INTRODUCTION
Currently due to the increase of global pollution caused by mankind’s reckless development and industrial advancement, public interest in environmental pollution is increasing. Among environmental pollution, the destruction of the ozone layer was first reported by a British Antarctica expedition team which raised concerns that the depleted ozone layer may lead to serious outcomes. Since then, there have been active studies on the ozone layer which provided more in-depth understanding of the importance of the ozone layer and its effects on mankind.1
The light emitted by the sun is an electromagnetic wave of various wavelengths. Among the light, the ultraviolet ray which has a short wavelength is known to be very harmful to humans and plants. The ozone layer absorbs, reflects and filters this harmful ray. However, if the ozone layer becomes thinner or even destroyed, the layer cannot play such a protective role, and as UV rays reach the earth’s surface, it can cause various diseases such as skin cancer and eye disease. Also, UV rays can inhibit the growth of plants and crops, and can cause a variety of problems. Not only that, but it can also discolor clothes and products.2-4
The eye is one of the things that can be most sensitive to the harmfulness of UV rays. Unlike other organs, the human eye is exposed directly to light. While light is essential for the human brain to identify objects, parts of the eye such as the cornea, retina and lens can be damaged when exposed directly to an excessive amount of UV rays which may also cause various eye diseases such as cataract and macular degeneration.5,6 Therefore, there have been many attempts to protect the eyes and wearing glasses that can block UV rays is one of the methods. Spectacles with coated material on the surface of the lens can easily block UV rays but in the case of contact lenses, it is difficult to coat the surface and due to the characteristics of the material, many problems can occur in blocking UV.7,8 Due to these reasons, studies are currently in progress in order to enhance the potential of the materials used to make contact lenses, but there are fewer studies of materials for UV-blocking contact lenses. Also, due to the increased interest on aesthetic features and the inconveniences of spectacles, more people are preferring contact lenses over glasses and the user rate of contact lenses is increasing throughout the world.
Hence, studies on high-performance materials used to produce contact lenses are being actively conducted along with studies on water content which greatly affect comfortable wear.9-11
Due to the present situation, in this study we added the benzophenone group which is used in films and bottles as a light-resistant stabilizer that absorbs UV rays in order to synthesize a polymer with a UV-blocking feature that can be used to produce contact lenses. Also, TiO2 was used as another UV-absorbing additive. TiO2 is known to be very stable in chemical and physical aspects and has the highest refractive index among white pigments and also has a well defined particle size and dispersibility. Also, TiO2 decomposes organic compounds when activated with a photo-catalyst and there is a recent global trend of various applications of such characteristics in various fields. This study used TiO2 as a material to absorb UV rays with a high visible transmittance and refractive index.
Therefore, we compared the UV absorbency of the polymer produced with the benzophenone group and TiO2 with previous materials and measured the properties of the produced contact lens in order to experiment whether the material is suitable for ophthalmic materials.
MATERIALS AND METHODS
Materials
The 2-hydroxy-4-methoxy-benzophenone and 2,4-dihydroxy-benzophenone used in this study were products from Aldrich and the SEM image taken in order to visualize the structure of TiO2 is shown in Fig. 1. The ethylene glycol dimethacrylate (EGDMA) was procured from Acros while the 2-hydroxyethyl methacrylate (HEMA) and azobisisobutyronitrile (AIBN) was supplied by JUNSEI and used without any purification.
Fig. 1.SEM image of TiO2.
Methods
Refractive index and water content: The refractive index of the produced contact lens was measured with ATAGO NAR 1T. It can be seen in Fig. 2. The hydrated material refractive index (nwet), dry material refractive index (ndry) and standard saline solution (ISO 18369-3) refractive index (nstd) were measured. Formula (1) based on the refractive index method of the ISO 18369-4:2006, Ophthalmic optics - Contact lenses - Part 4: Physicochemical properties of contact lens materials was used to measure to calculate the water content.
Fig. 2.Abbe refractormeter (ATAGO NAR 1T).
Fig. 3.Spectral transmittance meter (TOPCON TM-2).
Optical transmittance: TOPCON TM. 2 and Hitachi Model U-4001 Spectrophotometer were used to measure the optical transmittance for visible light, UV-A and UVB. It can be seen in Fig. 3. The average optical transmittance (τ) from wavelength λ1 to λ2 was calculated using Formula (2) and is shown as a percentage. The optical transmittance and the luminance transmittance of the produced contact lens were measured after hydrating for 24 hours in a 0.9% sodium chloride PBS solution.
Production method of the contact lens: The cast mould method was used in order to produce the contact lenses used in this study. The mixed materials were inserted in the mould and heated for 40 minutes at 70 ℃, for 40 minutes at 80 ℃ and for 40 minutes at 100 ℃ for polymerization. Meanwhile, 0.1% (wt) AIBN (azobisisobutyronitrile) was used as an initiator.
RESULTS AND DISCUSSION
Polymerization and lens production
The crosslinking agent EGDMA and UV-absorbents (2-hydroxy-4-methoxy-benzophenone, 2,4-dihydroxy-benzophenone, TiO2, etc.) were mixed with a certain amount of HEMA and other raw materials and the mixture was polymerized and measured for UV-blocking performance. The mixture ratio used in this study is shown in Table 1. In order to classify each reagent used in this study, the mixture of only HEMA and EGDMA is described as Blank while HMB indicates the addition of 2-hydroxy-4-methoxy-benzophenone to Blank and the addition of 2,4-dihydroxy-benzophenone to Blank is described as DHB. Also, the sample that is a mixture of 2-hydroxy-4-methoxy-benzophenone and 2,4-dihydroxy-benzophenone which are of the benzophenone group and Blank is described as HDB while the addition of TiO2 to Blank is described as TO in order to compare the measurements on the refractive index, water content and the visible transmittance.
Table 1.Composition ratio of each sample
Fig. 4.SEM image of HMB sample.
The polymerization used in this study all resulted in colorless transparent macromolecules and the SEM image of the produced contact lens is shown in Fig. 4.
Properties of the polymer produced with the benzophenone group
Refractive index and water content: The ndry of Blank which does not include any UV-absorbent was 1.501 while nwet was 1.434 and the water content was calculated to be 39.64%. The refractive index and water content of Blank is summarized in Table 2.
Table 2.Refractive index and water content of Blank
Also, the ndry of HMB which is 2-hydroxy-4-methoxybenzophenone added to Blank was 1.503 and the nwet was 1.434 while the water content was 40.41%, showing that the refractive index and water content are similar to that of Blank. In cases with DHB which is 2,4-dihydroxy-benzophenone added to Blank, the ndry was 1.507 and the nwet was 1.440. The water content was calculated to be 38.56% showing a higher refractive index compared to that of Blank but did not show any significant differences in water content. The ndry of HDB which is 2-hydroxy-4-methoxybenzophenone and 2,4-dihydroxy-benzophenone added to Blank was 1.500 while the nwet was 1.439, and the water content was 36.43% which was lower than that of Blank while the refractive index was similar to that of Blank. The refractive index and water content of the samples produced with the benzophenone group are summarized in Table 3. Also the distribution of water content is shown in Fig. 5.
Table 3.Refractive index and water content (benzophenone)
Fig. 5.Distribution of Water content results.
Optical transmittance: The optical transmittance of Blank which is the standard sample was high for all wavelengths such as the UV-B wavelength (280~315 nm), UVA wavelength (315~400 nm) and in the visible light range (400~750 nm). Meanwhile, the transparency calculated with Formula (2) was 89%, 88% and 89% for each wavelength. Therefore, considering that the sample Blank has high transparencies for all wavelengths of UV rays, Blank can be considered to be ineffective in blocking UV rays. Contrary to the above, the DHB’s optical transmittance showed a higher UV-blocking performance in UV-B (315~400 nm) than UV-A (280~315 nm) and also showed a higher transparency in the visible light wavelength (400~750 nm). The transparencies calculated with Formula (2) were 8%, 21% and 74%. The HMB’s optical transmittance showed a total UV-blocking performance in UV-B (280~315 nm) and also showed a high transparency in the visible light wavelength (400~750 nm). The transparencies calculated with Formula (2) were 0%, 4% and 80%. The results are shown in Fig. 6.
Comparing the transparencies of Blank with that of HDB, HDB showed much lower transparencies in UV-B (280~315 nm) and UV-A (315~400 nm) as can be seen in Fig. 7. The transparencies for Blank calculated with Formula (2) was 84% in UV-B and 88% in UV-A, and in cases with HDB, the transparencies were 0% in UV-B and 6% in UV-A. Based on this result, Blank and HDB all showed very high transparencies of 90% in the visible light range and in wavelengths between 400~750 nm showing that the contact lens’ transparency is suitable to visible light. The optical transmittances of each sample are summarized in Table 4.
Fig. 6.Optical transmittance of HMB(Ultraviolet rays).
Fig. 7.Optical transmittance of Blank and HDB.
Table 4.Optical transmittance of samples (Benzophenone)
Properties of the material using TiO2
Refractive index and water content: The ndry of TO with TiO2 added to the standard sample Blank was 1.507 and the nwet was 1.432 while the water content was calculated to be 43.09%. Also, TO showed the highest water content from all other samples.
The refractive index and water content of each sample of TO are shown in Table 5.
Table 5.Refractive index of TO sample
Optical transmittance: Comparing the transparencies of Blank with that of TO, TO showed lower transparencies in all wavelengths of UV-B (280~315 nm) and UV-A (315~400 nm) as can be seen in Fig. 8. The transparencies for Blank calculated with Formula (2) was 89% in UV-B and 88% in UV-A, and in cases with TO, the transparencies were 6% in UV-B and 51% in UV-A. Blank and HDB all showed high transparencies of 89% and 81% respectively in the visible light range (400~750 nm) showing that the contact lens’ transparency is suitable to visible light.
Fig. 8.Optical transmittance of Blank and TO.
CONCLUSION
In this study we polymerized macromolecule material that can block UV rays by adding 2-hydroxy-4-methoxybenzophenone, 2,4-dihydroxy-benzophenone and TiO2 to HEMA which is commonly used to produce contact lenses and measured the transparencies for visible light and UV rays. Also, by comparing the values with those of previous contact lenses, we tried to verify the effects of the materials used to block UV rays and its application to ophthalmological contact lenses.
As a result, we discovered that the contact lenses produced with UV-blockers are basically similar in water content and refractive index with previous lenses showing that there are no problems in applying the ophthalmological materials. Also, for optical transmittances of each wave length, the contact lens without the UV-absorbent was 89%, 88% and 89% respectively for UV-A, UVB and visible light, indicating that the UV transmittance is very high though contrary to cases with contact lenses with added 2-hydroxy-4-methoxy-benzophenone and 2,4-dihydroxy-benzophenone which showed transmittances of 0% and 6% respectively for UV-A and UV-B showing a UV-blocking effect. And in cases with contact lenses with added TiO2, they showed transparencies of 6% and 51% respectively for UV-A and UV-B showing that they have UV-blocking effects. The visible transmittances were between 77~89%, showing that it satisfies the visible transmittance condition required for ophthalmological contact lenses.
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