Book of Abstracts – 5th International Symposium on Highfield MR in Clinical Applications

Abstracts (HTML) List of Authors

Adam, G.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T
High resolution small animal imaging with dedicated solenoid coils at a clinical 3T scanner

Block, W.

3T-diffusion tensor tractography and 1H-MR-spectroscopy in motor neuron disease

Blom, K.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Boesch, C.

Intramyocellular lipids (IMCL) and tissue ordering effects observed by 1H-MRSI at 3 Tesla

Born, M.

Pediatric imaging at 3T

Börnert, P.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Boss, A.

Spin-labeling imaging of cerebral perfusion at 1.5 and 3.0 Tesla

Buller, S.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Claussen, C. D.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T
Spin-labeling imaging of cerebral perfusion at 1.5 and 3.0 Tesla

Crawley, A.

Imaging cerebrovascular reactivity using BOLD MRI at 1.5T and 3.0T: comparison of spiral and EPI combined with parallel imaging

Dingemans, H.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Duraj, J.

T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results

Duraj, J. R.

1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Falkenhausen, M. von

Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16

Fenchel, M.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Findeklee, C.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Gawaz, M.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Gieseke, J.

Pediatric imaging at 3T
T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results
Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16
Establishing a comprehensive multiple sclerosis imaging protocol at 7.0T
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Graesslin, I.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes
Send and Receive – what is the potential?

Griswold, M.

Highly accelerated imaging of cardiac function using a 32 channel cardiac phased array at 3 T

Guenther, R. W.

Highly accelerated, millimeter in-plane resolution myocardial perfusion imaging using a 32-channel 3.0 T MR system

Haaker, P.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Hackenbroch, M.

Stress tagging for detection of coronary artery disease at 3 Tesla: Combined stress perfusion and stress tagging protocol

Hadizadeh, D. R.

Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16

Hadozadeh, J.

Establishing a comprehensive multiple sclerosis imaging protocol at 7.0T

Harvey, P.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Heijden, Jvd

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Herrmann, K. A.

MR imaging of the liver on multi-channel MR systems at 1.5 and 3Tesla – Initial experiences

Hirooka, R.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

Hoevelborn, T.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Hoogenraad, F. G.

T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Hoogeveen, R.

Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16

Horst, A.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T

Hurst, G.

Establishing a comprehensive multiple sclerosis imaging protocol at 7.0T

Inoue, T.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

Ith, M.

Intramyocellular lipids (IMCL) and tissue ordering effects observed by 1H-MRSI at 3 Tesla

Ittrich, H.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T
High resolution small animal imaging with dedicated solenoid coils at a clinical 3T scanner

Jaeger, U.

Pediatric imaging at 3T

Jakob, P. M.

Highly accelerated imaging of cardiac function using a 32 channel cardiac phased array at 3 T

Kanbara, Y.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

Kassner, A.

Imaging cerebrovascular reactivity using BOLD MRI at 1.5T and 3.0T: comparison of spiral and EPI combined with parallel imaging

Katscher, U.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Kaul, M.

High resolution small animal imaging with dedicated solenoid coils at a clinical 3T scanner

Kaul, M. G.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T

Keupp, J.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Klose, U.

Spin-labeling imaging of cerebral perfusion at 1.5 and 3.0 Tesla

Klumpp, B.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Kobayashi, M.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

Kouwenhoven, M.

Highly accelerated, millimeter in-plane resolution myocardial perfusion imaging using a 32-channel 3.0 T MR system
Towards distortion-free fMRI using highly accelerated parallel imaging with 32 channels at 3.0 Tesla

Kramer, H.

MRA and perfusion measurements of the kidney at 1.5 and 3.0T

Kramer, U.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Kreis, R.

Intramyocellular lipids (IMCL) and tissue ordering effects observed by 1H-MRSI at 3 Tesla

Kuehl, H. P.

Highly accelerated, millimeter in-plane resolution myocardial perfusion imaging using a 32-channel 3.0 T MR system

Kuhl, C. K.

T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results
Establishing a comprehensive multiple sclerosis imaging protocol at 7.0T
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Lanz, T.

Highly accelerated imaging of cardiac function using a 32 channel cardiac phased array at 3 T
7T phased array head coil for transmission and reception

Laudan, H.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Leussler, C.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Lodemann, K. P.

MRA and perfusion measurements of the kidney at 1.5 and 3.0T

Luedeke, K. M.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Manka, C. A.

T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results
Establishing a comprehensive multiple sclerosis imaging protocol at 7.0T
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Martirosian, P.

Spin-labeling imaging of cerebral perfusion at 1.5 and 3.0 Tesla

Matsumura, Y.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

May, A.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Mens, G.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Meyer, C.

Stress tagging for detection of coronary artery disease at 3 Tesla: Combined stress perfusion and stress tagging protocol
T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Michaely, H. J.

MRA and perfusion measurements of the kidney at 1.5 and 3.0T

Miller, S.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Mollevanger, L.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Müller, M.

7T phased array head coil for transmission and reception

Nägele, T.

Spin-labeling imaging of cerebral perfusion at 1.5 and 3.0 Tesla

Nelles, M.

3T-diffusion tensor tractography and 1H-MR-spectroscopy in motor neuron disease

Niendorf, T.

Highly accelerated, millimeter in-plane resolution myocardial perfusion imaging using a 32-channel 3.0 T MR system
Towards distortion-free fMRI using highly accelerated parallel imaging with 32 channels at 3.0 Tesla

Nijenhuis, M.

Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16

Nishimoto, H.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

Nollau, P.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T

Nolte-Ernsting, C.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T
High resolution small animal imaging with dedicated solenoid coils at a clinical 3T scanner

Ogasawara, K.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

Ogawa, A.

Assessment of cerebral metabolism using magnetic resonance spectroscopy in patients undergoing carotid endarterectomy

Panteleon, A.

MR imaging of the liver on multi-channel MR systems at 1.5 and 3Tesla – Initial experiences

Peldschus, K.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T
High resolution small animal imaging with dedicated solenoid coils at a clinical 3T scanner

Poublanc, J.

Imaging cerebrovascular reactivity using BOLD MRI at 1.5T and 3.0T: comparison of spiral and EPI combined with parallel imaging

Reiser, M. F.

MRA and perfusion measurements of the kidney at 1.5 and 3.0T
MR imaging of the liver on multi-channel MR systems at 1.5 and 3Tesla – Initial experiences

Röschmann, P.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Ruhl, K.

Highly accelerated, millimeter in-plane resolution myocardial perfusion imaging using a 32-channel 3.0 T MR system

Scheef, L.

T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Schick, F.

Spin-labeling imaging of cerebral perfusion at 1.5 and 3.0 Tesla

Schild, H. H.

Pediatric imaging at 3T
Stress tagging for detection of coronary artery disease at 3 Tesla: Combined stress perfusion and stress tagging protocol
T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results
Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16
Establishing a comprehensive multiple sclerosis imaging protocol at 7.0T
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T
3T-diffusion tensor tractography and 1H-MR-spectroscopy in motor neuron disease

Schlorf, T.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T

Schmidt, J.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Schnitker, R.

Towards distortion-free fMRI using highly accelerated parallel imaging with 32 channels at 3.0 Tesla

Schoenberg, S. O.

MRA and perfusion measurements of the kidney at 1.5 and 3.0T
MR imaging of the liver on multi-channel MR systems at 1.5 and 3Tesla – Initial experiences

Scholz, J.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Schumacher, U.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T

Seeger, A.

Intraindividual comparison of myocardial perfusion imaging at 3.0T and 1.5T

Sommer, T.

Pediatric imaging at 3T
Stress tagging for detection of coronary artery disease at 3 Tesla: Combined stress perfusion and stress tagging protocol

Spencer, D.

Highly accelerated, millimeter in-plane resolution myocardial perfusion imaging using a 32-channel 3.0 T MR system

Strach, K.

Stress tagging for detection of coronary artery disease at 3 Tesla: Combined stress perfusion and stress tagging protocol

Swennen, N.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Thomas, D.

Stress tagging for detection of coronary artery disease at 3 Tesla: Combined stress perfusion and stress tagging protocol

Thompson, M.

1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T

Thompson, M. R.

T2* Perfusion Imaging at 7.0 Tesla using 3D PRESTO: Initial results

Tilbian, M.

Towards distortion-free fMRI using highly accelerated parallel imaging with 32 channels at 3.0 Tesla

Traeber, F.

Establishing a comprehensive multiple sclerosis imaging protocol at 7.0T
1H-MR spectroscopy at 7.0 T and intra-individual comparison to 3.0 T and 1.5 T
3T-diffusion tensor tractography and 1H-MR-spectroscopy in motor neuron disease

Urbach, H.

Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16
3T-diffusion tensor tractography and 1H-MR-spectroscopy in motor neuron disease

Utting, J. F.

Towards distortion-free fMRI using highly accelerated parallel imaging with 32 channels at 3.0 Tesla

Vermathen, P.

Intramyocellular lipids (IMCL) and tissue ordering effects observed by 1H-MRSI at 3 Tesla

Vernickel, P.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Vissers, G.

Whole body 3T MRI system with eight parallel RF transmit/receive channels and dual operation modes

Wagener, C.

Antibody-linked superparamagnetic iron oxide particles for detection of tumor cells at 3T

Weckbach, S.

MRA and perfusion measurements of the kidney at 1.5 and 3.0T

Weisser, A.

7T phased array head coil for transmission and reception

Wichmann, T.

Highly accelerated imaging of cardiac function using a 32 channel cardiac phased array at 3 T

Willinek, W. A.

Pediatric imaging at 3T
Contrast-enhanced supraaortic MRA at 3.0T using parallel acquisition with acceleration factors up to 16

Wüllner, U.

3T-diffusion tensor tractography and 1H-MR-spectroscopy in motor neuron disease

Zech, C. J.

MR imaging of the liver on multi-channel MR systems at 1.5 and 3Tesla – Initial experiences