2020
DOI: 10.1021/acsmaterialslett.9b00520
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Highly Transparent and Tough Filler Composite Elastomer Inspired by the Cornea

Abstract: We propose a strategy to develop a colorless, transparent, and tough composite elastomer inspired by the cornea, which is the transparent front portion of the eyeball. The composite elastomer, in which 34 vol % hard silica particles with a uniform particle size are dispersed as a filler in a lowcrosslinking polymer network exhibits a fracture energy that is ∼13.5 times higher than that of a system without the silica particles. This strategy also makes the elastomer optically transparent, because the light scat… Show more

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Cited by 22 publications
(26 citation statements)
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“…An interesting finding was, that in spite of the periodic fluctuations in nanofiller concentration, which were close to the micrometre scale in the extreme case (see Figure 4 b,e further above), no decrease in optical clarity was observed for the low-filled polyMEA/silica elastomers (see Figure 3 further above). This is in contrast with the results obtained for the distantly related nanocomposite based on PMEO2MA-silica (mentioned in Introduction: Asai, Takeoka and co-workers: [ 67 , 68 ]), where filler particles were much larger (110 nm) and where high optical clarity was observed only for highly regular distributions of the filler spheres. In case of polyMEA/nano-SiO 2 studied in this work, the surprising independence of the nanocomposite transparency from fluctuations of filler distribution can be explained by the close match in the refraction indices of filler and matrix: both are given as 1.46 in the literature (amorphous SiO 2 : [ 70 ], polyMEA: [ 71 ]).…”
Section: Resultscontrasting
confidence: 89%
See 1 more Smart Citation
“…An interesting finding was, that in spite of the periodic fluctuations in nanofiller concentration, which were close to the micrometre scale in the extreme case (see Figure 4 b,e further above), no decrease in optical clarity was observed for the low-filled polyMEA/silica elastomers (see Figure 3 further above). This is in contrast with the results obtained for the distantly related nanocomposite based on PMEO2MA-silica (mentioned in Introduction: Asai, Takeoka and co-workers: [ 67 , 68 ]), where filler particles were much larger (110 nm) and where high optical clarity was observed only for highly regular distributions of the filler spheres. In case of polyMEA/nano-SiO 2 studied in this work, the surprising independence of the nanocomposite transparency from fluctuations of filler distribution can be explained by the close match in the refraction indices of filler and matrix: both are given as 1.46 in the literature (amorphous SiO 2 : [ 70 ], polyMEA: [ 71 ]).…”
Section: Resultscontrasting
confidence: 89%
“…In spite of the large size of the filler, the elastomers displayed good tensile properties, which interestingly improved (including elongation at break) with rising filler content. In a subsequent study [ 67 ], the same authors embedded the same silica spheres into poly[di(ethylene glycol)methyl ether methacrylate] matrix (PMEO2MA) without any chemical crosslinker. PMEO2MA is a brush polymer structurally related to polyMEA, but with much larger side-chains.…”
Section: Introductionmentioning
confidence: 99%
“…Recently, we reported a transparent composite elastomer composed of diethylene glycol monomethyl ether methacrylate (PMEO 2 MA) and submicron spherical silica particles, which was inspired by the cornea, which is one of the extracellular matrices. 19 Spherical silica particles were fixed in colloidal crystals in the polymer matrix of this composite elastomer, and increasing the amount of silica significantly improved the strength and strain at break of the composite elastomer. Based on this result, we predicted that PMEA, which has a structure similar to PMEO 2 MA, can be reinforced by the filling of silica particles to obtain a selfsupporting composite elastomer that is blood compatible.…”
Section: Introductionmentioning
confidence: 96%
“…Bionanocomposites are nanocomposites containing a biological material such as collagen, cellulose, alginate or silk. They have been studied to develop replacement tissues, such as tendon (Yang et al, 2016 ), corneal stroma (Watanabe et al, 2020 ), bone (Raja and Yun, 2016 ) and dermis (Song et al, 2015 ).…”
Section: Silk-based Bionanocompositesmentioning
confidence: 99%