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10 results on '"Nathanael Leung"'

2. Light diffraction by sarcomeres produces iridescence in transmission in the transparent ghost catfish

Author

Xiujun Fan, Xuezhi Zheng, Tong An, Xiuhong Li, Nathanael Leung, Bin Zhu, Tan Sui, Nan Shi, Tongxiang Fan, and Qibin Zhao

Subjects
Multidisciplinary
Abstract

Despite the elaborate varieties of iridescent colors in biological species, most of them are reflective. Here we show the rainbow-like structural colors found in the ghost catfish ( Kryptopterus vitreolus ), which exist only in transmission. The fish shows flickering iridescence throughout the transparent body. The iridescence originates from the collective diffraction of light after passing through the periodic band structures of the sarcomeres inside the tightly stacked myofibril sheets, and the muscle fibers thus work as transmission gratings. The length of the sarcomeres varies from ~1 μm from the body neutral plane near the skeleton to ~2 μm next to the skin, and the iridescence of a live fish mainly results from the longer sarcomeres. The length of the sarcomere changes by ~80 nm as it relaxes and contracts, and the fish shows a quickly blinking dynamic diffraction pattern as it swims. While similar diffraction colors are also observed in thin slices of muscles from non-transparent species such as the white crucian carps, a transparent skin is required indeed to have such iridescence in live species. The ghost catfish skin is of a plywood structure of collagen fibrils, which allows more than 90% of the incident light to pass directly into the muscles and the diffracted light to exit the body. Our findings could also potentially explain the iridescence in other transparent aquatic species, including the eel larvae ( Leptocephalus ) and the icefishes (Salangidae).

Published
2023
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3. Multi-scale structural and mechanical characterisation in bioinspired polyurethane-based pancreatic cancer model

Author

Nathanael Leung, Priyanka Gupta, Hui Xing, Jiao Zhang, Jingyi Mo, Bin Zhu, Eirini Velliou, and Tan Sui

Subjects
In situ, Materials science, Biomaterials, Extracellular matrix, chemistry.chemical_compound, Surface functionalisation, Pancreatic cancer, Bioinspired polyurethane, Nano, medicine, Strengthening mechanisms of materials, Polyurethane, Mining engineering. Metallurgy, biology, Small-angle X-ray scattering, Synchrotron X-ray techniques, Metals and Alloys, TN1-997, medicine.disease, Surfaces, Coatings and Films, Fibronectin, chemistry, Ceramics and Composites, biology.protein, Biophysics, in situ mechanical testing
Abstract

In this work, novel bioinspired polyurethane (PU) scaffolds were fabricated via freeze casting for PU-based Pancreatic Ductal Adenocarcinoma (PDAC) model. In order to reproduce the tumour micro-environment that facilitates cellular kinetics, the PU scaffolds were surface modified with extracellular matrix (ECM) proteins including collagen and fibronectin (Col and FN). Synchrotron-based small- and wide-angle X-ray scattering (SAXS/WAXS) techniques were applied to probe structural evolution during in situ mechanical testing. Strains at macroscopic, nano-, and lattice scales were obtained to investigate the effects of ECM proteins and pancreatic cell activities to PU scaffolds. Significant mechanical strengthening across length scales of PU scaffolds was observed in specimens surface modified by FN. A model of stiffness modulation via enhanced interlamellar recruitment is proposed to explain the multi-scale strengthening mechanisms. Understanding multi-scale deformation mechanisms of a series of PU scaffolds opens an opportunity in developing a novel pancreatic cancer model for studying cancer evolution and predicting outcomes of drug/treatments.

Published
2021

4. Fabrication and characterisation of alumina/aluminium composite materials with a nacre-like micro-layered architecture

Author

Hongbo Wan, Nathanael Leung, Urangua Jargalsaikhan, Eric Ho, Chaolin Wang, Qiang Liu, Hua-Xin Peng, Bo Su, and Tan Sui

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science
Abstract

Many natural materials demonstrate ideal design inspirations for the development of lightweight composite materials with excellent damage tolerance. One notable example is the layered architecture of nacre, which possesses toughness an order of magnitude higher than its constituent parts. Man-made nacre-like ceramic/polymer composites obtained through direct infiltration of polymer in ceramic scaffolds have been shown to produce improved mechanical properties over other composite architectures. Replacing the polymer phase with metal could provide higher damage tolerance but the infiltration of metal into complex ceramic scaffolds is difficult due to the surface tension of molten metal. To address this, bioinspired nacre-like micro-layered (µL) alumina scaffolds with different ceramic fractions from 18 to 85% were infiltrated with aluminium alloy 5083 via pressureless and squeeze casting infiltrations techniques. The scaffolds were created using a bi-directional freeze-casting and one-step densification method. As a result, the µL alumina/aluminium composites displayed significant extrinsic toughening mechanisms with both high strength and toughness. The mechanical performance was highly dependent on the interface, microstructure, and composition. The nacre-like composites with 18% alumina and AlN interface displayed a maximum resistance‐curve toughness up to around 70 MPa.m½ (35 MPa.m½ at the ASTM limit) and a flexural strength around 600 MPa.

Published
2022
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6. Advanced microscopic characterisation of multi-scale high-resolution mechanical behaviour of a nacre-inspired composite

Author

Jingyi Mo, Nathanael Leung, Urangua Jargalsaikhan, Hongbo Wan, Bin Zhu, Bo Su, and Tan Sui

Subjects
Polymers and Plastics, Mechanics of Materials, Materials Chemistry, Ceramics and Composites
Abstract

A nacre-inspired composite with a lamellar architecture of polymethyl methacrylate (soft and tough phase) and alumina (stiff phase) was fabricated using a bidirectional freezing casting technique. The bulk fracture mechanics of the nacre-inspired composite has been reported along with detailed microstructural analysis. The mechanistic connection between microstructure and mechanical properties at the micro- and macro-scale was not fully understood. Herein we addressed this issue by quantifying phase-specific hardness, modulus, and residual stress at the micro-scale level and compared with the bulk mechanical response. A shear-lag model was applied to provide a quantitative understanding of the softening effects resulting from residual stress and the microstructure. Our findings demonstrated the potential of bioinspired synthetic architectures in providing a tuneable model system to investigate the underlying design principles of more complex hierarchical biological materials.

Published
2022
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8. 4D microstructural changes in dentinal tubules during acid demineralisation

Author

Richard M. Shelton, Gabriel Landini, Tan Sui, Bin Zhu, Nathanael Leung, and Robert A. Harper

Subjects
Chronic exposure, Materials science, Dentistry, stomatognathic system, medicine, Humans, General Materials Science, Cementum, Dental Enamel, General Dentistry, Gingival recession, Tooth Demineralization, Enamel paint, business.industry, Structural integrity, stomatognathic diseases, Dentinal Tubule, medicine.anatomical_structure, Mechanics of Materials, Irreversible loss, visual_art, Dentin, visual_art.visual_art_medium, Pulp (tooth), medicine.symptom, business, Tooth, Synchrotrons
Abstract

Objective Dental erosion is a common oral condition caused by chronic exposure to acids from intrinsic/extrinsic sources. Repeated acid exposure can lead to the irreversible loss of dental hard tissues (enamel, dentine, cementum). Dentine can become exposed to acid following severe enamel erosion, crown fracture, or gingival recession. Causing hypersensitivity, poor aesthetics, and potential pulp involvement. Improving treatments that can restore the structural integrity and aesthetics are therefore highly desirable. Such developments require a good understanding of how acid demineralisation progresses where relatively little is known in terms of intertubular dentine (ITD) and peritubular dentine (PTD) microstructure. To obtain further insight, this study proposes a new in vitro method for performing demineralisation studies of dentine. Methods Advanced high-speed synchrotron X-ray microtomography (SXM), with high spatial (0.325 μm) and temporal (15 min) resolution, was used to conduct the first in vitro, time-resolved 3D (4D) study of the microstructural changes in the ITD and PTD phases of human dentine samples (∼0.8 × 0.8 × 5 mm) during 6 h of continuous acid exposure. Results Different demineralisation rates of ITD (1.79 μm/min) and PTD (1.94 μm/min) and their progressive width-depth profiles were quantified, which provide insight for understanding the mechanisms of dentine demineralisation. Significance Insights obtained from morphological characterisations and the demineralisation process of ITD and PTD during acid demineralisation would help understand the demineralisation process and potentially aid in developing new therapeutic dentine treatments. This method enables continuous examination of relatively large volumes of dentine during demineralisation and also demonstrates the potential for studying the remineralisation process of proposed therapeutic dentine treatments.

Published
2021

9. Novel in situ multi-level analysis of structural-mechanical relations in a bioinspired polyurethane-based tissue model

Author

Tan Sui, Priyanka Gupta, Nathanael Leung, Eirini Velliou, Bin Zhu, and Jingyi Mo

Subjects
In situ, Materials science, Pancreatic tissue, Multi level analysis, Mechanical Engineering, Tissue Model, Stiffness, Pancreatic cancer, chemistry.chemical_compound, Surface functionalisation, chemistry, Bioinspired polyurethane, Nano, Synchrotron X-ray scattering techniques, TA401-492, medicine, Confocal laser scanning microscopy, General Materials Science, Lamellar structure, In situ micromechanical testing, medicine.symptom, Materials of engineering and construction. Mechanics of materials, Biomedical engineering, Polyurethane
Abstract

In this manuscript, we elucidated, for the first time, the substructural mechanisms present in our recently developed bioinspired polyurethane-based pancreatic tissue models. Different protein coatings of the model, i.e., collagen and fibronectin were examined. More specifically, analysis took place by combined real-time synchrotron X-ray scattering techniques and confocal laser scanning microscopy, to quantify the structural alteration of uncoated-polyurethane (PU) and protein-coated PU as well as the time-resolved structural reorganisation occurring at the micro-, nano- and lattice length scales during in situ micromechanical testing. We demonstrate that a clear increase of stiffness at the lamellar level following the fibronectin-PU modification, which is linked to the changes in the mechanics of the lamellae and interlamellar cohesion. This multi-level analysis of structural-mechanical relations in this polyurethane-based pancreatic cancer tissue model opens an opportunity in designing mechanically robust cost-effective tissue models not only for fundamental research but also for treatment screening.

Published
2021
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10. Cost-effective fabrication of bio-inspired nacre-like composite materials with high strength and toughness

Author

Bo Su, Hongbo Wan, Nathanael Leung, Sana W A R Algharaibeh, Hua-Xin Peng, Tan Sui, and Qiang Liu

Subjects
Toughness, Materials science, Fabrication, Composite number, Sintering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Industrial and Manufacturing Engineering, Stress (mechanics), Fracture toughness, Flexural strength, Ceramic, Composite material, Bio-inspired composites, Mechanical Engineering, 021001 nanoscience & nanotechnology, Bi-directional freeze casting, 0104 chemical sciences, Brick-and-mortar (BM), Mechanics of Materials, visual_art, Alumina/PMMA, Ceramics and Composites, visual_art.visual_art_medium, Micro-layered (μL), 0210 nano-technology
Abstract

A cost-effective one-step densification process based on bi-directional freeze casting was investigated to produce nacre-like alumina/poly(methyl methacrylate) (PMMA) composites with a unique micro-layered (µL) architecture. This method has the advantage of shorter processing time, as it requires only sintering once instead of twice as in the fabrication of conventional brick-and-mortar (BM) composites via freeze casting. By tuning the processing parameters, composites with different ceramic content and layer thickness were obtained. The resultant mechanical properties of µL composites showed that ceramic content and wall thickness affected mechanical properties significantly. The µL composite with fine ceramic walls (8 µm) and relatively high ceramic fraction (72 vol.%) exhibited an exceptional combination of high flexural strength (178 MPa) and fracture toughness (12.5 MPa m1/2). The µL composites were also compared with the conventional BM composites. Although the fracture behaviour of both composites exhibited similar extrinsic toughening mechanisms, the µL composites with longer ceramic walls displayed superior mechanical properties in terms of strength and fracture toughness in comparison with the BM composites comprising short ceramic walls (i.e. bricks), due to the effectiveness of stress transfer of load-bearing ceramic phase within the composites.

Published
2020
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