20 Best Tomography Podcasts of 2021

4 years ago

Are you wanting to learn more about tomography ? Well you’ve come to the right place. This is a curated list of the best tomography podcasts of 2021.

We have selected these podcasts for a variety of reasons, but they are all well worth a listen. We tried to select a variety of podcasts across the spectrum from hosts with a wide breadth of experience.

We are always keen to hear your feedback, if we have missed a podcast, tweet us @MagazineWelp and we will check it out!

Best Tomography Podcasts 2021

With thanks to ListenNotes, Crunchbase, SemRush and Ahrefs for providing the data to create and rank these podcasts.

JCCT Pulse

  • Publisher: Journal of Cardiovascular Computed Tomography (JCCT)
  • Total Episodes: 14

With each new Journal of Cardiovascular Computed Tomography (JCCT) issue, podcast host Kavitha M. Chinnaiyan, MD, FSCCT delivers highlights of key topics through interviews with the authors and subject matter experts. Tune in to stay up-to-date with the latest happenings in the field of Cardiovascular Computed Tomography. Theme music by Jason Lee.

Radiology (Audio)

  • Publisher: UCTV
  • Total Episodes: 23

University of California faculty and researchers explore medical imaging techniques, such as x-rays, computed tomography (CT), and magnetic resonance imaging (MRI), and how they are used.

Donut of Destiny

  • Publisher: SCCT: Society of Cardiovascular Computed Tomography
  • Total Episodes: 17

The Donut of Destiny — a podcast that explores new hot topics in cardiovascular CT. Grab a quick bite of the latest happenings. Created by the Society of Cardiovascular Computed Tomography’s FIRST committee. Thank you Heartflow for their sponsorship. Music by Jason Lee.

SCCT Voice of Technologists’ Podcast

  • Publisher: SCCT Voice of Technologists
  • Total Episodes: 4

The SCCT Voice of Technologists is a podcast for Technologists by Technologists. Episodes will cover relevant and trending topics in cardiovascular computed tomography that will help Technologist expand their skills and better their CCT practices. Join host David Caye, RT as he explores important issues and research in the CCT Technologist field.

Radiology (Video)

  • Publisher: UCTV
  • Total Episodes: 23

University of California faculty and researchers explore medical imaging techniques, such as x-rays, computed tomography (CT), and magnetic resonance imaging (MRI), and how they are used.

Quantum Field Theory with Dr. Rodeny A. Brooks

  • Publisher: Dr. Rodney A. Brooks
  • Total Episodes: 7

Rodney A. Brooks was born in Syracuse, NY, in 1932. He attended the University of Florida and Harvard University, where he received his Ph.D. in physics with Nobel laureate Norman Ramsey in 1963. At that time he was fortunate to learn Quantum Field Theory from its perfector, Nobel laureate Julian Schwinger, who had just published his five-paper series “The theory of quantized fields”, in which matter fields are treated for the first time on an equal basis with force fields. After several years as a post-doc at Harvard, Brooks spent five years working on aerospace projects. Then in 1970 he changed to the field of medical research. This led to a 25-year career at the National Institutes of Health, where he published 124 refereed articles. Among his accomplishments was construction of the highest resolution PET scanner of its time, the “Neuro-PET”. He also invented dual-energy computed tomography (US patent 4247774), a method which has now been incorporated into commercial scanners. As an amateur clarinetist he founded and led a klezmer band called Shir Delite. After moving to New Zealand when he retired, he became aware that the wonderful QFT that he had learned from Schwinger is largely forgotten or misunderstood, leaving the lay public to founder in the weirdness and paradoxes of Quantum Mechanics and Relativity. He then made it his retirement mission to tell the people about QFT – the only theory that makes sense.

Seismology

  • Publisher: Fabio Romanelli (University of Trieste)
  • Total Episodes: 62

The course introduces the key concepts to the comprehension of the modern themes on the generation propagation and analysys of the seismic waves. Topics: Seismic sources (faulting and rupture process; faults and their representation; faults and body forces; the elastodynamic Green function; focal mechanisms). Earthquakes and their measurement (earthquakes and seismometry; earthquakes size and seismometry; intensity and magnitude measurements; viscoelasticity and attenuation). Inversion of seismological data (Inverse Problems; seismic tomography; seismic sources inversion). — NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Eye care – getoct.com – professional messages

  • Publisher: Dr. med. Peter Maloca
  • Total Episodes: 35

OCT-oct. Good eyes for good vision! GETOCT.COM is specialized in Optical Coherence Tomography (OCT), a new laser microscope that carefully examines the eyes. Explore OCT images, films and tutorials and find the latest news about vision, eye diseases and modern eye technology.

Technological Innovation Liliane Bettencourt

  • Publisher: José-Alain Sahel
  • Total Episodes: 2

José-Alain Sahel studied medicine at the Medical School of Paris University and ophthalmology at the University of Strasbourg and at Harvard University (Boston-Cambridge, USA). He was appointed Professor of Ophthalmology at the University Louis Pasteur, Strasbourg. Currently, José-Alain Sahel is Professor of Ophthalmology at Pierre and Marie Curie University Medical School, Paris, France and Cumberlege Professor of Biomedical Sciences at the Institute of Ophthalmology-University College London, UK. He chairs the Departments of Ophthalmology at the Quinze-Vingts National Eye Hospital and at the Rothschild Ophthalmology Foundation (Paris, France). The primary focus of Sahel’s fundamental and clinical research is the understanding of the mechanisms associated with retinal degeneration, together with the conception, development and evaluation of innovative treatments for retinal diseases, with a special focus on genetic rod-cone dystrophies (e.g. neuroprotection, stem cells, gene therapy, pharmacology, and artificial retina). The group of José-Alain Sahel (with Saddek Mohand-Said and Thierry Léveillard) was the first to hypothesize and demonstrate that rod photoreceptors produce a protein that rescues cone photoreceptors, thereby maintaining light-adapted and high-resolution vision. This molecule, Rod-derived Cone Viability Factor (RdCVF), is now in translation into a possible therapeutic agent to save cones and treat a spectrum of retinal degenerative diseases. Once rods and cones have degenerated, optogenetics -a promising novel therapeutic strategy- provides alternative to restore vision. Sahel’s group (with Serge Picaud and Botond Roska at the Friedrich Miescher Institute for Biomedical Research) demonstrated that different retinal cell types such as ‘dormant cones’ can be converted into ‘artificial photoreceptors’ by targeting the expression of genetically encoded light sensors enabling mice with retinal degeneration to perform visually guided behaviors. Besides research on developmental biology, functional genomics, physiology and therapeutics, Sahel’s laboratory (with Michel Paques, Saddek Mohand-Said and Isabelle Audo) conducts research on genotype-phenotype correlations with high resolution in vivo non-invasive high-resolution retinal imaging techniques (optical coherence tomography and adaptive optics) aiming at identifying patients eligible for clinical application of innovative therapies. Together with Mathis Fink (Institut Langevin) he is the principal investigator of a very large ERC-synergy grant aiming at developing novel technologies for morpho-functional imaging of the visual system.

Technological Innovation Liliane Bettencourt

  • Publisher: José-Alain Sahel
  • Total Episodes: 2

José-Alain Sahel studied medicine at the Medical School of Paris University and ophthalmology at the University of Strasbourg and at Harvard University (Boston-Cambridge, USA). He was appointed Professor of Ophthalmology at the University Louis Pasteur, Strasbourg. Currently, José-Alain Sahel is Professor of Ophthalmology at Pierre and Marie Curie University Medical School, Paris, France and Cumberlege Professor of Biomedical Sciences at the Institute of Ophthalmology-University College London, UK. He chairs the Departments of Ophthalmology at the Quinze-Vingts National Eye Hospital and at the Rothschild Ophthalmology Foundation (Paris, France). The primary focus of Sahel’s fundamental and clinical research is the understanding of the mechanisms associated with retinal degeneration, together with the conception, development and evaluation of innovative treatments for retinal diseases, with a special focus on genetic rod-cone dystrophies (e.g. neuroprotection, stem cells, gene therapy, pharmacology, and artificial retina). The group of José-Alain Sahel (with Saddek Mohand-Said and Thierry Léveillard) was the first to hypothesize and demonstrate that rod photoreceptors produce a protein that rescues cone photoreceptors, thereby maintaining light-adapted and high-resolution vision. This molecule, Rod-derived Cone Viability Factor (RdCVF), is now in translation into a possible therapeutic agent to save cones and treat a spectrum of retinal degenerative diseases. Once rods and cones have degenerated, optogenetics -a promising novel therapeutic strategy- provides alternative to restore vision. Sahel‘s group (with Serge Picaud and Botond Roska at the Friedrich Miescher Institute for Biomedical Research) demonstrated that different retinal cell types such as “dormant cones” can be converted into “artificial photoreceptors” by targeting the expression of genetically encoded light sensors enabling mice with retinal degeneration to perform visually guided behaviors. Besides research on developmental biology, functional genomics, physiology and therapeutics, Sahel’s laboratory (with Michel Paques, Saddek Mohand-Said and Isabelle Audo) conducts research on genotype-phenotype correlations with high resolution in vivo non-invasive high-resolution retinal imaging techniques (optical coherence tomography and adaptive optics) aiming at identifying patients eligible for clinical application of innovative therapies. Together with Mathis Fink (Institut Langevin) he is the principal investigator of a very large ERC-synergy grant aiming at developing novel technologies for morpho-functional imaging of the visual system.

Experimental Cognitive Psychology

  • Publisher: Stanislas Dehaene
  • Total Episodes: 26

Stanislas Dehaene received his training in mathematics at the École normale supérieure in Paris, then completed a PhD in cognitive psychology with Jacques Mehler, post-doctoral studies with Michael Posner, as well as neuronal modelling studies with Jean-Pierre Changeux. He has been working since 1997 at the Orsay brain imaging center near Paris (Service Hospitalier Frédéric Joliot of the Commissariat à l’Énergie Atomique), where he directs the Cognitive Neuroimaging Unit since 2001. In September 2005 he was elected as a full professor on the newly created chair of Experimental Cognitive Psychology at the Collège de France in Paris. Stanislas Dehaene’s interests concern the cerebral bases of specifically human cognitive functions such as language, calculation, and reasoning. The team uses a variety of experimental methods, including mental chronometry in normal subjects, cognitive analyses of brain-lesioned patients, and brain-imaging studies with positron emission tomography, functional magnetic resonance imaging, and high-density recordings of event-related potentials. Formal models of minimal neuronal networks are also devised and simulated in an attempt to throw some links between molecular, physiological, imaging, and behavioral data. Stanislas Dehaene’s main scientific contributions include the study of the organization of the cerebral system for number processing. Using converging evidence from PET, ERPs, fMRI, and brain lesions, Stanislas Dehaene demonstrated the central role played by a region of the intraparietal sulcus in understanding quantities and arithmetic (the number sense). He was also the first to demonstrate that subliminal presentations of words can yield detectable cortical activations in fMRI, and has used these data to support an original theory of conscious and nonconscious processing in the human brain. With neurologist Laurent Cohen, he also studied the neural networks of reading and demonstrated the crucial role of the left occipito-temporal region in word recognition (the visual word form area). Stanislas Dehaene is the author of over 100 scientific publications in major international journals. He has received several international prizes including the McDonnell Centennial Fellowship and the Louis D. prize of the French Academy of Sciences (with D. Lebihan). He has published an acclaimed book (The Number Sense), which has been translated in eight languages. He has also edited three books on brain imaging, consciousness, and brain evolution, and has authored two general-audience films on the human brain. He is the associate editor of Cognition, an international journal of Cognitive Science.

Experimental Cognitive Psychology

  • Publisher: Stanislas Dehaene
  • Total Episodes: 26

Stanislas Dehaene received his training in mathematics at the École normale supérieure in Paris, then completed a PhD in cognitive psychology with Jacques Mehler, post-doctoral studies with Michael Posner, as well as neuronal modelling studies with Jean-Pierre Changeux. He has been working since 1997 at the Orsay brain imaging center near Paris (Service Hospitalier Frédéric Joliot of the Commissariat à l’Énergie Atomique), where he directs the Cognitive Neuroimaging Unit since 2001. In September 2005 he was elected as a full professor on the newly created chair of Experimental Cognitive Psychology at the Collège de France in Paris. Stanislas Dehaene’s interests concern the cerebral bases of specifically human cognitive functions such as language, calculation, and reasoning. The team uses a variety of experimental methods, including mental chronometry in normal subjects, cognitive analyses of brain-lesioned patients, and brain-imaging studies with positron emission tomography, functional magnetic resonance imaging, and high-density recordings of event-related potentials. Formal models of minimal neuronal networks are also devised and simulated in an attempt to throw some links between molecular, physiological, imaging, and behavioral data. Stanislas Dehaene’s main scientific contributions include the study of the organization of the cerebral system for number processing. Using converging evidence from PET, ERPs, fMRI, and brain lesions, Stanislas Dehaene demonstrated the central role played by a region of the intraparietal sulcus in understanding quantities and arithmetic (the number sense). He was also the first to demonstrate that subliminal presentations of words can yield detectable cortical activations in fMRI, and has used these data to support an original theory of conscious and nonconscious processing in the human brain. With neurologist Laurent Cohen, he also studied the neural networks of reading and demonstrated the crucial role of the left occipito-temporal region in word recognition (the visual word form area). Stanislas Dehaene is the author of over 100 scientific publications in major international journals. He has received several international prizes including the McDonnell Centennial Fellowship and the Louis D. prize of the French Academy of Sciences (with D. Lebihan). He has published an acclaimed book (The Number Sense), which has been translated in eight languages. He has also edited three books on brain imaging, consciousness, and brain evolution, and has authored two general-audience films on the human brain. He is the associate editor of Cognition, an international journal of Cognitive Science.

Today’s Neuroscience, Tomorrow’s History – Professor Terry Jones

  • Publisher: Professor Terry Jones
  • Total Episodes: 44

Supported by a Wellcome Trust Public Engagement grant (2006-2008) in the History of Medicine to Professor Tilli Tansey (QMUL) and Professor Leslie Iversen (Oxford), the History of Modern Biomedicine Research Group at Queen Mary, University of London presents a series of podcasts on the history of neuroscience featuring eminent people in the field: Professor Terry Jones studied physics and health physics at Birmingham University, graduating with a Masters degree in 1964. In the same year he joined the Medical Research Council (MRC) Cyclotron Unit at Hammersmith Hospital, London, the first hospital-based cyclotron in the world. His career has been in neuro-imaging research, and he produced among the first gamma camera of the brain’s metabolism and blood flow.In 1972 he visited the US where the first Positron Emission Tomography (PET) scanners were being developed by Michel Ter-Pogossian. Professor Jones developed a technique of breathing oxygen-15 (radioactive oxygen), which emits positrons, to image the brain’s regional metabolism a technique which he tried on himself to create the first image. He was responsible for installing one of Britain’s first PET scanners at the Hammersmith Hospital in 1979, where he recruited Richard Frackowiak, among others, to conduct research. His research interests have included looking at the pharmacokinetics of experimental drugs such as temazolomide, developed for brain tumours (gliomas), and imaging serotonergic receptors (the 5HT1A system) in the brain.

Imaging the Body Using Light – Audio

  • Publisher: Dr Adam Gibson
  • Total Episodes: 1

A new approach to medical imaging uses light to generate images both of newborn babies’ brains and of breast cancer. Blood absorbs light strongly and its colour depends on how much oxygen it is carrying, so imaging using light provides a direct measurement of both the volume of blood and its oxygen content. We have used this technique, called optical tomography, to image the blood supply to the brains of both ill and healthy premature babies, and the increased blood flow to cancer in the breast. Optical tomography provides relevant clinical information which may not otherwise be available.

Imaging the Body Using Light – Audio

  • Publisher: UCL
  • Total Episodes: 1

A new approach to medical imaging uses light to generate images both of newborn babies’ brains and of breast cancer. Blood absorbs light strongly and its colour depends on how much oxygen it is carrying, so imaging using light provides a direct measurement of both the volume of blood and its oxygen content. We have used this technique, called optical tomography, to image the blood supply to the brains of both ill and healthy premature babies, and the increased blood flow to cancer in the breast. Optical tomography provides relevant clinical information which may not otherwise be available.

Today’s Neuroscience, Tomorrow’s History – Professor Richard Frackowiak

  • Publisher: Professor Richard Frackowiak
  • Total Episodes: 42

Supported by a Wellcome Trust Public Engagement grant (2006-2008) in the History of Medicine to Professor Tilli Tansey (QMUL) and Professor Leslie Iversen (Oxford), the History of Modern Biomedicine Research Group at Queen Mary, University of London presents a series of podcasts on the history of neuroscience featuring eminent people in the field: Professor Richard Frackowiak was born in London and studied medicine at the University of Cambridge where he first became interested in the neurosciences. He joined the Medical Research Council’s Cyclotron Unit at Hammersmith Hospital, London, in 1979, under Professor Terry Jones, who had just installed one of Britain’s first Positron Emission Tomography (PET) scanners.Professor Frackowiak has always worked in brain imaging and his particular focus has been on determing how the normal brain functions, and how individuals’ activities and environments collaborate to shape their brains. In 1995, as Professor of Cognitive Neurology at UCL’s Institute of Neurology, he established the Functional Imaging Laboratory (now the Wellcome Trust Centre for Neuroimaging), developing new techniques for magnetic resonance imaging (MRI). In a now famous study, Professor Frackowiak and his team showed that in London taxi drivers, there was a connection between an area of the brain – the hippocampus – and their highly developed spatial and navigation skills. The hippocampus had enlarged as a result of navigational experience.The Centre’s current research focuses on how the brain recovers after injury, particularly strokes, and on structural brain characteristics with the aim of improving diagnosis and commencing early therapy in degenerative and devastating neurological diseases such as Huntington’s and Alzheimer’s. Professor Frackowiak has won the IPSEN and Wilhelm Feldberg prizes and during the 1990s was the fourth most highly cited British biomedical scientist. His books include Human Brain Function and Brain Mapping: The Disorders. He is currently setting up a new Clinical Neuroscience Department at the University of Lausanne

Highly Oscillatory Problems: Computation, Theory and Application

  • Publisher: Cambridge University
  • Total Episodes: 156

High oscillation pervades a very wide range of applications: electromagnetics, fluid dynamics, molecular modelling, quantum chemistry, computerised tomography, plasma transport, celestial mechanics, medical imaging, signal processing. It has been addressed by a wide range of mathematical techniques, inter alia from asymptotic theory, harmonic analysis, theory of dynamical systems, theory of integrable systems and differential geometry. The computation of highly oscillatory problems spawned a large number of different numerical approaches and algorithms. The purpose of this programme is to foster research into different aspects of high oscillation – the theoretical, the computational and the applied – from a united standpoint and to promote the synergy implicit in an interdisciplinary activity. Read more at: http://www.newton.ac.uk/programmes/HOP/

Imaging the Body Using Light – Video

  • Publisher: Dr Adam Gibson
  • Total Episodes: 1

A new approach to medical imaging uses light to generate images both of newborn babies’ brains and of breast cancer. Blood absorbs light strongly and its colour depends on how much oxygen it is carrying, so imaging using light provides a direct measurement of both the volume of blood and its oxygen content. We have used this technique, called optical tomography, to image the blood supply to the brains of both ill and healthy premature babies, and the increased blood flow to cancer in the breast. Optical tomography provides relevant clinical information which may not otherwise be available.

Imaging the Body Using Light – Video

  • Publisher: UCL
  • Total Episodes: 1

A new approach to medical imaging uses light to generate images both of newborn babies’ brains and of breast cancer. Blood absorbs light strongly and its colour depends on how much oxygen it is carrying, so imaging using light provides a direct measurement of both the volume of blood and its oxygen content. We have used this technique, called optical tomography, to image the blood supply to the brains of both ill and healthy premature babies, and the increased blood flow to cancer in the breast. Optical tomography provides relevant clinical information which may not otherwise be available.

Today’s Neuroscience, Tomorrow’s History – Professor Terry Jones – Audio

  • Publisher: UCL History of Medicine
  • Total Episodes: 22

Professor Terry Jones studied physics and health physics at Birmingham University, graduating with a Masters degree in 1964. In the same year he joined the Medical Research Council (MRC) Cyclotron Unit at Hammersmith Hospital, London, the first hospital-based cyclotron in the world. His career has been in neuro-imaging research, and he produced among the first gamma camera of the brain’s metabolism and blood flow. In 1972 he visited the US where the first Positron Emission Tomography (PET) scanners were being developed by Michel Ter-Pogossian. Professor Jones developed a technique of breathing oxygen-15 (radioactive oxygen), which emits positrons, to image the brain’s regional metabolism – a technique which he tried on himself to create the first image. He was responsible for installing one of Britain’s first PET scanners – at the Hammersmith Hospital in 1979, where he recruited Richard Frackowiak, among others, to conduct research. His research interests have included looking at the pharmacokinetics of experimental drugs such as temazolomide, developed for brain tumours (gliomas), and imaging serotonergic receptors (the 5HT1A system) in the brain.

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