A. Matturro, E. Zambelli, E. Cuoghi, D. Copelli, F. Usberti, A. Fioni, L. Labadini
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Moreover, proof of the hypothesis that products containing the current propellant and those using a LGWP propellant can achieve equivalent performance is reported, by showing comparability of a triple combination pMDI (Trimbow®) formulated using the LGWP HFA-152a propellant compared with HFA-134a. This paper will present the use of <i>in silico</i> mathematical modelling, leveraging on Chiesi proprietary Modulite® principles to predict and validate <i>in vitro</i> performances of the drug product under development. Validation is carried out using realistic aerodynamic particle size distribution (rAPSD), a novel approach that offers a more accurate prediction of aerosol distribution by incorporating variations compared to the standard aerodynamic particle size distribution (APSD). 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引用次数: 0
摘要
最近和新出现的环境政策推动了对对气候变化影响最小的加压计量吸入器(pMDI)的研究。目前正在从现有的氢氟碳化合物(HFC)基推进剂,特别是批准用于治疗哮喘和慢性阻塞性肺病(COPD)的氢氟烷烃(HFA)-134a和HFA-227ea基pMDI产品,转向使用低全球变暖潜值(LGWP)推进剂的产品。例如,将推进剂换成对环境破坏较小的HFA-152a,是许多制造商关注的焦点。本文报道了一种利用LGWP推进剂开发新型pMDI药物的创新方法。此外,通过显示与HFA-134a相比,使用LGWP HFA-152a推进剂配制的三重组合pMDI (Trimbow®)的可比性,报告了含有当前推进剂的产品和使用LGWP推进剂的产品可以达到同等性能的假设证明。本文将介绍利用Chiesi专有的Modulite®原理来预测和验证正在开发的药物的体外性能的计算机数学模型的使用。采用真实空气动力学粒径分布(rAPSD)进行验证,rAPSD是一种新颖的方法,通过结合与标准空气动力学粒径分布(APSD)相比的变化,可以更准确地预测气溶胶分布。此外,体外试验验证了硅模型的预测,并证实了HFA-152a和HFA-134a在空气动力学性能方面具有良好的可比性,动物模型的初步药代动力学(PK)和正式的临床PK生物等效性(BE)研究证明了这一点。(Rony et al. in Pulm Pharmacol Ther 85, 2024)。图形抽象
Innovative Drug Development Approach to Address the Transition to Low Global Warming Potential Propellant Using Hydrofluoroalkane-152a, for Triple Combination Pressurized Metered-Dose Inhaler Products Targeting Small Airways
Recent and emerging environmental policies have boosted the investigation of pressurized metered-dose inhalers (pMDI) that have a minimal impact on climate change. There is a current move away from existing hydrofluorocarbon (HFC)-based propellants, specifically the hydrofluoroalkane (HFA)-134a and HFA-227ea based pMDI products that are approved for the treatment of asthma and chronic obstructive pulmonary disease (COPD), towards those that use low global warming potential (LGWP) propellants. Changing the propellant to, for example, the less environmentally-damaging HFA-152a, is a focus for many manufacturers. In this paper, we report an innovative approach to developing new pMDI drug products with a LGWP propellant. Moreover, proof of the hypothesis that products containing the current propellant and those using a LGWP propellant can achieve equivalent performance is reported, by showing comparability of a triple combination pMDI (Trimbow®) formulated using the LGWP HFA-152a propellant compared with HFA-134a. This paper will present the use of in silico mathematical modelling, leveraging on Chiesi proprietary Modulite® principles to predict and validate in vitro performances of the drug product under development. Validation is carried out using realistic aerodynamic particle size distribution (rAPSD), a novel approach that offers a more accurate prediction of aerosol distribution by incorporating variations compared to the standard aerodynamic particle size distribution (APSD). Additional in vitro testing validates the prediction of in silico models and confirms good comparability in terms of aerodynamic performance between HFA-152a and HFA-134a, which translates in vivo as evidenced by the preliminary pharmacokinetics (PK) in animal models and the formal clinical PK bioequivalence (BE) studies. (Rony et al. in Pulm Pharmacol Ther 85, 2024).
期刊介绍:
AAPS PharmSciTech is a peer-reviewed, online-only journal committed to serving those pharmaceutical scientists and engineers interested in the research, development, and evaluation of pharmaceutical dosage forms and delivery systems, including drugs derived from biotechnology and the manufacturing science pertaining to the commercialization of such dosage forms. Because of its electronic nature, AAPS PharmSciTech aspires to utilize evolving electronic technology to enable faster and diverse mechanisms of information delivery to its readership. Submission of uninvited expert reviews and research articles are welcomed.
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