Your search keyword '"Cheng Yee Low"' showing total 4 results

1. Fracture behavior of multilayer fibrous scaffolds featuring microstructural gradients

Author

W Khoo, SM Chung, Shing Chee Lim, Cheng Yee Low, Jenna M. Shapiro, and Ching Theng Koh

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Multilayer nanofibrous scaffolds that mimic the microstructure gradient of connective tissues have shown promising results in tissue regeneration, but the effect of these gradients on the mechanical performance of fiber meshes is poorly understood. In this study, trilayer nanofibrous gelatin scaffolds with gradually increasing fiber diameters (227–679 nm) and pore sizes (1.14–4.93 μm2) were fabricated using a sequential electrospinning process, producing a fiber density gradient over the scaffold thickness. The mechanical properties of the fibrous scaffolds were evaluated using uniaxial tensile and fracture tests. Deformation of microscopic crack tip openings was simulated using finite element analysis. Results from uniaxial and fracture tensile tests showed that the mechanical properties of fibrous scaffolds were governed by network architectures. The microstructure gradient yielded corresponding changes of material properties over the scaffold thickness. Simulation results showed different stress distribution and energy dissipation at each layer of the graded scaffolds. Finite element analysis also revealed that a combination of network density and alignment gradients can improve fracture toughness of graded scaffolds. This study provides guidelines and methodologies for designing tailored gradient fibrous scaffolds to more closely mimic the structural and mechanical properties of native interfacial tissues. Keywords: Functionally graded materials, Multilayer fibrous scaffolds, Electrospinning, Tissue engineering, Finite element analysis, Mechanical properties

Published

2019

2. Dataset on microstructural characteristics and mechanical performance of homogeneous and functionally graded fibrous scaffolds

Author

Weily Khoo, She Man Chung, Shing Chee Lim, Cheng Yee Low, Jenna M. Shapiro, and Ching Theng Koh

Subjects

Computer applications to medicine. Medical informatics, R858-859.7, Science (General), Q1-390

Abstract

Data in this article are supplementary to the corresponding research article [1]. Morphological features of homogeneous and graded nanofibrous electrospun gelatin scaffolds were observed using scanning electron microscopy. Microstructural properties including fiber diameter and pore size were determined via image analysis, using ImageJ. Uniaxial tensile and fracture tests were performed on both homogeneous and graded scaffolds using a universal testing machine. Stress-strain curves of all scaffolds are presented. Computing software, MATLAB, was used to design fibrous networks with thickness-dependent density and alignment gradients (DAG). Finite element analysis software, Abaqus, was used to determine the effect of the number of layers on the fracture properties of DAG multilayer scaffolds. Keywords: Electrospinning, Gelatin scaffold, Thickness, Tensile properties, Fracture properties, Finite element analysis, Functionally graded materials, Fibrous materials

Published

2019

3. A modified Q-learning path planning approach using distortion concept and optimization in dynamic environment for autonomous mobile robot

Author

Ee Soong Low, Ee Soong Low, Pauline Ong, Pauline Ong, Cheng Yee Low, Cheng Yee Low, Ee Soong Low, Ee Soong Low, Pauline Ong, Pauline Ong, and Cheng Yee Low, Cheng Yee Low

Abstract

Autonomous mobile robot path planning in unknown and dynamic environment is a crucial task for successful mobile robot navigation. This study proposes an improved Q-learning (IQL) algorithm to address the challenges of path planning in such environments. To this end, three different modes are introduced into the IQL algorithm, namely the normal mode, the distortion mode, and the optimization mode. The normal mode operates according to the standard Q-learning procedures. The distortion mode distorts the Q-values of states around dynamic obstacles to facilitate avoidance, while the optimization mode is employed to overcome the local minimum problem. The efficacy of the IQL algorithm is assessed through a series of comparative studies involving fourteen navigation environments, each with distinct obstacle layouts and types. Comparative analyses are performed based on several metrics, including computational time, travelled distance, collision rate, and success rate. The proposed IQL algorithm exhibits a lower collision rate and a higher success rate when compared to dynamic window approach, influence zone and inflated A*.

Published

2023

4. Dataset on microstructural characteristics and mechanical performance of homogeneous and functionally graded fibrous scaffolds

Author

Cheng Yee Low, She Man Chung, Shing Chee Lim, Ching Theng Koh, Weily Khoo, and Jenna M. Shapiro

Subjects

Pore size, Functionally graded materials, Materials science, food.ingredient, Scanning electron microscope, Tensile properties, Materials Science, lcsh:Computer applications to medicine. Medical informatics, Gelatin, 03 medical and health sciences, 0302 clinical medicine, food, Composite material, lcsh:Science (General), 030304 developmental biology, 0303 health sciences, Universal testing machine, Fibrous materials, Multidisciplinary, Electrospinning, Finite element analysis, Fracture properties, Gelatin scaffold, Finite element method, Homogeneous, Fracture (geology), lcsh:R858-859.7, Thickness, 030217 neurology & neurosurgery, lcsh:Q1-390

Abstract

Data in this article are supplementary to the corresponding research article [1]. Morphological features of homogeneous and graded nanofibrous electrospun gelatin scaffolds were observed using scanning electron microscopy. Microstructural properties including fiber diameter and pore size were determined via image analysis, using ImageJ. Uniaxial tensile and fracture tests were performed on both homogeneous and graded scaffolds using a universal testing machine. Stress-strain curves of all scaffolds are presented. Computing software, MATLAB, was used to design fibrous networks with thickness-dependent density and alignment gradients (DAG). Finite element analysis software, Abaqus, was used to determine the effect of the number of layers on the fracture properties of DAG multilayer scaffolds. Keywords: Electrospinning, Gelatin scaffold, Thickness, Tensile properties, Fracture properties, Finite element analysis, Functionally graded materials, Fibrous materials

Published

2019