Dr Alice Pyne

Dr Alice Pyne, Senior Lecturer and UK Research and Innovation Future Leaders Fellow shares more about her research and the impact of her open source pipeline.

Full-body view of Alice who is facing the camera with arms crossed.
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Dr Alice Pyne, Senior Lecturer and UK Research and Innovation Future Leaders Fellow in the School of Chemical, Materials and Biological Engineering (previously Department of Materials Science and Engineering), Faculty of Engineering.

Alice鈥檚 passion for microscopy began during her time in Bristol, where she completed her Masters in Physics looking at how dental enamel dissolved in 鈥渇izzy drinks鈥. Her passion grew during her PhD in Biophysics at UCL. During her PhD, Alice worked closely with a microscope manufacturer and it was at their headquarters in California that Alice first saw variations within the double helix of DNA on a single molecule.

Alice鈥檚 research group develops new Atomic Force Microscopy methods to understand how tiny variations in the structure of DNA molecules affect fundamental biological processes, with implications from cancer to antibiotic resistance. This includes developing image analysis tools that anyone can use - as part of her drive to make science more accessible and open to all. 


Alice shares more about her research, the development of her open source pipeline and the role of mentors and the impact this can have: 

鈥淒uring my PhD, I had the opportunity to work with a major microscope manufacturer, Bruker, which was something I enjoyed greatly as it helped me understand how academic research can integrate with industrial research and development (R&D) processes. We worked together to develop new technological developments and to make them available to the field, in particular Atomic Force Microscopy probes for high-resolution imaging. It was during our collaboration, working at the factory in Santa Barbara that I first saw variations in the double helix on a single molecule of DNA. This went on to form the which I am still so proud of.  

鈥淢ore recently, we have been able to use these technological developments to perform time-resolved imaging of DNA at the sub-molecular scale, showing 鈥 in ways that had not previously been possible to observe. This work has formed the foundation of our research vision, to understand how tiny variations in the structure of DNA molecules affect fundamental biological processes, with implications from cancer to antibiotic resistance.

鈥淲hen I started my second fellowship, I was manually processing all my data - something that is still very normal in my field and is very time-consuming. I knew there had to be a way to make this process much more efficient. I taught myself Python and started developing an which I hoped would be useful across my field. The idea is that by creating a robust platform that we can all contribute to, we can save people time and develop faster as a field through a shared community effort.

鈥淟ooking back, I鈥檝e been so lucky to be supported by a brilliant and diverse group of people. They have listened to me and discussed my ideas with enthusiasm and constructive criticism. Those interactions guided me to explore avenues which have made such a difference to my career. My brilliant mentors are one of the reasons I love mentoring myself. You can make a huge difference to someone鈥檚 career but also must remember that it's not about trying to mould someone into you, it's trying to help them organise their ideas and find and understand what motivates them so they can take their own path.鈥


Thank you to all the women for taking the time to share their stories and reflections and for providing the information featured on these web pages.