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3. In vitro and ex vivo methods predict the enhanced lung residence time of liposomal ciprofloxacin formulations for nebulisation

Author

Ong, HX, Benaouda, F, Traini, D, Cipolla, D, Gonda, I, Bebawy, M, Forbes, B, and Young, PM

Subjects
Male, Time Factors, Nebulizers and Vaporizers, Chemistry, Pharmaceutical, Membranes, Artificial, Models, Biological, Cell Line, Rats, Anti-Bacterial Agents, Absorption, Perfusion, Ciprofloxacin, Predictive Value of Tests, Delayed-Action Preparations, Liposomes, Administration, Inhalation, Animals, Humans, Tissue Distribution, Pharmacology & Pharmacy, Rats, Wistar, Lung
Abstract

Liposomal ciprofloxacin formulations have been developed with the aim of enhancing lung residence time, thereby reducing the burden of inhaled antimicrobial therapy which requires multiple daily administration due to rapid absorptive clearance of antibiotics from the lungs. However, there is a lack of a predictive methodology available to assess controlled release inhalation delivery systems and their effect on drug disposition. In this study, three ciprofloxacin formulations were evaluated: a liposomal formulation, a solution formulation and a 1:1 combination of the two (mixture formulation). Different methodologies were utilised to study the release profiles of ciprofloxacin from these formulations: (i) membrane diffusion, (ii) air interface Calu-3 cells and (iii) isolated perfused rat lungs. The data from these models were compared to the performance of the formulations in vivo. The solution formulation provided the highest rate of absorptive transport followed by the mixture formulation, with the liposomal formulation providing substantially slower drug release. The rank order of drug release/transport from the different formulations was consistent across the in vitro andex vivo methods, and this was predictive of the profiles in vivo. The use of complimentary in vitro and ex vivo methodologies provided a robust analysis of formulation behaviour, including mechanistic insights, and predicted in vivo pharmacokinetics.© 2013 Elsevier B.V. All rights reserved.

Published
2013

5. In vitro and ex vivo methods predict the enhanced lung residence time of liposomal ciprofloxacin formulations for nebulisation

Author

Ong, HX, Benaouda, F, Traini, D, Cipolla, D, Gonda, I, Bebawy, M, Forbes, B, Young, PM, Ong, HX, Benaouda, F, Traini, D, Cipolla, D, Gonda, I, Bebawy, M, Forbes, B, and Young, PM

Abstract

Liposomal ciprofloxacin formulations have been developed with the aim of enhancing lung residence time, thereby reducing the burden of inhaled antimicrobial therapy which requires multiple daily administration due to rapid absorptive clearance of antibiotics from the lungs. However, there is a lack of a predictive methodology available to assess controlled release inhalation delivery systems and their effect on drug disposition. In this study, three ciprofloxacin formulations were evaluated: a liposomal formulation, a solution formulation and a 1:1 combination of the two (mixture formulation). Different methodologies were utilised to study the release profiles of ciprofloxacin from these formulations: (i) membrane diffusion, (ii) air interface Calu-3 cells and (iii) isolated perfused rat lungs. The data from these models were compared to the performance of the formulations in vivo. The solution formulation provided the highest rate of absorptive transport followed by the mixture formulation, with the liposomal formulation providing substantially slower drug release. The rank order of drug release/transport from the different formulations was consistent across the in vitro andex vivo methods, and this was predictive of the profiles in vivo. The use of complimentary in vitro and ex vivo methodologies provided a robust analysis of formulation behaviour, including mechanistic insights, and predicted in vivo pharmacokinetics.© 2013 Elsevier B.V. All rights reserved.

Published
2014

8. Localized Epidermal Drug Delivery Induced by Supramolecular Solvent Structuring

Author

Benaouda, F., Jones, S. A., Martin, G. P., and Brown, M. B.

Abstract

The preferential localization of drug molecules in the epidermis of human skin is considered advantageous for a number of agents, but achieving such a delivery profile can be problematic. The aim of the present study was to assess if the manipulation of solvent supramolecular structuring in the skin could be used to promote drug residence in the epidermal tissue. Skin deposition studies showed that a 175-fold increase in the epidermal loading of a model drug diclofenac (138.65 ± 11.67 μg·cm–2), compared to a control (0.81 ± 0.13 μg·cm–2), could be achieved by colocalizing the drug with a high concentration of propylene glycol (PG) in the tissue. For such a system at 1 h postdose application, the PG flux into the skin was 9.3 mg·cm2·h–1and the PG–water ratio in the epidermis was 76:24 (v/v). At this solvent ratio infrared spectroscopy indicated that PG rich supramolecular structures, which displayed a relatively strong physical affinity for the drug, were formed. Encouraging the production of the PG-rich supermolecular structures in the epidermis by applying diclofenac to the skin using a high PG loading dose (240 μg·cm–2) produced an epidermal–transdermal drug distribution of 6.8:1. However, generating water-rich solvent supermolecular structures in the epidermis by applying diclofenac using a low PG loading dose (2.2 μg·cm–2) led to a loss of preferential epidermal localization of diclofenac in the tissue (0.7:1 epidermal–transdermal drug distribution). This change in diclofenac skin deposition profile in response to PG variations and the accompanying FTIR data supported the notion that supramolecular solvent structures could control drug accumulation in the human epidermis.

Published
2016
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9. In-Silico Modelling of Transdermal Delivery of Macromolecule Drugs Assisted by a Skin Stretching Hypobaric Device.

Author

Sebastia-Saez D, Benaouda F, Lim CH, Lian G, Jones SA, Cui L, and Chen T

Subjects
Pharmaceutical Preparations, Administration, Cutaneous, Epidermis, Dextrans, Skin
Abstract

Objectives: To develop a simulation model to explore the interplay between mechanical stretch and diffusion of large molecules into the skin under locally applied hypobaric pressure, a novel penetration enhancement method., Methods: Finite element method was used to model the skin mechanical deformation and molecular diffusion processes, with validation against in-vitro transdermal permeation experiments. Simulations and experimental data were used together to investigate the transdermal permeation of large molecules under local hypobaric pressure., Results: Mechanical simulations resulted in skin stretching and thinning (20%-26% hair follicle diameter increase, and 21%-27% skin thickness reduction). Concentration of dextrans in the stratum corneum was below detection limit with and without hypobaric pressure. Concentrations in viable epidermis and dermis were not affected by hypobaric pressure (approximately 2 μg [Formula: see text] cm -2 ). Permeation into the receptor fluid was substantially enhanced from below the detection limit at atmospheric pressure to up to 6 μg [Formula: see text] cm -2 under hypobaric pressure. The in-silico simulations compared satisfactorily with the experimental results at atmospheric conditions. Under hypobaric pressure, satisfactory comparison was attained when the diffusion coefficients of dextrans in the skin layers were increased from [Formula: see text] 10 μm 2 [Formula: see text] s -1 to between 200-500 μm 2 [Formula: see text] s -1 ., Conclusions: Application of hypobaric pressure induces skin mechanical stretching and enlarges the hair follicle. This enlargement alone cannot satisfactorily explain the increased transdermal permeation into the receptor fluid under hypobaric pressure. The results from the in-silico simulations suggest that the application of hypobaric pressure increases diffusion in the skin, which leads to improved overall transdermal permeation., (© 2022. The Author(s).)

Published
2023
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10. Needleless administration of advanced therapies into the skin via the appendages using a hypobaric patch.

Author

Benaouda F, Inacio R, Lim CH, Park H, Pitcher T, Alhnan MA, Aly MMS, Al-Jamal KT, Chan KL, Gala RP, Sebastia-Saez D, Cui L, Chen T, Keeble J, and Jones SA

Subjects
Administration, Cutaneous, Animals, Mice, Needles, Rats, Skin Absorption, Swine, Skin metabolism, Vaccines
Abstract

Advanced therapies are commonly administered via injection even when they act within the skin tissue, and this increases the chances of off-target effects. Here we report the use of a skin patch containing a hypobaric chamber that induces skin dome formation to enable needleless delivery of advanced therapies directly into porcine, rat, and mouse skin. Finite element method modeling showed that the hypobaric chamber in the patch opened the skin appendages by 32%, thinned the skin, and compressed the appendage wall epithelia. These changes allowed direct delivery of an H1N1 vaccine antigen and a diclofenac nanotherapeutic into the skin. Fluorescence imaging and infrared mapping of the skin showed needleless delivery via the appendages. The in vivo utility of the patch was demonstrated by a superior immunoglobulin G response to the vaccine antigen in mice compared to intramuscular injection and a 70% reduction in rat paw swelling in vivo over 5 h with diclofenac without skin histology changes.

Published
2022
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11. Numerical analysis of the strain distribution in skin domes formed upon the application of hypobaric pressure.

Author

Sebastia-Saez D, Benaouda F, Lim CH, Lian G, Jones S, Chen T, and Cui L

Subjects
Biomechanical Phenomena, Elasticity, Finite Element Analysis, Pressure, Stress, Mechanical, Skin
Abstract

Background: Suction cups are widely used in applications such as in measurement of mechanical properties of skin in vivo, in drug delivery devices or in acupuncture treatment. Understanding mechanical response of skin under hypobaric pressure is of great importance for users of suction cups. The aim of this work is to predict the hypobaric pressure induced 3D stretching of the skin., Methods: Experimental skin tensile tests were carried out for mechanical property characterization. Both linear elasticity and hyperelasticity parameters were determined and implemented in Finite Element modelling. Skin suction tests were performed in both experiments and FEM simulations for model validation. 3D skin stretching is then visualized in detail in FEM simulations., Results: The simulations showed that the skin was compressed consistently along the thickness direction, leading to reduced thickness. At the center of the dome, the radial and angular strain decreases from the top surface to the bottom surface, although always in tension. Hyperelasticity modelling showed superiority over linear elasticity modelling while predicting the strain distribution because the stretch ratio reaches values exceeding the initial linear elastic stage of the stress-strain curve for skin., Conclusion: Hyperelasticity modelling is an effective approach to predict the 3D strain distribution, which paves a way to accurately design safe commercial products that interface with the skin., (© 2021 The Authors. Skin Research and Technology published by John Wiley & Sons Ltd.)

Published
2021
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12. A Cyclodextrin-Stabilized Spermine-Tagged Drug Triplex that Targets Theophylline to the Lungs Selectively in Respiratory Emergency.

Author

Sofian ZM, Benaouda F, Wang JT, Lu Y, Barlow DJ, Royall PG, Farag DB, Rahman KM, Al-Jamal KT, Forbes B, and Jones SA

Abstract

Ion-pairing a lifesaving drug such as theophylline with a targeting moiety could have a significant impact on medical emergencies such as status asthmaticus or COVID-19 induced pneumomediastinum. However, to achieve rapid drug targeting in vivo the ion-pair must be protected against breakdown before the entry into the target tissue. This study aims to investigate if inserting theophylline, when ion-paired to the polyamine transporter substrate spermine, into a cyclodextrin (CD), to form a triplex, could direct the bronchodilator to the lungs selectively after intravenous administration. NMR demonstrates that upon the formation of the triplex spermine protruded from the CD cavity and this results in energy-dependent uptake in A549 cells (1.8-fold enhancement), which persists for more than 20 min. In vivo, the triplex produces a 2.4-fold and 2.2-fold increase in theophylline in the lungs 20 min after injection in rats and mice, respectively ( p < 0.05). The lung targeting is selective with no increase in uptake into the brain or the heart where the side-effects of theophylline are treatment-limiting. Selectively doubling the concentration of theophylline in the lungs could improve the benefit-risk ratio of this narrow therapeutic index medicine, which continues to be important in critical care., Competing Interests: The authors declare no conflict of interest., (© 2020 The Authors. Published by Wiley‐VCH GmbH.)

Published
2020
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13. Ion-Pairing with Spermine Targets Theophylline To the Lungs via the Polyamine Transport System.

Author

Benaouda F, Jones SA, Chana J, Dal Corno BM, Barlow DJ, Hider RC, Page CP, and Forbes B

Subjects
A549 Cells, Animals, Bronchodilator Agents pharmacokinetics, Humans, Hydrogen-Ion Concentration, Ions chemistry, Male, Polyamines metabolism, Rats, Rats, Wistar, Spermine chemistry, Spermine metabolism, Theophylline pharmacokinetics, Tissue Distribution, Bronchodilator Agents administration & dosage, Cation Transport Proteins metabolism, Drug Delivery Systems methods, Lung metabolism, Theophylline administration & dosage
Abstract

Certain xenobiotics, such as paraquat, are sequestered into the lungs from the systemic circulation by the polyamine transporter system (PTS). The aim of this study was to investigate whether ion-pairing a drug (theophylline) with a PTS substrate (spermine) provides a means of using this active transport mechanism to target drug delivery to the lungs. Fourier transform infrared spectroscopy showed that two of the amine groups of spermine interact with C-N 7 and C 6 ═O of theophylline, leaving two free amines to interact with the PTS. In A549 cells, which possess a functional PTS (spermidine K m and V max , 0.6 ± 0.3 μM and 1.8 ± 0.3 pmol·min -1 per 10 5 cells, respectively), uptake of the theophylline-spermine ion-pair was increased 1.8-fold compared to free theophylline at 37 °C, but not at 4 °C. In an isolated perfused rat lung model (IPL) a 3.6-fold increase in lung theophylline concentration was observed after vascular administration of the ion-pair compared to free theophylline. Theophylline was cleared from the IPL with similar kinetics irrespective of whether it was delivered as the free drug or an ion-pair, although lung levels remained elevated after washout following delivery as an ion-pair. In vitro simulation of the theophylline-spermine break down demonstrated that a drop in pH from 9.6 to 7.4, such as that undergone by the ion-pair in biological matrices, induces rapid and almost complete dissociation of the ion-paired species. However, infusion of the ion-pair formulations via the vasculature provides almost immediate delivery to the pulmonary capillary bed permitting PTS-mediated active sequestering of ion-paired theophylline into the lungs.

Published
2018
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14. In vitro and ex vivo methods predict the enhanced lung residence time of liposomal ciprofloxacin formulations for nebulisation.

Author

Ong HX, Benaouda F, Traini D, Cipolla D, Gonda I, Bebawy M, Forbes B, and Young PM

Subjects
Absorption, Administration, Inhalation, Animals, Anti-Bacterial Agents chemistry, Cell Line, Chemistry, Pharmaceutical, Ciprofloxacin chemistry, Delayed-Action Preparations, Humans, Liposomes, Male, Membranes, Artificial, Models, Biological, Nebulizers and Vaporizers, Perfusion, Predictive Value of Tests, Rats, Rats, Wistar, Time Factors, Tissue Distribution, Anti-Bacterial Agents administration & dosage, Anti-Bacterial Agents pharmacokinetics, Ciprofloxacin administration & dosage, Ciprofloxacin pharmacokinetics, Lung metabolism
Abstract

Liposomal ciprofloxacin formulations have been developed with the aim of enhancing lung residence time, thereby reducing the burden of inhaled antimicrobial therapy which requires multiple daily administration due to rapid absorptive clearance of antibiotics from the lungs. However, there is a lack of a predictive methodology available to assess controlled release inhalation delivery systems and their effect on drug disposition. In this study, three ciprofloxacin formulations were evaluated: a liposomal formulation, a solution formulation and a 1:1 combination of the two (mixture formulation). Different methodologies were utilised to study the release profiles of ciprofloxacin from these formulations: (i) membrane diffusion, (ii) air interface Calu-3 cells and (iii) isolated perfused rat lungs. The data from these models were compared to the performance of the formulations in vivo. The solution formulation provided the highest rate of absorptive transport followed by the mixture formulation, with the liposomal formulation providing substantially slower drug release. The rank order of drug release/transport from the different formulations was consistent across the in vitro and ex vivo methods, and this was predictive of the profiles in vivo. The use of complimentary in vitro and ex vivo methodologies provided a robust analysis of formulation behaviour, including mechanistic insights, and predicted in vivo pharmacokinetics., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published
2014
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15. Topical corticosteroid delivery into human skin using hydrofluoroalkane metered dose aerosol sprays.

Author

Reid ML, Benaouda F, Khengar R, Jones SA, and Brown MB

Subjects
Administration, Topical, Aerosols, Beclomethasone chemistry, Betamethasone Valerate chemistry, Ethanol chemistry, Glucocorticoids chemistry, Humans, In Vitro Techniques, Metered Dose Inhalers, Myristates chemistry, Polyethylene Glycols chemistry, Polyvinyls chemistry, Pyrrolidines chemistry, Solvents chemistry, Aerosol Propellants administration & dosage, Beclomethasone administration & dosage, Betamethasone Valerate administration & dosage, Glucocorticoids administration & dosage, Hydrocarbons, Fluorinated administration & dosage, Skin metabolism
Abstract

Drug loaded hydrofluoroalkane (HFA) sprays can generate effective pharmaceutical formulations, but a deeper understanding of the manner in which these dynamic systems drive the process of in situ semi-solid dosage form assembly is required. The aim of this study was to investigate the effect of the matrix assembly and composition on drug localisation in human skin. Comparing the characteristics of sprays constituting HFA 134a, ethanol (EtOH), poly(vinyl pyrrolidone) K90, isopropyl myristate (IPM), and poly(ethylene glycol) (PEG) demonstrated that the addition of non-volatile solvents acted to delay EtOH evaporation, control the degree of drug saturation (DS) and enhance the corticosteroid delivery from HFA spray formulations. In a dose matched skin penetration study the HFA sprays containing only EtOH as a co-solvent delivered 2.1 μg BMV (DS 13.5) into the tissue, adding IPM to the EtOH HFA delivered 4.03 μg BMV (DS 11.2), whist adding PEG to the EtOH HFA delivered 6.1 μg BMV (DS 0.3). Compared to commercial cream (delivering 0.91 μg BMV) the EtOH/PEG HFA spray deposited over 6 times (p<0.05) more drug into the skin. Post spray deposition characterisation of the semi-solid suggested that the superior performance of the EtOH/PEG HFA spray was a consequence of retarding EtOH evaporation and presenting the drug in an EtOH rich PEG residual phase, which promoted BMV passage through the SC and into epidermis., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published
2013
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