Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
European Radiology
Published in: European Radiology 9/2022

24-03-2022 | Magnetic Resonance Imaging of the Spine | Musculoskeletal

Evaluation of deep learning reconstructed high-resolution 3D lumbar spine MRI

Authors: Simon Sun, Ek Tsoon Tan, Douglas N. Mintz, Meghan Sahr, Yoshimi Endo, Joseph Nguyen, R. Marc Lebel, John A. Carrino, Darryl B. Sneag

Published in: European Radiology | Issue 9/2022

Login to get access

Abstract

Objectives

To compare interobserver agreement and image quality of 3D T2-weighted fast spin echo (T2w-FSE) L-spine MRI images processed with a deep learning reconstruction (DLRecon) against standard-of-care (SOC) reconstruction, as well as against 2D T2w-FSE images. The hypothesis was that DLRecon 3D T2w-FSE would afford improved image quality and similar interobserver agreement compared to both SOC 3D and 2D T2w-FSE.

Methods

Under IRB approval, patients who underwent routine 3-T lumbar spine (L-spine) MRI from August 17 to September 17, 2020, with both isotropic 3D and 2D T2w-FSE sequences, were retrospectively included. A DLRecon algorithm, with denoising and sharpening properties was applied to SOC 3D k-space to generate 3D DLRecon images. Four musculoskeletal radiologists blinded to reconstruction status evaluated randomized images for motion artifact, image quality, central/foraminal stenosis, disc degeneration, annular fissure, disc herniation, and presence of facet joint cysts. Inter-rater agreement for each graded variable was evaluated using Conger’s kappa (κ).

Results

Thirty-five patients (mean age 58 ± 19, 26 female) were evaluated. 3D DLRecon demonstrated statistically significant higher median image quality score (2.0/2) when compared to SOC 3D (1.0/2, p < 0.001), 2D axial (1.0/2, p < 0.001), and 2D sagittal sequences (1.0/2, p value < 0.001). κ ranges (and 95% CI) for foraminal stenosis were 0.55–0.76 (0.32–0.86) for 3D DLRecon, 0.56–0.73 (0.35–0.84) for SOC 3D, and 0.58–0.71 (0.33–0.84) for 2D. Mean κ (and 95% CI) for central stenosis at L4-5 were 0.98 (0.96–0.99), 0.97 (0.95–0.99), and 0.98 (0.96–0.99) for 3D DLRecon, 3D SOC and 2D, respectively.

Conclusions

DLRecon 3D T2w-FSE L-spine MRI demonstrated higher image quality and similar interobserver agreement for graded variables of interest when compared to 3D SOC and 2D imaging.

Key Points

3D DLRecon T2w-FSE isotropic lumbar spine MRI provides improved image quality when compared to 2D MRI, with similar interobserver agreement for clinical evaluation of pathology.
3D DLRecon images demonstrated better image quality score (2.0/2) when compared to standard-of-care (SOC) 3D (1.0/2), p value < 0.001; 2D axial (1.0/2), p value < 0.001; and 2D sagittal sequences (1.0/2), p value < 0.001.
Interobserver agreement for major variables of interest was similar among all sequences and reconstruction types. For foraminal stenosis, κ ranged from 0.55 to 0.76 (95% CI 0.32–0.86) for 3D DLRecon, 0.56–0.73 (95% CI 0.35–0.84) for standard-of-care (SOC) 3D, and 0.58–0.71 (95% CI 0.33–0.84) for 2D.
Literature
1.
McBee MP, Awan OA, Colucci AT et al (2018) Deep learning in radiology. Acad Radiol 25:1472–1480CrossRef
2.
Mazurowski MA, Buda M, Saha A, Bashir MR (2019) Deep learning in radiology: an overview of the concepts and a survey of the state of the art with focus on MRI. J Magn Reson Imaging 49:939–954CrossRef
3.
Rajpurkar P, Irvin J, Zhu K et al (2017) CheXNet: radiologist-level pneumonia detection on chest X-rays with deep learning. arXiv:1711.05225
4.
Castro-Mateos I, Hua R, Pozo JM, Lazary A, Frangi AF (2016) Intervertebral disc classification by its degree of degeneration from T2-weighted magnetic resonance images. Eur Spine J 25:2721–2727CrossRef
5.
Hallinan JTPD, Zhu L, Yang K et al (2021) Deep learning model for automated detection and classification of central canal, lateral recess, and neural foraminal stenosis at lumbar spine MRI. Radiology 300:130–138CrossRef
6.
LewandrowskI K-U, Muraleedharan N, Eddy SA et al (2020) Feasibility of deep learning algorithms for reporting in routine spine magnetic resonance imaging. Int J Spine Surg 14:S86–S97CrossRef
7.
Higaki T, Nakamura Y, Tatsugami F, Nakaura T, Awai K (2019) Improvement of image quality at CT and MRI using deep learning. Jpn J Radiol 37:73–80CrossRef
8.
Chaudhari AS, Fang Z, Kogan F et al (2018) Super-resolution musculoskeletal MRI using deep learning. Magn Reson Med 80:2139–2154CrossRef
9.
Tatsugami F, Higaki T, Nakamura Y et al (2019) Deep learning–based image restoration algorithm for coronary CT angiography. Eur Radiol 29:5322–5329CrossRef
10.
Kidoh M, Shinoda K, Kitajima M et al (2020) Deep learning based noise reduction for brain MR imaging: tests on phantoms and healthy volunteers. Magn Reson Med Sci 19:195–206CrossRef
11.
Hammernik K, Klatzer T, Kobler E et al (2018) Learning a variational network for reconstruction of accelerated MRI data. Magn Reson Med 79:3055–3071CrossRef
12.
Lee S, Jee WH, Jung JY, Lee SY, Ryu KS, Ha KY (2015) MRI of the lumbar spine: comparison of 3D isotropic turbo spin-echo SPACE sequence versus conventional 2D sequences at 3.0 T. Acta Radiol 56:174–181CrossRef
13.
Blizzard DJ, Haims AH, Lischuk AW, Arunakul R, Hustedt JW, Grauer JN (2015) 3D-FSE isotropic MRI of the lumbar spine: novel application of an existing technology. J Spinal Disord Tech 28:152–157CrossRef
14.
Sayah A, Jay AK, Toaff JS, Makariou EV, Berkowitz F (2016) Effectiveness of a rapid lumbar spine MRI protocol using 3D T2-weighted SPACE imaging versus a standard protocol for evaluation of degenerative changes of the lumbar spine. AJR Am J Roentgenol 207:614–620CrossRef
15.
Rodegerdts EA, Boss A, Riemarzik K et al (2006) 3D imaging of the whole spine at 3T compared to 1.5T: initial experiences. Acta Radiol 47:488–493CrossRef
16.
Ristow O, Steinbach L, Sabo G et al (2009) Isotropic 3D fast spin-echo imaging versus standard 2D imaging at 3.0 T of the knee--image quality and diagnostic performance. Eur Radiol 19:1263–1272CrossRef
17.
Carrino JA, Lurie JD, Tosteson AN et al (2009) Lumbar spine: reliability of MR imaging findings. Radiology 250:161–170CrossRef
18.
Schizas C, Theumann N, Burn A et al (2010) Qualitative grading of severity of lumbar spinal stenosis based on the morphology of the dural sac on magnetic resonance images. Spine (Phila Pa 1976) 35:1919–1924CrossRef
19.
Lurie JD, Tosteson AN, Tosteson TD et al (2008) Reliability of readings of magnetic resonance imaging features of lumbar spinal stenosis. Spine (Phila Pa 1976) 33:1605–1610CrossRef
20.
Pfirrmann CW, Metzdorf A, Zanetti M, Hodler J, Boos N (2001) Magnetic resonance classification of lumbar intervertebral disc degeneration. Spine (Phila Pa 1976) 26:1873–1878CrossRef
21.
Weishaupt D, Zanetti M, Boos N, Hodler J (1999) MR imaging and CT in osteoarthritis of the lumbar facet joints. Skelet Radiol 28:215–219CrossRef
22.
Lebel RM (2020) Performance characterization of a novel deep learning-based MR image reconstruction pipeline.
23.
Kim M, Kim HS, Kim HJ et al (2021) Thin-slice pituitary MRI with deep learning-based reconstruction: diagnostic performance in a postoperative setting. Radiology 298:114–122CrossRef
24.
Zochowski KC, Tan ET, Argentieri EC et al (2021) Improvement of peripheral nerve visualization using a deep learning-based MR reconstruction algorithm. Magn Reson Imaging 85:186–192CrossRef
25.
van der Velde N, Hassing HC, Bakker BJ et al (2021) Improvement of late gadolinium enhancement image quality using a deep learning-based reconstruction algorithm and its influence on myocardial scar quantification. Eur Radiol 31:3846–3855CrossRef
26.
Oh CH, Yoon SH (2017) Whole spine disc degeneration survey according to the ages and sex using Pfirrmann disc degeneration grades. Korean J Spine 14:148–154CrossRef
27.
Ishimoto Y, Yoshimura N, Muraki S et al (2013) Associations between radiographic lumbar spinal stenosis and clinical symptoms in the general population: the Wakayama Spine Study. Osteoarthritis Cartilage 21:783–788
28.
Stadnik TW, Lee RR, Coen HL, Neirynck EC, Buisseret TS, Osteaux MJ (1998) Annular tears and disk herniation: prevalence and contrast enhancement on MR images in the absence of low back pain or sciatica. Radiology 206:49–55CrossRef
29.
Weishaupt D, Zanetti M, Hodler J, Boos N (1998) MR imaging of the lumbar spine: prevalence of intervertebral disk extrusion and sequestration, nerve root compression, end plate abnormalities, and osteoarthritis of the facet joints in asymptomatic volunteers. Radiology 209:661–666CrossRef
30.
Schönström N, Hansson T (1988) Pressure changes following constriction of the cauda equina. An experimental study in situ. Spine (Phila Pa 1976) 13:385–388CrossRef
31.
Argentieri EC, Koff MF, Breighner RE, Endo Y, Shah PH, Sneag DB (2018) Diagnostic accuracy of zero-echo time MRI for the evaluation of cervical neural foraminal stenosis. Spine (Phila Pa 1976) 43:928–933CrossRef
32.
Ashby D (1991) Practical statistics for medical research. Douglas G. Altman, Chapman and Hall, London, 1991. No. of pages: 611. Stat Med 10:1635–1636CrossRef
33.
Landis JR, Koch GG (1977) The measurement of observer agreement for categorical data. Biometrics 33:159–174CrossRef
34.
Koontz NA, Wiggins RH 3rd, Mills MK et al (2017) Less is more: efficacy of rapid 3D-T2 SPACE in ED patients with acute atypical low back pain. Acad Radiol 24:988–994CrossRef
35.
Lee S, Lee JW, Yeom JS et al (2010) A practical MRI grading system for lumbar foraminal stenosis. AJR Am J Roentgenol 194:1095–1098CrossRef
Metadata
Title
Evaluation of deep learning reconstructed high-resolution 3D lumbar spine MRI
Authors
Simon Sun
Ek Tsoon Tan
Douglas N. Mintz
Meghan Sahr
Yoshimi Endo
Joseph Nguyen
R. Marc Lebel
John A. Carrino
Darryl B. Sneag
Publication date
24-03-2022
Publisher
Springer Berlin Heidelberg
Published in
European Radiology / Issue 9/2022
Print ISSN: 0938-7994
Electronic ISSN: 1432-1084
DOI
https://doi.org/10.1007/s00330-022-08708-4

Other articles of this Issue 9/2022

European Radiology 9/2022 Go to the issue

Imaging Informatics and Artificial Intelligence

FDG PET/CT radiomics as a tool to differentiate between reactive axillary lymphadenopathy following COVID-19 vaccination and metastatic breast cancer axillary lymphadenopathy: a pilot study

Interventional

Microwave ablation versus parathyroidectomy for the treatment of primary hyperparathyroidism: a cohort study

Imaging Informatics and Artificial Intelligence

Artificial intelligence-based detection of atrial fibrillation from chest radiographs

Magnetic Resonance

Assessment of HCC response to Yttrium-90 radioembolization with gadoxetate disodium MRI: correlation with histopathology

Imaging Informatics and Artificial Intelligence

Radiomics in precision medicine for gastric cancer: opportunities and challenges

Vascular-Interventional

Organ doses and normalized organ doses for various age groups in ultralow dose pediatric C-arm cone-beam CT