[EXPIRED] The Capital Region of Copenhagen is looking for a Postdoc in mapping brain microstructure and its functional correlates

Postdoc in mapping brain microstructure and its functional correlates

Are you fascinated by modeling tissue microstructure from high quality diffusion MRI acquisitions, exploring its morphological validity against novel 3D histology imaging technologies and investigating its correlates to the communication speed of brain pathways? How does disease impact the microstructure, and can you predict the impact on saltatory conduction velocity along white matter axons? Are you curious if biophysical models or machine learning are the best modeling approaches? Try it out!

Join our diverse research group headed by Professor Tim B. Dyrby at the Danish Research Centre for MR (DRCMR) at Copenhagen University Hospital - Amager and Hvidovre in the Copenhagen area of Denmark. We have all the expertise to leverage your scientific curiosity and develop you as a researcher. Take part to make a difference in predicting how brain diseases impact patients for establishing future diagnostic tools. The research is supported by the European Research Council (ERC) consolidator project “Non-invasive Conduction Velocity Mapping in Brain Networks” - CoM-BraiN. The research will also be carried out at the Department of Applied Mathematics and Computer Science at the Technical University of Denmark (DTU Compute) with access to large scale computing facilities.

Your responsibilities:

To establish machine learning and/or biophysical models for mapping axon morphology and cells in health and disease from diffusion MRI and quantitative MRI acquisitions.
To explore diffusion MRI parameters for obtaining the best model fits using a powerful preclinical MRI scanner or a clinical MRI scanner.
To verify your models via diffusion MRI simulations, validate your models against 3D histology data, and correlate them with functional data.
To actively collaborate and create synergies with group members, i.e., taking part in image analysis and participating in the collection of 3D histology data. We use nanoscopic 3D imaging using large-scale x-ray synchrotron imaging facilities, microscopic imaging using Light-sheet fluorescence Microscopy experiments, and Electron Microscopy. Animal models or tissue samples will be made for you by team members.

Your profile:

You should be a highly motivated open-minded team player with the following qualifications:

Ph.D. degree in MRI physics, computer science or relevant field with a foundation in MRI data modelling.
Interest in experimental MRI techniques. It is a plus if you have experience with preclinical scanner systems but is not a requirement as we will train you.
Proven expertise in biophysical modelling or machine learning models and working with Monte Carlo simulations.
Experience in 3D histology techniques such x-ray synchrotron imaging and Light-Sheet Fluorescence Microscopy (LSFM) is a plus but not a requirement as you will be introduced to this.
Fluency in English writing and scientific communication.
Demonstrated ability to work independently and think critically, while also effectively collaborating and contributing to the research team.

About us:

The project will be carried out at the Danish Research Centre for Magnetic Resonance (DRCMR) which is a leading research centre for biomedical MRI in Europe (www.drcmr.dk). Our mission is to triangulate MR physics and basic physiology from preclinical to clinical research. Approximately 75 researchers from a diverse range of disciplines are currently pursuing basic and clinically applied MR research and its validation with a focus on structural, functional, and metabolic MRI of the human brain and its disorders. The DRCMR is embedded in the Department of Radiology and Nuclear Medicine, a large diagnostic imaging department that houses all biomedical imaging modalities at the Copenhagen University Hospital - Amager and Hvidovre. The hospital has strong collaborative links with the Technical University of Denmark and is part of the newly established organisational framework, The Technical University Hospital of Greater Copenhagen.

The DRCMR has a state-of-the-art MR research infrastructure enabling translational research, which includes a pre-clinical 7T Bruker MR scanner, and six whole-body MR scanners (one 7T, four 3T, and one 1.5T scanners). The DRCMR has high performance computing cluster facilities, pre-clinical labs, a neuropsychology laboratory, an EEG laboratory, and two laboratories for non-invasive brain stimulation.

Our preclinical labs perform basic research in functional, microstructure, and plasticity imaging centred around the 7T Bruker BioSpec MRI system. The preclinical labs include a GMO2-classified virus lab fully equipped with stereotaxic surgery equipment, and electrophysiology facilities. Our cross-disciplinary research team is designing and validating new types of diffusion MRI and quantitative MRI imaging technologies for non-invasively disentangling the microstructure of brain networks and their function. Here, it is key to have a true interest in how the microanatomy and saltatory conduction velocity are related in the normal, and how it impacts brain function in the diseased brain. Our vision is translating our research to clinics to improve future non-invasive imaging technologies for better patient diagnosis.

Your position:

The candidate will be employed for a period of 24 months with the possibility for an extension at the Danish Research Centre for Magnetic Resonance where he/she will be an active part of the Microstructure and Plasticity Group (drcmr.dk/map) and the Preclinical Method group, both led by Professor Tim B. Dyrby.

Recent Publications

Beha GH, Stemmerik MG, Boer VO, van der Ploeg AT, van der Beek NAME, Andersen H, Marsman A, Jacobsen LN, Theunissen MTM, Petersen ET, Vissing J. 2025. Quantification of muscle glycogen distribution in Pompe disease using 7 Tesla 13C NMR spectroscopy. JNNP. Accepted.

Güler S, Zivkovic I, Boer VO, Zhurbenko V, Petersen ET. 2025. The mode of operation of high-impedance coils and shielded coaxial cable coils: A comparative study. NMR Biomed. 38(8): e70071. https://doi.org/10.1002/nbm.70071

London A, Schaufuss A, Povazan M, Dichman M-L, Merhout J, Dirksen C, Madsbad S, Siebner HR, Lundsgaard A, Fritzen AM, Kiens B, Bojsen-Møller KN. 2025. Effects of acute iso- and hypocaloric carbohydrate restriction on liver fat and glucose and lipid metabolism. J Clin Endocrinol Metab. dgaf382, https://doi.org/10.1210/clinem/dgaf382

Güler S, Povazan M, Zhurbenko V, Zivkovic I. 2025. An 8Tx/32Rx head-neck coil at 7T by combining 2Tx/32Rx Noval coil with 6TRx shielded coaxial cable elements. Magn Reson Med. 93(2): 864-872. https://doi.org/10.1002/mrm.30297

Madelung CF, Løkkegaard A, Fuglsang SA, Marques MM, Boer VO, Madsen KH, Hejl A-M, Meder D, Siebner HR. 2025. High-resolution mapping of substantia nigra in Parkinson’s disease using 7 tesla magnetic resonance imaging. Npj Parkinsons Dis. 11(113). https://doi.org/10.1038/s41531-025-00972-7

London A, Richter MM, Sjøberg KA, Wewer Albrechtsen NJ, Povazan M, Drici L, Schaufuss A, Madsen L, Øyen J, Madsbad S, Juul Holst J, van Hall G, Siebner HR, Richter EA, Kiens B, Lundsgaard A, Bojsen-Møller KN. 2024. The impact of short-term eucaloric low- and high-carbohydrate diets on liver triacylglycersol content in males with overweight and obesity: a randomized crossover study. Am J Clin Nutrition. 120(2): 283-293. https://doi.org/10.1016/j.ajcnut.2024.06.006

Madsen MAJ, Povazan M, Wiggermann V, Lundell H, Blinkenberg M, Romme Christensen J, Sellebjerg F, Siebner HR. 2024. Association of cortical lesions with regional glutamate, GABA, N-Acetylaspartate, and Myoinositol levels in patients with multiple sclerosis. Neurology. 103(1): e209543. https://doi.org/10.1212/WNL.0000000000209543

Stærkind H, Jensen K, Müller JH, Boer VO, Polzik ES, Petersen ET. 2024. High-field optical cesium magnetometer for magnetic resonance imaging. PRX Quantum. 5(2): 020320. https://doi.org/10.1103/PRXQuantum.5.020320

Stærkind H, Jensen K, Müller JH, Boer VO, Petersen ET, Polzik ES. 2023. Precision measurement of the excited state Landé g-factor and diamagnetic shift of the Cesium D2 line. Phys Rev X. 13(2): 021036. https://doi.org/10.1103/PhysRevX.13.021036

Boer VO, Pedersen JO, Arango N, Kuang I, Stockmann J, Petersen ET. 2022. Improving brain B0 shimming using an easy and accessible multi-coil shim array at ultra-high field. MAGMA. 35(6): 943-951. https://doi.org/10.1007/s10334-022-01014-6

Andersen M, Laustsen M, Boer V. Accuracy investigations for volumetric head-motion navigators with and without EPI at 7 T. 2022. Magn Reson Med. 88(3): 1198-1211. https://doi.org/10.1002/mrm.29296

Madsen MAJ, Wiggermann V, Marques MFM, Lundell H, Cerri S, Puonti O, Blinkenberg M, Romme Christensen J, Sellebjerg F, Siebner HR. 2022. Linking lesions in sensorimotor cortex to contralateral hand function in multiple sclerosis: a 7 T MRI study. Brain. 145(10): 3522-3535. https://doi.org/10.1093/brain/awac203

Sandström KO, Baltzersen OB, Marsman A, Lemvigh CK, Boer VO, Bojesen KB, Nielsen MØ, Lundell H, Sulaiman DK, Sørensen ME, Fagerlund B, Lahti AC, Syeda WT, Pantelis C, Petersen ET, Glenthøj BY, Siebner HR, Ebdrup BH. 2022. Add-on memantine to dopamine antagonism to improve negative symptoms at first psychosis – the AMEND trial protocol. Front Psychiatry. 13: 889572. https://doi.org/10.3389/fpsyt.2022.889572

Madelung CF, Meder D, Fuglsang SA, Marques MM, Boer VO, Madsen KH, Petersen ET, Hejl A-M, Løkkegaard A, Siebner HR. 2022. Locus coeruleus shows a spatial pattern of structural disintegration in Parkinson’s disease. Movement Disord. 37(3): 479-489. https://doi.org/10.1002/mds.28945

Selected Recent Conference Abstracts

Engel K, Wiggermann V, Ronen I, Lundell H. Correction of phase fluctuations in diffusion-weighted MRS at high b-values with external phantom reference. ISMRM annual meeting. 05/2025,

Madsen MAJ, Christiansen L, Povazan M, Wiggermann V, Siebner HR. Regional glutamate but not GABA concentration scales with TMS-based measures of cortical excitability – a combined 7T MR spectroscopy and TMS study of the human primary motor hand area. Brain Stimulation, Kyoto, Japan, 02/2025 [Brain Stimulation 18(1) 576, 2025]

Madsen MAJ, Wiggermann V, Lundell H, Christiansen L, Romme Christensen J, Blinkenberg M, Sellebjerg F, Siebner HR. The impact of pathway-specific cortical and white matter pathology on trans-callosal conduction and inhibition in multiple sclerosis, ECTRIMS, Copemhagen, Denmark, 09/2024

Madsen MAJ, Wiggermann V, Christiansen L, Povazan M, Lundell H, Puonti O, Romme Christensen J, Sellebjerg F, Siebner HR. The ipsilateral silent period and its link to cortical lesions in multiple sclerosis, Brain Stimulation, Lisbon, Portugal, 02/2023, [Brain Stimulation 14(6) 1628, 2023]

Stemmerik M, Beha G, Boer V, Marsman A, Jacobsen L, Petersen E, Vissing J. 2022. Using high-field magnetic resonance spectroscopy to measure muscle glycogen in patients with McArdle disease. Neuromuscular Disorders. 32. S73-S74.

Beha G, Stemmerik M, Boer V, Marsman A, Jacobsen L, Petersen E, Vissing J. 2022. Quantification of glycogen distribution in late-onset Pompe patients using 7 Tesla C13 NMR spectroscopy. Neuromuscular Disorders. 32. S73.

Madsen MAJ, Wiggermann V, Povazan M, Lundell H, Boer VO, Marsman A, Blinkenberg MB, Romme Christensen J, Sellebjerg FT, Siebner HR. 2022. Linking cortical demyelination to changes in brain metabolism in multiple sclerosis: a 7T MR spectroscopy study. ECTRIMS annual (virtual) meeting.

Güler S, Costa G, Boer V, Paulides M, Baltus P, Petersen E, Zivkovic I. 2022. Shielded coaxial cable coils: the array configuration for maximized central SNR at 7T MRI. Joint Annual Meeting ISMRM-ESMRMB, 31^st annual ISMRM meeting.

Güler S, Zhurbenko V, Zivkovic I, Boer V, Petersen ET. 2022. Second resonance mode ensure intrinsic low coupling between elements on shielded-coaxial-cable coil designs. Joint Annual Meeting ISMRM-ESMRMB, 31^st annual ISMRM meeting.