in order to evaluate hydration, which may change due to an alteration in epithelial secretory activity, such as an increase in chloride secretion. A Mettler analytical balance (Mettler Toledo, Inc., Columbus, OH, USA) was used to weigh the sputum samples before and after evaporation to dryness in a microwave oven at 750 W 27.
Electrolyte analysis of sputum aliquots was carried out with atomic emission spectrometry, using an inductive-coupled plasma technique for the analysis of sodium, potassium and calcium. Chloride analysis was then performed with a segmented continuous-flow analysis system, where chloride was detected by the formation of azo-complexes. The results were expressed as mmol·L−1 (wet weight).
Photometric protease activity measurements were performed at 405 nm light wavelength and expressed as extinction increase·min−1 (i.e. as inhibitor units). The elastase-neutralizing activity of protease inhibitor was determined by pre-incubation of identical amounts of inhibitor and elastase. The remaining inhibitor activity was measured with neutrophil granulocytic elastase as the target enzyme and suc-l-alanyl-l-valyl-4-nitroanilide as a specific chromogenic substrate.
Statistical methods
Data from each protocol are presented as mean±sd. To analyse the significance of the changes in clinical, pulmonary function and sputum parameters, data following therapy were compared with those prior to it. Equality of means was tested by analysis of variance; post hoc analysis of changes from pre-inhalation values was determined where appropriate by a two-tailed, paired t-test. A p-value of 0.05 was considered statistically significant.
Results
Study 1: dose-finding study
Patient characteristics
The age, sex, genotype, radiograph score, and respiratory characteristics of the patients at the pre-inclusion examination are summarized in table 1⇓. On average, the females were younger (mean age 17.8 yrs) than the males (23.2 yrs). There were no sex-related differences in pulmonary function when corrected for height and weight. All 10 patients enrolled in this pilot study completed each of the five study days.
Pulmonary function change with Nacystelyn or placebo
Table 2⇓ summarizes the pre- and post-test values of VC, FEV1, FEV1/VC, sRaw, PEF for the 12-puff, 24-mg NAL administration and the 12-puff, randomized, blinded placebo administration. Acute administration of NAL or placebo did not cause significant changes in any of these pulmonary function parameters. Similar findings were obtained for the three lower doses of NAL (4 mg, 8 mg, and 16 mg). There were no significant differences in pre-aerosol pulmonary function from one study day to the next. Adverse effects were seen in five patients, as noted in table 3⇓. The majority of the adverse events (four of seven) were associated with 12 puffs of the placebo and not with the active drug. On six occasions and in three patients, dyspnoea was reported as improved; for five of these six occasions, NAL had been administered.
Sputum rheology
Figure 1a⇓ shows the principal index of mucus rigidity: G* in dyne (dyn)·cm−2, as determined by magnetic rheometry at 1 rad·s−1 and expressed on a logarithmic scale (log G*1). The differences between log G* at 10 and 100 rad·s−1 with NAL dose were negligible. In simple terms, the mucus became less rigid or more deformable, thus benefiting clearability, based on predictions from model studies, as illustrated in figure 2⇓ (mucociliary clearability index and cough clearability index). After eight and 12 puffs of NAL (16 and 24 mg), sputum viscoelasticity decreased significantly (p=0.0081 and p=0.0009, respectively) and both clearability indices increased significantly.
Figure 1b⇑ also depicts the dose-response relationship of sputum spinnability, as determined by a filancemeter. The results indicate increasing elastic deformation with NAL, consistent with the decrease in log G*. The increase in spinnability at 12 puffs of NAL was statistically significant (p=0.045).
Sputum electrolyte/solids content
There was a significant decrease in sputum solids content (fig. 3⇓) or, in other words, an increase in sputum water content. The changes at eight and 12 puffs were highly significant (p=0.0009 and p=0.0002, respectively).
There was also a dose-dependent increase in chloride ion content with increasing NAL administration. The changes in chloride and sodium ion content at 12 puffs of NAL are illustrated in figure 4⇓. Both ion contents increased with NAL administration in comparison with placebo (p=0.009 for Cl− and p=0.004 for Na+). There was no change in either potassium or calcium content.
Sputum elastase activity
For all NAL concentrations, the assayed level of human neutrophil elastase in the sputum supernatant did not change significantly. However, the elastase content in the sample sediment tended to decrease at eight and 12 puffs of NAL. The level of bronchial secretory inhibitor activity in the supernatant did not change with the dose of NAL.
Study 2: 24-h monitoring study
The age, sex, genotype, radiograph score, and respiratory characteristics of the patients at the pre-inclusion examination are summarized in table 4⇓. Five of these patients, all recruited from the Academic Hospital-VUB, had an FEV1 of <30%. The main reasons that the investigator included them in the study was that they all regularly produced the large quantities of sputum required for analysis of the primary efficacy criteria in this study and the investigator considered that there were no undue safety concerns. These patients satisfied all the other inclusion and exclusion criteria; in particular, they all gave their informed written consent and were all able to clinically support the ∼11-day washout period of antibiotics, bronchodilators, mucolytics and expectorant drugs from 3 days before and until the end of the study. Of these five patients, four regularly took inhaled mucolytics, three took inhaled bronchodilators, and only one took an oral antibiotic prior to their entry into the protocol. Hence, they were considered to be protocol deviations and kept for analysis in the study. The evolution of the symptomatology and the physical examination (tiredness, appetite, dyspnoea, general status) over the course of 24 h, following inhalation of the test drug, was not statistically different between the two groups of patients. There were no important adverse events in either group.
Sputum rheological values
Figure 5a⇓ shows the principal index of mucus rigidity (G* in dyn·cm−2), as determined by magnetic rheometry at 1 rad·s−1 and expressed on a logarithmic scale (log G*1). The differences in log G* at 100 rad·s−1, which were very similar, are illustrated in figure 5b⇓. The maximum difference in log G*1 was 0.43 log units (factor of 2.7 decrease on a linear scale), which occurred at 4 h after inhalation of NAL. In simple terms, the mucus became less rigid or more deformable with NAL administration at 1, 2, 4, and 8 h (only 100 rad·s−1). The net effect of these changes in sputum viscoelasticity is a projected benefit in clearability, based on predictions from model studies 25. There was no apparent order-of-treatment effect (placebo first or NAL first). There was, however, some indication of a diurnal cycle of sputum viscoelasticity in the placebo data.
Solids and ion content/elastase and inhibitor activity
There were no significant differences in the sputum solids content during NAL inhalation over the 24 h of the study. None of the measured sputum ion contents (Na, Cl, K, Ca) were found to vary significantly between NAL and placebo administration over the course of 24 h. The assayed levels of human neutrophil elastase did not change significantly over the course of 24 h, and there were no differences (either in supernatant or sediment) associated with NAL administration. There was also no change in bronchial secretory inhibitor in the sputum supernatant.
Particle size distribution
With the MDI device (Armstrong Laboratories) plus Volumatic spacer (Allen & Hanburys), the respirable fraction (weight fraction of particles of diameter <4.7 µm) was 9±1% or approximately one-tenth the nominal dose, measured on an Andersen Cascade Impactor (Andersen plc) at an airflow rate of 28.3 L·min−1. The deposition extended to several stages and was reproducible between runs. In addition, it was proven that the lung deposition of NAL from the MDI was uniform during the life of the inhaler (150 puffs).
Discussion
NAL inhalation in study 1 was well tolerated by all of the patients, and there were no acute changes in pulmonary function associated with NAL administration at any of the doses studied or with placebo inhalation. There were very few adverse events recorded (seven out of a total 50 study days) and none were serious. With the exception of cough and throat irritation in one patient, the adverse events can all be considered as transitory wheezing. Given the fact that the majority of the adverse events were associated with 12 puffs of the placebo, they can probably be attributed to the chlorofluorocarbon propellants of the MDI. This will not be a factor in the newer dry powder technology 28. Long-term adverse events, or those which evolve more slowly (e.g. allergic reactions), are beyond the scope of the present studies.
Even allowing for the fact that detection of adverse events is difficult in CF patients because of pre-existing lung damage, the lack of adverse events associated with NAL administration is consistent with the wide margin of safety indicated by prior toxicology studies conducted on dogs 29 and healthy human volunteers 12.
The baseline values of log G* (rigidity factor) of the sputum of these CF patients are high when compared with those for tracheal mucus from normal humans 30, or even smokers, with or without obstructive bronchitis 31. However, the values are not dissimilar to the control values (placebo treatment group) obtained for CF patients in other studies involving magnetic rheometry analysis 27, 32, 33. Similarly, the per cent solids content is also elevated over the normal range. This picture is consistent with the expectations for sputum rheology and composition in CF, where a high content of proteins and deoxyribonucleic acid (DNA) of cellular origin is believed to add significantly to the cross-linking of the mucous gel network. The placebo rheological data (fig. 5⇑) give some indication of a diurnal cycle of sputum viscoelasticity, which has not been reported previously.
In study 1, the rheological effect of NAL was determined at only a single time point (∼30 min following drug inhalation). At this time point, only the acute effects of the drug in the central airways may have been measured. The dose-dependent decrease in mucus viscoelasticity (log G*) can partly be attributed to the known mucolytic effect of disulphide bond disruption due to the ACC component 5, 6. The fact that there was also a dose-dependent decrease in solids content (increase in mucous gel hydration) suggests that the mechanism of action also involves increased chloride secretion to the epithelial lining fluid, accompanied by augmented transfer of sodium and water. This argument is reinforced by the finding of an increased content of chloride and sodium in the sputum samples after NAL administration. These ion content changes appear to involve an active ion transport process, rather than general dehydration, since there was no change in either potassium or calcium content.
The results of study 2, as illustrated by the significant changes in sputum viscoelasticity and spinnability, confirm the acute effect of NAL inhalation in CF patients on the important properties of airway mucus that relate to mucociliary and cough clearance. Furthermore, the present results demonstrate that these significant changes persist for ≥4 h, and perhaps 8 h after administration of aerosol. The peak effect appears to occur ∼4 h after inhalation, consistent with a 4–6-h clearance half-time of mucus from the airways 14, 15. The timing of the rheological changes indicates a good profile for a mucolytic drug, an effect lasting long enough to clear the majority of the mucus from the lung 16. Based on these results, a twice- or three-times daily inhalation of NAL, at a 24-mg delivered dose, would probably be an appropriate target range for further clinical testing 34.
In study 2, the significant changes in sputum viscoelasticity (log G*) were not accompanied by significant changes in sputum solids content or Cl−/Na+ contents, as was the case in study 1. The reason for this discrepancy is unknown.
The value of the respirable fraction obtained in the present study was similar to that observed by Hardy et al. 19 in six healthy volunteers. The study of Hardy et al. 19 also demonstrated that the lung deposition was similar in central, intermediate and peripheral lung compartments in healthy volunteers. The relatively small values of standard deviations obtained in vitro and in vivo show that lung deposition from the MDI is reproducible and can be assumed to be 10%. Since each actuation delivers 2 mg of NAL, 12 puffs from the inhaler are needed to obtain the lung deposition dose of 2.4 mg of NAL. This equates to the inhalation of one 8-mg dry powder inhaler capsule, where the lung deposition is ∼30%.
In summary, administration of a single dose of Nacystelyn by metered-dose inhaler, ⪕12 puffs (24 mg) in patients with mild-to-moderate cystic fibrosis lung dysfunction, was well tolerated and free of any adverse effects due to the active ingredient. Although there was no acute change in pulmonary function or any clinical indicator, there were significant changes in sputum rheology and hydration predictive of improved airway mucus clearance. Over 24 h, there were no adverse events associated with administration of 24 mg of Nacystelyn by metered-dose inhaler. Potentially beneficial changes in sputum rheology lasting ⪕8 h were observed. The results of these initial studies justify further testing of this drug in cystic fibrosis patients.
Acknowledgments
The authors gratefully acknowledge the skilled editing assistance of S.G. Cochrane.
- Received March 16, 2001.
- Accepted September 19, 2001.
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