Subtherapeutic triazole concentrations as result of a drug-drug interaction with lumacaftor/ivacaftor.

Lumacaftor/ivacaftor (Orkambi®, LUM/IVA) is indicated for the treatment of cystic fibrosis (CF) patients aged ≥ 2 years with homozygous F580del mutation in the CFTR gene. Triazole fungal agents are used to treat fungal disease in CF. The use of triazoles is limited by pharmacokinetic challenges, such as drug-drug interactions. The most notable drug-drug interaction between triazoles and LUM/IVA is due to strong induction of CYP3A4 and UGT by LUM. In this real-world retrospective observational study, we described the effect of LUM/IVA on the trough concentration of triazoles. Concomitant use of LUM/IVA with itraconazole, posaconazole or voriconazole resulted in subtherapeutic triazole levels in 76% of the plasma samples. In comparison, in patients with triazole agents without LUM/IVA only 30.6% of the plasma samples resulted in subtherapeutic concentrations. Subtherapeutic plasma concentrations of triazoles should be considered in CF patients on LUM/IVA and further research is warranted for other dosing strategies and alternative antifungal therapy.

Pharmacokinetics and Tolerability of Once Daily Double Dose Tobramycin Inhalation in Cystic Fibrosis Using Controlled and Conventional Nebulization.

BACKGROUND: Better treatment outcomes in cystic fibrosis (CF) may be expected by changing standard twice daily (BID) tobramycin inhalation with the conventional nebulizer to once daily (OD) inhalation at double the standard BID dose with a controlled-inhalation nebulizer. We aimed to determine the pharmacokinetics and tolerability of inhaled double-dose tobramycin with the controlled-inhalation AKITA(®) and conventional PARI-LC(®) Plus nebulizer in patients with CF. METHODS: Randomized, open label, crossover study. Pharmacokinetics were assessed in 10 adult CF patients following inhalation of tobramycin (Bramitob(®)) at double the recommended BID dose with the AKITA (300 mg fill dose) and PARI-LC Plus (600 mg fill dose). RESULTS: No significant differences were found in pharmacokinetic parameters between the two nebulizers. Median maximum serum levels were 3.44 (2.25-5.49) and 2.84 (0.82-6.63) mg/L for AKITA and PARI-LC Plus, respectively. Trough serum levels were very low for both nebulizers: 0.03 (0.00-0.09) and 0.02 (0.00-0.06) mg/L for AKITA and PARI-LC Plus, respectively. Time to maximum level was comparable: 0.44 (0.08-0.96) and 0.40 (0.08-0.96) hours for AKITA and PARI-LC Plus, respectively. Serum levels were well below the toxic limit. Inhalations were well tolerated and no serious adverse events occurred. Nebulization time was 33% shorter with the AKITA. CONCLUSIONS: OD tobramycin inhalation of the double standard BID dose with a controlled-inhalation and conventional nebulizer resulted in similar pharmacokinetics in the doses given, with serum levels below the toxic limit. Further research demonstrating clinical efficacy and safety of this treatment approach is required. Dutch trial register number NTR4525.

Limited premature termination codon suppression by read-through agents in cystic fibrosis intestinal organoids.

Premature termination codon read-through drugs offer opportunities for treatment of multiple rare genetic diseases including cystic fibrosis. We here analyzed the read-through efficacy of PTC124 and G418 using human cystic fibrosis intestinal organoids (E60X/4015delATTT, E60X/F508del, G542X/F508del, R1162X/F508del, W1282X/F508del and F508del/F508del). G418-mediated read-through induced only limited CFTR function, but functional restoration of CFTR by PTC124 could not be confirmed. These studies suggest that better read-through agents are needed for robust treatment of nonsense mutations in cystic fibrosis.

A bioassay using intestinal organoids to measure CFTR modulators in human plasma.

Treatment efficacies of drugs depend on patient-specific pharmacokinetic and pharmacodynamic properties. Here, we developed an assay to measure functional levels of the CFTR potentiator VX-770 in human plasma and observed that VX-770 in plasma from different donors induced variable CFTR function in intestinal organoids. This assay can help to understand variability in treatment response to CFTR potentiators by functionally modeling individual pharmacokinetics.

What the pulmonary specialist should know about the new inhalation therapies.

A collaboration of multidisciplinary experts on the delivery of pharmaceutical aerosols was facilitated by the European Respiratory Society (ERS) and the International Society for Aerosols in Medicine (ISAM), in order to draw up a consensus statement with clear, up-to-date recommendations that enable the pulmonary physician to choose the type of aerosol delivery device that is most suitable for their patient. The focus of the consensus statement is the patient-use aspect of the aerosol delivery devices that are currently available. The subject was divided into different topics, which were in turn assigned to at least two experts. The authors searched the literature according to their own strategies, with no central literature review being performed. To achieve consensus, draft reports and recommendations were reviewed and voted on by the entire panel. Specific recommendations for use of the devices can be found throughout the statement. Healthcare providers should ensure that their patients can and will use these devices correctly. This requires that the clinician: is aware of the devices that are currently available to deliver the prescribed drugs; knows the various techniques that are appropriate for each device; is able to evaluate the patient's inhalation technique to be sure they are using the devices properly; and ensures that the inhalation method is appropriate for each patient.

The Sophia Anatomical Infant Nose-Throat (Saint) model: a valuable tool to study aerosol deposition in infants.

Relatively little is known about the variables that influence lung deposition of inhaled aerosols in children. A model of the upper airways of an infant could be a useful tool to study these variables in vitro. The objective of this study was to construct an anatomically correct model of the upper airways of a young child. A routine three-dimensional (3D) CT scan of the skull and neck of a child was selected that included the airway from the nasal cavity down to the subglottic region. The CT scan was edited to obtain an anatomically correct distinction between air and mucosa. Next, a model was constructed with a stereolithographic technique using a UV-sensitive resin. To validate the model, a 3D CT scan of the model was made and compared to the anatomy of the original image. To study aerosol deposition, the model was connected to a breathing simulator. Medical aerosols were delivered to the model by MDI/spacer during stimulated breathing. An upper airway model was made of a 9-month-old child that needed reconstructive surgery for a skull deformity and with normal anatomy of the upper airways. The nasal airway of the model was open for air passage and the oral airway was closed. The CT scan of the model matched the original in vivo CT scan closely. Aerosol deposition measurements showed that dose passing the model, or lung dose, was comparable with in vivo lung deposition data. We have constructed an anatomically correct model of the upper airways of a child, using a stereolithographic method for in vitro studies of aerosol deposition in young children. This model will be used to obtain insight in aerosol treatment that cannot be obtained in vivo.