Ocular Delivery of Quercetin Using Microemulsion System: Design, Characterization, and Ex-vivo Transcorneal Permeation

Background: The goal of this research was to design and characterize quercetin microemulsions (MEs) to resolve water solubility issues related to quercetin and improve transcorneal permeation into the eye. Methods: MEs were prepared by the phase diagram method. Oily phase (oleic acid-Transcutol P), surfactant (Tween 80, Span 20), and co-surfactant (propylene glycol) were used to make a quercetin-loaded ME. The size of the droplets, their viscosity, pH, release, flux, and diffusivity were all measured. Results: Droplet diameters in ME samples ranged from 5.31 to 26.07 nanometers. The pH varied from 5.22 to 6.20, and the release test revealed that 98.06 percent of the medication was released during the first 24 hours. The flux and diffusivity coefficients of the ME-QU-8 formulation were 58.8 µg/cm2.h and 0.009 cm2/h, respectively, which were 8.8 and 17.9 times greater than the quercetin aqueous control (0.2 percent). The maximum percentage of drug permeated through rabbit cornea after five hours was 16.11%. Conclusions: It is concluded that ME containing quercetin could increase transcorneal permeation and that permeation could be altered by any change in the composition of the ME formulation. This effect might be caused by structural alterations in the cornea caused by ME components.

[1]  D. Fatouros,et al.  Ocular Co-Delivery of Timolol and Brimonidine from a Self-Assembling Peptide Hydrogel for the Treatment of Glaucoma: In Vitro and Ex Vivo Evaluation , 2020, Pharmaceuticals.

[2]  P. Siafaka,et al.  Novel Ocular Drug Delivery Systems: An Update on Microemulsions. , 2020, Journal of ocular pharmacology and therapeutics : the official journal of the Association for Ocular Pharmacology and Therapeutics.

[3]  Naida Omerović,et al.  Application of nanoparticles in ocular drug delivery systems , 2020, Health and Technology.

[4]  A. Salimi,et al.  Enhancement of Dermal Delivery of Finasteride Using Microemulsion Systems , 2019, Advanced pharmaceutical bulletin.

[5]  V. Khutoryanskiy,et al.  Penetration Enhancers in Ocular Drug Delivery , 2019, Pharmaceutics.

[6]  Paulami Pal,et al.  Novel drug delivery systems for ocular therapy: With special reference to liposomal ocular delivery , 2019, European journal of ophthalmology.

[7]  A. Salabat,et al.  Formulation, characterization, and in vitro/ex vivo evaluation of quercetin-loaded microemulsion for topical application , 2018, Pharmaceutical development and technology.

[8]  A. Salimi Preparation and Evaluation of Celecoxib Nanoemulsion for Ocular Drug Delivery , 2017 .

[9]  E. Moghimipour,et al.  Preparation and Microstructural Characterization of Griseofulvin Microemulsions Using Different Experimental Methods: SAXS and DSC , 2017, Advanced pharmaceutical bulletin.

[10]  R. Salehi,et al.  Novel Pentablock Copolymers as Thermosensitive Self-Assembling Micelles for Ocular Drug Delivery , 2017, Advanced pharmaceutical bulletin.

[11]  D. Karamichos,et al.  Quercetin and the ocular surface: What we know and where we are going , 2017, Experimental biology and medicine.

[12]  M. Panahi-Bazaz,et al.  A Novel Microemulsion System for Ocular Delivery of Azithromycin: Design, Characterization and Ex-Vivo Rabbit Corneal Permeability , 2017 .

[13]  H. Qi,et al.  Effects of Oleic Acid on the Corneal Permeability of Compounds and Evaluation of its Ocular Irritation of Rabbit Eyes , 2014, Current eye research.

[14]  F. Klamt,et al.  Flavonoids from Achyrocline satureioides: promising biomolecules for anticancer therapy , 2014 .

[15]  E. Moghimipour,et al.  Preparation and Characterization of Cyanocobalamin (Vit B12) Microemulsion Properties and Structure for Topical and Transdermal Application , 2013, Iranian journal of basic medical sciences.

[16]  Amitava Ghosh,et al.  Microemulsion: New Insights into the Ocular Drug Delivery , 2013, ISRN pharmaceutics.

[17]  Qigui Li,et al.  Formulation and Particle Size Reduction Improve Bioavailability of Poorly Water-Soluble Compounds with Antimalarial Activity , 2013, Malaria research and treatment.

[18]  M. Chakrapani,et al.  Preparation and Evaluation of Vancomycin Microemulsion for Ocular Drug Delivery , 2012 .

[19]  G. Russo,et al.  The flavonoid quercetin in disease prevention and therapy: facts and fancies. , 2012, Biochemical pharmacology.

[20]  Milan Stefek,et al.  Eye lens in aging and diabetes: effect of quercetin. , 2011, Rejuvenation research.

[21]  Jilong Li,et al.  Lipid nanoemulsions loaded with doxorubicin-oleic acid ionic complex: characterization, in vitro and in vivo studies. , 2011, Die Pharmazie.

[22]  R. Alany,et al.  Design and evaluation of controlled-release niosomes and discomes for naltrexone hydrochloride ocular delivery. , 2011, Journal of pharmaceutical sciences.

[23]  Yolanda Diebold,et al.  Applications of nanoparticles in ophthalmology , 2010, Progress in Retinal and Eye Research.

[24]  M. B. Pierre,et al.  Influence of oleic acid on the rheology and in vitro release of lumiracoxib from poloxamer gels. , 2010, Journal of pharmacy & pharmaceutical sciences : a publication of the Canadian Society for Pharmaceutical Sciences, Societe canadienne des sciences pharmaceutiques.

[25]  Rohit Ramesh Shah,et al.  Preparation and Evaluation of Aceclofenac Topical Microemulsion , 2010, Iranian journal of pharmaceutical research : IJPR.

[26]  E. Souto,et al.  Nanomedicines for ocular NSAIDs: safety on drug delivery. , 2009, Nanomedicine : nanotechnology, biology, and medicine.

[27]  Jie Shen,et al.  Mucoadhesive effect of thiolated PEG stearate and its modified NLC for ocular drug delivery. , 2009, Journal of controlled release : official journal of the Controlled Release Society.

[28]  H. Schipper,et al.  Oxidative stress in diseases of the human cornea. , 2008, Free radical biology & medicine.

[29]  S. Krishnakumar,et al.  Nanotechnology in ocular drug delivery. , 2008, Drug discovery today.

[30]  R. Notman,et al.  Interaction of oleic acid with dipalmitoylphosphatidylcholine (DPPC) bilayers simulated by molecular dynamics. , 2007, The journal of physical chemistry. B.

[31]  U. Pleyer,et al.  The human corneal endothelium: New insights into electrophysiology and ion channels , 2007, Progress in Retinal and Eye Research.

[32]  Mark R Prausnitz,et al.  Model of transient drug diffusion across cornea. , 2004, Journal of controlled release : official journal of the Controlled Release Society.

[33]  D. Rootman,et al.  Optisol vs Dexsol as storage media for preservation of human corneal epithelium , 2004, Eye.

[34]  T. Vandamme Microemulsions as ocular drug delivery systems: recent developments and future challenges , 2002, Progress in Retinal and Eye Research.

[35]  D. Monti,et al.  Increased corneal hydration induced by potential ocular penetration enhancers: assessment by differential scanning calorimetry (DSC) and by desiccation. , 2002, International journal of pharmaceutics.

[36]  I. Kaur,et al.  Penetration Enhancers and Ocular Bioadhesives: Two New Avenues for Ophthalmic Drug Delivery , 2002, Drug development and industrial pharmacy.

[37]  M. Lawrence,et al.  Microemulsion-based media as novel drug delivery systems , 2000 .

[38]  Nissim Garti,et al.  A DSC study of water behavior in water-in-oil microemulsions stabilized by sucrose esters and butanol , 2000 .

[39]  D. Lamson,et al.  Antioxidants and cancer, part 3: quercetin. , 2000, Alternative medicine review : a journal of clinical therapeutic.

[40]  D. Tang-Liu,et al.  Effects of four penetration enhancers on corneal permeability of drugs in vitro. , 1994, Journal of pharmaceutical sciences.

[41]  J. Tiffany,et al.  Tear film stability and tear surface tension. , 1989, Current eye research.

[42]  N. Rao,et al.  Pharmacologic modulation of acute ocular inflammation with quercetin. , 1989, Ophthalmic research.

[43]  K. Morisaki,et al.  Effects of Tween 80 and liposomes on the corneal permeability of anti-inflammatory steroids. , 1988, Journal of pharmacobio-dynamics.