AI Article Synopsis
- Polymerizable microspheres (P) were added to acrylamide to create hydrogels with improved mechanical properties and a unique three-dimensional pore structure.
- Testing revealed that hydrogels with P had superior rheological properties, tensile strength, and compression strength compared to normal hydrogels (N) and those with regular microspheres (O), demonstrating less fracture and better recovery under strain.
- Scanning electron microscopy (SEM) showed that the network structure of P is denser and more compact than that of N, contributing to the enhanced mechanical strength by reducing the flow of free water within the hydrogel matrix.
Article Abstract
Polymerizable microspheres are introduced into acrylamide to prepare the high mechanical strength hydrogels with a novel three-dimensional pore structure. Rheological properties, compressive stress⁻strain, tensile property, and compression strength of three different types of hydrogels were investigated. Moreover, a scanning electron microscope (SEM) was adopted to observe the three-dimension network structure of three different types of hydrogels. The test results illustrated that viscous moduli (G″) and elastic moduli (G') of a hydrogel containing polymerizable microspheres (P) reached maximum values, compared to the normal hydrogel (N) and the composite hydrogel containing ordinary microspheres (O). When the hydrogels were squeezed, the N was easily fractured under high strain (99%), whereas the P was not broken, and quickly recovered its initial morphology after the release of load. The P showed excellent tensile properties, with an elongation at break up to 90% and a tensile strength greater than 220 g. The compression strength of the N was 100.44 kPa·m, while the resulting strength of P was enhanced to be 248.00 kPa·m. Therefore, the various performances of N were improved by adding polymerizable microspheres. In addition, the SEM images indicated that N has a general three-dimensional network structure; the conventional network structure did not exist in the P, which has a novel three-dimensional pore structure in the spherical projection and very dense channels, which led to the compaction of the space between the three-dimensional pore network layers and reduced the flowing of free water wrapped in the network. Therefore, the mechanical strength of hydrogel was enhanced.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6025025 | PMC |
| http://dx.doi.org/10.3390/ma11060880 | DOI Listing |
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