|Funding for:||UK Students, EU Students|
|Funding amount:||£15,000 + approximate annual stipend|
|Placed On:||15th January 2019|
|Closes:||28th February 2019|
The project aims at developing radiation biology models and simulation approaches for using micro-dosimetric data into cancer radiotherapy treatment planning using proton and hadron beams.
Hadron therapy is the fastest growing cancer treatment strategy providing therapeutic advantages for treatments where a localised energy deposition and/ or sparing of healthy tissues is required. The NHS has invested over £250M for two clinical centres and several private initiatives are ongoing to support the achievement of world class cancer treatment in the UK. However, there are still scientific and technological challenges that need to be addressed in order to achieve hadron therapy full potentials, as for instance accounting for the increased effectiveness of hadron beams compared to photons.
This project aims at studying and developing the methodology and the formalism for the definition of micro-dosimetric quantities directly linked to radiobiological response and their implementation in Treatment Planning Systems (TPS).
In collaboration with ongoing radiation detection research, this project will critically evaluate existing and new experimental data developing methods for quantitative assessment of track structure with the final aim of defining operational quantities and approaches for their implementation in dedicated radiobiological models. A key aim of the project is to collect a set of accurate radiobiological data on clinical relevant proton and carbon ion beams with well–characterized track structures. Monte-Carlo approaches, analytical description and alternative techniques will be used to investigate integration methods of radiobiological and physical response models into Treatment Planning Systems. The radiobiological calculations will be carried out using two clinically relevant and complementary models, the Microdosimetric Kinetic Model (MKM) and the Local Effect Model (LEM4). A study for a combined LEM-MKM as alternative approach to correlate the radiobiology to nano-dosimetric quantities will be also carried out.
The student will take part in experimental campaigns at national and international clinical facilities and he/she will interact with micro-dosimetry and modelling experts. The project is highly multidisciplinary with component of radiation biology, dosimetry and computer simulations interacting with clinical, research and industrial partners. Collaboration between international leading institutes in Italy, Austria and the UK will provide the student with access to a unique range of multidisciplinary expertise, equipment and facilities. The project will deliver high-impact research papers and it will attract interest from industry and healthcare providers offering unique career development opportunities to the student.
The project will start in October 2019 and will finish in September 2023.
UK or EU applicants, who hold a First or 2:1 UK honours degree in a relevant subject area, or a 2:2 alongside a good Master degree (a distinction is usually required).
If English is not your first language, you will be required to have an IELTS Academic of 6.5 or above (or equivalent), with no sub-test score below 6.
The studentship is fully funded for UK/EU applicants by the University of Surrey, covering the University fees and a student stipend of approximately £15,000.
How to apply
Applications can be made through our Physics PhD course page https://www.surrey.ac.uk/postgraduate/physics-phd
Please state the project title and supervisor clearly on all applications.
Closing date for applications:
Thursday 28th February 2019
Prof. Giuseppe Schettino, Giuseppe.firstname.lastname@example.org 01483 655703
Type / Role: