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DOI: 10.1055/s-2006-927203
© Georg Thieme Verlag KG Stuttgart · New York
T2-Relaxationszeit am Patellaknorpel - Globale und regionale Reproduzierbarkeit bei 1,5 Tesla und 3 Tesla
T2 Relaxation Time in Patellar Cartilage - Global and Regional Reproducibility at 1.5 Tesla and 3 TeslaPublikationsverlauf
eingereicht: 6.7.2006
angenommen: 21.9.2006
Publikationsdatum:
29. Januar 2007 (online)
Zusammenfassung
Ziel: Evaluation der globalen und regionalen Reproduzierbarkeit der T2-Relaxationszeit des Patellaknorpels im Vergleich zwischen 1,5 T und 3 T. Material und Methoden: Sechs linksseitige Patellae von sechs jungen gesunden Probanden (Alter 25 - 30, drei weiblich, drei männlich) wurden mit einer fettvorgesättigten Multiecho-TSE-Sequenz und einer T1w-3D-FLASH-Sequenz mit selektiver Wasseranregung bei 1,5 und 3 T untersucht. Es wurden drei konsekutive Datensätze mit Reposition des Knies in Spule und MR-Tomograph zwischen den einzelnen Datensatzakquisitionen in einer MRT-Sitzung erhoben. Nach Überlagerung der Knorpelsegmentation (FLASH-Sequenz) auf die Multiechosequenz, wurden sowohl die T2-Werte für den gesamten Patellaknorpel, 3 horizontale Schichten mit Aufteilung in oberflächliche, intermediäre und tiefe Zone und 3 Facetten mit Aufteilung in mediale, mediane (First) und laterale Facette (globaler T2-Wert) als auch die T2-Werte für je 27 ROIs/MRT-Schicht (regionaler T2-Wert) ausgewertet. Der Reproduzierbarkeitsfehler (Präzisionsfehler) wurde als root mean square average aus den individuellen Standardabweichungen [ms] und Variationskoeffizienten (COV) [%] berechnet. Ergebnisse: Der mittlere Reproduzierbarkeitsfehler für globale T2-Werte lag bei 3,53 % (± 0,38 %) bei 1,5 Tesla bzw. 3,25 % (± 0,61 %) bei 3 Tesla. Der mittlere Reproduzierbarkeitsfehler für regionale T2-Werte lag bei 8,62 % (± 2,61 %) bei 1,5 Tesla bzw. 9,66 % (± 3,37 %) bei 3 Tesla. Bei gleicher räumlicher Auflösung ergab sich kein signifikanter Unterschied für die absoluten Reproduzierbarkeitsfehler zwischen 1,5 T und 3 T. Es zeigten sich jedoch unterschiedliche Reproduzierbarkeitsfehler zwischen den einzelnen Knorpelzonen. Ein Drittel Gesamtvariabilität der Daten konnte auf die unterschiedlichen Knorpelzonen zurückgeführt werden, weitere 10 % zusätzlich auf den Einfluss der einzelnen MRT-Schichten. Schlussfolgerung: Unsere Daten liefern eine Abschätzung von globalen und regionalen Reproduzierbarkeitsfehlern der T2-Relaxationszeit von gesundem Knorpel. Bei der Analyse kleinerer Subregionen muss ein Anstieg des regionalen Reproduzierbarkeitsfehlers in Kauf genommen werden. Die Daten können zur Abschätzung der Kollektivgröße für Studienpopulationen und als Entscheidungshilfe, mit welchem Grad an Detailliertheit eine Auswertung angestrebt werden soll, herangezogen werden.
Abstract
Purpose: Evaluation of the global and regional reproducibility of T2 relaxation time in patellar cartilage at 1.5 T and 3 T. Materials and Methods: 6 left patellae of 6 healthy volunteers (aged 25 - 30, 3 female, 3 male) were examined using a fat-saturated multiecho sequence and a T1-w 3D-FLASH sequence with water excitation at 1.5 Tesla and 3 Tesla. Three consecutive data sets were acquired within one MRI session with the examined knee being repositioned in the coil and scanner between each data set. The segmented cartilage (FLASH sequence) was overlaid on the multiecho data and T2 values were calculated for the total cartilage, 3 horizontal layers consisting of a superficial, intermedial and deep layer, 3 facets consisting of a medial, median (ridge) and lateral facet (global T2 values) and 27 ROIs/MRI slices (regional T2 value). The reproducibility (precision error) was calculated as the root mean square average of the individual standard deviations [ms] and coefficients of variation (COV) [%]. Results: The mean global reproducibility error for T2 was 3.53 % (± 0.38 %) at 1.5 Tesla and 3.25 % (± 0.61 %) at 3 Tesla. The mean regional reproducibility error for T2 was 8.62 % (± 2.61 %) at 1.5 Tesla and 9.66 % (± 3.37 %) at 3 Tesla. There was no significant difference with respect to absolute reproducibility errors between 1.5 Tesla and 3 Tesla at a constant spatial resolution. However, different reproducibility errors were found between the cartilage layers. One third of the data variability could be attributed to the influence of the different cartilage layers, and another 10 % to the influence of the separate MRI slices. Conclusion: Our data provides an estimation of the global and regional reproducibility errors of T2 in healthy cartilage. In the analysis of small subregions, an increase in the regional reproducibility error must be accepted. The data may serve as a basis for sample size calculations of study populations and may contribute to the decision regarding the level of detail of an evaluation of study data.
Key words
cartilage - T2 relaxation time - reproducibility - precision
Literatur
- 1
Eckstein F, Glaser C.
Measuring cartilage morphology with quantitative magnetic resonance imaging.
Semin Musculoskelet Radiol.
2004;
8
329-353
Reference Ris Wihthout Link
- 2
Glaser C.
New techniques for cartilage imaging: T2 relaxation time and diffusion-weighted MR
imaging.
Radiol Clin North Am.
2005;
43
641-653
Reference Ris Wihthout Link
- 3
Mosher T J, Dardzinski B J.
Cartilage MRI T2 relaxation time mapping: overview and applications.
Semin Musculoskelet Radiol.
2004;
8
355-368
Reference Ris Wihthout Link
- 4
Lusse S, Claassen H, Gehrke T. et al .
Evaluation of water content by spatially resolved transverse relaxation times of human
articular cartilage.
Magn Reson Imaging.
2000;
18
423-430
Reference Ris Wihthout Link
- 5
Goodwin D W, Zhu H, Dunn J F.
In vitro MR imaging of hyaline cartilage: correlation with scanning electron microscopy.
AJR Am J Roentgenol.
2000;
174
405-409
Reference Ris Wihthout Link
- 6
Nieminen M T, Rieppo J, Toyras J. et al .
T2 relaxation reveals spatial collagen architecture in articular cartilage: a comparative
quantitative MRI and polarized light microscopic study.
Magn Reson Med.
2001;
46
487-493
Reference Ris Wihthout Link
- 7 Nissi M J. T2 Relaxation Reveals Differences in Spatial Collagen Network Anisotropy in Human,
Bovine and Porcine Articular Cartilage. 11th Scientific Meeting and Exhibition, Abstract No. 54 Toronto; ISMRM 2003
Reference Ris Wihthout Link
- 8
Schäfer F K, Muhle C, Heller M. et al .
Gelenkknorpel in der MR-Tomographie.
Fortschr Röntgenstr.
2001;
173
279-88
Reference Ris Wihthout Link
- 9
Kaufman J H, Regatte R R, Bolinger L. et al .
A novel approach to observing articular cartilage deformation in vitro via magnetic
resonance imaging.
J Magn Reson Imaging.
1999;
9
653-662
Reference Ris Wihthout Link
- 10
Menezes N M, Gray M L, Hartke J R. et al .
T2 and T1rho MRI in articular cartilage systems.
Magn Reson Med.
2004;
51
503-509
Reference Ris Wihthout Link
- 11
Nieminen M T, Toyras J, Laasanen M S at al.
Prediction of biomechanical properties of articular cartilage with quantitative magnetic
resonance imaging.
J Biomech.
2004;
37
321-328
Reference Ris Wihthout Link
- 12
Nieminen M T, Toyras J, Rieppo J. et al .
Quantitative MR microscopy of enzymatically degraded articular cartilage.
Magn Reson Med.
2000;
43
676-681
Reference Ris Wihthout Link
- 13
Watrin-Pinzano A, Ruaud J P, Olivier P. et al .
Effect of proteoglycan depletion on T2 mapping in rat patellar cartilage.
Radiology.
2005;
234
162-170
Reference Ris Wihthout Link
- 14
Wayne J S, Kraft K A, Shields K J. et al .
MR imaging of normal and matrix-depleted cartilage: correlation with biomechanical
function and biochemical composition.
Radiology.
2003;
228
493-499
Reference Ris Wihthout Link
- 15
David-Vaudey E, Ghosh S, Ries M. et al .
T2 relaxation time measurements in osteoarthritis.
Magn Reson Imaging.
2004;
22
673-682
Reference Ris Wihthout Link
- 16
Mlynarik V, Trattnig S, Huber M. et al .
The role of relaxation times in monitoring proteoglycan depletion in articular cartilage.
J Magn Reson Imaging.
1999;
10
497-502
Reference Ris Wihthout Link
- 17
Nissi M J, Toyras J, Laasanen M S. et al .
Proteoglycan and collagen sensitive MRI evaluation of normal and degenerated articular
cartilage.
J Orthop Res.
2004;
22
557-564
Reference Ris Wihthout Link
- 18
Spandonis Y, Heese F P, Hall L D.
High resolution MRI relaxation measurements of water in the articular cartilage of
the meniscectomized rat knee at 4. 7 T.
Magn Reson Imaging.
2004;
22
943-951
Reference Ris Wihthout Link
- 19
Watrin-Pinzano A, Ruaud J P, Cheli Y at al.
T2 mapping: an efficient MR quantitative technique to evaluate spontaneous cartilage
repair in rat patella.
Osteoarthritis Cartilage.
2004;
12
191-200
Reference Ris Wihthout Link
- 20
Frank L R, Wong E C, Luh W M. et al .
Articular cartilage in the knee: mapping of the physiologic parameters at MR imaging
with a local gradient coil - preliminary results.
Radiology.
1999;
210
241-246
Reference Ris Wihthout Link
- 21
Mosher T J, Dardzinski B J, Smith M B.
Human articular cartilage: influence of aging and early symptomatic degeneration on
the spatial variation of T2 - preliminary findings at 3 T.
Radiology.
2000;
214
259-266
Reference Ris Wihthout Link
- 22
Gold G E, Han E, Stainsby J. et al .
Musculoskeletal MRI at 3. 0 T: relaxation times and image contrast.
Am J Roentgenol.
2004;
183
343-351
Reference Ris Wihthout Link
- 23
Baker C L, Ferguson C M.
Future treatment of osteoarthritis.
Orthopedics.
2005;
28
s227-234
Reference Ris Wihthout Link
- 24
Smith G D, Knutsen Jr. G, Richardson J B.
A clinical review of cartilage repair techniques.
J Bone Joint Surg Br.
2005;
87
445-449
Reference Ris Wihthout Link
- 25
Schröder R J, Boack D H, Nekwasil S J. et al .
Diagnostische Wertigkeit der MR-tomographischen Knorpelläsionsdarstellung im Vergleich
mit der intraoperativen Arthroskopie bei Calcaneusfrakturen.
Fortschr Röntgenstr.
2005;
177
367-374
Reference Ris Wihthout Link
- 26
Stork A, Kemper J, Priemel M. et al .
Evaluation experimenteller Knorpeldefekte mit der ultrahochauflösenden Mehrzeilen-CT
im Vergleich zur Histologie.
Fortschr Röntgenstr.
2004;
176
746-751
Reference Ris Wihthout Link
- 27
Gluer C C, Blake G, Lu Y. et al .
Accurate assessment of precision errors: how to measure the reproducibility of bone
densitometry techniques.
Osteoporos Int.
1995;
5
262-270
Reference Ris Wihthout Link
- 28
Liess C, Lusse S, Karger N. et al .
Detection of changes in cartilage water content using MRI T2-mapping in vivo.
Osteoarthritis Cartilage.
2002;
10
907-913
Reference Ris Wihthout Link
- 29 Mosher T J. Reproducibility of In Vivo Cartilage T2 Profiles: Implication for Longitudinal Studies. 9th Scientific Meeting and Exhibition, Abstract No. 2097 Glasgow; ISMRM 2001
Reference Ris Wihthout Link
- 30
Eckstein F, Hudelmaier M, Wirth W. et al .
Double Echo Steady State (DESS) Magnetic Resonance Imaging of Knee Articular Cartilage
at 3 Tesla - a Pilot Study for the Osteoarthritis Initiative.
Ann Rheum Dis.
2006;
65
433-441
Reference Ris Wihthout Link
- 31
Eckstein F, Tieschky M, Faber S C. et al .
Effect of physical exercise on cartilage volume and thickness in vivo: MR imaging
study.
Radiology.
1998;
207
243-248
Reference Ris Wihthout Link
- 32
Mosher T J, Smith H E, Collins C. et al .
Change in knee cartilage T2 at MR imaging after running: a feasibility study.
Radiology.
2005;
234
245-249
Reference Ris Wihthout Link
- 33
Burgkart R, Glaser C, Hyhlik-Durr A. et al .
Magnetic resonance imaging-based assessment of cartilage loss in severe osteoarthritis:
accuracy, precision, and diagnostic value.
Arthritis Rheum.
2001;
44
2072-2077
Reference Ris Wihthout Link
- 34
Glaser C, Faber S, Eckstein F. et al .
Optimization and validation of a rapid high-resolution T1-w 3D FLASH water excitation
MRI sequence for the quantitative assessment of articular cartilage volume and thickness.
Magn Reson Imaging.
2001;
19
177-185
Reference Ris Wihthout Link
- 35
Graichen H, Eisenhart-Rothe von R, Vogl T. et al .
Quantitative assessment of cartilage status in osteoarthritis by quantitative magnetic
resonance imaging: technical validation for use in analysis of cartilage volume and
further morphologic parameters.
Arthritis Rheum.
2004;
50
811-816
Reference Ris Wihthout Link
- 36
Mendlik T, Faber S C, Weber J. et al .
T2 quantitation of human articular cartilage in a clinical setting at 1. 5 T: implementation
and testing of four multiecho pulse sequence designs for validity.
Invest Radiol.
2004;
39
288-299
Reference Ris Wihthout Link
- 37
Poon C S, Henkelman R M.
Practical T2 quantitation for clinical applications.
J Magn Reson Imaging.
1992;
2
541-553
Reference Ris Wihthout Link
- 38
Eckstein F, Reiser M, Englmeier K H. et al .
In vivo morphometry and functional analysis of human articular cartilage with quantitative
magnetic resonance imaging-from image to data, from data to theory.
Anat Embryol.
2001;
203
147-173
Reference Ris Wihthout Link
- 39
Muensterer O J, Eckstein F, Hahn D. et al .
Computer-aided three dimensional assessment of knee-joint cartilage with magnetic
resonance imaging.
Clin Biomech.
1996;
11
260-266
Reference Ris Wihthout Link
- 40
Stammberger T, Eckstein F, Englmeier K H. et al .
Determination of 3D cartilage thickness data from MR imaging: computational method
and reproducibility in the living.
Magn Reson Med.
1999;
41
529-536
Reference Ris Wihthout Link
- 41
Schröder R J, Fischbach F, Unterhauser F N. et al .
Wertigkeit verschiedener MR-Sequenzen bei einer Feldstärke von 1,5- und 3,0 Tesla
für die Analyse von Knorpeldefekten der Patella im Tiermodell.
Fortschr Röntgenstr.
2004;
176
1667-1675
Reference Ris Wihthout Link
- 42
Hohe J, Faber S, Muehlbauer R. et al .
Three-dimensional analysis and visualization of regional MR signal intensity distribution
of articular cartilage.
Med Eng Phys.
2002;
24
219-27
Reference Ris Wihthout Link
- 43
Mosher T J, Collins C M, Smith H E. et al .
Effect of gender on in vivo cartilage magnetic resonance imaging T2 mapping.
J Magn Reson Imaging.
2004;
19
323-328
Reference Ris Wihthout Link
- 44
Van Breuseghem I, Bosmans H T, Elst L V. et al .
T2 mapping of human femorotibial cartilage with turbo mixed MR imaging at 1. 5 T:
feasibility.
Radiology.
2004;
233
609-614
Reference Ris Wihthout Link
- 45
Clark J M.
Variation of collagen fiber alignment in a joint surface: a scanning electron microscope
study of the tibial plateau in dog, rabbit, and man.
J Orthop Res.
1991;
9
246-257
Reference Ris Wihthout Link
- 46
Clark J M, Norman A, Notzli H.
Postnatal development of the collagen matrix in rabbit tibial plateau articular cartilage.
J Anat.
1997;
191
215-221
Reference Ris Wihthout Link
- 47
Mosher T J.
Imaging of rheumatoid arthritis: can MR imaging be used to monitor cellular response
of disease?.
Radiology.
2004;
233
1-2
Reference Ris Wihthout Link
- 48
Dardzinski B J, Mosher T J, Li S. et al .
Spatial variation of T2 in human articular cartilage.
Radiology.
1997;
205
546-550
Reference Ris Wihthout Link
1 C. Glaser und A. Horng haben beide gleichermaßen zum Manuskript beigetragen.
Annie Horng
Institut für Klinische Radiologie, Kliniken der Universität München Großhadern
Marchioninistraße 15
81377 München
Telefon: ++49/89/70 95 36 20
Fax: ++49/89/70 95 88 32
eMail: annie.horng@med.uni-muenchen.de