Project Title: Neurophysiological investigation of brain stimulation via temporally interfering electric fields
Supervisor: Dr Nir Grossman
Location: Burlington Danes Building, Hammersmith Hospital Campus
MRC PhD Studentship
About Me
Charlotte graduated from King's College London with a BSc (Hons) degree in Biomedical Science in 2014, specialising in neuroscience and including a final year project in the MRC centre for Developmental Neurobiology, involving glial degeneration in Drosophila.
In 2015, she completed an internship at the Institute of Neuroscience at Newcastle University, working on an Alzheimer's Society funded project using human brain tissue from Lewy Body Dementia and Parkinson's disease patients.
In 2016/2017, Charlotte studied towards the MRes Experimental Neuroscience at 天美传媒. During the course, she worked on three projects involving non-invasive brain stimulation techniques, optical imaging and immunohistological investigation of neuronal subpopulations involved in sleep and thermoregulation respectively.
In 2017, Charlotte was awarded an MRC funded Studentship and undertook a PhD in non-invasive, targeted bioelectronic brain modulation in the Grossman Lab of the Dementia Research Institute (DRI) at Imperial College. She spent the first year of my PhD gathering data in the Boyden Lab at Massachusetts Institute of Technology, where she was trained in groundbreaking robotic techniques for neurophysiological measurement of brain activity.
She finished her PhD in 2023 and moved onto a postdoc role in California, at Stanford University.
Qualifications
- PhD Clinical Medical Research at 天美传媒, 2017 - 2023
- MRes Experimental Neuroscience from 天美传媒, 2016 - 2017
- BSc Biomedical Science from King’s College London, 2011 - 2014
Research Interests
Deep brain stimulation (DBS) as a means to control neural activity is successfully utilised in the treatment of a multitude of disorders caused by neuronal dysfunction. A major limitation of DBS however, is that it requires an invasive surgery to implant the stimulation electrode, which carries the risk of intraoperative and post-surgical complications, thus greatly limiting the number of reachable patients. On the other hand, non-invasive brain stimulation methods such as transcranial magnetic stimulation (TMS), and transcranial electrical stimulation (TES), involve application of magnetic pulses and electrical current respectively, across the intact scalp and skull. Whilst these techniques are safe and painless, efficacy of treatments have been questioned due to their inability to reach deep brain structures. A recently reported, novel method for non-invasive deep brain stimulation is Temporal Interference (TI) stimulation. This technique has the potential to address the issues described above and become an invaluable tool in medicine. The mechanism of action of TI stimulation is unknown and before widespread adoption can happen however, the focality of the stimulation must be improved to rival DBS. The overarching goal of my research is to facilitate the improvement and clinical adoption of TI stimulation by discovering its underlying physiological mechanism, and I aim to achieve this by utilising a combination of innovative neurophysiological and optical imaging techniques.
Professional memberships
British Neuroscience Association (BNA)
Public Engagement and Fundraising
- Three Peaks Challenge for Mind the Mental Health Charity- September 2017
- Dementia Revolution Volunteer at the London Marathon- April 2019
Contact Details
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