Improved antibacterial efficiency of inhaled thiamphenicol dry powders: Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Improved antibacterial efficiency of inhaled thiamphenicol dry powders : Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy. / Wang, Junwei; Grégoire, Nicolas; Marchand, Sandrine; Kutter, Jörg P.; Mu, Huiling; Moodley, Arshnee; Couet, William; Yang, Mingshi.

In: European Journal of Pharmaceutical Sciences, Vol. 152, 105435, 2020.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Wang, J, Grégoire, N, Marchand, S, Kutter, JP, Mu, H, Moodley, A, Couet, W & Yang, M 2020, 'Improved antibacterial efficiency of inhaled thiamphenicol dry powders: Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy', European Journal of Pharmaceutical Sciences, vol. 152, 105435. https://doi.org/10.1016/j.ejps.2020.105435

APA

Wang, J., Grégoire, N., Marchand, S., Kutter, J. P., Mu, H., Moodley, A., Couet, W., & Yang, M. (2020). Improved antibacterial efficiency of inhaled thiamphenicol dry powders: Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy. European Journal of Pharmaceutical Sciences, 152, [105435]. https://doi.org/10.1016/j.ejps.2020.105435

Vancouver

Wang J, Grégoire N, Marchand S, Kutter JP, Mu H, Moodley A et al. Improved antibacterial efficiency of inhaled thiamphenicol dry powders: Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy. European Journal of Pharmaceutical Sciences. 2020;152. 105435. https://doi.org/10.1016/j.ejps.2020.105435

Author

Wang, Junwei ; Grégoire, Nicolas ; Marchand, Sandrine ; Kutter, Jörg P. ; Mu, Huiling ; Moodley, Arshnee ; Couet, William ; Yang, Mingshi. / Improved antibacterial efficiency of inhaled thiamphenicol dry powders : Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy. In: European Journal of Pharmaceutical Sciences. 2020 ; Vol. 152.

Bibtex

@article{fa6d122f9c30454a94974170c0ad308b,
title = "Improved antibacterial efficiency of inhaled thiamphenicol dry powders: Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy",
abstract = "Thiamphenicol (TAP) is reported to be effective against many respiratory pathogens including methicillin-resistant Staphylococcus aureus (MRSA). However, its poor solubility in water remains as one of the obstacles hindering the preparation of inhalable TAP formulations. The aim of this study was to improve the dissolution rate of TAP by micronization, and investigate whether variations in the dissolution rates of TAP would affect its in vitro antibacterial activity. Inhalable dry powders composed of TAP microcrystals (MDP) or nanocrystals (NDP) were prepared by using a wet ball milling method followed by spray drying. The morphology, solid state and in vitro dissolution of these dry powders were characterized. In vitro antibacterial activities of the inhalable TAP dry powders against a MRSA strain were evaluated. A dissolution-efficacy model relating antibacterial activity with time and dissolution rate was established via modified time-kill assays. Upon being spray dried, the volumetric mean diameters of MDP and NDP were found to be around 5 µm. Solid state analyses showed that MDP and NDP possess the same crystalline form as the raw materials. NDP exhibited faster in vitro dissolution rate as compared to MDP. The in vitro antibacterial efficiency of NDP and MDP were superior to raw TAP when the test was performed at a TAP concentration of 32 mg/L. Simulated colony forming units predictions were consistent with the result measured in the time-kill experiments with Raw TAP, MDP and NDP. This study characterized the effect of the dissolution rate of TAP dry powders on in vitro antibacterial activity against MRSA, and an enhanced antibacterial activity of TAP was observed with an increase in the dissolution rate of TAP from the dry powders at certain concentration ranges.",
keywords = "Antibacterial activity, Dissolution rate, Inhaled dry powder, Mathematical modelling, Respiratory infection, Thiamphenicol",
author = "Junwei Wang and Nicolas Gr{\'e}goire and Sandrine Marchand and Kutter, {J{\"o}rg P.} and Huiling Mu and Arshnee Moodley and William Couet and Mingshi Yang",
year = "2020",
doi = "10.1016/j.ejps.2020.105435",
language = "English",
volume = "152",
journal = "Norvegica Pharmaceutica Acta",
issn = "0928-0987",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Improved antibacterial efficiency of inhaled thiamphenicol dry powders

T2 - Mathematical modelling of in vitro dissolution kinetic and in vitro antibacterial efficacy

AU - Wang, Junwei

AU - Grégoire, Nicolas

AU - Marchand, Sandrine

AU - Kutter, Jörg P.

AU - Mu, Huiling

AU - Moodley, Arshnee

AU - Couet, William

AU - Yang, Mingshi

PY - 2020

Y1 - 2020

N2 - Thiamphenicol (TAP) is reported to be effective against many respiratory pathogens including methicillin-resistant Staphylococcus aureus (MRSA). However, its poor solubility in water remains as one of the obstacles hindering the preparation of inhalable TAP formulations. The aim of this study was to improve the dissolution rate of TAP by micronization, and investigate whether variations in the dissolution rates of TAP would affect its in vitro antibacterial activity. Inhalable dry powders composed of TAP microcrystals (MDP) or nanocrystals (NDP) were prepared by using a wet ball milling method followed by spray drying. The morphology, solid state and in vitro dissolution of these dry powders were characterized. In vitro antibacterial activities of the inhalable TAP dry powders against a MRSA strain were evaluated. A dissolution-efficacy model relating antibacterial activity with time and dissolution rate was established via modified time-kill assays. Upon being spray dried, the volumetric mean diameters of MDP and NDP were found to be around 5 µm. Solid state analyses showed that MDP and NDP possess the same crystalline form as the raw materials. NDP exhibited faster in vitro dissolution rate as compared to MDP. The in vitro antibacterial efficiency of NDP and MDP were superior to raw TAP when the test was performed at a TAP concentration of 32 mg/L. Simulated colony forming units predictions were consistent with the result measured in the time-kill experiments with Raw TAP, MDP and NDP. This study characterized the effect of the dissolution rate of TAP dry powders on in vitro antibacterial activity against MRSA, and an enhanced antibacterial activity of TAP was observed with an increase in the dissolution rate of TAP from the dry powders at certain concentration ranges.

AB - Thiamphenicol (TAP) is reported to be effective against many respiratory pathogens including methicillin-resistant Staphylococcus aureus (MRSA). However, its poor solubility in water remains as one of the obstacles hindering the preparation of inhalable TAP formulations. The aim of this study was to improve the dissolution rate of TAP by micronization, and investigate whether variations in the dissolution rates of TAP would affect its in vitro antibacterial activity. Inhalable dry powders composed of TAP microcrystals (MDP) or nanocrystals (NDP) were prepared by using a wet ball milling method followed by spray drying. The morphology, solid state and in vitro dissolution of these dry powders were characterized. In vitro antibacterial activities of the inhalable TAP dry powders against a MRSA strain were evaluated. A dissolution-efficacy model relating antibacterial activity with time and dissolution rate was established via modified time-kill assays. Upon being spray dried, the volumetric mean diameters of MDP and NDP were found to be around 5 µm. Solid state analyses showed that MDP and NDP possess the same crystalline form as the raw materials. NDP exhibited faster in vitro dissolution rate as compared to MDP. The in vitro antibacterial efficiency of NDP and MDP were superior to raw TAP when the test was performed at a TAP concentration of 32 mg/L. Simulated colony forming units predictions were consistent with the result measured in the time-kill experiments with Raw TAP, MDP and NDP. This study characterized the effect of the dissolution rate of TAP dry powders on in vitro antibacterial activity against MRSA, and an enhanced antibacterial activity of TAP was observed with an increase in the dissolution rate of TAP from the dry powders at certain concentration ranges.

KW - Antibacterial activity

KW - Dissolution rate

KW - Inhaled dry powder

KW - Mathematical modelling

KW - Respiratory infection

KW - Thiamphenicol

U2 - 10.1016/j.ejps.2020.105435

DO - 10.1016/j.ejps.2020.105435

M3 - Journal article

C2 - 32590123

AN - SCOPUS:85087316947

VL - 152

JO - Norvegica Pharmaceutica Acta

JF - Norvegica Pharmaceutica Acta

SN - 0928-0987

M1 - 105435

ER -

ID: 244613784