Traitements inhalés : critères de choix des dispositifs, absorption systémique des médicaments par voie inhalée et récepteurs pulmonaires à l’amertume

[Reducing the environmental impact of inhalers dispensed in France. From diagnosis to sustainable action]

OBJECTIVES

While inhaled drugs are mainly used to treat chronic respiratory diseases, they are also responsible for greenhouse gas (GHG) emission. To highlight this issue, a dispensed analysis and a carbon footprint evaluation of inhalers in France have been conducted.

METHODS

A national qualitative and quantitative analysis of dispensed inhalers in community pharmacies (CP) and hospitals (H) was conducted in France for 2019. A data review from the literature led to the determination of the inhalers carbon footprint, expressed in carbon dioxide equivalent (CO₂e) during the inhaler life cycle.

RESULTS

Close to 40 million inhalers were dispensed by community pharmacies and one million by hospitals in 2019. It concerned three types of inhalers: metered-dose inhalers (MDI) [CP: 49%; H: 45%], dry powder inhalers (DPI) [CP: 47%; H: 51%], and soft mist inhalers (SMI) [CP: 4%; H: 4%]. According to the literature, MDI have the highest carbon footprint, ranging from 11 to 28 kgCO2e versus less than 1 kgCO2e for DPI/SMI. In 2019, the national carbon footprint of salbutamol (MDI), the most dispensed inhaler, was estimated to be over 310 million kgCO2e (CP+H) corresponding to more than 310,000 round-trip Paris-New York.

CONCLUSIONS

This study shows the involvement of MDI in GHG emissions. Taking actions as part of a global and coordinated approach to limit their environmental impact is possible and thus is a priority.

Scope and limitations on aerosol drug delivery for the treatment of infectious respiratory diseases

The rise of antimicrobial resistance has created an urgent need for the development of new methods for antibiotics delivery to patients with pulmonary infections in order to mainly increase the effectiveness of the drugs administration, to minimize the risk of emergence of resistant strains, and to prevent patients reinfection. Since bacterial resistance is often related to antibiotic concentration, their pulmonary administration could eradicate strains resistant to the same drug at the concentration achieved through the systemic circulation. Pulmonary administration offers several advantages; it directly targets the site of the infection which allows the inhaled dose of the drug to be reduced compared to that administered orally or parenterally while keeping the same local effect. The review article is made with an objective to compile information about various existing modern technologies developed to provide greater patient compliance and reduce the undesirable side effect of the drugs. In conclusion, aerosol antibiotic delivery appears as one of the best technologies for the treatment of pulmonary infectious diseases and able to limit the systemic adverse effects related to the high drug dose and to make life easier for the patients.