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DOI: 10.1055/s-0028-1109128
© Georg Thieme Verlag KG Stuttgart · New York
Clinical Application of MRI in Children for the Assessment of Pulmonary Diseases
Klinische Anwendung von MRT zur Untersuchung von Lungenerkrankungen im KindesalterPublication History
received: 10.12.2008
accepted: 22.12.2008
Publication Date:
07 April 2009 (online)
Zusammenfassung
Das diagnostische Routineverfahren für pulmonale Erkrankungen bei Kindern ist die Röntgenübersichtsaufnahme. Dabei handelt es sich um eine schnell durchzuführende und kostengünstige Untersuchung, die einen guten Überblick über die Anatomie und Pathologien zeigt. Bei Patienten mit unklaren Befunden oder wo eine detaillierte Darstellung der Anatomie nötig ist, z. B. vor Interventionen, wird meistens eine Computertomografie durchgeführt. Dieses Verfahren besitzt zwar eine sehr gute Ortsauflösung, aber nur einen schlechten Weichteilkontrast und zudem ist die applizierte Röntgenstrahlung nicht zu unterschätzen. Aktuell steht mit der Magnet-Resonanz-Tomografie (MRT) ein Verfahren zur Verfügung, mit dem sich ebenfalls schnell und zuverlässig Lungenerkrankungen diagnostizieren lassen. Aufgrund des hohen Weichteilkontrasts kann die Diagnose oftmals ohne Kontrastmittelapplikation gestellt werden. Diese Übersichtsarbeit stellt das Routine-Protokoll unserer Klinik vor. Die Anwendung und Ergebnisse wird bei Patienten mit infektiösen Erkrankungen, Patienten mit Immunschwächen, anatomischen Abnormalitäten, erworbenen chronischen Lungenkrankungen und pulmonalen Tumoren demonstriert. Da die MRT vor allem für funktionelle Untersuchungen gut geeignet ist, wird ein Untersuchungsprotokoll für Thoraxdeformitäten vorgestellt. Diese Übersichtsarbeit demonstriert der Einsatz der Lungen-MRT in der klinischen pädiatrischen Routine mit speziellem Bezug zu klinischen Indikationen als strahlenfreie Methode.
Abstract
The standard examination technique for the chest in children is an X-ray examination – it is fast, cheap and provides a good overview of anatomy and pathology. In cases with an unclear pathology or if more details are needed (i. e. pre-therapeutically), computed tomography is most often performed with the well known drawbacks of limited soft tissue contrast and radiation. Radiation should be avoided in children, especially if follow-up examinations are needed. Recent magnetic resonance (MR) techniques allow for fast and reliable assessment of pulmonary diseases in children. Due to the inherent soft tissue contrast, diagnosis can be frequently performed without contrast media application. This review provides an exemplary MR examination protocol for routine application in pediatric patients. The diagnostic value of MRI is shown in patients with infectious diseases, patients with immunodeficiency, anatomic abnormalities, acquired chronic diseases, and pulmonary tumors. Since MRI is especially suitable for functional imaging, an MR protocol is provided for the examination of thoracic deformities. This review summarizes the use of thoracic MRI in the clinical pediatric setting with special focus on the clinical indications as a radiation-free method.
Key words
Pediatric - Lung - thorax - MR imaging - MR perfusion
References
- 1
Brenner D, Elliston C, Hall E. et al .
Estimated risks of radiation-induced fatal cancer from pediatric CT.
Am J Roentgenol.
2001;
176
289-296
MissingFormLabel
- 2
Jong P A, Tiddens H A, Lequin M H. et al .
Estimation of the radiation dose from CT in cystic fibrosis.
Chest.
2008;
133
1289-1291; author reply 1290 – 1291
MissingFormLabel
- 3
Fiel S B, Friedman A C, Caroline D F. et al .
Magnetic resonance imaging in young adults with cystic fibrosis.
Chest.
1987;
91
181-184
MissingFormLabel
- 4
Carr D H, Oades de P, Trotman-Dickenson B. et al .
Magnetic resonance scanning in cystic fibrosis: comparison with computed tomography.
Clin Radiol.
1995;
50
84-89
MissingFormLabel
- 5
Puderbach M, Hintze C, Ley S. et al .
MR imaging of the chest: A practical approach at 1.5T.
Eur J Radiol.
2007;
64
345-355
MissingFormLabel
- 6
Biederer J, Hintze C, Fabel M.
MRI of pulmonary nodules: technique and diagnostic value.
Cancer Imaging.
2008;
8
125-130
MissingFormLabel
- 7
Puderbach M, Eichinger M, Haeselbarth J. et al .
Assessment of morphological MRI for pulmonary changes in cystic fibrosis (CF) patients:
comparison to thin-section CT and chest x-ray.
Invest Radiol.
2007;
42
715-725
MissingFormLabel
- 8
Ley-Zaporozhan J, Ley S, Kauczor H U.
Morphological and functional imaging in COPD with CT and MRI: present and future.
Eur Radiol.
2008;
18
510-521
MissingFormLabel
- 9
Ley S, Zaporozhan J, Arnold R. et al .
Preoperative assessment and follow-up of congenital abnormalities of the pulmonary
arteries using CT and MRI.
Eur Radiol.
2007;
17
151-162
MissingFormLabel
- 10
Ley-Zaporozhan J, Ley S, Kauczor H U.
Proton MRI in COPD.
Copd.
2007;
4
55-65
MissingFormLabel
- 11
Hirokawa Y, Isoda H, Maetani Y S. et al .
MRI artifact reduction and quality improvement in the upper abdomen with PROPELLER
and prospective acquisition correction (PACE) technique.
Am J Roentgenol.
2008;
191
1154-1158
MissingFormLabel
- 12
Puderbach M, Eichinger M, Gahr J. et al .
Proton MRI appearance of cystic fibrosis: Comparison to CT.
Eur Radiol.
2007;
17
716-724
MissingFormLabel
- 13
Hirsch W, Sorge I, Krohmer S. et al .
MRI of the lungs in children.
Eur J Radiol.
2008;
68
278-288
MissingFormLabel
- 14
Eibel R, Herzog P, Dietrich O. et al .
Pulmonary abnormalities in immunocompromised patients: comparative detection with
parallel acquisition MR imaging and thin-section helical CT.
Radiology.
2006;
241
880-891
MissingFormLabel
- 15
Rieger C, Herzog P, Eibel R. et al .
Pulmonary MRI – a new approach for the evaluation of febrile neutropenic patients
with malignancies.
Support Care Cancer.
2008;
16
599-606
MissingFormLabel
- 16
Euler U, Liljestrand G.
Observations on the pulmonary arterial blood pressure in the cat.
Acta Physiol Scand.
1946;
12
301-320
MissingFormLabel
- 17
Gustafsson P M, Aurora P, Lindblad A.
Evaluation of ventilation maldistribution as an early indicator of lung disease in
children with cystic fibrosis.
Eur Respir J.
2003;
22
972-979
MissingFormLabel
- 18
Eichinger M, Puderbach M, Fink C. et al .
Contrast-enhanced 3D MRI of lung perfusion in children with cystic fibrosis-initial
results.
Eur Radiol.
2006;
16
2147-2152
MissingFormLabel
- 19
Allen T C.
Pulmonary Langerhans cell histiocytosis and other pulmonary histiocytic diseases:
a review.
Arch Pathol Lab Med.
2008;
132
1171-1181
MissingFormLabel
- 20
Alavi S, Ashena Z, Paydar A. et al .
Langerhans cell histiocytosis manifesting as recurrent simultaneous bilateral spontaneous
pneumothorax in early infancy.
Pediatr Int.
2007;
49
1020-1022
MissingFormLabel
- 21
Lacronique J, Roth C, Battesti J P. et al .
Chest radiological features of pulmonary histiocytosis X: a report based on 50 adult
cases.
Thorax.
1982;
37
104-109
MissingFormLabel
- 22
Anjorin A, Schmidt H, Posselt H G. et al .
Comparative evaluation of chest radiography, low-field MRI, the Shwachman-Kulczycki
score and pulmonary function tests in patients with cystic fibrosis.
Eur Radiol.
2008;
18
1153-1161
MissingFormLabel
- 23
Toyoda H, Azuma E, Hori H. et al .
Successful unrelated BMT in a patient with Kostmann syndrome complicated by pre-transplant
pulmonary ‘bacterial’ abscesses.
Bone Marrow Transplant.
2001;
28
413-415
MissingFormLabel
- 24
Alibek S, Holter W, Staatz G.
Das strahlensensible Kind: Lungen-MRT bei EBV-induzierter Lymphoproliferation beim
Nijmegen-Breakage-Syndrom.
Röntgenstr Fortschr.
2007;
179
1075-1077
MissingFormLabel
- 25
Findik G, Gezer S, Sirmali M. et al .
Thoracotomies in children.
Pediatr Surg Int.
2008;
24
721-725
MissingFormLabel
- 26
Mutlu H, Basekim C, Silit E. et al .
Gadolinium-Enhanced 3D MRA Findings of Pulmonary Hypoplasia And Aplasia.
Am J Roentgenol.
2006;
187
398-403
MissingFormLabel
- 27
Fenchel M, Greil G F, Martirosian P. et al .
Three-dimensional morphological magnetic resonance imaging in infants and children
with congenital heart disease.
Pediatr Radiol.
2006;
36
1265-1272
MissingFormLabel
- 28
Berrocal T, Madrid C, Novo S. et al .
Congenital anomalies of the tracheobronchial tree, lung, and mediastinum: embryology,
radiology, and pathology.
Radiographics.
2004;
24
e17
MissingFormLabel
- 29
Hakulinen A L, Jarvenpaa A L, Turpeinen M. et al .
Diffusing capacity of the lung in school-aged children born very preterm, with and
without bronchopulmonary dysplasia.
Pediatr Pulmonol.
1996;
21
353-360
MissingFormLabel
- 30
Griscom N T, Wheeler W B, Sweezey N B. et al .
Bronchopulmonary dysplasia: radiographic appearance in middle childhood.
Radiology.
1989;
171
811-814
MissingFormLabel
- 31
Aukland S M, Halvorsen T, Fosse K R. et al .
High-resolution CT of the chest in children and young adults who were born prematurely:
findings in a population-based study.
Am J Roentgenol.
2006;
187
1012-1018
MissingFormLabel
- 32
Mahut B, Blic de J, Emond S. et al .
Chest computed tomography findings in bronchopulmonary dysplasia and correlation with
lung function.
Arch Dis Child Fetal Neonatal Ed.
2007;
92 (06)
F 459-464
MissingFormLabel
- 33
Ochiai M, Hikino S, Yabuuchi H. et al .
A new scoring system for computed tomography of the chest for assessing the clinical
status of bronchopulmonary dysplasia.
J Pediatr.
2008;
152
90-95, 95 e91 – e93
MissingFormLabel
- 34
Ley-Zaporozhan J, Puderbach M, Kauczor H U.
MR for the evaluation of obstructive pulmonary disease.
Magn Reson Imaging Clin N Am.
2008;
16
291-308, ix
MissingFormLabel
- 35
Balassy C, Kulemann V, Hormann M.
Malignant pulmonary tumors in children.
Radiologe.
2008;
48 (10)
955-961
MissingFormLabel
- 36
McCahon E.
Lung tumours in children.
Paediatr Respir Rev.
2006;
7
191-196
MissingFormLabel
- 37
Altman R L, Miller W E, Carr D T. et al .
Radiographic appearance of bronchial carcinoid.
Thorax.
1973;
28
433-434
MissingFormLabel
- 38
Both M, Schultze J, Reuter M. et al .
Fast T 1- and T 2-weighted pulmonary MR-imaging in patients with bronchial carcinoma.
Eur J Radiol.
2005;
53
478-488
MissingFormLabel
- 39
Schroeder T, Ruehm S G, Debatin J F. et al .
Detection of pulmonary nodules using a 2D HASTE MR sequence: comparison with MDCT.
Am J Roentgenol.
2005;
185
979-984
MissingFormLabel
- 40
Hierholzer J, Luo L, Bittner R C. et al .
MRI and CT in the differential diagnosis of pleural disease.
Chest.
2000;
118
604-609
MissingFormLabel
- 41
Kono R, Fujimoto K, Terasaki H. et al .
Dynamic MRI of solitary pulmonary nodules: comparison of enhancement patterns of malignant
and benign small peripheral lung lesions.
Am J Roentgenol.
2007;
188
26-36
MissingFormLabel
- 42
Zou Y, Zhang M, Wang Q. et al .
Quantitative investigation of solitary pulmonary nodules: dynamic contrast-enhanced
MRI and histopathologic analysis.
Am J Roentgenol.
2008;
191
252-259
MissingFormLabel
- 43
Nakagawa Y, Uemura S, Nakaoka T. et al .
Evaluation of the Nuss procedure using pre- and postoperative computed tomographic
index.
J Pediatr Surg.
2008;
43
518-521
MissingFormLabel
- 44
Malek M H, Fonkalsrud E W, Cooper C B.
Ventilatory and cardiovascular responses to exercise in patients with pectus excavatum.
Chest.
2003;
124
870-882
MissingFormLabel
- 45
Herrmann K A, Zech C, Strauss T. et al .
Cine MRI of the thorax in patients with pectus excavatum.
Radiologe.
2006;
46
309-316
MissingFormLabel
Dr. Sebastian Ley
Diagnostische und Interventionelle Radiologie, Universitätsklinik Heidelberg
Im Neuenheimer Feld 430
69120 Heidelberg
Germany
Phone: + + 49/62 21/5 63 82 78
Fax: + + 49/62 21/5 62 998
Email: ley@gmx.de