OHBM Neurosalience S1E16: A critical look at the field of fMRI - A conversation

This podcast idea was precipitated by an editorial that Dimitri Kullmann wrote in Brain about a year ago, causing a stir in the community. It levelled criticism about some aspects of fMRI. Some of it was outdated but some were indeed on point. In this podcast, we had a great discussion on all things fMRI - what it can and cannot measure, and how it can continue to proceed. We also discuss some of the scientific culture surrounding fMRI. Overall, the discussion was useful in bringing some of the flaws as well as some of the outstanding innovations to light. We ended up agreeing that fMRI is in fact, an extremely useful tool that allows penetrating insight into the brain at a specific temporal and spatial scale. We feel that there is still considerable hope yet also a considerable challenge in increasing its clinical relevance.

Guests:

Dr. Dimitri Kullmann is a professor of Neurology at UCL Queen Square Institute of Neurology.

He received his doctorate from the University of Oxford in 1984 and his Bachelor of Medicine/Surgery from the University of London in 1986. He alternated between research in synaptic transmission and postgraduate medical training in London. In 1992, he started his lab at the Institute of Neurology and in 2000, he became a fellow of the Royal College of Physicians.

His interests span the fundamental mechanisms of synaptic transmission, the computational properties of small neuronal circuits, and alterations in neuronal and circuit excitability in epilepsy and other neurological disorders. The core methods in his lab are in vitro electrophysiology and pharmacology, but he also applies confocal and two-photon laser scanning microscopy, computational simulations, molecular genetic methods, and heterologous expression of mutated ion channels.

His laboratory has contributed to the discovery of silent synapses, glutamate spillover, presynaptic GABAA receptors in the cortex, human epilepsy caused by K+ and Ca2+ channel mutations, tonic inhibition in the hippocampus, and Hebbian and anti-Hebbian LTP in hippocampal interneurons.

One of his goals is to understand how phenomena that he has studied at the cellular level interact to regulate the excitability of small neuronal circuits. He is integrating studies on hippocampal circuit function with knowledge of how interneurons and principal cells fire during different behaviours. This is being approached both experimentally and with computational simulations. He also aims to apply his lab's recent insights into the cellular consequences of inherited mutations of ion channels (channelopathies) to develop new ways to diagnose and treat neurological diseases.

He also was editor of the journal, Brain, from 2013 to 2020. He brings to the table the perspective of a clinician neuroscientist who does research at the neuronal scale.

Dr. Vince Calhoun is the director, since 2019, of Translational Research in Neuroimaging and Data Science (TReNDS), which includes three universities: Georgia State, Georgia Tech, and Emory.

In 2002, he received his Ph.D. in Electrical Engineering from the University of Maryland Baltimore County, and then became an assistant clinical professor at Yale, Director of the Medical Image Analysis laboratory Institute of Living, in Hartford. He moved on in 2006 to the University of New Mexico, Albuquerque as an associate professor, and moved up to become a Distinguished Professor at The University of New Mexico and as a leader in various forms of the Mind Research Network in Albuquerque.

Vince is an expert on brain imaging acquisition and analysis and has created numerous algorithms for making sense of complex brain imaging data. He is the creator of the group independent component analysis algorithm, which has become widely used for extracting 'networks' of coherent activity from functional magnetic resonance imaging (fMRI) data. He was also an early innovator in approaches to characterizing the dynamics of brain connectivity. He has also developed techniques to link many different types of data, called 'data fusion' including various types of brain imaging (structural, functional, connectivity) with genomic and epigenomic data. A key focus of Calhoun's work is the development of tools to identify brain imaging markers to help identify and potentially treat various brain disorders including schizophrenia, bipolar disorder, autism, Alzheimer's disease, and many more.

He has recently served as President of the Organization for Human Brain Mapping and has been truly prolific in his work to push the methodology of fMRI.

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