Identyfikatory
DOI
Warianty tytułu
Języki publikacji
Abstrakty
The purpose of this study was to examine the in vitro dehydration characteristics of new and worn conventional and silicone-hydrogel contact lenses. Four contact lens materials were investigated: three conventional hydrogels (etafilcon, nelfilcon, omafilcon) and one silicone-hydrogel (narafilcon). Gravimetric data were obtained with analytical balance with 1 min intervals. Quantitative parameters of water content and dehydration rate were calculated allowing quantitative description of dehydration process. Differential scanning calorimetry was used to monitor changes in water states in samples studied. As expected, dehydration behavior of each material is different in terms of mean dehydration rate values and phases of dehydration. Gravimetric data allowed us to distinguish three phases of dehydration. Interestingly, the effect of the osmolality of storing solutions on dehydration was found – lenses stored in hyperosmotic solutions needed more time to achieve equilibrium with the environment. Effect of wearing on dehydration patterns and water properties was confirmed. In worn samples, a decrease in water content was observed. Additionally, there was a change in water structure after 6 h of wearing in all lenses studied. This behavior may be ascribed to tear film components deposition and changes in surface wettability that appear during wearing.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
237--250
Opis fizyczny
Bibliogr. 34 poz., tab., wykr.
Twórcy
autor
- Division of Medical Physics, Division of Physics, Adam Mickiewicz University, Umultowska 85, 61-614 Poznań, Poland
autor
- Division of Medical Physics, Division of Physics, Adam Mickiewicz University, Umultowska 85, 61-614 Poznań, Poland
Bibliografia
- [1] MORGAN P.B., EFRON N., MORGAN S.L., LITTLE S.A., Hydrogel contact lens dehydration in controlled environmental conditions, Eye and Contact Lens 30(2), 2004, pp. 99–102.
- [2] TRANOUDIS I., EFRON N., Water properties of soft contact lens materials, Contact Lens and Anterior Eye 27(4), 2004, pp. 193–208.
- [3] RAMAMOORTHY P., SINNOTT L.T., NICHOLS J.J., Contact lens material characteristics associated with hydrogel lens dehydration, Ophthalmic and Physiological Optics 30(2), 2010, pp. 160–166.
- [4] JONES L., MAY C., NAZAR L., SIMPSON T., In vitro evaluation of the dehydration characteristics of silicone hydrogel and conventional hydrogel contact lens materials, Contact Lens and Anterior Eye 25(3), 2002, pp. 147–156.
- [5] PEPPAS N.A., HILT J.Z., KHADEMHOSSEINI A., LANGER R., Hydrogels in biology and medicine: from molecular principles to bionanotechnology, Advanced Materials 18(11), 2006, pp. 1345–1360.
- [6] NICHOLSON P.C., VOGT J., Soft contact lens polymers: an evolution, Biomaterials 22(24), 2001, pp. 3273–3283.
- [7] FRENCH K., Contact lens material properties. Part 3 – Oxygen performance, Optician 230, 2005, pp. 16–21.
- [8] FRENCH K., Contact lens material properties. Part 1 – Wettability, Optician 230, 2005, pp. 20–28.
- [9] MIREJOVSKY D., PATEL A.S., RODRIGUEZ D.D., Effect of proteins on water an transport properties of various hydrogel contact lens materials, Current Eye Research 10(3), 1991, pp. 187–196.
- [10] TRANOUDIS I., EFRON N., Parameter stability of soft contact lenses made from different materials, Contact Lens and Anterior Eye 27(3), 2004, pp. 115–131.
- [11] LUENSMANN D., JONES L., Albumin adsorption to contact lens materials: a review, Contact Lens and Anterior Eye 31(4), 2008, pp. 179–187.
- [12] MATHERS W., Evaporation from the ocular surface, Experimental Eye Research 78(3), 2004, pp. 389–394.
- [13] YOUNG G., Why one million contact lens wearers dropped out, Contact Lens and Anterior Eye 27(2), 2004, pp. 83–85.
- [14] YOUNG G., CHALMERS R.L., NAPIER L., HUNT C., KERN J., Characterizing contact lens-related dryness symptoms in a cross-section of UK soft lens wearers, Contact Lens and Anterior Eye 34(2), 2011, pp. 64–70.
- [15] RAMAMOORTHY P.A, SINNOT L.T., NICHOLS J.J., Treatment, material, care, and patient-related factors in contact lens-related dry eye, Optometry and Vision Science 85(8), 2008, pp. 764–772.
- [16] NICHOLS J.J., SINNOTT L.T., Tear film, contact lens, and patient-related factors associated with contact lens-related dry eye, Investigative Ophthalmology and Visual Science 47(4), 2006, pp. 1319–1328.
- [17] FONN D., SITU P., SIMPSON T., Hydrogel lens dehydration and subjective comfort and dryness ratings in symptomatic and asymptomatic contact lens wearers, Optometry and Vision Science 76(10), 1999, pp. 700–704.
- [18] LUM E., PERERA I., HO A., Osmolality and buffering agents in soft contact lens packaging solutions, Contact Lens and Anterior Eye 27(1), 2004, pp. 21–26.
- [19] GONZÁLEZ-MÉIJOME J.M., LÓPEZ-ALEMANY A., ALMEIDA, J.B., PARAFITA M.A., Dynamic in vitro dehydration patterns of unworn and worn silicone hydrogel contact lenses, Journal of Biomedical Materials Research Part B: Applied Biomaterials 90B(1), 2009, pp. 250–258.
- [20] ALEMANY A.L., REFOJO M.F., Comarative study of the hydration of hydrophilic contact lenses by refractive index and gravimetry, CLAO J 26(4), 2000, pp. 200–203.
- [21] KRYSZTOFIAK K., PŁUCISZ M., SZYCZEWSKI A., The influence of wearing on water states and dehydration of silicone-hydrogel contact lenses, Engineering of Biomaterials/Inżynieria Biomateriałów 15(115), 2012, pp. 18–25.
- [22] SEKINE Y., IKEDA-FUKAZAWA T., Structural changes of water in a hydrogel during dehydration, The Journal of Chemical Physics 130, 2009, art. no. 034501.
- [23] LIRA M., SANTOS L., AZEREDO J., YEBRA-PIMENTEL E., REAL OLIVEIRA M.E.C.D., The effect of lens wear on refractive index of conventional hydrogel and silicone-hydrogel contact lenses: a comparative study, Contact Lens and Anterior Eye 31(2), 2008, pp. 89–94.
- [24] MALDONADO-CODINA C., Soft lens materials, [In] EFRON N., Contact Lens Practice, Butterworth -Heineman, 2010, pp. 67–86.
- [25] WINTERTON L.C., LALLY J.M., SENTELL K.B., CHAPOY L.L., The elution of poly(vinyl alcohol) from a contact lens: the realization of a time release moisturizing agent/artificial tear, Journal of Biomedical Materials Research Part B: Applied Biomaterials 80B(2), 2007, pp. 424–432.
- [26] FORNASIERO F., KRULL F., RADKE C.J., PRAUSNITZ J.M., Diffusivity of water through a HEMA-based soft contact lens, Fluid Phase Equilibria 228–229, 2005, pp. 269–273.
- [27] TEICHROEB J.H., FORREST J.A., NGAI V., MARTIN J.W., JONES L., MEDLEY J., Imaging protein deposits on contact lens materials, Optometry and Vision Science 85(12), 2008, pp. 1151–1164.
- [28] BRENNAN N.A., COLES M.L.C., Deposits and symptomatology with soft contact lens wear, International Contact Lens Clinic 27(3), 2000, pp. 75–100.
- [29] CHALMERS R., LONG B., DILLEHAY S., BEGLEY C., Improving contact-lens related dryness symptoms with silicone hydrogel lenses, Optometry and Vision Science 85(8), 2008, pp. 778–784.
- [30] QUESNEL N.-M., GIASSON C.J., On-eye dehydration of proclear, resolution 55G and acuvue contact lenses, Contact Lens and Anterior Eye 24(3), 2001, pp. 88–93.
- [31] LEVER O.W., GROEMMINGER S.F., ALLEN M.E., BORNEMANN R.H., DEY D.R., BARNA B.J., Evaluation of the relationship between total lens protein deposition and patient-rated comfort of hydrophilic (soft) contact lenses, International Contact Lens Clinic 22(1–2), 1995, pp. 5–13.
- [32] STAHL U., WILCOX M.M., STAPLETON F., Role of hypo-osmotic saline drops in ocular comfort during contact lens wear, Contact Lens and Anterior Eye 33(2), 2010, pp. 68–75.
- [33] MURUBE J., Tear osmolarity, Ocular Surface 4(2), 2006, pp. 62–73.
- [34] HUGLIN M.B., REGOT J.M., Influence of a salt on some properties of hydrophilic methacrylate hydrogels, Macromolecules 24(9), 1991, pp. 2556–2563.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-816d0ffb-a890-4b91-8e30-27e393aa9420