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#PhD #studentship in #Mechanics of #Materials
Subject:#Draping of #non-crimp #fabrics
Univesity of #Cambridge
The aim of the PhD is to develop a #micromechanical model for forming of non-crimp fabrics (NCFs), and use this to optimise the pre-forming process for manufacture of complex shapes. The work will include both experimental work and #finite #element #modelling. The work will benefit from close links with industrial partners #Formax (manufacturer of NCFs), #Simulia (developers of #Abaqus forming simulation tools) and #Jaguar Land Rover.
An EPSRC doctoral training grant will be available in the Department of Engineering, University of Cambridge, from October 2016. Applicants should have, or expect to achieve, a first-class degree in Engineering or a relevant subject in the Physical Sciences or Mathematics. Applicants with a 2.1 will be considered. Applicants from the UK are eligible for a full award, full University and College fees and a maintenance allowance of at least £14,057 per year. Applicants from the EU are eligible for a fees only award.
Informal enquiries should be made to Dr Michael Sutcliffe (mpfs@eng.cam.ac.uk).
Applications should be made on-line via the Cambridge Graduate Admissions Office before the deadline: http://www.admin.cam.ac.uk/students/gradadmissions/prospec/apply/ with Dr Sutcliffe identified as the potential supervisor.
The University values diversity and is committed to equality of opportunity.
CLOSING DATE FOR APPLICATIONS IS 4 MARCH 2016.
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💻 @BanuMusa
🌎 https://Banumusagr.com
#PhD #studentship in #Mechanics of #Materials
Subject:#Draping of #non-crimp #fabrics
Univesity of #Cambridge
The aim of the PhD is to develop a #micromechanical model for forming of non-crimp fabrics (NCFs), and use this to optimise the pre-forming process for manufacture of complex shapes. The work will include both experimental work and #finite #element #modelling. The work will benefit from close links with industrial partners #Formax (manufacturer of NCFs), #Simulia (developers of #Abaqus forming simulation tools) and #Jaguar Land Rover.
An EPSRC doctoral training grant will be available in the Department of Engineering, University of Cambridge, from October 2016. Applicants should have, or expect to achieve, a first-class degree in Engineering or a relevant subject in the Physical Sciences or Mathematics. Applicants with a 2.1 will be considered. Applicants from the UK are eligible for a full award, full University and College fees and a maintenance allowance of at least £14,057 per year. Applicants from the EU are eligible for a fees only award.
Informal enquiries should be made to Dr Michael Sutcliffe (mpfs@eng.cam.ac.uk).
Applications should be made on-line via the Cambridge Graduate Admissions Office before the deadline: http://www.admin.cam.ac.uk/students/gradadmissions/prospec/apply/ with Dr Sutcliffe identified as the potential supervisor.
The University values diversity and is committed to equality of opportunity.
CLOSING DATE FOR APPLICATIONS IS 4 MARCH 2016.
—---------------------------—
💻 @BanuMusa
🌎 https://Banumusagr.com
www.graduate.study.cam.ac.uk
How Do I Apply? | Graduate Admissions
How to prepare and submit an application for Graduate Study at the University of Cambridge.
#Job
#Industrial #UCL #PhD #Studentship in the #Design of Novel #Microfluidic Devices
PhD Studentship
Department of Mechanical Engineering
University College London
UCL-EPSRC DTP-CASE PhD Studentship expression of interest
TITLE: #Computational and #experimental design of new microfluidic devices for isolating circulating #tumour cells:
Description: Outstanding applications are invited to submit their expression of interest to join the Department of Mechanical Engineering at UCL as part of an EPSRC Doctoral Training Programme CASE (DTP-CASE) PhD studentship. The PhD project is being jointly supervised by Professor Emad Moeendarbary from the Department of Mechanical Engineering (University College London, UCL) and Dr Cesar Cortes-Quiroz from ANGLE plc (British multinational medical device company).
Project Brief: Cancer Research UK‘s statistics suggest that men have a 45% likelihood of suffering from cancer during their life, while women are only slightly lower at 41%. All forms of cancer are characterized by excessive proliferation of cells in the form of solid tumours, which often shed cancer cells into the patient’s bloodstream to other secondary locations (metastasis cascade). These cells, known as Circulating Tumour Cells (CTCs), are very rare (a single cell in one billion blood cells) and difficult to isolate. However, they are highly valuable cells due to their defining features. They contain information on the type of disease for cancer diagnosis, which can help in deciding targeted drug therapies and treatment monitoring, while their presence and quantity are indicative of patient prognosis.
For CTC isolation, size-/deformability-based cell separation (enrichment) technologies are distinguished because their operating methods are label-free, fast and simple. Enriched CTCs remain unmodified and viable for downstream analyses.
The aim of this project will be to develop a numerical simulation platform for the design and analysis of the flow patterns of whole blood and biological reagents during the operation of microfluidic devices used for CTCs isolation from patient blood samples. Insights of flow characteristics will be determined and design modifications proposed to improve the capacities and efficiency of the system. Traditional mechanical components of lab equipment systems such as reservoirs, flow generators, valves, tubing, sensors and actuators will be investigated on their efficacy to carry the biological fluids without compromising the performance of the system. A CAD tool will be used to model 2-D and 3-D geometries of a proposed medical device and a CFD tool will explore the fluid flow characteristics in different system components. Aspects of cellular biomechanics and behaviour during blood transport can be included to determine their impact on the performance of critical capturing microdevices of the system. The final outcome of the work will be an improved system configuration and composition as well as its optimum operating conditions. Experimental validations will be coordinated with a leading biotechnology company in new liquid biopsy technology.
Environment, Research and Training: The project is mainly based at UCL (Bloomsbury Campus located in the heart of Central London) which is one of the world’s top multidisciplinary universities, with an international reputation for the quality of its research and teaching. The candidate will benefit from state-of-the-art mechanical engineering research training, high-performance computing, experimental laboratories and combined supervision by world-leading engineers and scientists in the fields of microfluidics, cellular biology, biomechanics, mathematical and computational modelling. As part of this project, you will be collaborating with the industrial partner.
#Industrial #UCL #PhD #Studentship in the #Design of Novel #Microfluidic Devices
PhD Studentship
Department of Mechanical Engineering
University College London
UCL-EPSRC DTP-CASE PhD Studentship expression of interest
TITLE: #Computational and #experimental design of new microfluidic devices for isolating circulating #tumour cells:
Description: Outstanding applications are invited to submit their expression of interest to join the Department of Mechanical Engineering at UCL as part of an EPSRC Doctoral Training Programme CASE (DTP-CASE) PhD studentship. The PhD project is being jointly supervised by Professor Emad Moeendarbary from the Department of Mechanical Engineering (University College London, UCL) and Dr Cesar Cortes-Quiroz from ANGLE plc (British multinational medical device company).
Project Brief: Cancer Research UK‘s statistics suggest that men have a 45% likelihood of suffering from cancer during their life, while women are only slightly lower at 41%. All forms of cancer are characterized by excessive proliferation of cells in the form of solid tumours, which often shed cancer cells into the patient’s bloodstream to other secondary locations (metastasis cascade). These cells, known as Circulating Tumour Cells (CTCs), are very rare (a single cell in one billion blood cells) and difficult to isolate. However, they are highly valuable cells due to their defining features. They contain information on the type of disease for cancer diagnosis, which can help in deciding targeted drug therapies and treatment monitoring, while their presence and quantity are indicative of patient prognosis.
For CTC isolation, size-/deformability-based cell separation (enrichment) technologies are distinguished because their operating methods are label-free, fast and simple. Enriched CTCs remain unmodified and viable for downstream analyses.
The aim of this project will be to develop a numerical simulation platform for the design and analysis of the flow patterns of whole blood and biological reagents during the operation of microfluidic devices used for CTCs isolation from patient blood samples. Insights of flow characteristics will be determined and design modifications proposed to improve the capacities and efficiency of the system. Traditional mechanical components of lab equipment systems such as reservoirs, flow generators, valves, tubing, sensors and actuators will be investigated on their efficacy to carry the biological fluids without compromising the performance of the system. A CAD tool will be used to model 2-D and 3-D geometries of a proposed medical device and a CFD tool will explore the fluid flow characteristics in different system components. Aspects of cellular biomechanics and behaviour during blood transport can be included to determine their impact on the performance of critical capturing microdevices of the system. The final outcome of the work will be an improved system configuration and composition as well as its optimum operating conditions. Experimental validations will be coordinated with a leading biotechnology company in new liquid biopsy technology.
Environment, Research and Training: The project is mainly based at UCL (Bloomsbury Campus located in the heart of Central London) which is one of the world’s top multidisciplinary universities, with an international reputation for the quality of its research and teaching. The candidate will benefit from state-of-the-art mechanical engineering research training, high-performance computing, experimental laboratories and combined supervision by world-leading engineers and scientists in the fields of microfluidics, cellular biology, biomechanics, mathematical and computational modelling. As part of this project, you will be collaborating with the industrial partner.