Several recommendations have been issued regarding the development and implementation of MRI acquisition protocols (request, performance, and image acquisition) and MRI reports, both for patients with suspected MS and for those with an established diagnosis.14–16,27–29 These protocols establish a common language to facilitate communication between the professionals involved in the diagnosis and follow-up of these patients,26 assisting in their work and minimising the risk of incoherences, errors, or loss of information. Correct interpretation and implementation of protocols requires that the neurologists and neuroradiologists using them participate actively in their development.

Such aspects as the type of sequence or technical parameters of the study may vary according to the available equipment and the experience of the professionals at each centre. However, it is essential that the information included in the MRI request protocol and in radiology reports be approved and validated by a multidisciplinary team, based on the available scientific evidence and expert guidelines.14–16,27–30 To improve the design, implementation, and assessment of these shared protocols, it is essential to establish bilateral communication processes and schedule periodic team meetings. Furthermore, protocols should ideally be available in writing, to ensure that they are readily accessible by all the healthcare professionals involved.

Requests for diagnostic or follow-up MRI studies should include relevant clinical information, given that the results of these studies determine diagnostic and therapeutic decision-making. In clinical practice, MRI request forms submitted by the neurology department do not always include the information required by neuroradiologists (justification for the study,28 missing clinical information, or omission of questions to be addressed). The lack of clinical information negatively impacts the technical planning of the test and the subsequent radiology report29; therefore, the neurologist is responsible for providing the necessary data as completely, as clearly, and as accurately as possible.

To this end, we recommend standardising the minimum information to be included in MRI requests in cases of suspected and established MS (Table 1). This will not only provide the neuroradiologist with the information needed to prioritise and plan the MRI study, but also inform about the reasons for requesting the study and summarise the patient’s clinical status, which will inform the study report.32

Radiology reports vary greatly in terms of structure and the type of information provided by the neuroradiologist. On occasion, reports provide a brief summary of findings that confirm diagnosis or merely inform about an increase in lesion number; this information is insufficient for treatment decision-making. A structured radiology report makes it easier for the neuroradiologist to include information relevant to the neurologist, simplifies reporting of findings for the neuroradiologist, improves communication between both parties, and enables the inclusion of information in a common database for subsequent analysis. There is growing evidence that structured radiology reports provide a greater number of relevant findings in MS, improve comprehension of the data by the neurologist,33,34 and improve the consistency of reports.35 In the light of these benefits, several international expert groups have recommended the implementation of structured radiology reports.14,27,36

Based on the available evidence,14,25,27,36,38 the assessment committee recommends that MRI reports include the minimum radiological information needed to establish a diagnosis of MS (according to the 2017 revised McDonald criteria17) and to plan patient management.14,26,27,32,37 Therefore, reports should include the following: 1) an initial description of radiological findings; 2) parts of the CNS that were examined; 3) type and dose of contrast medium administered; 4) number, size, and location of demyelinating lesions (with and without contrast uptake); 5) description and interpretation of relevant incidental findings; 6) whether findings meet the radiological McDonald criteria for dissemination in time and space; and 7) interpretation of differential radiological and diagnostic findings.

Reports of studies requested for patient follow-up must also include an assessment of any relevant changes with respect to the previous study.

Table 2 presents our proposal for diagnostic and follow-up structured radiology reports.

The quantification of lesion load plays a pivotal role in assessing a patient’s status. On the one hand, the number, size, and location of lesions, together with the number of relapses, demonstrating dissemination in time and space, determines the diagnosis of MS.17 On the other hand, quantification of the number of active lesions (new or growing on T2-weighted images, or displaying contrast uptake) is increasingly important in the follow-up of patients with MS due to the increasing availability of DMTs. The presence of active lesions, a well-known marker of disease progression, is one of the parameters used to determine the presence or absence of disease activity (NEDA, or no evidence of disease activity)38 in patients receiving DMTs. The most frequently used MRI sequences in MS are T2-weighted and T2-FLAIR sequences in studies of the brain, and T2-weighted and STIR sequences for the spinal cord. These sequences are sometimes complemented by gadolinium-enhanced T1-weighted sequences.39 The number or volume of T2 lesions and the number of gadolinium-enhancing lesions predict the progression of disability40,41 and increases in the relapse rate.42

There are inherent difficulties in quantifying the total number of lesions or the number of new or growing T2 lesions, especially when these are small or in patients with a high lesion load. Although automated techniques have been developed to count MS lesions in recent years,43 the most widely used technique in clinical practice is visual analysis, which is subject to great variability.22 Another added difficulty is the lack of a standardised criterion for reporting lesion number, which results in great variability between neuroradiology reports. Some national44 and international guidelines25 propose classifying the number of lesions using ranges.

Table 3 presents our proposal for quantifying the number of brain and spinal T2 lesions in radiology reports. For counts of up to 20 brain lesions or 10 spinal cord lesions, these will be identified visually one by one; for greater numbers, the count will be approximate and expressed as a range. If brain lesions cannot be counted or are confluent with other lesions, or if spinal cord lesions present a diffuse pattern, this information should be indicated in the report.

Radiology departments offer numerous types of MRI studies; the criteria for scheduling one study or another must therefore be unified. The factors affecting MRI scheduling include the time needed to complete the study, the specific MRI protocol, equipment availability, and even the patient’s level of independence. This results in high variability in the time elapsed between the MRI request and performance of the study. We present some recommendations for improving the scheduling of MRI studies.

The use of standard times (typically 20-40 minutes) for all MRI studies is a common practice; however, studies should be scheduled according to the time needed for each patient or type of study. Based on the times proposed by experts from other countries45 and the experience of the members of the assessment committee, we propose estimated minimum times for diagnostic and follow-up MRI studies (Table 4).

To minimise delays caused by the performance of unscheduled (emergency) studies, we propose allocating a pre-established number of appointments for emergency studies based on historical data on the department’s activity. This would enable emergency MRI studies to be performed without delaying previously scheduled appointments.

Effective scheduling must be sufficiently flexible to accommodate unscheduled emergency or priority studies. For example, in patients with typical CIS, a diagnostic MRI study should be performed within a week. To meet this objective, specific time slots should be allocated for these emergency studies.

To optimise the use of the available resources, last-minute changes and cancellations by the patient should be minimised. To this end, a telephone call should be made 24 to 48 hours before the appointment, or an automated appointment reminder system should be implemented.

The same MRI machine and acquisition protocol or the same neuroradiology team should ideally be used to minimise variability between studies and radiology reports.14 Radiologists should also have a high level of experience with and knowledge about MRI, as MRI reports made by radiologists without specific expertise in neuroradiology have shown lower sensitivity and a higher false-negative rate in the detection of new MS lesions than those performed by experienced neuroradiologists.24 This suggests that a neuroradiology team with experience in performing and interpreting MRI studies in patients with MS improves clinical outcomes.

The assessment committee recommends that working teams be stable and in close communication. The activity of neuroradiologists should be organised by neurology subspecialty; this promotes specialisation and participation in research projects. To improve communication between neurologists and neuroradiologists, we recommend appointing “consultant” neuroradiologists based on their experience; these neuroradiologists will answer any questions posed by other specialists. This should be a rotating position, and the appointed neuroradiologists should be readily available through pre-established communication protocols.

As MS is a multidimensional disease, patients require multidisciplinary management. Coordination between all the specialists involved is essential to ensuring appropriate management.26,46,47 The existence of a multidisciplinary committee would ensure that the diagnosis, treatment, and follow-up of these patients meets the required standards. Table 5 includes our recommendations on the functions, responsibilities, and composition of the multidisciplinary team. Together with the specialists included in the support team (Table 5), multidisciplinary teams may include other specialists, according to the patient’s needs.

To contribute to the continuous improvement of the care provided to patients with MS, a management structure should be created to coordinate the neurology and neuroradiology departments. However, this practice is not sufficiently widespread among healthcare centres treating these patients. Establishing liaison sessions between neurologists and neuroradiologists, on the one hand, and the organisation and management team, on the other, may bring numerous improvements, such as sharing relevant information, developing shared protocols, analysing results using indicators, monitoring compliance with quality standards, and scheduling appointments. Table 6 presents the recommendations for liaison sessions established by the assessment committee.

One of the most frequent organisational problems in the hospital setting is the use of informal channels of communication. The use of informal mechanisms not only results in additional time costs for the professionals involved, but also has a detrimental effect on cases in which immediate action is needed.

Establishing formal channels of communication would result in faster, more efficient coordination between professionals. Communication should be automated whenever possible, adapting to each centre’s possibilities. To standardise communication channels, such mechanisms as alert systems, telephone calls, and mobile instant messaging applications may be implemented. Communication should be bilateral, with the receiver sending confirmation of receipt.