Abstract
Objectives
It is uncertain whether modern iodine-based or gadolinium-based contrast media (CM) administration can lead to increased symptoms in patients with myasthenia gravis.
Methods
A systematic search in Medline was conducted for studies describing the symptomatology of myasthenia gravis patients before and after receiving intravenous (IV) CM and having a matched control group of myasthenia gravis patients who did not receive IV CM.
Results
Three retrospective studies were selected with a total of 374 myasthenia gravis patients who received iodine-based CM and a total of 313 myasthenia gravis patients who underwent unenhanced CT and served as controls. Pooling of the data from the three retrospective studies showed that in 23 of 374 patients, increased symptoms after iodine-based CM administration were described (6.1%). Increased symptomatology also occurred in 11 of 313 patients after unenhanced CT (3.5%). When looking more deeply into the data of the three studies, conflicting results were found, as two articles did not find any relationship between CM and myasthenia gravis symptoms. The remaining study only found a significant increase in symptomatology within 1 day after CT scanning: seven patients (6.3%) in the contrast-enhanced CT group and one patient (0.6%) in the unenhanced CT group (p = 0.01).
Conclusions
There is limited evidence on the relationship between CM and myasthenia gravis symptoms. In the vast majority of myasthenia gravis patients, CM are safe. Probably, in less than 5% of the patients, iodine-based CM administration may lead to increased severity of the symptoms within the first 24 h after administration.
Clinical relevance statement
Be aware that intravenous administration of iodine-based contrast media can lead to an increase of symptoms in patients with myasthenia gravis within the first 24 h. This can probably happen in less than 5% of the patients.
Key Points
• It is unclear whether modern contrast media can lead to increased symptoms in myasthenia gravis patients after intravenous administration.
• There seems to be a small risk of increased myasthenia gravis symptoms within 24 h after intravenous administration of iodine-based contrast media, probably in less than 5% of the administrations.
• Gadolinium-based contrast media are safe for patients with myasthenia gravis.
Avoid common mistakes on your manuscript.
Introduction
Myasthenia gravis is an autoimmune disease in which antibodies bind to acetylcholine receptors or functionally related molecules in the postsynaptic membrane at the neuromuscular junction [1]. These antibodies induce weakness of skeletal muscles, the sole disease manifestation. Patients are defined on the basis of autoimmune and antibody disease mechanisms, target molecules of skeletal muscle, thymic status, genetics, response to therapy, and disease phenotype into seven different subgroups, including the thymoma subgroup, which constitutes 10% of the patients [1]. The annual incidence is eight to ten cases per 1 million persons with a prevalence of 150–250 cases per million, making it the major disease that affects the neuromuscular junction [1].
In the era of ionic high-osmolar contrast media (CM), several case reports and small series without control groups described adverse outcomes and myasthenic crisis in patients with myasthenia gravis who received iodine-based CM [2,3,4,5,6,7,8]. There is also one case report from 1992 on acute deterioration of myasthenia gravis after intravenous administration (IV) of a linear gadolinium-based CM [9]. The possible mechanism of CM leading to myasthenic crisis is unknown, although it has been postulated that CM might interfere with the calcium-mediated acetylcholine release [10].
The question remains whether in the era of non-ionic low- and iso-osmolar iodine-based CM and in the era of more stable cyclic Gd chelates acute deterioration of myasthenia gravis symptoms by CM still exists. Therefore, the European Society of Urogenital Radiology (ESUR) Contrast Media Safety Committee (CMSC) considered it necessary to undertake a systematic review of the available literature about CM and myasthenia gravis in order to provide up-to-date guidance. Special emphasis was to find articles with control groups of myasthenia gravis patients who did not receive IV CM and whose symptoms were recorded for the research period. The results of this review and the following guidelines were extensively discussed by the CMSC academic members and were also reviewed by representatives of the four major contrast media companies (Bayer, Bracco, GE, and Guerbet), who are consultants to the CMSC. Both academic members and representatives had been sent a version of this article for review in advance of the June 2022 meeting. During the meeting, everybody could ask questions and provide suggestions to improve the guidance. The academic members agreed on the final version by consensus. This was achieved at their meeting in June 2022.
Methods
A systematic search in Medline was performed for studies reporting deterioration of myasthenia gravis symptomatology, the preceding administration of CM, and a control group of myasthenia patients who did not receive IV contrast media. A combination of Medical Subject Headings (MeSH) terms contrast media and myasthenia gravis was used. The MeSH term contrast media also encompasses other entry terms such as contrast agent, contrast material, radiocontrast media, radiocontrast agent, and radiopaque media. The MeSH term myasthenia gravis also encompasses other entry terms of clinical and receptor subtypes. A total of 15 articles were found. After reading the title and abstract, articles were selected when they described patients with myasthenia gravis who received IV CM and a control group of myasthenia patients who did not receive CM existed. Based on these criteria, three articles were selected by one reviewer (R.G.), with 24 years of experience in diagnostic radiology. Two articles described retrospective series on myasthenia gravis patients who underwent contrast-enhanced CT (CECT) and a control group of myasthenia gravis patients that underwent CT without contrast [11, 12]. The third article has the same research design, but patients who underwent MRI were also included [13].
Of these three articles, in Medline the similar article option was used. This option creates a list of articles by comparing words from the title, abstract, and Mesh terms using a word-weighted algorithm without the use of filters. This led to 240 additional articles on the article of Somashkehar et al [11], 83 additional articles on the article of Rath et al [12], and 80 additional articles on the article of Mehrizi et al [13]. The titles of all these additional articles were read and if necessary and applicable, the abstract was read by one reviewer (R.G.). This led to three additional papers in the form of recent case reports on this subject [14,15,16]. As literature on myasthenia gravis and CM is limited, these three case reports on three patients were also included, as they provide some additional views on this subject.
Based on the literature and the CMSC consensus, the guideline was graded using the Oxford Centre for Evidence Based Medicine (OCEBM) 2011 evidence classification: level 1: systematic review of randomized trials, level 2: randomized trial, level 3: non-randomized controlled cohort/follow-up study, level 4: case series, case-controlled, or historically controlled studies, level 5: mechanism-based reasoning [17].
Results
Somashekar et al describe 112 myasthenia gravis patients undergoing CECT and 155 myasthenia gravis patients undergoing unenhanced CT in the period 1995–2011 [11]. Statistics were performed with the Mantel–Cox log rank test, chi-square test, or Fisher exact test where appropriate. Comparison of both groups did not show any significant differences when it came to demographics, medical history, myasthenia gravis symptomatology immediately before CT, and medical therapy for myasthenia gravis. There was a significant difference in CT indication, with unenhanced CT being performed more often for acute neuromuscular compromise and CECT being performed more often for acute dyspnea (p = 0.002). In the CECT group, several non-ionic CM were used and the specific type could not be traced in the records in 54 of 112 patients (48%). Disease-related symptom exacerbation within 45 days after the index CT scan occurred in 14 CECT patients (12.5%) and in nine patients (5.8%) in the unenhanced CT group. Both groups had a similar proportion of new or worsening symptoms occurring 2–7 days (p = 0.70) and 8–45 days (p = 0.99) after the index CT. Between 2 and 7 days, this occurred in a total of six patients, three patients in each group. Between 8 and 45 days, this occurred in a total of nine patients, four in the CECT group and five in the unenhanced CT group. However, within the first day after the index CT, the CECT group had a significantly higher rate of acute symptoms (p = 0.01) (6.3% [seven of 112 patients; 95% confidence interval 0.03, 0.12] vs. 0.6% [one of 155 patients; 95% confidence interval 0.0002, 0.04]). Six of seven patients developed new respiratory symptoms; the 7th patient developed progressive weakness. Of the 112 patients in the CECT group, 66 (59%) had stable symptoms, 17 (15%) had deteriorating symptoms, and 29 (26%) had only recently diagnosed with myasthenia gravis. Two patients in the stable group, two in the deteriorating group, and three in the just diagnosed group showed symptom exacerbation within 1 day after CECT. Five of the seven patients received medical therapy at time of the CECT; the other two started with medical therapy after the CT. In the unenhanced CT group of 155 patients, symptoms of 83 (54%) patients were stable, symptoms were deteriorating in 34 (22%) patients, and 38 (25%) patients had been recently diagnosed with myasthenia gravis. The only case of symptom exacerbation happened in the just diagnosed group and this patient had already started medical therapy before the unenhanced CT. The time of onset to exacerbation was significantly shorter in the CECT group (2.5 days) than in the unenhanced CT group (14 days) (p = 0.05). The authors conclude that a significant association between intravenous low-osmolality CM and acute exacerbation within 1 day after administration of myasthenia gravis symptoms exists, with an incremental frequency that is 5–6% above baseline [11].
Rath et al report on 73 myasthenia gravis patients who underwent CECT with low-osmolality CM and 52 patients who underwent unenhanced CT in the period 2005–2015 [12]. Statistics were performed with the Man-Whitney U test, Student’s t test, the chi-square test, or the Fisher exact test where appropriate. Furthermore, univariate and multivariate logistic regression analyses were used to compare the primary endpoint, clinically relevant deterioration of myasthenic symptoms within 30 days of the CT study, between the two groups. The baseline characteristics were well matched between both groups as well as the disease duration, antibody status, and current medical therapy. The two groups differed in the CT indication and body region scanned. Scans of the chest and abdomen were performed more often with CM in comparison with scans of the head and other regions whereas dyspnea and acute, non-neurological symptoms were indications for CECT. At least two different non-ionic low-osmolar CM were used and in 45 of 73 patients (62%), the exact type of CM could not be extracted retrospectively. Nine patients in the CECT group (12.3%) and two patients in the unenhanced CT group (3.8%) had worsening of their symptoms within 30 days of the CT (p = 0.12) (odds ratio 3.52, 95% CI 0.73 17.0) The mean time to worsening was 11.1 days in the CECT group and 13 days in the unenhanced CT group. The medical records of the nine CECT patients were critically reviewed and authors concluded that in none of these patients were CM a likely cause of the deterioration [12].
Mehrizi et al reported on 354 myasthenia gravis patients, of whom 189 underwent CECT, 106 unenhanced CT, 42 CEMRI, and 17 unenhanced MR in the time period 2001–2012 [13]. Two different types of non-ionic low-osmolar CM were used. For MRI, one cyclic Gd chelate or a liver-specific linear Gd chelate was used. One patient from the CECT group reported nausea and vomiting. No worsening of the myasthenia symptoms occurred in any of the groups [13]. This is the only article that addresses gadolinium-based CM and provides the only data that gadolinium-based CM are safe for myasthenia gravis patients. Compared to the other two articles, this article gives a brief description of the patient groups, as no baseline characteristics are described. The demographics of all three studies are summarized in Table 1.
Bonani et al describe a 79-year-old male with suspected myasthenia gravis who underwent a CECT with 200 mL Iohexol 300 mgI/mL [14]. Two hours later, the patient developed acute respiratory failure requiring intubation and ventilation. After 2 days of ventilation, extubation could be performed and the patient was found to have severe muscle weakness in the ear, nose, and throat (ENT) region. While waiting for the acetylcholine-receptor antibody test result, treatment with pyridostigmine was given. This gave a marked improvement in the following 24 h. Later, the acetylcholine-receptor antibody test was positive, confirming myasthenia gravis [14].
A more or less similar case is reported from India [15]. A 41-year-old female with myasthenia gravis and treated with pyridostigmine and prednisolone underwent CECT with 50 mL Iopromide 370 mgI/mL. Immediately thereafter, she developed severe respiratory distress which required intubation and ventilation. She was medically treated with steroids and immunoglobulins and was successfully extubated 3 days later [15].
Recently, a rare case of respiratory failure after a swallow under fluoroscopic guidance of 10 mL of Iohexol resulting in aspiration of contrast into the right main bronchus has been described [16]. This happened to a 48-year-old male patient with myasthenia gravis treated with pyridostigmine, mycophenolate mofetil, and prednisolone. Forty-five minutes after swallowing, the patient had to be intubated and ventilated. A neurologist was consulted and made the diagnosis of myasthenic crisis, probably due to aspiration pneumonitis caused by contrast aspiration. The patient was treated with immunoglobulin and increased doses of his three medications. After 72 h, his respiratory mechanics made remarkable improvement. Due to complications of intubation and ventilation, the patient stayed in the hospital for 18 days [16].
Discussion
The evidence in the literature on CM and myasthenia gravis is limited, as only three retrospective series with control groups have been published. In a recent consensus guideline, iodine-based CM are mentioned as a class of drugs that should be used with caution in myasthenia gravis patients [18]. Three retrospective series have been published describing a total of 374 patients receiving IV contrast and 313 undergoing either unenhanced CT or MRI, serving as a control group. Pooling of the data from these three retrospective studies showed that in 23 of 374 patients, increased symptoms after iodine-based CM administration were described (6.1%). Increased symptomatology also occurred in 11 of 313 patients after unenhanced CT or MRI (3.5%) [11,12,13].
When looking more deeply into the data, one article is a short communication on myasthenia gravis symptoms before and after CM administration and does not provide thorough patient characteristics and statistics of the several groups [13]. This only shows that increased symptoms of myasthenia gravis did not occur after IV administration of both iodine-based and gadolinium-based CM in their retrospective groups.
The other two articles describe patient characteristics and statistics in more detail; thus, their results are stronger evidence [11, 12]. However, their comparability is limited, as they looked at partially different patient characteristics. Somashekar et al recorded myasthenia gravis symptomatology immediately before CT scanning and found no significant difference between the CECT and unenhanced CT group [11]. This is an important parameter in interpreting the data and this is lacking in the article of Rath et al [12]. However, Rath et al recorded antibody status and found no significant difference between their groups [12]. Another important parameter, medication, was recorded by both studies [11, 12]. No significant difference existed in medication in the CECT and unenhanced CT groups in both studies. Somashekar et al looked into a period of 45 days after initial CT scan, Rath et al at a period of 30 days. Moreover, a panel of experts went through the charts of the nine patients with increased symptoms after iodine-based IV CM administration in the study of Rath et al and decided that it was highly unlikely that iodine-based CM were responsible for the deterioration. This expert panel is lacking in the study of Somashekar et al who only recorded symptomatology and did not interpret this in the context of the entire clinical picture [11, 12]. Therefore, the percentage of exacerbations due to iodine-based CM administration may be overestimated in this study.
Both studies had, due to their retrospective nature, difficulties in recording the exact type of CM administrated. The exact type, dose, and administration rate were only available in 48% of the patients in the study of Somashekar et al and in 62% of the study of Rath et al [11, 12]. Somashekar et al state that all patients received one of a variety of low-osmolar CM [11]. The study of Rath et al covered the years 2005–2015; thus, all these patients must have received non-ionic CM. Despite the uncertainty of the precise type of CM used in a large group of included patients, we can be sure that all patients received non-ionic CM, and thus, both studies were included as they match the research criteria.
What remains is the significant difference in exacerbations up to 1 day after CT in the study of Somashekar et al [11]. This occurred in seven patients (6.3%) in the CECT group and in one patient (0.6%) in the unenhanced CT group (p = 0.01). As no expert panel reviewed these charts, we do not know whether this entire 5–6% difference between both groups is attributable to iodine-based CM. The CMSC panel believes that it is likely that this percentage is an overestimate and that with the limited evidence we have, in daily practice, this figure will be below 5%. Furthermore, the limited data show a trend that symptom exacerbation can happen in patients with both stable and deteriorating or recently diagnosed symptomatology and whether patients are being treated with medication for myasthenia gravis does not necessarily prevent an exacerbation.
Two of the three published case reports show that intravenous non-ionic iodine-based CM can cause an exacerbation of myasthenia gravis [14, 15]. In both publications, the increase in symptomatology occurred within minutes to 2 h after IV CM administration, supporting the detected significant increase in exacerbations within 24 h after IV CM administration noted in the paper of Somashekar et al [11, 14, 15]. The last case report describes a very rare case of an acute exacerbation of myasthenia gravis after aspiration of a non-ionic iodinated CM during a swallow study and it is likely that aspiration pneumonitis of any liquid could have caused this [16].
The data on gadolinium-based CM are even more sparse than on iodine-based CM. Mehrizi et al describe in 42 patients with CEMRI versus 17 patients with unenhanced MRI no increased myasthenia gravis symptomatology [13]. Furthermore, only one case report of increased symptoms after administration of a linear gadolinium-based CM has ever been published [9]. No case reports after cyclic gadolinium-based CM exist.
Conclusion
Iodine-based CM can cause an aggravation of myasthenia gravis symptoms, although this is rare. The limited literature on this subject shows that these exacerbations usually occur within the first 24 h after IV CM administration. The exact incidence is unknown, probably below 5%.
Gadolinium-based CM, especially cyclic chelates, are safe for myasthenia gravis patients, according to the only study that has looked at that subject and the lack of more than a single case report on this subject. Further research on this subject, in the form of a prospective study of myasthenia gravis patients undergoing CECT with a matched control group of myasthenia gravis patients who did not receive iodine-based CM, is needed in order to clarify when iodine-based CM in myasthenia gravis patients can result in a higher chance of an exacerbation. Guidelines are proposed (Table 2).
Abbreviations
- CECT:
-
Contrast-enhanced CT
- CEMRI:
-
Contrast-enhanced MRI
- CM:
-
Contrast media
- CMSC:
-
Contrast Media Safety Committee
- IV:
-
Intravenous
- MeSH:
-
Medical Subject Headings
References
Gilhus NE (2016) Myasthenia gravis. N Engl J Med 375:2570–2581
Canal N, Franceschi M (1983) Myasthenic crisis precipitated by iothalamic acid. Lancet 321:1288
Chagnac Y, Hadani M, Goldhammer Y (1985) Myasthenic crisis after intravenous administration of iodinated contrast media. Neurology 35:1219–1220
Anzola GP, Capra R, Magoni M, Vignolo LA (1986) Myasthenic crisis during intravenous iodinated contrast medium injection. Ital J Neurol Sci 7:273
Frank JH, Cooper FJH, Black WC, Philips LH 2nd (1987) Iodinated contrast agents in myasthenia gravis. Neurology 37:1400–1402
Bonmarchand B, Weiss P, Clavier E, Lerebours-Pigeonniere G, Massari P, Leroy J (1987) Myasthenic crisis following the injection of an iodinated contrast medium. Intensive Care Med 13:365
Eliashiv S, Wirguin I, Brenner T, Argov Z (1990) Aggravation of human and experimental myasthenia gravis by contrast media. Neurology 40:1623–1625
de Rocha MS, Bacheschi LA (1994) Exacerbation of myasthenia gravis by contrast media. AJR Am J Roentgenol 162:997
Nordenbo AM, Somnier FE (1992) Acute deterioration of myasthenia gravis after intravenous administration of gadolinium-DTPA. Lancet 340:1168
Van den Bergh P, Kelly JJ Jr, Carter B, Munsat TL (1986) Intravascular contrast media and neuromuscular junction disorders. Ann Neurol 19:206–207
Somashekar DK, Davenport MS, Cohan RH, Dillman JR, Ellis JH (2013) Effect of intravenous low-osmolality iodinated contrast media on patients with myasthenia gravis. Radiology 267:727–734
Rath J, Mauritz M, Zulehner G et al (2017) Iodinated contrast agents in patients with myasthenia gravis: a retrospective cohort study. J Neurol 264:1209–1217
Mehrizi M, Pascuzzi M (2014) Complications of radiologic contrast in patients with myasthenia gravis. Muscle Nerve 50:443–444
Bonanni L, Dalla Vestra M, Zancanaro A, Presotto F (2014) Myasthenia gravis following low-osmolality iodinated contrast media. Case Rep Radiol. https://doi.org/10.1155/2014/963461
Khandelwal A, Shamim R, Supriya (2016) Low – osmolality contrast agents – a risk for myasthenics. Neurol India 64:558–559
Bopeththa BVKM, Hewavithana PB, Hewapathirana HLI, Ralapanawa U (2019) Myasthenic crisis following iodinated contrast material (Iohexol) aspiration: a case report. J Med Case Rep 13:166
Grading using the Oxford Centre for Evidence Based Medicine (OCEBM) evidence classification (2011) Available via https://www.cebm.ox.ac.uk/resources/levels-of-evidence/ocebm-levels-of-evidence. Accessed 21 May 2023
Narayanaswami P, Sanders DB, Wolfe G et al (2021) International consensus guidance for management of myasthenia gravis. 2020 update. Neurology 96:114–122
Acknowledgements
For the Contrast Media Safety Committee.
Funding
The authors state that this work has not received any funding.
Author information
Authors and Affiliations
Consortia
Corresponding author
Ethics declarations
Guarantor
The scientific guarantor of this publication is Dr. Remy Geenen.
Conflict of interest
The authors of this manuscript declare relationships with the following companies:
Remy W. F. Geenen: None
Giles Roditi: None
Marie-France Bellin: None
Michele Bertolotto: None
Torkel B. Brismar: None
Jean-Michel Correas: Bracco Imaging, Guerbet
Ilona A. Dekkers: None
Gertraud Heinz-Peer: None
Andreas H. Mahnken: None
Aart J. van der Molen: Guerbet
Carlo C. Quattrocchi: Bracco Imaging, Guerbet, Bayer Healthcare, GE Healthcare
Alexander Radbruch: None
Peter Reimer: None
Carmen Sebastià: None
Fulvio Stacul: None
Laura Romanini: None
Olivier Clement: Bracco Imaging, Guerbet, Bayer Healthcare
The contrast media companies Bayer, Bracco, GE Healthcare, and Guerbet are consultant to the Contrast Media Safety Committee and participate in all scientific discussions, but are not involved in the final recommendations.
Statistics and biometry
Basic statistics.
Informed consent
Not applicable.
Ethical approval
Not applicable.
Study subjects or cohorts overlap
Not applicable.
Methodology
• retrospective
• observational
• multicenter study
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Geenen, R.W.F., Roditi, G., Bellin, MF. et al. Safe use of contrast media in myasthenia gravis: systematic review and updated European Society of Urogenital Radiology Contrast Media Safety Committee guidelines. Eur Radiol 34, 4561–4566 (2024). https://doi.org/10.1007/s00330-023-10463-z
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00330-023-10463-z