Nuclear medicine, Magnetic resonance imaging, Radiology, Angiography and Perfusion are his primary areas of study. His Nuclear medicine study combines topics from a wide range of disciplines, such as Steady-state free precession imaging, Tomography, Mr imaging and Dual energy ct. His study on Magnetic resonance imaging also encompasses disciplines like
His studies examine the connections between Radiology and genetics, as well as such issues in Renal artery stenosis, with regards to Grading. His work in the fields of Mr angiography overlaps with other areas such as Cost effectiveness. He has researched Perfusion in several fields, including Kidney, Gadodiamide, Blood volume and Compartment.
Stefan O. Schoenberg spends much of his time researching Radiology, Nuclear medicine, Magnetic resonance imaging, Internal medicine and Cardiology. In general Radiology study, his work on Angiography, Ultrasound, Stenosis and Magnetic resonance angiography often relates to the realm of Neuroradiology, thereby connecting several areas of interest. His work in Nuclear medicine tackles topics such as Perfusion which are related to areas like Blood volume.
His Magnetic resonance imaging study combines topics in areas such as Renal artery stenosis, Renal function and Pathology. His work on Pulmonary embolism as part of general Internal medicine research is often related to In patient, thus linking different fields of science. Coronary artery disease and Ejection fraction are subfields of Cardiology in which his conducts study.
His main research concerns Radiology, Nuclear medicine, Magnetic resonance imaging, Internal medicine and Cardiology. His work on Ultrasound and Stenosis as part of general Radiology research is frequently linked to Neuroradiology, thereby connecting diverse disciplines of science. The concepts of his Stenosis study are interwoven with issues in Computed tomography angiography and Angiography.
His Nuclear medicine research incorporates elements of Diffusion MRI, Perfusion, Effective diffusion coefficient, Colorectal cancer and Iterative reconstruction. His Magnetic resonance imaging course of study focuses on Ejection fraction and Sampling. His work on Systemic mastocytosis and Pulmonary embolism as part of general Internal medicine study is frequently linked to In patient, therefore connecting diverse disciplines of science.
Stefan O. Schoenberg focuses on Radiology, Nuclear medicine, Magnetic resonance imaging, Internal medicine and Surgery. In his works, Stefan O. Schoenberg conducts interdisciplinary research on Radiology and Neuroradiology. His studies in Nuclear medicine integrate themes in fields like High signal intensity, Diffusion MRI, Angiography and Perfusion.
His Angiography research focuses on Peripheral and how it relates to Pulmonary embolism. His Magnetic resonance imaging research includes elements of Ejection fraction, Urology, Predictive value of tests, Modality and Iterative reconstruction. His Internal medicine research is multidisciplinary, relying on both Gastroenterology, Functional imaging, Medical imaging and Cardiology.
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Measurement of signal‐to‐noise ratios in MR images: Influence of multichannel coils, parallel imaging, and reconstruction filters
Olaf Dietrich;José G. Raya;Scott B. Reeder;Scott B. Reeder;Maximilian F. Reiser.
Journal of Magnetic Resonance Imaging (2007)
MR imaging in patients with suspected liver metastases: value of liver-specific contrast agent Gd-EOB-DTPA.
Christoph J. Zech;Karin A. Herrmann;Maximilian F. Reiser;Stefan O. Schoenberg.
Magnetic Resonance in Medical Sciences (2007)
Autologous Bone Marrow Stem Cell Mobilization Induced by Granulocyte Colony-Stimulating Factor After Subacute ST-Segment Elevation Myocardial Infarction Undergoing Late Revascularization : Final Results From the G-CSF-STEMI (Granulocyte Colony-Stimulating Factor ST-Segment Elevation Myocardial Infarction) Trial
Markus G. Engelmann;Hans D. Theiss;Christine Hennig-Theiss;Armin Huber.
Journal of the American College of Cardiology (2006)
Practical approaches to the evaluation of signal‐to‐noise ratio performance with parallel imaging: Application with cardiac imaging and a 32‐channel cardiac coil
Scott B. Reeder;Bernd J. Wintersperger;Olaf Dietrich;Titus Lanz.
Magnetic Resonance in Medicine (2005)
Diagnostic performance and description of morphological features of focal nodular hyperplasia in Gd-EOB-DTPA-enhanced liver magnetic resonance imaging: results of a multicenter trial.
Christoph J. Zech;Luigi Grazioli;Josy Breuer;Maximilian F. Reiser.
Investigative Radiology (2008)
Whole-Body MRI Versus Whole-Body MDCT for Staging of Multiple Myeloma
Andrea Baur-Melnyk;Sonja Buhmann;Christoph Becker;Stefan Oswald Schoenberg.
American Journal of Roentgenology (2008)
Artifacts in 3-T MRI: physical background and reduction strategies.
Olaf Dietrich;Maximilian F. Reiser;Stefan O. Schoenberg.
European Journal of Radiology (2008)
White matter damage in Alzheimer disease and mild cognitive impairment: assessment with diffusion-tensor MR imaging and parallel imaging techniques.
Robert Stahl;Olaf Dietrich;Stefan J Teipel;Harald Hampel.
Screening for bone metastases: whole-body MRI using a 32-channel system versus dual-modality PET-CT
Gerwin P. Schmidt;Stefan O. Schoenberg;Rupert Schmid;Robert Stahl.
European Radiology (2007)
Measurement of basal forebrain atrophy in Alzheimer's disease using MRI
Stefan J. Teipel;Wilhelm H. Flatz;Helmut Heinsen;Arun L. W. Bokde.
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