Institution
Queensland University of Technology
Education•Brisbane, Queensland, Australia•
About: Queensland University of Technology is a education organization based out in Brisbane, Queensland, Australia. It is known for research contribution in the topics: Population & Poison control. The organization has 14188 authors who have published 55022 publications receiving 1496237 citations. The organization is also known as: QUT.
Topics: Population, Poison control, Raman spectroscopy, Health care, Curriculum
Papers published on a yearly basis
Papers
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TL;DR: In this paper, the authors reviewed and synthesized the existing knowledge on ultrafine particles in the air with a specific focus on those originating due to vehicles emissions and focused on secondary particle formation in urban environments resulting from semi volatile precursors emitted by the vehicles.
570 citations
01 May 2014
TL;DR: The publication of Working Together: Aboriginal and Torres Strait Islander Mental Health and Wellbeing Principles and Practice marks a watershed in the treatment of Indigenous mental health issues.
Abstract: Editors: Nola Purdie, Pat Dudgeon and Roz Walker Foreword by Tom Calma ‘Designed for practitioners and mental health workers, as well as students training to be mental health workers, I am confident that the publication of Working Together: Aboriginal and Torres Strait Islander Mental Health and Wellbeing Principles and Practice marks a watershed in the treatment of Indigenous mental health issues.’ Tom Calma Aboriginal and Torres Strait Islander Social Justice Commissioner
570 citations
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TL;DR: In this paper, the authors provide an overview of bike share programs, followed by a critical examination of the growing body of literature on these programs, including a synthesis of previous works, both peer-reviewed and gray, including an identification of the current gaps in knowledge related to the impacts of bike sharing programs.
567 citations
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TL;DR: A review of the chemistry of levulinic acid synthesis from lignocellulosics can be found in this paper, where the authors discuss current and potential technologies for producing ligninic acid from biomass.
Abstract: Biomass represents an abundant and relatively low cost carbon resource that can be utilized to produce platform chemicals such as levulinic acid. Current processing technology limits the cost-effective production of levulinic acid in commercial quantities from biomass. The key to improving the yield and efficiency of levulinic acid production from biomass lies in the ability to optimize and isolate the intermediate products at each step of the reaction pathway and reduce re-polymerization and side reactions. New technologies (including the use of microwave irradiation and ionic liquids) and the development of highly selective catalysts would provide the necessary step change for the optimization of key reactions. A processing environment that allows the use of biphasic systems and/or continuous extraction of products would increase reaction rates, yields and product quality. This review outlines the chemistry of levulinic acid synthesis and discusses current and potential technologies for producing levulinic acid from lignocellulosics. © 2011 Society of Chemical Industry and John Wiley & Sons, Ltd
566 citations
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TL;DR: This work reinforces soft hydrogels with highly organized, high-porosity microfibre networks that are 3D-printed with a technique termed as melt electrospinning writing, showing that the stiffness of the gel/scaffold composites increases synergistically (up to 54-fold), compared with hydrogel or microf fibre scaffolds alone.
Abstract: Despite intensive research, hydrogels currently available for tissue repair in the musculoskeletal system are unable to meet the mechanical, as well as the biological, requirements for successful outcomes. Here we reinforce soft hydrogels with highly organized, high-porosity microfibre networks that are 3D-printed with a technique termed as melt electrospinning writing. We show that the stiffness of the gel/scaffold composites increases synergistically (up to 54-fold), compared with hydrogels or microfibre scaffolds alone. Modelling affirms that reinforcement with defined microscale structures is applicable to numerous hydrogels. The stiffness and elasticity of the composites approach that of articular cartilage tissue. Human chondrocytes embedded in the composites are viable, retain their round morphology and are responsive to an in vitro physiological loading regime in terms of gene expression and matrix production. The current approach of reinforcing hydrogels with 3D-printed microfibres offers a fundament for producing tissue constructs with biological and mechanical compatibility.
565 citations
Authors
Showing all 14597 results
Name | H-index | Papers | Citations |
---|---|---|---|
Nicholas G. Martin | 192 | 1770 | 161952 |
Paul M. Thompson | 183 | 2271 | 146736 |
Christopher J. O'Donnell | 159 | 869 | 126278 |
Robert G. Parton | 136 | 459 | 59737 |
Tim J Cole | 136 | 827 | 92998 |
Daniel I. Chasman | 134 | 484 | 72180 |
David Smith | 129 | 2184 | 100917 |
Dmitri Golberg | 129 | 1024 | 61788 |
Chao Zhang | 127 | 3119 | 84711 |
Shi Xue Dou | 122 | 2028 | 74031 |
Thomas H. Marwick | 121 | 1063 | 58763 |
Peter J. Anderson | 120 | 966 | 63635 |
Bruno S. Frey | 119 | 900 | 65368 |
David M. Evans | 116 | 632 | 74420 |
Michael Pollak | 114 | 663 | 57793 |