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Development of a Topical Ocular Drug Delivery System Using Polymeric Nanoparticles

Author: Shengyan Liu
Publisher:
ISBN:
Category : Drug delivery systems
Languages : en
Pages : 102

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Book Description
Common eye diseases such as dry eye syndrome affect 15% of the population. Although eye drops are the most common treatment for these diseases, over 95% of the drugs applied through eye drops are quickly cleared away due to blinking and tear turnover. Consequently, patients struggle with the multiple daily applications required and the resulting side effects. Nanoparticle (NP) drug carriers have gained significant traction recently because of several advantages they provide over conventional eye drop delivery methods. NP surfaces can be tuned to achieve specific properties such as binding affinity towards the ocular surface. NPs can also carry a large amount of drugs and release them in a sustained manner over a long period. Due to their small size, NPs do not cause abrasive sensations on the eye upon patient application. With these unique advantages, NP drug carriers may drastically improve patient compliance while reducing side effects. The thesis focuses on developing an ocular drug delivery platform using NPs to improve retention of ocular therapeutics on the precorneal surface. We developed a method to synthesize an amphiphilic block copolymer composed of poly(D,L-lactide) (PLA) and dextran (Dex) that can self-assemble into NP drug carriers. The size of the NPs can be tuned between 15 and 70 nm by adjusting the molecular weights of PLA and/or Dex. The PLA-b-Dex NPs form the foundation of the ocular drug delivery platform developed in this thesis. A targeted delivery system is crucial for ocular drug delivery due to the rapid clearance by tear drainage on the corneal surface. The PLA-b-Dex NPs were surface modified with phenylboronic acid (PBA) molecules, which can undergo covalent binding with the mucous membrane to circumvent the rapid clearance. Due to the abundance of functional groups on the dextran, we were able to tune the density of PBA on the NP surface to optimize the binding affinity between the NPs and the mucin. While maximizing the PBA density on the NP surface improved the covalent interaction between the NPs and the mucin, it also compromised the NP colloidal stability. The PBA modified NPs demonstrated encapsulation of Cyclosporine A (CsA), a dry eye treatment drug, and sustained release for up to 5 days in vitro, showing their potential as a long-term eye drop delivery platform. We then performed biocompatibility and efficacy studies on these NPs using animal models. Biocompatibility is of the utmost importance in developing new drug delivery formulations. During the 12 weeks of study, no physical signs of irritation or discomfort were detected nor was any inflammatory response or ocular tissue damage observed in the eyes administered with NPs. Topical administration of CsA-loaded NPs on dry eye induced mice using once a week dosing demonstrated complete elimination of the inflammatory response as well as full recovery of the integrity of the ocular tissues. In the same study, the commercial eye drop form of CsA, Restasis®, administered thrice daily only eliminated the inflammatory infiltrates without recovering ocular goblet cells. By delivering CsA through PLA-b-Dex-g-PBA NPs, we can significantly reduce the dose and the frequency of eye drop administration without compromising the treatment efficacy. In vitro mucoadhesion as a result of PBA's on NP surfaces was demonstrated. We proceeded to further demonstrate this mucoadhesion using in vivo models. Indocyanine green (ICG), a near-infrared fluorescent dye, was encapsulated in the NPs and administered to rabbit eyes to track its ocular retention. ICG delivered via PBA modified NPs showed ocular retention beyond 24 hours on rabbit eyes, whereas free ICG or ICG delivered via unmodified NPs were mostly cleared within the first 3 hours. When the weekly dosing of CsA loaded PLA-b-Dex-g-PBA NPs was repeated for 4 weeks on dry eye induced mice, we observed the same elimination of inflammatory infiltrates but also the damaged ocular tissue structures. When the concentration of the CsA in the weekly dosing of NPs was further reduced 5 times, the treatment effect was much more pronounced, showing both the elimination of the inflammation and the full recovery of the ocular surface tissues. Overall, by using mucoadhesive nanoparticle drug carriers, we reduced the dosage of CsA at least 50-fold compared with the commercial product, Restasis®, without compromising the dry eye treatment efficacy. Finally, we developed a scalable method to synthesize PLA-b-Dex-g-PBA block copolymers using a semi-solid state reaction chemistry. The previous method of conjugating PBA to the Dex required long reaction hours with multiple reaction and purification steps. In contrast, the new method combines the quickness of a semi-solid state reaction with the simplicity of a Williamson ether chemistry to graft PBA to Dex. The results showed that the new method achieved a similar range of tunability of PBA density onto Dex using reaction times as short as 10 minutes. This thesis demonstrates the development process of a polymeric NP as a topical ocular drug delivery system. The PLA-b-Dex-g-PBA NPs demonstrated delivery of a clinically relevant dosage of dry eye therapeutics, controlled release of therapeutics over prolonged period of time, and mucoadhesive properties resulting in prolonged ocular surface retention of drugs. These mucoadhesive NPs show remarkable promise as a long-term topical ocular drug delivery system that significantly reduces the dose and the administration frequency of the eye drops while minimizing side effects.

Development of a Topical Ocular Drug Delivery System Using Polymeric Nanoparticles

Author: Shengyan Liu
Publisher:
ISBN:
Category : Drug delivery systems
Languages : en
Pages : 102

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Update on Polymers for Ocular Drug Delivery

Author: Atish S Mundada
Publisher: Smithers Rapra
ISBN: 1847355641
Category : Medical
Languages : en
Pages : 210

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Book Description
The eye is the most easily accessible site for topical administration of a medication. Drugs are commonly applied to the eye for localised action on the surface or in the interior of the eye. A major problem in ocular therapeutics is the attainment of an optimal drug concentration at the site of action. Poor bioavailability of drugs from ocular dosage forms is mainly due to the precorneal loss factors which include tear dynamics, non-productive absorption, transient residence time in the cul-de-sac, and the relative impermeability of the corneal epithelial membrane. Due to these physiological and anatomical constraints only a small fraction of the drug, effectively 1% or even less of the instilled dose is ocularly absorbed. The effective dose of medication administered ophthalmically may be altered by increasing the retention time of medication in contact with the surface of the eye. To date, Pharmaceutical Technologists have tried to develop different novel formulations like gel, ocular inserts, collagen shields, implants, liposomes, nanoparticles, penetration enhancers and in-situ gelling systems, in order to increase the bioavailability and duration of the therapeutic action of ocular drugs and polymers plays an important role in all these approaches. This book provides detailed information regarding all such polymers which have been used and shown to be excellent in improving the bioavailability of ocular drugs.

Ocular Drug Delivery Systems

Author: Deepak Thassu
Publisher: CRC Press
ISBN: 1439848009
Category : Medical
Languages : en
Pages : 477

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Book Description
Drug discovery for ocular diseases has taken great strides in the last two decades. From cornea to choroid, new drugs have been formulated to address a great variety of ocular diseases. Yet without good drug delivery systems, these drugs are less effective than they might be or could even cause serious side effects. Ocular Drug Delivery Systems: Barriers and Application of Nanoparticulate Systems presents research on the development of currently marketed devices and recent trends in the topical delivery of drugs to the posterior of the eye. With contributions from leading pharmaceutical researchers and industry experts, eye researchers, surgeons, pharmacologists from academia, the National Eye Institute, and leading ophthalmic companies such as Pfizer, Allergan, and Novartis, the book presents the state of the art in the use of nanoparticles in ocular drug delivery systems and also sets the stage for future developments. This volume provides both a current evaluation and a future roadmap for developments in ocular drug delivery. The subjects range from biological needs to material challenges and finally to clinical applications for improving drug delivery for conditions where treatments already exist. It also explores areas where effective drugs may be currently available but yet need a safe, efficient, and efficacious delivery vehicle.

Ophthalmic Drug Delivery Systems

Author: Ashim K. Mitra
Publisher: CRC Press
ISBN: 9780367446765
Category :
Languages : en
Pages : 847

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Book Description
The second edition of this text assembles significant ophthalmic advances and encompasses breakthroughs in gene therapy, ocular microdialysis, vitreous drug disposition modelling, and receptor/transporter targeted drug delivery.

Nano-Biomaterials For Ophthalmic Drug Delivery

Author: Yashwant Pathak
Publisher: Springer
ISBN: 331929346X
Category : Medical
Languages : en
Pages : 631

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Book Description
This consolidated reference book addresses the various aspects of nano biomaterials used in ophthalmic drug delivery, including their characterization, interactions with ophthalmic system and applications in treatments of the ophthalmic diseases and disorders. In the last decade, a significant growth in polymer sciences, nanotechnology and biotechnology has resulted in the development of new nano- and bioengineered nano-bio-materials. These are extensively explored as drug delivery carriers as well as for implantable devices and scaffolds. At the interface between nanomaterials and biological systems, the organic and synthetic worlds merge into a new science concerned with the safe use of nanotechnology and nano material design for biological applications. For this field to evolve, there is a need to understand the dynamic forces and molecular components that shape these interactions. While it is impossible to describe with certainty all the bio physicochemical interactions at play at the interface, we are at a point where the pockets of assembled knowledge are providing a conceptual framework to guide this exploration, and review the impact on future product development. The book is intended as a valuable resource for academics and pharmaceutical scientists working in the field of polymers, polymers materials for drug delivery, drug delivery systems and ophthalmic drug delivery systems, in addition to medical and health care professionals in these areas.

Topical and Transdermal Drug Delivery Systems

Author: Nayan A. Gujarathi
Publisher: CRC Press
ISBN: 1000577643
Category : Medical
Languages : en
Pages : 353

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Book Description
Topical and transdermal drug delivery systems (TDDs) have several advantages over traditional drug delivery methods, as they can be less invasive, more sanitary, more cost-effective, and may result in better patient compliance. TDDs play a significant role in therapeutics with a variety of preparations and approaches designed by expert formulation scientists. This volume integrates a wide variety of case studies, research, and theories to reveal their diversity and capture the novel approaches of transdermal and topical drug delivery employed by developers and content experts in the field. It provides an abundance of important information and state-of-the-art research on topical and transdermal drug delivery systems and addresses the basics of drug delivery systems, strategies to enhance permeation across membranes, and formulation and evaluation of diverse dosage forms. The volume presents an evaluation of the pros and cons of conventional drug delivery systems against TDDs and discusses the nuances of micro- and nano-systems in TDDs. The extraordinary packages of nano systems (vesicular systems, polymeric nanoparticles, nanoemulsion and dendrimers) are broadly discussed, and their applications are reviewed through a transdermal route. The book looks at TDDs and the main nanoparticles used in skin diseases and lesions of the aging, such as psoriasis, vitiligo, cancer, lesions of the aging and others. Chapters also discuss polymeric micelles in topical and transdermal delivery; microneedles; emulsion, nanoemulsion and microemulsion; TDDs in pulmonary drug delivery systems; nanoencapsulated nasal drug delivery systems; skin sensitivity and irritation testing for transposing transdermal drug delivery systems; and regulatory aspects of drug development for dermal products. Topical and Transdermal Drug Delivery Systems: Applications and Prospects will be a valuable resource for pharmaceutical scientists and researchers, industry professionals, and academicians and students of the pharmaceutical and biomedical sciences.

Double Emulsion Mucoadhesive Nanoparticles for Hydrophilic Ocular Drug Delivery

Author: Noor El-Huda Bahsoun
Publisher:
ISBN:
Category :
Languages : en
Pages :

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Book Description
Common eye diseases such as conjunctivitis affect around 6 million people annually. Although eye drops are the most common treatment for these diseases, topical administration is limited by low ocular bioavailability due to lachrymal drainage, low drug permeability across the corneal epithelium, and low drug stability as a result of tear dilution and turnover. This results in over 95% of the drugs applied through eye drops to be quickly cleared away. Consequently, patients struggle with the multiple daily applications required and the resulting side effects. In order to overcome these barriers and to increase contact time of drugs on the surface of the eye, several nanoparticle (NP) technologies have been developed for the delivery of drugs to our systems like liposomes, hydrogels, microparticles, micelles, implants...etc. NP surfaces can be tuned to achieve specific properties such as binding affinity towards the ocular surface. NPs can also carry a large amount of drugs and release them in a sustained manner over a long period. Due to their small size, NPs do not cause abrasive sensations on the eye upon patient application. There is no one technology that is suitable for any drug to any site, however biodegradable colloidal systems appear to be the most advantageous. Their popularity stems from their biocompatibility with ocular tissues, high encapsulation efficiency, sustained release, and ability to degrade into non-toxic by-products that are safely cleared from ocular tissues. With these unique advantages, NP drug carriers may drastically improve patient compliance while reducing side effects. Research conducted in the Frank Gu Research Group suggests that NP drug carriers are capable of circumventing corneal clearance mechanisms by manipulating the surface functionalization of polymeric nanoparticles (NPs) such that they can interact with the ocular mucosa. In view of this background, this thesis was aimed at exploring the potential of mucoadhesive NPs (MNPs) to encapsulate hydrophilic drugs in the core of the NP, while maintaining mucoadhesive functionality in the shell of the NP. We developed a novel approach to formulate a double emulsion mucoadhesive nanoparticle (DE MNP) system to deliver hydrophilic molecules. Double emulsions allow us to generate a vesicle-like structure of hydrophilic interior and hydrophilic exterior and have been successful as nanoparticle drug carriers in the past. Most double emulsions utilize PLGA to make up the primary emulsion because it is a biodegradable and biocompatible polymer that has the ability to degrade into non-toxic by-products (lactic acid and glycolic acid) that are metabolized by the human body. The novelty in the DE MNP method involves using PLA-Dex-PBA in the outer emulsion, rather than common stabilizers such as PVA and Tween. The amphiphilic characteristics of PLA-Dex-PBA will arrange on the surface of PLGA emulsions with PLA facing the oil phase and Dex-PBA facing the exterior of the particle, making up the surface of DE MNPs. The PBA moieties on the surface of DE MNPs can covalently target the sialic acid moieties that are abundant on the ocular mucous membrane and avoid rapid clearance. DE MNPs form the foundation of the ocular drug delivery platform developed in this thesis, using fluorescein isothiocyanate dextran (FITC-Dex), a commercially used fluorescent dye, as the model drug to determine the capability of DE MNPs to encapsulate and release hydrophilic molecules. DE MNPs were first evaluated for size and morphology. They demonstrated sizes in the sub-200 nm range, nearly double the size of PLA-Dex-PBA MNP micelles. Their spherical shell/vesicle conformation was confirmed by static light scattering and TEM, and remained stable and unchanged with the addition of model FITC-Dex. DE MNPs demonstrated encapsulation of FITC-Dex up to 87 wt%, and sustained release for up to 7 days in vitro, showing their potential as a long-term eye drop delivery platform. In vitro mucoadhesion study as a proof of concept demonstration of PBA on DE MNPs' surfaces was demonstrated by studying the binding kinetics of PBA to sialic acid through the Stern-Volmer equation. The KA value for DE MNPs with sialic acid was determined to be 107.83 M-1, which is far higher than the literature values for PBA-SA. This gave confidence to the presence of PBA on the surface of DE MNPs. Next, we proceeded to attempt to demonstrate this mucoadhesion using in vivo models. FITC-Dex was encapsulated in the NPs and administered to rabbit eyes to track its ocular retention. FITC-Dex delivered DE MNPs showed ocular retention for no longer than 3 hours on rabbit eyes; this trend was also seen for free FITC-Dex. Povidone-Iodine (PVP-I), an inexpensive and commercially available drug commonly used to treat ocular bacterial infections, was encapsulated and evaluated for bactericidal activity upon release from DE MNPs. DE MNPs revealed that that encapsulation of the drug did not change the properties of the drug, and also confirmed that the amount of drug being encapsulated (1% w/v) in DE MNPs, is a sufficient concentration to elicit antimicrobial activity, and better than current formulations such as Betadine® which uses 5%w/v PVP-I for treatment of ocular infection. This thesis demonstrates the development process of DE MNPs as topical ocular drug delivery systems for hydrophilic drugs. DE MNPs demonstrated delivery of a clinically relevant dosage of PVP-I, controlled release of therapeutics over prolonged period of time, and mucoadhesive properties in vitro. These DE mucoadhesive NPs show significant promise as a long-term topical ocular hydrophilic drug delivery system that significantly reduces the dose and the administration frequency of the eye drops while minimizing side effects.

Applications of Polymers in Drug Delivery

Author: Ambikanandan Misra
Publisher: Smithers Rapra
ISBN: 1847358535
Category : Medical
Languages : en
Pages : 576

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Book Description
Use of polymers has become indispensable in the field of drug delivery. Polymers play a crucial role in modulating drug delivery to exploit maximum therapeutic benefits and have been fundamental in the successful development of several novel drug delivery systems that are now available. This book provides details of the applications of polymeric drug delivery systems that will be of interest to researchers in industries and academia. It describes the development of polymeric systems ranging from the conventional dosage forms up to the most recent smart systems. The regulatory and intellectual property aspects as well as the clinical applicability of polymeric drug delivery systems are also discussed.Each different drug delivery route is discussed in a separate chapter of the book. All major routes of drug delivery have been covered to provide the reader with a panoramic as well as an in-depth view of the developments in polymer-based drug delivery systems. Appendices are included which incorporate useful pharmaceutical properties of the polymers and important polymeric applications for various drug delivery routes.

Polymeric Drug Delivery Systems

Author: Glen S. Kwon
Publisher: CRC Press
ISBN: 9780824725327
Category : Medical
Languages : en
Pages : 680

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Book Description
Emphasizing four major classes of polymers for drug delivery-water-soluble polymers, hydrogels, biodegradable polymers, and polymer assemblies-this reference surveys efforts to adapt, modify, and tailor polymers for challenging molecules such as poorly water-soluble compounds, peptides/proteins, and plasmid DNA.

Drug Product Development for the Back of the Eye

Author: Uday B. Kompella
Publisher: Springer Science & Business Media
ISBN: 1441999205
Category : Medical
Languages : en
Pages : 596

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Book Description
This comprehensive volume discusses approaches for a systematic selection of delivery systems for various classes of therapeutic agents including small molecule, protein, and nucleic acid drugs. Specific topics covered in this book include: Solution, suspension, gel, nanoparticle, microparticle, and implant dosage forms Refillable and microneedle devices Intravitreal, suprachoroidal, intrascleral, transscleral, systemic, and topical routes of delivery Physical methods including iontophoresis for drug delivery Rational selection of routes of administration and delivery systems Noninvasive and continuous drug monitoring Regulatory path to drug product development Clinical endpoints for drug product development Emerging and existing drugs and drug targets Drug Product Development for the Back of the Eye is authored by renowned ocular drug delivery experts, representing academic, clinical, and industrial organizations and serves as indispensable resource for ophthalmic researchers, drug formulation scientists, drug delivery and drug disposition scientists, as well as clinicians involved in designing and developing novel therapeutics for the back of the eye diseases. This book is also relevant for students in various disciplines including ophthalmology, pharmaceutical sciences, drug delivery, and biomedical engineering. Refillable and microneedle devices Intravitreal, suprachoroidal, intrascleral, transscleral, systemic, and topical routes of delivery Physical methods including iontophoresis for drug delivery Rational selection of routes of administration and delivery systems Noninvasive and continuous drug monitoring Regulatory path to drug product development Clinical endpoints for drug product development Emerging and existing drugs and drug targets Drug Product Development for the Back of the Eye is authored by renowned ocular drug delivery experts, representing academic, clinical, and industrial organizations and serves as indispensable resource for ophthalmic researchers, drug formulation scientists, drug delivery and drug disposition scientists, as well as clinicians involved in designing and developing novel therapeutics for the back of the eye diseases. This book is also relevant for students in various disciplines including ophthalmology, pharmaceutical sciences, drug delivery, and biomedical engineering. Refillable and microneedle devices Intravitreal, suprachoroidal, intrascleral, transscleral, systemic, and topical routes of delivery Physical methods including iontophoresis for drug delivery Rational selection of routes of administration and delivery systems Noninvasive and continuous drug monitoring Regulatory path to drug product development Clinical endpoints for drug product development Emerging and existing drugs and drug targets Drug Product Development for the Back of the Eye is authored by renowned ocular drug delivery experts, representing academic, clinical, and industrial organizations and serves as indispensable resource for ophthalmic researchers, drug formulation scientists, drug delivery and drug disposition scientists, as well as clinicians involved in designing and developing novel therapeutics for the back of the eye diseases. This book is also relevant for students in various disciplines including ophthalmology, pharmaceutical sciences, drug delivery, and biomedical engineering.