2018
Design of a sustainable prepolarizing magnetic resonance imaging system for infant hydrocephalus
Obungoloch J, Harper J, Consevage S, Savukov I, Neuberger T, Tadigadapa S, Schiff S. Design of a sustainable prepolarizing magnetic resonance imaging system for infant hydrocephalus. Magnetic Resonance Materials In Physics, Biology And Medicine 2018, 31: 665-676. PMID: 29644479, PMCID: PMC6135672, DOI: 10.1007/s10334-018-0683-y.Peer-Reviewed Original ResearchMeSH KeywordsBrainCerebrospinal FluidContrast MediaEquipment DesignHumansHydrocephalusInfantMagnetic Resonance ImagingPhantoms, ImagingRadio WavesSignal-To-Noise RatioConceptsLow power requirementsSpatial resolutionLF-MRIModest spatial resolutionMagnetic resonance imaging systemPower requirementsCoil systemImage spatial resolutionUnshielded environmentGradient fieldResonance imaging systemLow costDeployment potentialEnergy supplySpecific applicationsUnshielded roomImaging systemLow-field magnetic resonance imaging
2016
Design of a mobile, homogeneous, and efficient electromagnet with a large field of view for neonatal low-field MRI
Lother S, Schiff S, Neuberger T, Jakob P, Fidler F. Design of a mobile, homogeneous, and efficient electromagnet with a large field of view for neonatal low-field MRI. Magnetic Resonance Materials In Physics, Biology And Medicine 2016, 29: 691-698. PMID: 26861046, PMCID: PMC5695548, DOI: 10.1007/s10334-016-0525-8.Peer-Reviewed Original ResearchConceptsCryogen-free systemField mapping measurementsHigh B0 fieldsLow field devicesLow power consumptionSteel platesLight weightMagnetic resonance imaging systemSimple fabricationNumerical optimization algorithmHomogeneous magnetic fieldPower consumptionElectromagnetResonance imaging systemPower useB0 fieldLow-field scannersMagnetic fieldLow-field MRIField strengthHigh homogeneityMedical applicationsField limitationsLarge fieldMagnets