Your search keyword '"Koh, Ct"' showing total 5 results

1. Serosal surface small vessel vasculitis in Henoch-Schonlein purpura.

Author

Lee WS and Koh CT

Abstract

Competing Interests: Declaration of Competing Interest We have no conflict of interest to declare for this case report.

Published

2020

2. Systematic mechanical evaluation of electrospun gelatin meshes.

Author

Butcher AL, Koh CT, and Oyen ML

Subjects

Finite Element Analysis, Microscopy, Electron, Scanning, Tissue Engineering, Gelatin analysis, Materials Testing

Abstract

Electrospinning is a simple and efficient process for producing sub-micron fibres. However, the process has many variables, and their effects on the non-woven mesh of fibres is complex. In particular, the effects on the mechanical properties of the fibre meshes are poorly understood. This paper conducts a parametric study, where the concentration and bloom strength of the gelatin solutions are varied, while all electrospinning process parameters are held constant. The effects on the fibrous meshes are monitored using scanning electron microscopy and mechanical testing under uniaxial tension. Mesh mechanical properties are relatively consistent, despite changes to the solutions, demonstrating the robustness of electrospinning. The gel strength of the solution is shown to have a statistically significant effect on the morphology, stiffness and strength of the meshes, while the fibre diameter has surprisingly little influence on the stiffness of the meshes. This experimental finding is supported by finite element analysis, demonstrating that the stiffness of the meshes is controlled by the volume fraction, rather than fibre diameter. Our results demonstrate the importance of understanding how electrospinning parameters influence the pore size of the meshes, as controlling fibre diameter alone is insufficient for consistent mechanical properties., (Copyright © 2017 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2017

3. Time-dependent fracture toughness of cornea.

Author

Tonsomboon K, Koh CT, and Oyen ML

Subjects

Animals, Biomechanical Phenomena, Materials Testing, Polymers, Stress, Mechanical, Swine, Time Factors, Cornea, Corneal Injuries, Mechanical Phenomena

Abstract

The fracture and time-dependent properties of cornea are very important for the development of corneal scaffolds and prostheses. However, there has been no systematic study of cornea fracture; time-dependent behavior of cornea has never been investigated in a fracture context. In this work, fracture toughness of cornea was characterized by trouser tear tests, and time-dependent properties of cornea were examined by stress-relaxation and uniaxial tensile tests. Control experiments were performed on a photoelastic rubber sheet. Corneal fracture resistance was found to be strain-rate dependent, with values ranging from 3.39±0.57 to 5.40±0.48kJm(-2) over strain rates from 3 to 300mmmin(-1). Results from stress-relaxation tests confirmed that cornea is a nonlinear viscoelastic material. The cornea behaved closer to a viscous fluid at small strain but became relatively more elastic at larger strain. Although cornea properties are greatly dependent on time, the stress-strain responses of cornea were found to be insensitive to the strain rate when subjected to tensile loading., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

4. Failure mechanisms in fibrous scaffolds.

Author

Koh CT, Strange DG, Tonsomboon K, and Oyen ML

Subjects

Elastic Modulus, Electrochemistry, Equipment Design, Equipment Failure Analysis, Hardness, Materials Testing, Rotation, Tensile Strength, Gelatin chemistry, Nanofibers chemistry, Nanofibers ultrastructure, Polyesters chemistry, Tissue Scaffolds

Abstract

Polymeric fibrous scaffolds have been considered as replacements for load-bearing soft tissues, because of their ability to mimic the microstructure of natural tissues. Poor toughness of fibrous materials results in failure, which is an issue of importance to both engineering and medical practice. The toughness of fibrous materials depends on the ability of the microstructure to develop toughening mechanisms. However, such toughening mechanisms are still not well understood, because the detailed evolution at the microscopic level is difficult to visualize. A novel and simple method was developed, namely, a sample-taping technique, to examine the detailed failure mechanisms of fibrous microstructures. This technique was compared with in situ fracture testing by scanning electron microscopy. Examination of three types of fibrous networks showed that two different failure modes occurred in fibrous scaffolds. For brittle cracking in gelatin electrospun scaffolds, the random network morphology around the crack tip remained during crack propagation. For ductile failure in polycaprolactone electrospun scaffolds and nonwoven fabrics, the random network deformed via fiber rearrangement, and a large number of fiber bundles formed across the region in front of the notch tip. These fiber bundles not only accommodated mechanical strain, but also resisted crack propagation and thus toughened the fibrous scaffolds. Such understanding provides insight for the production of fibrous materials with enhanced toughness., (Copyright © 2013 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2013

5. Branching toughens fibrous networks.

Author

Koh CT and Oyen ML

Subjects

Biocompatible Materials chemistry, Biomechanical Phenomena, Computer Simulation, Cross-Linking Reagents chemistry, Elasticity, Finite Element Analysis, Humans, Materials Testing, Models, Chemical, Models, Statistical, Pressure, Shear Strength, Software, Stress, Mechanical, Collagen chemistry, Collagen Type I chemistry

Abstract

Fibrous collagenous networks are not only stiff but also tough, due to their complex microstructures. This stiff yet tough behavior is desirable for both medical and military applications but it is difficult to reproduce in engineering materials. While the nonlinear hyperelastic behavior of fibrous networks has been extensively studied, the understanding of toughness is still incomplete. Here, we identify a microstructure mimicking the branched bundles of a natural type I collagen network, in which partially cross-linked long fibers give rise to novel combinations of stiffness and toughness. Finite element analysis shows that the stiffness of fully cross-linked fibrous networks is amplified by increasing the fibril length and cross-link density. However, a trade-off of such stiff networks is reduced toughness. By having partially cross-linked networks with long fibrils, the networks have comparable stiffness and improved toughness as compared to the fully cross-linked networks. Further, the partially cross-linked networks avoid the formation of kinks, which cause fibril rupture during deformation. As a result, the branching allows the networks to have stiff yet tough behavior., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012