Single-dose pharmacokinetics and lung function of nebulized niclosamide ethanolamine in sheep
- Weiss, Anne, Bischof, Robert, Landersdorfer, Cornelia, Nguyen, Tri-Hung, Davies, Andrew, Ibrahim, Jibrill, Wynne, Paul, Wright, Phillip, Ditzinger, Gunter, Montgomery, Alan, Meeusen, Els, McIntosh, Michelle, Sommer, Morten
- Authors: Weiss, Anne , Bischof, Robert , Landersdorfer, Cornelia , Nguyen, Tri-Hung , Davies, Andrew , Ibrahim, Jibrill , Wynne, Paul , Wright, Phillip , Ditzinger, Gunter , Montgomery, Alan , Meeusen, Els , McIntosh, Michelle , Sommer, Morten
- Date: 2023
- Type: Text , Journal article
- Relation: Pharmaceutical Research Vol. 40, no. 8 (2023), p. 1915-1925
- Full Text:
- Reviewed:
- Description: Purpose: Niclosamide is approved as an oral anthelminthic, but its low oral bioavailability hinders its medical use requiring high drug exposure outside the gastrointestinal tract. An optimized solution of niclosamide for nebulization and intranasal administration using the ethanolamine salt has been developed and tested in a Phase 1 trial. In this study we investigate the pulmonary exposure of niclosamide following administration via intravenous injection, oral administration or nebulization. Methods: We characterized the plasma and pulmonary pharmacokinetics of three ascending doses of nebulized niclosamide in sheep, compare it to intravenous niclosamide for compartmental PK modelling, and to the human equivalent approved 2 g oral dose to investigate in the pulmonary exposure of different niclosamide delivery routes. Following a single-dose administration to five sheep, niclosamide concentrations were determined in plasma and epithelial lining fluid (ELF). Non-compartmental and compartmental modeling was used to characterize pharmacokinetic profiles. Lung function tests were performed in all dose groups. Results: Administration of all niclosamide doses were well tolerated with no adverse changes in lung function tests. Plasma pharmacokinetics of nebulized niclosamide behaved dose-linear and was described by a 3-compartmental model estimating an absolute bioavailability of 86%. ELF peak concentration and area under the curve was 578 times and 71 times higher with nebulization of niclosamide relative to administration of oral niclosamide. Conclusions: Single local pulmonary administration of niclosamide via nebulization was well tolerated in sheep and resulted in substantially higher peak ELF concentration compared to the human equivalent oral 2 g dose. © 2023, The Author(s).
- Authors: Weiss, Anne , Bischof, Robert , Landersdorfer, Cornelia , Nguyen, Tri-Hung , Davies, Andrew , Ibrahim, Jibrill , Wynne, Paul , Wright, Phillip , Ditzinger, Gunter , Montgomery, Alan , Meeusen, Els , McIntosh, Michelle , Sommer, Morten
- Date: 2023
- Type: Text , Journal article
- Relation: Pharmaceutical Research Vol. 40, no. 8 (2023), p. 1915-1925
- Full Text:
- Reviewed:
- Description: Purpose: Niclosamide is approved as an oral anthelminthic, but its low oral bioavailability hinders its medical use requiring high drug exposure outside the gastrointestinal tract. An optimized solution of niclosamide for nebulization and intranasal administration using the ethanolamine salt has been developed and tested in a Phase 1 trial. In this study we investigate the pulmonary exposure of niclosamide following administration via intravenous injection, oral administration or nebulization. Methods: We characterized the plasma and pulmonary pharmacokinetics of three ascending doses of nebulized niclosamide in sheep, compare it to intravenous niclosamide for compartmental PK modelling, and to the human equivalent approved 2 g oral dose to investigate in the pulmonary exposure of different niclosamide delivery routes. Following a single-dose administration to five sheep, niclosamide concentrations were determined in plasma and epithelial lining fluid (ELF). Non-compartmental and compartmental modeling was used to characterize pharmacokinetic profiles. Lung function tests were performed in all dose groups. Results: Administration of all niclosamide doses were well tolerated with no adverse changes in lung function tests. Plasma pharmacokinetics of nebulized niclosamide behaved dose-linear and was described by a 3-compartmental model estimating an absolute bioavailability of 86%. ELF peak concentration and area under the curve was 578 times and 71 times higher with nebulization of niclosamide relative to administration of oral niclosamide. Conclusions: Single local pulmonary administration of niclosamide via nebulization was well tolerated in sheep and resulted in substantially higher peak ELF concentration compared to the human equivalent oral 2 g dose. © 2023, The Author(s).
Effective pulmonary delivery of an aerosolized plasmid DNA vaccine via surface acoustic wave nebulization
- Rajapaksa, Anushi, Ho, Jenny, Qi, Aaisha, Bischof, Robert, Nguyen, Tri-Hung, Tate, Michelle, Piedrafita, David, McIntosh, Michelle, Yeo, Leslie, Meeusen, Els, Coppel, Ross, Friend, James
- Authors: Rajapaksa, Anushi , Ho, Jenny , Qi, Aaisha , Bischof, Robert , Nguyen, Tri-Hung , Tate, Michelle , Piedrafita, David , McIntosh, Michelle , Yeo, Leslie , Meeusen, Els , Coppel, Ross , Friend, James
- Date: 2014
- Type: Text , Journal article
- Relation: Respiratory Research Vol. 15, no. 1 (2014), p. 1-12
- Full Text:
- Reviewed:
- Description: Background: Pulmonary-delivered gene therapy promises to mitigate vaccine safety issues and reduce the need for needles and skilled personnel to use them. While plasmid DNA (pDNA) offers a rapid route to vaccine production without side effects or reliance on cold chain storage, its delivery to the lung has proved challenging. Conventional methods, including jet and ultrasonic nebulizers, fail to deliver large biomolecules like pDNA intact due to the shear and cavitational stresses present during nebulization.Methods: In vitro structural analysis followed by in vivo protein expression studies served in assessing the integrity of the pDNA subjected to surface acoustic wave (SAW) nebulisation. In vivo immunization trials were then carried out in rats using SAW nebulized pDNA (influenza A, human hemagglutinin H1N1) condensate delivered via intratracheal instillation. Finally, in vivo pulmonary vaccinations using pDNA for influenza was nebulized and delivered via a respirator to sheep.Results: The SAW nebulizer was effective at generating pDNA aerosols with sizes optimal for deep lung delivery. Successful gene expression was observed in mouse lung epithelial cells, when SAW-nebulized pDNA was delivered to male Swiss mice via intratracheal instillation. Effective systemic and mucosal antibody responses were found in rats via post-nebulized, condensed fluid instillation. Significantly, we demonstrated the suitability of the SAW nebulizer to administer unprotected pDNA encoding an influenza A virus surface glycoprotein to respirated sheep via aerosolized inhalation.Conclusion: Given the difficulty of inducing functional antibody responses for DNA vaccination in large animals, we report here the first instance of successful aerosolized inhalation delivery of a pDNA vaccine in a large animal model relevant to human lung development, structure, physiology, and disease, using a novel, low-power (<1 W) surface acoustic wave (SAW) hand-held nebulizer to produce droplets of pDNA with a size range suitable for delivery to the lower respiratory airways. © 2014 Rajapaksa et al.; licensee BioMed Central Ltd.
- Authors: Rajapaksa, Anushi , Ho, Jenny , Qi, Aaisha , Bischof, Robert , Nguyen, Tri-Hung , Tate, Michelle , Piedrafita, David , McIntosh, Michelle , Yeo, Leslie , Meeusen, Els , Coppel, Ross , Friend, James
- Date: 2014
- Type: Text , Journal article
- Relation: Respiratory Research Vol. 15, no. 1 (2014), p. 1-12
- Full Text:
- Reviewed:
- Description: Background: Pulmonary-delivered gene therapy promises to mitigate vaccine safety issues and reduce the need for needles and skilled personnel to use them. While plasmid DNA (pDNA) offers a rapid route to vaccine production without side effects or reliance on cold chain storage, its delivery to the lung has proved challenging. Conventional methods, including jet and ultrasonic nebulizers, fail to deliver large biomolecules like pDNA intact due to the shear and cavitational stresses present during nebulization.Methods: In vitro structural analysis followed by in vivo protein expression studies served in assessing the integrity of the pDNA subjected to surface acoustic wave (SAW) nebulisation. In vivo immunization trials were then carried out in rats using SAW nebulized pDNA (influenza A, human hemagglutinin H1N1) condensate delivered via intratracheal instillation. Finally, in vivo pulmonary vaccinations using pDNA for influenza was nebulized and delivered via a respirator to sheep.Results: The SAW nebulizer was effective at generating pDNA aerosols with sizes optimal for deep lung delivery. Successful gene expression was observed in mouse lung epithelial cells, when SAW-nebulized pDNA was delivered to male Swiss mice via intratracheal instillation. Effective systemic and mucosal antibody responses were found in rats via post-nebulized, condensed fluid instillation. Significantly, we demonstrated the suitability of the SAW nebulizer to administer unprotected pDNA encoding an influenza A virus surface glycoprotein to respirated sheep via aerosolized inhalation.Conclusion: Given the difficulty of inducing functional antibody responses for DNA vaccination in large animals, we report here the first instance of successful aerosolized inhalation delivery of a pDNA vaccine in a large animal model relevant to human lung development, structure, physiology, and disease, using a novel, low-power (<1 W) surface acoustic wave (SAW) hand-held nebulizer to produce droplets of pDNA with a size range suitable for delivery to the lower respiratory airways. © 2014 Rajapaksa et al.; licensee BioMed Central Ltd.
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