Characterization of Nanomaterial-Based Contact Lenses by Atomic Force Microscopy

Mileusnić, Ivana; Đuričić, Ivan; Hut, Igor; Stamenković, Dragoslav; Петров, Л. М.; Bojović, Božica; Koruga, Dj.

doi:10.7251/comen1202177m

Cited by 4 publications

(4 citation statements)

References 2 publications

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“…Therefore, fractal dimension, as numerical representation of surface roughness, could be used for contact lenses comparison. We already used the result of comparison as feedback for machining process optimization [1], for contact lens wear-out diagnostics [5] and for ongoing investigation that considers new "nanophotonic" material for gas permeable contact lenses [6].…”

Section: Resultsmentioning

confidence: 99%

Effects of Image Size and Sample Areas on Comparison of Contact Lens Surfaces Based on Fractal Dimension

Bojović

2013

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Methods used for calculation of fractal dimension demand large image resolution and adequate sample size, in terms of roughness threshold that defines spatial scope for rough surface fractal properties. Imaging device operators, on the one hand, recommend the image size and sample area based on experience and expertise, in order to minimize the imaging time. On the other hand, engineers make decisions based on their own requirements. To overcome these problems, in this paper we used ANOVA statistical approach (one-way and multi comparison) so as to establish significant image size and sample area. The conclusion made in this paper will enable decision guidelines on selection of parameters for new nanophotonic lenses imaging by scanning microscopes in near future.

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Section: Resultsmentioning

confidence: 99%

Effects of Image Size and Sample Areas on Comparison of Contact Lens Surfaces Based on Fractal Dimension

Bojović

2013

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“…The AFM has proven to be a great asset for characterization of surface properties of various materials. It has been widely used even to measure different aspects of contact lenses, such as surface roughness [8][9][10], lateral forces [11,12] and also their magnetic properties [13,14].…”

Section: Methodsmentioning

confidence: 99%

Comparative Study of Classical and Nanophotonic Materials for RGP Contact Lenses by Scanning Probe Microscopy

Đuričić

Mileusnić

Stamenković³

et al. 2013

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In this paper comparative study of the classical (Soleko SP40TM) and new nanophotonic materials for contact lenses was conducted. Two photonic nanomaterials were made by adding fullerene (C60) and fullerol (C60OH24) to the classic, commercially available, base material (PMMA- polymethylmethacrylate). Nanomaterials are added to the base material to change the transmission characteristics of light, because of different electromagnetic properties of the materials. Two new nanophotonic nanomaterials, along with the base material were investigated with Scanning Probe Microscopy methods of Atomic Force Microscopy and Magnetic Force Microscopy (AFM/MFM) to determine roughness, electro-magnetic properties of materials, and static Force-distance curve for investigating materials mechanical characteristics. Results and analysis of investigations for all three materials are compared and presented in the paper.

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“…All relevant materials have been compared to assess suitability for contact lenses manufacture. Materials were characterized by their surface and electromagnetic properties using Atomic Force Microscopy (AFM) and Magnetic Force Microscopy (MFM), which have been proven to be reliable characterization methods for contact lens investigations [6,7,8,9,10,11].…”

Section: Introductionmentioning

confidence: 99%

Nanophotonic Rigid Contact Lenses: Engineering and Characterization

Koruga

Stamenković²,

Djuricic

et al. 2013

AMR

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Contact lenses are a common optical aid to provide help with refractive anomalies of the human eye. Construction of contact lenses is a complex engineering task as it requires knowledge of optics, materials science, production and characterization methods for product quality. Besides correcting refractive anomalies, by using contact lenses it is possible to change the characteristics of light through the manipulation of material structure properties. Nanomaterials, such as fullerene C60, are candidates for the medium that interacts with light, thus changing its properties. During material syntheses for contact lenses, fullerenes are added to the base material and optical characteristics of the new nanophotonic material are compared with the base material. The engineering, manufacture and characterization of both a commercial and a new nanophotonic contact lens is presented in this paper. The interaction of water with both base and nanophotonic contact lens materials is described. Using experimental techniques, the phenomena of an exclusion zone (EZ) is also identified.

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Characterization of Nanomaterial-Based Contact Lenses by Atomic Force Microscopy

Cited by 4 publications

References 2 publications

Effects of Image Size and Sample Areas on Comparison of Contact Lens Surfaces Based on Fractal Dimension

Effects of Image Size and Sample Areas on Comparison of Contact Lens Surfaces Based on Fractal Dimension

Comparative Study of Classical and Nanophotonic Materials for RGP Contact Lenses by Scanning Probe Microscopy

Nanophotonic Rigid Contact Lenses: Engineering and Characterization

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