A comprehensive screening platform for aerosolizable protein formulations for intranasal and pulmonary drug delivery

Röhm, Martina; Carle, Stefan; Maigler, Frank; Flamm, J; Kramer, Viktoria; Mavoungou, Chrystelle; Schmid, Otmar; Schindowski, Katharina

doi:10.1016/j.ijpharm.2017.09.027

Cited by 49 publications

(49 citation statements)

References 83 publications

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“…Airways epithelial cells cultured at the air-liquid interface reproduce a physiological respiratory epithelium and may be combined with a dose-controlled aerosol-cell exposure system (ALICE CLOUD) to evaluate transepithelial absorption of aerosolized protein therapeutic (Röhm et al, 2017). Additional applications with this delivery system may include the impact of inhaled biotherapeutics on airways epithelium integrity.…”

Section: Future Directions and Conclusionmentioning

confidence: 99%

Insights on animal models to investigate inhalation therapy: Relevance for biotherapeutics

Guillon

Sécher

Dailey

et al. 2018

International Journal of Pharmaceutics

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Acute and chronic respiratory diseases account for major causes of illness and deaths worldwide. Recent developments of biotherapeutics opened a new era in the treatment and management of patients with respiratory diseases. When considering the delivery of therapeutics, the inhaled route offers great promises with a direct, non-invasive access to the diseased organ and has already proven efficient for several molecules. To assist in the future development of inhaled biotherapeutics, experimental models are crucial to assess lung deposition, pharmacokinetics, pharmacodynamics and safety. This review describes the animal models used in pulmonary research for aerosol drug delivery, highlighting their advantages and limitations for inhaled biologics. Overall, non-clinical species must be selected with relevant scientific arguments while taking into account their complexities and interspecies differences, to help in the development of inhaled medicines and ensure their successful transposition in the clinics.

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Section: Future Directions and Conclusionmentioning

confidence: 99%

Insights on animal models to investigate inhalation therapy: Relevance for biotherapeutics

Guillon

Sécher

Dailey

et al. 2018

International Journal of Pharmaceutics

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“…Note that due to the imaged plane of the device (i.e., PET membrane), only deposited particles are identified (compared with those deposited on the PDMS side walls). Altogether, our in vitro exposure assays capture realistic aerosol transport determinants that still remain widely absent in more traditional PM instillations or direct spraying techniques (Blank et al, 2006;Lenz et al, 2014;Röhm et al, 2017) on plates and inserts. Furthermore, our airway-on-chips highlight for the first time that exposure assays can be configured to explore localized deposition effects, capturing for example deposition outcomes pertinent to regional lung lobes (e.g., upper versus lower lobes) that span broad orientation angles across the chest cavity (Sauret et al, 2002).…”

Section: Aerosol Inhalation Exposure Assaymentioning

confidence: 99%

“…Importantly, our in vitro inhalation assays deliver aerosols simultaneously across four airway-on-chips integrated within a larger conductive airway tree model to explore in situ-like aerosol deposition outcomes under physiological respiratory airflows and for various gravitational orientations. Given that current cytotoxicity assays are still widely based on either non-physiological liquid installations of PM suspensions (Hittinger et al, 2017) or alternatively direct spraying at an ALI (Blank et al, 2006;Lenz et al, 2014;Röhm et al, 2017), our airway-on-chip exposure setup is part of steadfast efforts (Artzy-schnirman et al, 2019a) leading toward a new generation of advanced in vitro lung toolkits for human inhalation toxicity assays.…”

Section: Introductionmentioning

confidence: 99%

In situ-Like Aerosol Inhalation Exposure for Cytotoxicity Assessment Using Airway-on-Chips Platforms

Elias-Kirma

Artzy‐Schnirman

Das

et al. 2020

Front. Bioeng. Biotechnol.

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Lung exposure to inhaled particulate matter (PM) is known to injure the airway epithelium via inflammation, a phenomenon linked to increased levels of global morbidity and mortality. To evaluate physiological outcomes following PM exposure and concurrently circumvent the use of animal experiments, in vitro approaches have typically relied on traditional assays with plates or well inserts. Yet, these manifest drawbacks including the inability to capture physiological inhalation conditions and aerosol deposition characteristics relative to in vivo human conditions. Here, we present a novel airway-onchip exposure platform that emulates the epithelium of human bronchial airways with critical cellular barrier functions at an air-liquid interface (ALI). As a proof-of-concept for in vitro lung cytotoxicity testing, we recapitulate a well-characterized cell apoptosis pathway, induced through exposure to 2 µm airborne particles coated with αVR1 antibody that leads to significant loss in cell viability across the recapitulated airway epithelium. Notably, our in vitro inhalation assays enable simultaneous aerosol exposure across multiple airway chips integrated within a larger bronchial airway tree model, under physiological respiratory airflow conditions. Our findings underscore in situ-like aerosol deposition outcomes where patterns depend on respiratory flows across the airway tree geometry and gravitational orientation, as corroborated by concurrent numerical simulations. Our airway-on-chips not only highlight the prospect of realistic in vitro exposure assays in recapitulating characteristic local in vivo deposition outcomes, such platforms open opportunities toward advanced in vitro exposure assays for preclinical cytotoxicity and drug screening applications.

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“…In comparison, chamber configurations can deliver a uniform density through larger membranes (diameter ≥24 mm), with a reduced reading variation (Srinivasan et al, 2015). Both excised mucosa and cell layers require an equilibrium time (∼30 min or 60 min (Röhm et al, 2017;Lungare et al, 2016;Wang et al, 2017;Li et al, 2006) before performing the permeation study, which then consists of taking aliquots from the basal compartment at regular intervals (Gonçalves et al, 2016). The deposition of a reproducible and uniform amount of drug on the tissue is thus crucial as it will directly influence the gradient concentration and could thus introduce variation in the permeability (Upadhyay et al, 2017).…”

Section: Assessment Of the Drug Permeationmentioning

confidence: 99%

How to characterize a nasal product. The state of the art of in vitro and ex vivo specific methods

Salade

Wauthoz

Goole

et al. 2019

International Journal of Pharmaceutics

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Nasal delivery offers many benefits over other conventional routes of delivery (e.g. oral or intravenous administration). Benefits include, among others, a fast onset of action, non-invasiveness and direct access to the central nervous system. The nasal cavity is not only limited to local application (e.g. rhinosinusitis) but can also provide direct access to other sites in the body (e.g. the central nervous system or systemic circulation). However, both the anatomy and the physiology of the nose impose their own limitations, such as a small volume for delivery or rapid mucociliary clearance. To meet nasal-specific criteria, the formulator has to complete a plethora of tests, in vitro and ex vivo, to assess the efficacy and tolerance of a new drug-delivery system. Moreover, depending on the desired therapeutic effect, the delivery of the drug should target a specific pathway that could potentially be achieved through a modified release of this drug. Therefore, this review focuses on specific techniques that should be performed when a nasal formulation is developed. The review covers both the tests recommended by regulatory agencies (e.g. the Food and Drug Administration) and other complementary experiments frequently performed in the field.

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A comprehensive screening platform for aerosolizable protein formulations for intranasal and pulmonary drug delivery

Cited by 49 publications

References 83 publications

Insights on animal models to investigate inhalation therapy: Relevance for biotherapeutics

Insights on animal models to investigate inhalation therapy: Relevance for biotherapeutics

In situ-Like Aerosol Inhalation Exposure for Cytotoxicity Assessment Using Airway-on-Chips Platforms

How to characterize a nasal product. The state of the art of in vitro and ex vivo specific methods

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