Biomaterial Database

Comparison of low-field (0.2 Tesla) and high-field (1.5 Tesla) magnetic resonance imaging of the knee joint. 1995

B Kladny, and K Glückert, and B Swoboda, and W Beyer, and G Weseloh

Department of Orthopedics, University of Erlangen, Germany.

In order to evaluate the reliability of low-field magnetic resonance imaging (MRI), we examined 22 patients using a 0.2-Tesla magnet unit in comparison with a 1.5-Tesla system. The MRI findings were compared with the intraoperative findings. Concerning the diagnosis of meniscal tears, the gradings of both systems differed only in three cases. The specificity was 97% (both systems), the sensitivity 83% (1.5 T) versus 75% (0.2 T). The sensitivity and specificity for detection of tears of the anterior cruciate ligament were 100% and 75%, respectively, for both systems. The gradings differed only in two cases. In our series we found 6 full-thickness cartilage defects that were all detected with the high-field imaging system. They were missed by the low-field imaging system in 5 cases. The results suggest that both systems are reliable in diagnosing meniscal tears and ruptures of the anterior cruciate ligament.

UI	MeSH Term	Description	Entries
D007718	Knee Injuries	Injuries to the knee or the knee joint.	Injuries, Knee,Injury, Knee,Knee Injury
D007719	Knee Joint	A synovial hinge connection formed between the bones of the FEMUR; TIBIA; and PATELLA.	Superior Tibiofibular Joint,Joint, Knee,Joint, Superior Tibiofibular,Knee Joints,Superior Tibiofibular Joints,Tibiofibular Joint, Superior
D008279	Magnetic Resonance Imaging	Non-invasive method of demonstrating internal anatomy based on the principle that atomic nuclei in a strong magnetic field absorb pulses of radiofrequency energy and emit them as radiowaves which can be reconstructed into computerized images. The concept includes proton spin tomographic techniques.	Chemical Shift Imaging,MR Tomography,MRI Scans,MRI, Functional,Magnetic Resonance Image,Magnetic Resonance Imaging, Functional,Magnetization Transfer Contrast Imaging,NMR Imaging,NMR Tomography,Tomography, NMR,Tomography, Proton Spin,fMRI,Functional Magnetic Resonance Imaging,Imaging, Chemical Shift,Proton Spin Tomography,Spin Echo Imaging,Steady-State Free Precession MRI,Tomography, MR,Zeugmatography,Chemical Shift Imagings,Echo Imaging, Spin,Echo Imagings, Spin,Functional MRI,Functional MRIs,Image, Magnetic Resonance,Imaging, Magnetic Resonance,Imaging, NMR,Imaging, Spin Echo,Imagings, Chemical Shift,Imagings, Spin Echo,MRI Scan,MRIs, Functional,Magnetic Resonance Images,Resonance Image, Magnetic,Scan, MRI,Scans, MRI,Shift Imaging, Chemical,Shift Imagings, Chemical,Spin Echo Imagings,Steady State Free Precession MRI
D008297	Male		Males
D008592	Menisci, Tibial	The interarticular fibrocartilages of the superior surface of the tibia.	Lateral Menisci,Medial Menisci,Menisci, Lateral,Menisci, Medial,Semilunar Cartilages,Tibial Menisci,Meniscus, Medial,Meniscus, Tibial,Tibial Meniscus,Cartilage, Semilunar,Cartilages, Semilunar,Lateral Meniscus,Medial Meniscus,Meniscus, Lateral,Semilunar Cartilage
D008875	Middle Aged	An adult aged 45 - 64 years.	Middle Age
D005260	Female		Females
D006801	Humans	Members of the species Homo sapiens.	Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D000070598	Anterior Cruciate Ligament Injuries	Sprain or tear injuries to the ANTERIOR CRUCIATE LIGAMENT of the knee.	ACL Injuries,ACL Tears,Anterior Cruciate Ligament Injury,Anterior Cruciate Ligament Tear,Anterior Cruciate Ligament Tears,ACL Injury,ACL Tear,Injuries, ACL,Injury, ACL,Tear, ACL,Tears, ACL
D000070600	Tibial Meniscus Injuries	Injuries to the TIBIAL MENISCUS of the leg.	Bucket Handle Tears,Flap Tears,Tibial Meniscus Tears,Torn Tibial Meniscus,Bucket Handle Tear,Flap Tear,Injuries, Tibial Meniscus,Injury, Tibial Meniscus,Meniscus Injuries, Tibial,Meniscus Injury, Tibial,Meniscus Tear, Tibial,Meniscus Tears, Tibial,Meniscus, Torn Tibial,Tear, Tibial Meniscus,Tears, Flap,Tears, Tibial Meniscus,Tibial Meniscus Injury,Tibial Meniscus Tear,Tibial Meniscus, Torn