Pharmacokinetic considerations for optimizing inhaled spray-dried pyrazinoic acid formulations
Author:
Yeshwante Shekhar B.,Hanafin Patrick,Miller Brittany K.,Rank Laura,Murcia Sebastian,Xander Christian,Annis Ayano,Baxter Victoria K.,Anderson Elizabeth J.,Jermain Brian,Konicki Robyn,Schmalstig Alan A.,Stewart Ian,Braunstein Miriam,Hickey Anthony J.,Rao Gauri G.
Abstract
ABSTRACTTuberculosis (TB), caused byMycobacterium tuberculosis(Mtb), remains a leading cause of death with 1.6 million deaths worldwide reported in 2021. Oral pyrazinamide (PZA) is an integral part of anti-TB regimens, but its prolonged use has the potential to drive development of PZA resistantMtb. PZA is converted to the active moiety pyrazinoic acid (POA) by theMtbpyrazinamidase encoded bypncA, and mutations inpncAare associated with the majority of PZA resistance. Conventional oral and parenteral therapies may result in subtherapeutic exposure in the lung, hence direct pulmonary administration of POA may provide an approach to rescue PZA efficacy for treatingpncA-mutant PZA-resistantMtb.The objectives of the current study were to i) develop novel dry powder POA formulations ii) assess their feasibility for pulmonary delivery using physicochemical characterization, iii) evaluate their pharmacokinetics (PK) in the guinea pig model and iv) develop a mechanism based pharmacokinetic model (MBM) usingin vivoPK data to select a formulation providing adequate exposure in epithelial lining fluid (ELF) and lung tissue.We developed three POA formulations for pulmonary delivery and characterized their PK in plasma, ELF, and lung tissue following passive inhalation in guinea pigs. Additionally, the PK of POA following oral, intravenous and intratracheal administration was characterized in guinea pigs. The MBM was used to simultaneously model PK data following administration of POA and its formulations via the different routes. The MBM described POA PK well in plasma, ELF and lung tissue.Physicochemical analyses and MBM predictions suggested that POA maltodextrin was the best among the three formulations and an excellent candidate for further development as it has: (i) the highest ELF-to-plasma exposure ratio (203) and lung tissue-to-plasma exposure ratio (30.4) compared with POA maltodextrin and leucine (75.7/16.2) and POA leucine salt (64.2/19.3); (ii) the highest concentration in ELF (CmacELF: 171 nM) within 15.5 minutes, correlating with a fast transfer into ELF after pulmonary administration (kPM: 22.6 1/h).The data from the guinea pig allowed scaling, using the MBM to a human dose of POA maltodextrin powder demonstrating the potential feasibility of an inhaled product.Table of Contents (TOC)/Abstract Graphic
Publisher
Cold Spring Harbor Laboratory
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