Thoughtful prescription of inhaled medication has the potential to reduce inhaler-related greenhouse gas emissions by 85.

IF 3.6 3区 医学 Q1 RESPIRATORY SYSTEM BMJ Open Respiratory Research Pub Date : 2024-09-01 DOI:10.1136/bmjresp-2023-001782
Ville Vartiainen, Ashley A Woodcock, Alex Wilkinson, Christer Janson, Unnur Björnsdóttir, Tari Haahtela, Lauri Lehtimäki
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Abstract

Introduction: Both physicians and patients are increasingly aware of the environmental impacts of medication. The shift of treatment paradigm towards MART-treatment (Maintenance and Reliever Therapy) in asthma affects the treatment-related emissions. The carbon footprint of inhaled medication is also tied to the type of the device used. Today the most commonly used propellant-containing pressurised metered-dose inhalers (pMDIs) have a carbon footprint typically 20-40-fold higher than propellant-free dry powder inhalers (DPIs) and soft mist inhalers.

Methods: We analysed the carbon footprint of inhaled medications in Europe using published life cycle analyses of marketed inhalers and comprehensive 2020 European sales data. In addition, we give an estimate on treatment-related emissions of different treatment regimens on Global Initiative for Asthma (GINA) step 2.

Results: There is potential to reduce the carbon footprint of inhaled medications by 85% if DPIs are preferred over pMDIs. Emissions from pMDIs in the EU were estimated to be 4.0 megatons of carbon dioxide equivalent (MT CO2e) and this could be reduced to 0.6 MT CO2e if DPIs were used instead. In the treatment of moderate asthma with DPI, an as-needed combination of inhaled corticosteroid and long-acting beta-agonist in a single inhaler had a substantially lower annual carbon footprint (0.8 kg CO2e) than the more traditional maintenance therapy with an inhaled corticosteroid alone with as-needed short-acting beta-agonist (2.9 kg CO2e).

Discussion: There has been an urgent call for healthcare to reduce its carbon footprint for appropriate patients with asthma and chronic obstructive pulmonary disease (COPD), changing to non-propellant inhalers can reduce the carbon footprint of their treatment by almost 20-fold.

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经过深思熟虑的吸入式药物处方有可能将与吸入器相关的温室气体排放量减少 85%。
导言:医生和患者都越来越意识到药物治疗对环境的影响。哮喘治疗模式向 MART 治疗(维持和缓解治疗)的转变影响了与治疗相关的排放。吸入式药物的碳足迹也与所用设备的类型有关。目前最常用的含推进剂的加压计量吸入器(pMDIs)的碳足迹通常比不含推进剂的干粉吸入器(DPIs)和软雾吸入器高 20-40 倍:方法:我们利用已公布的市场上销售的吸入器的生命周期分析和 2020 年欧洲的综合销售数据,分析了欧洲吸入式药物的碳足迹。此外,我们还根据全球哮喘倡议(GINA)第二步对不同治疗方案与治疗相关的排放量进行了估算:结果:如果首选 DPIs 而不是 pMDIs,吸入式药物的碳足迹有可能减少 85%。据估计,欧盟的 pMDIs 排放量为 4.0 兆吨二氧化碳当量(MT CO2e),如果改用 DPIs,则可减少到 0.6 兆吨二氧化碳当量(MT CO2e)。在使用干粉吸入器治疗中度哮喘的过程中,在单个吸入器中按需组合使用吸入皮质类固醇和长效β-受体激动剂的年度碳足迹(0.8 千克二氧化碳当量)大大低于仅使用吸入皮质类固醇和按需使用短效β-受体激动剂的传统维持疗法(2.9 千克二氧化碳当量):对于哮喘和慢性阻塞性肺病(COPD)患者来说,改用非推进剂吸入器可将其治疗的碳足迹减少近 20 倍。
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来源期刊
BMJ Open Respiratory Research
BMJ Open Respiratory Research RESPIRATORY SYSTEM-
CiteScore
6.60
自引率
2.40%
发文量
95
审稿时长
12 weeks
期刊介绍: BMJ Open Respiratory Research is a peer-reviewed, open access journal publishing respiratory and critical care medicine. It is the sister journal to Thorax and co-owned by the British Thoracic Society and BMJ. The journal focuses on robustness of methodology and scientific rigour with less emphasis on novelty or perceived impact. BMJ Open Respiratory Research operates a rapid review process, with continuous publication online, ensuring timely, up-to-date research is available worldwide. The journal publishes review articles and all research study types: Basic science including laboratory based experiments and animal models, Pilot studies or proof of concept, Observational studies, Study protocols, Registries, Clinical trials from phase I to multicentre randomised clinical trials, Systematic reviews and meta-analyses.
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