Quantitative systems pharmacology of the eye: Tools and data for ocular QSP

Kuepfer, Lars; Fuellen, Georg; Stahnke, Thomas

doi:10.1002/psp4.12918

Cited by 9 publications

(5 citation statements)

References 102 publications

(206 reference statements)

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“…Interestingly, progress has been made in the development of PBPK and QSP models for ocular delivery, in part due to advancement in current understanding of ocular physiology and transport processes, that can be used to describe both systemic and ocular distribution of the drug. 75 A semimechanistic model was developed in rabbits to study ocular PK of various proteins administered IVT; the model was used to estimate half-life in retina, vitreous and aqueous humor in relation to protein size up to a hydrodynamic radius of 14 nm, which is the minimum radius for monomeric AAVs, and the authors suggested that the half-life in each compartment (retina, vitreous, and aqueous humor) could be geometrically scaled to humans. 76 Network systems biology is another promising technique that has been used to study ophthalmic indications for which gene therapy products are being developed; for example, networks of gene regulation have been constructed in glaucoma 9 and AMD, [77][78][79] providing insights into the mechanisms underlying these multifactorial diseases, as well as used to identify the most effective proteins for retinal regeneration.…”

Section: Modeling Efforts For Retina Gene Therapymentioning

confidence: 99%

“…76 Network systems biology is another promising technique that has been used to study ophthalmic indications for which gene therapy products are being developed; for example, networks of gene regulation have been constructed in glaucoma 9 and AMD, [77][78][79] providing insights into the mechanisms underlying these multifactorial diseases, as well as used to identify the most effective proteins for retinal regeneration. 78 Moreover, by coupling network systems biology models with complex QSP models, 75 one could study the drug effects on the downstream disease pathway.…”

Section: Modeling Efforts For Retina Gene Therapymentioning

confidence: 99%

“…One approach proposed previously 28 is the use of PK‐PD models of transgene protein levels coupled with more complex QSP models of AAV biodistribution, transcription, and translation to characterize the processes from administration of the vector dose in the ocular compartment to pharmacological effect or clinical efficacy. Interestingly, progress has been made in the development of PBPK and QSP models for ocular delivery, in part due to advancement in current understanding of ocular physiology and transport processes, that can be used to describe both systemic and ocular distribution of the drug 75 . A semimechanistic model was developed in rabbits to study ocular PK of various proteins administered IVT; the model was used to estimate half‐life in retina, vitreous and aqueous humor in relation to protein size up to a hydrodynamic radius of 14 nm, which is the minimum radius for monomeric AAVs, and the authors suggested that the half‐life in each compartment (retina, vitreous, and aqueous humor) could be geometrically scaled to humans 76 .…”

Section: Modeling Efforts For Retina Gene Therapymentioning

confidence: 99%

See 2 more Smart Citations

Clinical Pharmacology Perspective on Development of Adeno‐Associated Virus Vector‐Based Retina Gene Therapy

Ford,

Karatza,

Mody

et al. 2024

Clin Pharma and Therapeutics

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Adeno‐associated virus (AAV) vector‐based gene therapy is an innovative modality being increasingly investigated to treat diseases by modifying or replacing defective genes or expressing therapeutic entities. With its unique anatomic and physiological characteristics, the eye constitutes a very attractive target for gene therapy. Specifically, the ocular space is easily accessible and is generally considered “immune‐privileged” with a low risk of systemic side effects following local drug administration. As retina cells have limited cellular turnover, a one‐time gene delivery has the potential to provide long‐term transgene expression. Despite the initial success with voretigene neparvovec (Luxturna), the first approved retina gene therapy, there are still challenges to be overcome for successful clinical development of these products and scientific questions to be answered. The current review paper aims to integrate published experience learned thus far for AAV‐based retina gene therapy related to preclinical to clinical translation; first‐in‐human dose selection; relevant bioanalytical assays and strategies; clinical development considerations including trial design, biodistribution and vector shedding, immunogenicity, transgene expression, and pediatric populations; opportunities for model‐informed drug development; and regulatory perspectives. The information presented herein is intended to serve as a guide to inform the clinical development strategy for retina gene therapy with a focus on clinical pharmacology.

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Section: Modeling Efforts For Retina Gene Therapymentioning

confidence: 99%

Section: Modeling Efforts For Retina Gene Therapymentioning

confidence: 99%

Section: Modeling Efforts For Retina Gene Therapymentioning

confidence: 99%

See 1 more Smart Citation

Clinical Pharmacology Perspective on Development of Adeno‐Associated Virus Vector‐Based Retina Gene Therapy

Ford,

Karatza,

Mody

et al. 2024

Clin Pharma and Therapeutics

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“…Примером успешной диффузии являются липофильные препараты, способные пассивно проходить через эпителий роговицы, но затем задерживающиеся благодаря барьерным свойствам гидрофильной стромы. Монослой эндотелия роговицы выступает в качестве клеточного барьера между стромой и водянистой влагой и также может модулировать степень проникновения лекарственных препаратов [7,12]. Дальнейшее распределение препарата, преодолевшего роговицу, происходит в водянистой влаге.…”

Section: анатомические и физиологические барьеры снижающие биодоступн...unclassified

“…Многие местные лекарственные формы, содержащие НПВС, противоаллергические препараты, антибиотики, обладают в значительной степени гидрофильными свойствами, что ограничивает степень их проникновения в структуры глаза благодаря особенностям строения роговицы и конъюнктивы. Время местного воздействия препарата ограничивает оборот слезной пленки, что в итоге приводит к снижению концентрации действующего вещества в стекловидном теле и сетчатке [7].…”

Section: Introductionunclassified

Hypromellose in Ophthalmology

Butranova,

Zyryanov

2023

Oftalʹmologiâ

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Dosage forms for topical ocular administration are the basis of patient management in ophthalmology. The eye is a structure evolutionarily protected from the effects of xenobiotics by a number of physiological and anatomical barriers. The development of dosage forms, the targeted delivery into the eye structures is carried out due to the inclusion of special excipients, is aimed at improving the efficiency of managing patients with eye diseases. The action mechanisms of the most common groups of excipients used in ophthalmology underlie their effectiveness and safety, as well as create a basis for the various dosage forms development. Cellulose derivatives, due to their physicochemical and pharmacological characteristics, are one of the preferred groups for the development of topical dosage forms used in ophthalmology. Hypromellose (hydroxypropyl methylcellulose) is one of the most studied cellulose derivatives, which is characterized by a wide range of indications for both the active substance (artificial tear component) and the excipient. The favorable pharmacological properties of hypromellose (the ability to provide long-term exposure to effective concentrations of drugs used topically in ophthalmology, the ability to increase the degree of hydration of the cornea) contribute to the active study of this substance to assess the possibilities of its use in the development of new dosage forms (nanoparticles), as well as expanding the existing list of indications. This review is devoted to the analysis of clinical and experimental studies of the efficacy and safety of hypromellose.

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Quantitative systems pharmacology of the eye: Tools and data for ocular QSP

Kuepfer

Fuellen

Stahnke

2023

CPT Pharmacom & Syst Pharma

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Good eyesight belongs to the most‐valued attributes of health, and diseases of the eye are a significant healthcare burden. Case numbers are expected to further increase in the next decades due to an aging society. The development of drugs in ophthalmology, however, is difficult due to limited accessibility of the eye, in terms of drug administration and in terms of sampling of tissues for drug pharmacokinetics (PKs) and pharmacodynamics (PDs). Ocular quantitative systems pharmacology models provide the opportunity to describe the distribution of drugs in the eye as well as the resulting drug‐response in specific segments of the eye. In particular, ocular physiologically‐based PK (PBPK) models are necessary to describe drug concentration levels in different regions of the eye. Further, ocular effect models using molecular data from specific cellular systems are needed to develop dose–response correlations. We here describe the current status of PK/PBPK as well as PD models for the eyes and discuss cellular systems, data repositories, as well as animal models in ophthalmology. The application of the various concepts is highlighted for the development of new treatments for postoperative fibrosis after glaucoma surgery.

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Quantitative systems pharmacology of the eye: Tools and data for ocular QSP

Cited by 9 publications

References 102 publications

Clinical Pharmacology Perspective on Development of Adeno‐Associated Virus Vector‐Based Retina Gene Therapy

Clinical Pharmacology Perspective on Development of Adeno‐Associated Virus Vector‐Based Retina Gene Therapy

Hypromellose in Ophthalmology

Quantitative systems pharmacology of the eye: Tools and data for ocular QSP

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