Models and Approaches Describing the Metabolism, Transport, and Toxicity of Drugs Administered by the Ocular Route

Dumouchel, Jennifer L.; Chemuturi, Nagendra V.; Milton, Mark; Camenisch, Gian; Chastain, James E.; Walles, Markus; Sasseville, Vito G.; Gunduz, Mithat; Iyer, Ganesh; Argikar, Upendra A.

doi:10.1124/dmd.118.082974

Cited by 18 publications

(16 citation statements)

References 88 publications

(102 reference statements)

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“…In addition, due to the differences in anatomy and morphology of the eyes, they do not accurately mimic the human cornea (Agarwal and Rupenthal 2016). Research efforts have been directed toward developing 3D corneal models and more realistic equivalents to study wound healing, drug permeation, and availability (Toropainen et al 2001;Elliott and Yuan 2011;Dumouchel et al 2018;Kaluzhny et al 2018), as well as ocular toxicity (Curren and Harbell 2002;Elliott and Yuan 2011;Shafaie et al 2016). In contrast to in vivo and ex vivo models, in vitro cell-based models offer the advantage of being simple, less time consuming, and reproducible, while providing a mechanistic understanding of the results on the cellular and molecular level (Wilson et al 2015;Lotz et al 2016).…”

Section: Requirements For In Vitro Reconstructed 3d Corneal Tissue Modelsmentioning

confidence: 99%

“…In this view, many tumor or immortalized cell lines are not suitable to replace animal models since they lack these in vivo characteristics. Others argue that a single in vitro reconstructed corneal tissue model, no matter how complex, will not be able to correctly predict human toxicity and completely replace animal studies (Abdelkader et al 2015;Dumouchel et al 2018). This approach reasons that more specialized in vitro tissue models can be used to address specific toxicological mechanisms in a stepwise (tiered) approach with the ultimate goal of entirely replacing animal studies to predict human effects (Curren and Harbell 2002;.…”

Section: Requirements For In Vitro Reconstructed 3d Corneal Tissue Modelsmentioning

confidence: 99%

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In vitro reconstructed 3D corneal tissue models for ocular toxicology and ophthalmic drug development

Kaluzhny

Klausner

2021

In Vitro Cell.Dev.Biol.-Animal

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Testing of all manufactured products and their ingredients for eye irritation is a regulatory requirement. In the last two decades, the development of alternatives to the in vivo Draize eye irritation test method has substantially advanced due to the improvements in primary cell isolation, cell culture techniques, and media, which have led to improved in vitro corneal tissue models and test methods. Most in vitro models for ocular toxicology attempt to reproduce the corneal epithelial tissue which consists of 4-5 layers of non-keratinized corneal epithelial cells that form tight junctions, thereby limiting the penetration of chemicals, xenobiotics, and pharmaceuticals. Also, significant efforts have been directed toward the development of more complex threedimensional (3D) equivalents to study wound healing, drug permeation, and bioavailability. This review focuses on in vitro reconstructed 3D corneal tissue models and their utilization in ocular toxicology as well as their application to pharmacology and ophthalmic research. Current human 3D corneal epithelial cell culture models have replaced in vivo animal eye irritation tests for many applications, and substantial validation efforts are in progress to verify and approve alternative eye irritation tests for widespread use. The validation of drug absorption models and further development of models and test methods for many ophthalmic and ocular disease applications is required.

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Section: Requirements For In Vitro Reconstructed 3d Corneal Tissue Modelsmentioning

confidence: 99%

Section: Requirements For In Vitro Reconstructed 3d Corneal Tissue Modelsmentioning

confidence: 99%

In vitro reconstructed 3D corneal tissue models for ocular toxicology and ophthalmic drug development

Kaluzhny

Klausner

2021

In Vitro Cell.Dev.Biol.-Animal

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“…Extraction of each ocular tissue is not possible and these assays rely on homogenization of the whole eye. However, homogenization of the whole eye may dilute the metabolic enzymes and misrepresent the metabolism at the individual tissue (Dumouchel et al., 2018).…”

Section: In Vitro Assaysmentioning

confidence: 99%

“…While the lens will have no direct impact on PK, it will influence the volume of other ocular compartments that have been shown to impact PK, for example, the vitreous volume. The volume of the vitreous and subsequent compound elimination from this ocular compartment is often used to interpret ocular PK and define safety margins for systemically administered compounds (Del Amo et al., 2017; Vellonen et al., 2016), however, significant caution has been noted for the vitreous volumes noted in the literature (Dumouchel et al., 2018; Vellonen et al., 2016). The blood aqueous barrier may also contribute to the permeability of drugs out of the eye; however, the literature is often contradictory, making it difficult to define the impact on PK (Del Amo et al., 2017; Liu & Liu, 2019; Tournier et al., 2018).…”

Section: Introductionmentioning

confidence: 99%

Blood retinal barrier and ocular pharmacokinetics: Considerations for the development of oncology drugs

Williamson

Reddy

2021

Biopharm & Drug Disp

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Tyrosine kinase inhibitors (TKIs) are an example of targeted drug therapy to treat cancer while minimizing damage to healthy tissue. In contrast to traditional oncology drugs, the toxicity profile of targeted therapies is less well understood and can include severe ocular adverse events, which are among the most common toxicity reported by these therapeutics. Inhibition of Mer receptor tyrosine kinase (MERTK) promotes innate tumor immunity by decreasing M2‐macrophage polarization and efferocytosis. This mechanism offers the opportunity for targeted immunotherapy to treat cancer; however, the ocular expression of MERTK increases the difficulty for developing a targeted drug due to toxicity concerns. In this article we review the pharmacokinetic (PK) parameters and in vitro absorption, distribution, metabolism, and excretion (ADME) assays available to evaluate ocular disposition and assess the relationship between clinical PK and reported ocular events for TKIs to allow backtranslation to preclinical models. Understanding the ocular disposition in the context of PK and safety remains an evolving area and is likely to be a key aspect of developing safe and efficacious oncology drugs, devoid of ocular toxicity.

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“…In addition to permeability assessments, understanding the disposition, distribution, and toxicology of molecules across the corneal epithelium is of importance. In this issue, Dumouchel et al (2018) reviewed additional in vitro ocular models derived from primary systems to study the disposition and toxicity of small molecules. This mini-review discusses the advantages and disadvantages of ocular cell lines, ocular tissue homogenates and tissue sections, and ocular subcellular fractions, with the caveat that extensive pharmacokinetic data on human ocular disposition are not available.…”

Section: In Vitro Modelsmentioning

confidence: 99%

Emerging Models of Drug Metabolism, Transporters, and Toxicity

Sawant-Basak

Obach

2018

Drug Metab Dispos

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This commentary summarizes expert mini-reviews and original research articles that have been assembled in a special issue on novel models of drug metabolism and disposition. The special issue consists of research articles or reviews on novel static or microflow based models of the intestine, liver, eye, and kidney. This issue reviews static intestinal systems like mucosal scrapings and cryopreserved intestinal enterocytes, as well as novel bioengineered or chemically engineered intestinal models derived from primary human tissue, iPSCs, enteroids, and crypts. Experts have reviewed hepatic systems like cryopermeabilized Metmax hepatocytes and longer term, hepatocyte coculture system from HmREL, yielding in vivo-like primary and secondary drug metabolite profiles. Additional liver models, including micropattern hepatocyte coculture, 3D liver spheroids, and microflow systems, applicable to the study of drug disposition and toxicology have also been reviewed. In this commentary, we have outlined expert opinions and current efforts on hepaticand nephrotoxicity models. Ocular disposition models including corneal permeability models have been included within this special issue. This commentary provides a summary of in vivo mini-reviews of the issue, which have discussed the applications and drawbacks of pig and humanized mice models of P450, UGT, and rat organic anionic transporting polypeptide 1a4. While not extensively reviewed, novel positron emissions tomography imaging-based approaches to study the distribution of xenobiotics have been highlighted. This commentary also outlines in vitro and in vivo models of drug metabolism derived from breakthrough genetic, chromosomal, and tissue engineering techniques. The commentary concludes by providing a futuristic view of the novel models discussed in this issue.

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Models and Approaches Describing the Metabolism, Transport, and Toxicity of Drugs Administered by the Ocular Route

Cited by 18 publications

References 88 publications

In vitro reconstructed 3D corneal tissue models for ocular toxicology and ophthalmic drug development

In vitro reconstructed 3D corneal tissue models for ocular toxicology and ophthalmic drug development

Blood retinal barrier and ocular pharmacokinetics: Considerations for the development of oncology drugs

Emerging Models of Drug Metabolism, Transporters, and Toxicity

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