nach oben

Erschienen in:

Open Access 03.08.2016 | Magnetic Resonance

Magnetic resonance imaging of pelvic floor dysfunction - joint recommendations of the ESUR and ESGAR Pelvic Floor Working Group

verfasst von: Rania Farouk El Sayed, Celine D. Alt, Francesca Maccioni, Matthias Meissnitzer, Gabriele Masselli, Lucia Manganaro, Valeria Vinci, Dominik Weishaupt, On behalf of the ESUR and ESGAR Pelvic Floor Working Group

Erschienen in: European Radiology | Ausgabe 5/2017

Abstract

Objective

To develop recommendations that can be used as guidance for standardized approach regarding indications, patient preparation, sequences acquisition, interpretation and reporting of magnetic resonance imaging (MRI) for diagnosis and grading of pelvic floor dysfunction (PFD).

Methods

The technique included critical literature between 1993 and 2013 and expert consensus about MRI protocols by the pelvic floor-imaging working group of the European Society of Urogenital Radiology (ESUR) and the European Society of Gastrointestinal and Abdominal Radiology (ESGAR) from one Egyptian and seven European institutions. Data collection and analysis were achieved in 5 consecutive steps. Eighty-two items were scored to be eligible for further analysis and scaling. Agreement of at least 80 % was defined as consensus finding.

Results

Consensus was reached for 88 % of 82 items. Recommended reporting template should include two main sections for measurements and grading. The pubococcygeal line (PCL) is recommended as the reference line to measure pelvic organ prolapse. The recommended grading scheme is the “Rule of three” for Pelvic Organ Prolapse (POP), while a rectocele and ARJ descent each has its specific grading system.

Conclusion

This literature review and expert consensus recommendations can be used as guidance for MR imaging and reporting of PFD.

Key points

• These recommendations highlight the most important prerequisites to obtain a diagnostic PFD-MRI.

• Static, dynamic and evacuation sequences should be generally performed for PFD evaluation.

• The recommendations were constructed through consensus among 13 radiologists from 8 institutions.

Rania Farouk El Sayed and Celine D. Alt share first authorship

Introduction

Imaging of the female pelvic floor is of rising interest due to an ageing population, harboring an increasing incidence of pelvic floor disorders (PFD) and the rising need for comprehensive diagnosis and treatment. The Population Reference Bureau reported the percentage of the population aged 65 and older to be 13 % of the total population in the U.S. in 2010 with an expected increase to 20 % in 2050, whereas in Europe, the percentage was reported around 18 % in 2010 with an expected increase to 28 % in 2050 [1]. Women that are affected by PFD, often complain most about the impairment of their quality of life and ask for sufficient therapy, which is commonly surgical repair [2, 3]. Thus, imaging techniques have been constantly developed in recent years to support therapy planning and management. Magnetic resonance imaging (MRI) of the female pelvic floor, particularly, combines high-resolution images with an excellent soft tissue contrast and provides the possibility to assess noninvasively and more objectively a spectrum of possible disorders affecting the pelvic floor in one examination [4‐7]. There is general agreement that MRI of the pelvic floor should encompass static and dynamic MR images, whereas dynamic means imaging under maximum stress to the pelvic floor and MR defecography. Static MR images visualize pelvic floor anatomy and defects of the supporting structures, while dynamic MR images visualize pelvic organ mobility, pelvic floor weakness, pelvic organ prolapse (POP) and associated compartment defects [5, 8‐11]. Additionally, MRI may diagnose unexpected underlying masked functional abnormalities, which might be discrepant from the dominant symptom and may influence the choice of the surgical technique in around 42 % of patients with different spectra of PFD [12, 13].

Several studies and detailed reviews are published about MRI of the pelvic floor and different acronyms have been used for this examination including static and dynamic MR of the pelvic floor, MR defecography or MR proctography [4, 12, 14‐16]. However, to date, there is neither consensus on a standardized imaging protocol nor on a systematic reporting scheme for MR-imaging of PFD. This may be due to the complexity of the anatomy and the functional interaction of the organs with the supporting structures resulting in a broad spectrum of PFD. Another important factor that contributes to this lack of consensus is the fact that PFD is treated by urologists, urogynecologists or proctologists. Consequently, each clinician may manage the patients’ condition from a different perspective. Therefore, MR-imaging acquisition varies according to the referring specialty and their rudiments for proper management and treatment decision. The wide range of different available MR protocols and a lack of standardization additionally increase variation between different centers. There is, therefore a necessity for recommendations from an expert panel that clearly defines the minimum prerequisites to obtain a state-of-the-art MR examination of the pelvic floor. This paper reports the recommendations of a panel of expert radiologists in pelvic floor imaging, which are joined in the pelvic floor-working group, which is under the umbrella of the European Society of Urogenital Radiology (ESUR) and the European Society of Gastrointestinal and Abdominal Radiology (ESGAR).

Materials and methods

The study went through five basic steps that are displayed in Fig. 1.

Step 1

Member recruitment and data sheet creation

Participants for the working group were recruited among ESUR and ESGAR members between 2010 and 2011. The final working group consisted of 13 radiologists from one Egyptian and seven European institutions, all with known expertise in pelvic floor imaging. One member (RFE) created a data sheet to collect technical protocol details of the members’ institution. This sheet focused on information about the clinical referrer, patient population, patient preparation, and MR technique (hardware, imaging sequence and imaging parameters).

Step 2

Review of imaging protocols of the participating institutions and data sheet creation for literature review

Data collection, review and discussion of all imaging protocols of the participating institutions took place between 2012 and 2013. During this period modifications on the data sheet were implemented by (RFE) in which full details about both the geometry and the contrast of the static and dynamic MRI during straining as well as those of MRI defecography were added to the original data sheet. The results were presented and discussed in a face-to-face meeting during ECR 2014 during which a consensus was reached to finalize the data sheet for literature research (Appendix 1).

Step 3

Literature search, data collection and analysis

Literature search was conducted in the Medline database for articles published between 1993 and 2013 using the following keywords: “MRI AND Pelvic Floor“, “MRI defecography“, “MRI pelvic organ prolapse“, “MRI anal incontinence“, “MRI stress urinary incontinence“, “MRI AND defecography“, “Pelvic obstruction syndrome and MRI“, “Pelvic outlet obstruction and MRI“, “MRI and fecal incontinence“, “Pelvic floor and MRI“, “MRI and urinary incontinence“ and “Pelvic organ prolapse and MRI“.

Inclusion criteria were original data with full information about the parameters and the protocol of the examination that matched with our final data collection sheet for literature review.

Articles that were not written in English, did not deal with a human study population or lack of information about the performance of the examination were excluded.

The papers concerning MRI of PFD were divided by (RFE) into the following subchapters: urinary incontinence (160 articles), pelvic organ prolapse (182 articles) and MR-defecography (172 articles). Paper revision and data extraction was divided among participating members into three subspecialty groups (urology, gynaecology and proctology) with one leader for each group (GM, CDA, DW). Each subspecialty leader wrote a final report summarizing the data that was agreed upon. The collected evidence by this literature analysis was used to extract the relevant topics, which should be addressed by the working group panelists in order to construct a questionnaire.

Step 4

Creation and analysis of a questionnaire

From October 2014 to March 2015, one author (CDA) developed a questionnaire to define the most important information and requisites needed to perform MRI of PFD with standardized imaging protocol and reporting scheme. It was finalized in consensus with one author of ESGAR (DW). Since all panelists are using MR systems with a conventional closed-magnet design where the patient can only be examined in supine (lying) body position, procedural and technical aspects of pelvic floor imaging was focused to this type of magnet design. The questionnaire included binomial, multiple choice, numerical and open questions, in total 89 items (Appendix 2). This questionnaire was mailed to all panelists. In total, 82 of 89 questions were answered by all experts and were scaled according to the individual item in question for further analysis. The data obtained were analyzed using descriptive statistics. Agreement of at least 80 % was defined as consensus finding.

Step 5

Discussion and voting for the final consensus recommendations

The second face-to-face meeting took place during ECR congress in 2015. For those questions that did not reach consensus at the first round of the questionnaire analysis, wording was modified to obtain better-defined statements subjected for voting by the experts in a face-to-face meeting. During that meeting the panelists discussed those items and were asked to vote. However, there were items that did not reach consensus but were reported by number of panelist to be important and warrants being included in the recommendations. These items were re-analyzed, and those that were found to be supported by case control or cohort studies from the literature, in particular level of evidence 2 according to the sign criteria, whereas expert opinion is level of evidence 4 (www.sign.ac.uk), were also included in the final recommendation.

Results

Consensus was reached for 88 % of 82 items and the recommendations regarding indication, patient preparation, imaging protocol, criteria for MRI assessment and reporting were constructed from these.

Indications for MR imaging of pelvic floor dysfunction

The indications for MR imaging of the pelvic floor that scored the highest number of agreement among the group members and the literature review are rectal outlet obstruction (92 % agreed upon), rectocele (92 % agreed upon), recurrent pelvic organ prolapse (POP) (85 % agreed upon), enterocele (85 % agreed upon) and dyssynergic defecation (anismus)(85 % agreed upon) (Table 1).

Table 1

Most common indications for MR-imaging of pelvic floor dysfunction*

Indications	Score of agreement achieved**
Anterior compartment
Stress urinary incontinence	7/13
Recurrence after surgical POP repair	7/13
Middle compartment
Recurrence after surgical POP repair	11/13
Enterocele / Peritoneocele	11/13
POP	7/13
Posterior compartment
Outlet obstruction	12/13
Rectocele	12/13
Anismus	11/13
Fecal incontinence	10/13
Recurrence after surgical POP repair	9/13
Rectal intussusception	8/13
Non-specific compartment
Pelvic pain / perineal pain	7/13
Descending perineal syndrome	7/13

POP pelvic organ prolapse

* The indications of MRI in each compartment are listed in a descending order from those that scored the highest number of agreement among both the group members and the literature review

** Number of group members n = 13

Patients’ preparation and hardware requirements

Full patients’ history of pelvic floor disorder should be taken prior to scanning (consensus 100 %). The patient should be examined at least in a 1.5 T MRI unit with a phased array coil, as this is the most agreed-upon field strength (consensus 100 %). The patient is examined in the supine position with the knees elevated (e.g. on a pillow with firm consistency) as this was found to facilitate straining and evacuation (consensus 100 %). The coil should be centered low on the pelvis to ensure complete visualization of prolapsed organs [4, 15]. The bladder should be moderately filled, therefore voiding 2 hours before the examination is recommended (consensus 100 %).

Prior to the examination the patient should be trained on how to correctly perform the dynamic phases of the examination and the evacuation phase (consensus 100 %). The patient is instructed to squeeze as if trying to prevent the escape of urine or feces and hold this position for the duration of the sequence. For maximum straining, the patient is instructed to bear down as much as she/he could, as though she/he is constipated and is trying to defecate [15]. For the evacuation phase, the patient should be instructed to repeat the evacuation process until the rectum is emptied.

To decrease possible patient’s discomfort, a protective pad or a diaper pant should be offered to the patient, which helps to increase patients’ compliance during dynamic and evacuation phases (consensus 100 %). No oral or intravenous contrast is necessary [15].

The rectum should be distended in order to visualize the anorectal junction (ARJ), rectoceles and intussusceptions, and to evaluate the efficacy of rectal evacuation (consensus 100 %). Ultrasound gel is the recommended medium to distend the rectum, however, the amount varies between 120 to 250 cc (consensus 100 %). For rectal distension a large amount of gel (180-200 cc) likely improves the capacity of the patient to defecate. A checklist for the recommended patients’ preparation is listed in (Table 2).

A rectal cleansing enema prior to the examination is helpful but reached no consensus to be generally performed. Vaginal filling with 20 cc ultrasound gel is helpful for better demarcation, however, it reached no consensus for general performance and its application may be limited due to social or religious backgrounds.

Table 2

Checklist for the recommended patients’ preparation and MR-Imaging protocols

https://static-content.springer.com/image/art%3A10.1007%2Fs00330-016-4471-7/MediaObjects/330_2016_4471_Tab2_HTML.gif

BSFP balanced state free precession, FSE fast spin echo, RARE rapid acquisition with relaxation enhancement, SSFP steady state free precession, TSE turbo spin echo

* Level of evidence 2 = based on systematic reviews, case control or cohort studies; Level of evidence 4 = based on expert opinion (www.sign.ac.uk)

MR-imaging protocol

The recommended MR-imaging protocol is summarized in (Table 3). The protocols consists of static MR sequences and dynamic sequences, whereas dynamic means imaging during straining, squeezing and during evacuation or defecation.

Table 3

Recommended MR-imaging protocols

Plane		Sequence	Technique	TE (ms)	TR (ms)	ST (mm)	FOV (mm)	Matrix	Angulation	Number of slices	Level of evidence*
Static MRI sequences 2D MRI
	Sagittal	T2WI	Turbo/fast spin echo	77-132	500-4210	4	200-300	256-448	Midsagittal	23	2
	Transverse	T2WI	Turbo/fast spin echo	88-132	500-7265	4	200-300	256-512	Perpendicular to the urethra	25	2
	Coronal	T2WI	Turbo/fast spin echo	80-132	500-7265	4	200-260	256-512	parallel to the urethra	26	2
Dynamic MR sequences
Squeezing
	Sagittal	T2WI	GE, FFE	1.27-1.88	3.3-397.4	8	250-310	126-280	Midsagittal	1 or 3	2
Straining
	Sagittal	T2WI	GE, FFE	1.27-1.88	3.3-397.4	8	250-310	126-280	Midsagittal	1 or 3	2
optional ^a	Transverse	T2WI	GE, FFE	1.6-80	5.0-1200	5 or 6	250-310	126-280	Perpendicular to the urethra	5	2
optional ^b	Coronal	T2WI	GE, FFE	1.6	5	5 or 6	300	256	Parallel to the urethra	5	2
MR-Defecography
	sagittal	T2w	GE, FFE	1.27-1.88	3.3-397.4	8	250-310	168-280	Midsagittal	1 or 3	2
optional ^c	coronal	T2w	GE, FFE	1.27-1.6	5-397	4 or 8	257-350	154-256	Parallel to anorectum	5	2

FFE fast field echo, FOV field of view, GE gradient echo, ST slice thickness, 2D two-dimensional, TE time of echo, TR time of repetition, T2WI T2-weighted

^aTechnique was reported by 3/8 experts and is supported by reference [15, 21]

^bTechnique was reported by 3/8 experts and is supported by reference [15, 21]

^cTechnique was reported by 3/8 experts and is supported by reference [22]

* Level of evidence 2 = based on systematic reviews, case control or cohort studies; Level of evidence 4 = based on expert opinion (www.sign.ac.uk)

According to the concordance of experts and level of evidence, high resolution T2-weighted images (T2WI) (e.g. Turbo Spin Echo, TSE ; Fast Spin Echo, FSE; Rapid Acquisition with Relaxation Enhancement, RARE) in three planes are recommended for static images, whereas steady state (e.g. FISP, GRASS, FFE, PSIF, SSFP, T2-FFE) or balanced state free precession sequence (e.g. trueFISP, FIESTA, B-FFE) in sagittal plane is recommended for dynamic sequences (squeezing and straining) and evacuation sequence (consensus 100 %). The dynamic sequence should not exceed 20 seconds each, as breath holding is required (consensus 100 %). The evacuation sequence should be repeated until the rectum is emptied to exclude rectal intussusception (total time duration around 2-3 minutes)(consensus 100 %). Dynamic MR imaging during evacuation is mandatory, because certain abnormalities and the full extent of POP is only visible during evacuation. Optional MRI sequences can be added and acquired for further assessment of pelvic floor relaxation. These include axial and coronal dynamic sequences during maximum straining. Illustration of all the recommended imaging sequences and patients’ maneuvers is summarized in (Fig. 2).

Since the performance of adequate pelvic stress during the dynamic sequences is important in order to assess the full extent of PFD, quality control of the study is essential. The study can only be considered diagnostic if a clear movement of the abdominal wall is seen during squeezing and straining. If no evacuation of rectal content at all or a delayed evacuation time (more than 30 seconds to evacuate 2/3 of the rectal content) is present, anismus should be considered (consensus 88 %) [23].

Image analysis, measurements, grading and MRI report

Image analysis

A clear consensus was reached that the assessment of a MR study of the pelvic floor should include analysis of static images for detection and classification of structural abnormalities. The dynamic images are analyzed with regard to functional abnormalities that are assessed by metric measurements of the three compartments of the pelvic floor (consensus 100 %) (Fig. 3). The measurements help to recognize and grade the extent of POP and pelvic floor relaxation (PFR), as well as they are used to grade anterior rectoceles and enteroceles (consensus 100 %). Both static and dynamic MRI findings as well as the results of the metric measurements should be reported in a structured MR reporting scheme (consensus 100 %) (Table 4).

Table 4

Checklist for the recommended MRI reporting scheme

https://static-content.springer.com/image/art%3A10.1007%2Fs00330-016-4471-7/MediaObjects/330_2016_4471_Tab4_HTML.gif

PCL pubococcygeal line, ARA anorectal angle, POP pelvic organ prolapse, ARJ anorectal junction

* Level of evidence 2 = based on systematic reviews, case control or cohort studies; Level of evidence 4 = based on expert opinion (www.sign.ac.uk)

Due to the different views of the clinical specialists involved in the treatment of PFD, it is suggested to consider adapting the MRI reporting scheme according to the specialty of the referring physician. A proposal for a specialty-based MRI report is given in (Table 5).

Table 5

Specialty-based MRI reporting scheme

Urologic patients

Report of pathologies if present

During dynamic sequences

Loss of urine through the urethra at maximum straining

Hypermobility of the urethra

Kinking of the vesicourethral junction

Uretherocele

Cystocele; type (distension or displacement), size (cm), grade

On static images

Damage of the supporting urethral ligaments

Avulsion or defect of the puborectal muscle

Measurements

Pelvic organ mobility

Pelvic floor relaxation

Iliococcygeus angle

Hiatal dimensions

Further evaluation

Additional findings regarding the pelvic organs*

Coexistent middle and posterior compartment disorders

(Uro)gynecologic patients

Report of pathologies, if present:

During dynamic sequences

Cystocele; type (distension or displacement), size (cm), grade

Uterine prolapse: partial or total

Enterocele: type (content of the peritoneal sac), size (cm), grade

On static images

Avulsion or defect of the puborectal muscle

Measurements

Pelvic organ mobility

Pelvic floor relaxation

Iliococcygeus angle

Hiatal dimensions

Further evaluation

Additional findings regarding the pelvic organs*

Coexistent anterior and posterior compartment disorders

Proctologic patients

Report of pathologies, if present:

During dynamic sequences

Rectocele: type (anterior or rarely posterior) size (cm), grade

Rectal mucosal invagination or prolapse: differentiation, extent, grade

Rectal descent: distance to PCL (cm), grade

Enterocele: type (content of the peritoneal sac), size (cm), grade

Lack of changes of ARA

Insufficient opening of the anal canal with inadequate rectal emptying during evacuation

Rectal intussusception

Measurements

Rectocele

Rectal decent

ARA

Pelvic organ mobility

Pelvic floor relaxation

Further evaluation

Additional findings regarding the pelvic organs*

Coexistent anterior and middle compartment disorders

ARA anorectal angle, PCL pubococcygeal line, PFD pelvic floor disorder.

* e.g. adnexal lesions, uterine diseases, urethral and bladder diverticula, diverticulosis, diverticulitis

Measurements

The pubococcygeal line (PCL), drawn on sagittal plane from the inferior aspect of the pubic symphysis to the last coccygeal joint, is recommended as reference line to measure POP (consensus 100 %). It shows the highest inter- and intraobserver reliability of MRI measurements in women with POP of the anterior and middle compartment compared to all proposed reference lines in the literature with an intercorrelation coefficient (ICC) between 0.70-0.99 (Fig. 3a) [14, 37, 38].

After defining the PCL, the distance from each reference point is measured perpendicularly to the PCL at rest and at maximum strain (consensus 100 %) [26, 29]. In the anterior compartment, the organ-specific reference point is the most inferior aspect of the bladder base (B), in the middle compartment, the organ-specific reference point is the anterior cervical lip (most distal edge of the cervix)(C), or the vaginal vault in case of previous hysterectomy (V), and in the posterior compartment, the organ-specific reference point is the anorectal junction (ARJ) (consensus 100 %) (Fig. 3a) [15, 16, 20, 25, 29, 39]. Measured values above the reference line have a minus sign, values below a plus sign (consensus 100 %) [25].

Reporting of the movement of the organs compared to their location at rest is stated to give more valuable information for the referrer than a grading system alone [8, 25]. We therefore recommend giving the difference of the values at rest and during straining for each organ-specific reference point (pelvic organ mobility)(consensus 100 %) (Fig 3a, b).

A rectocele is diagnosed as an anterior rectal wall bulge and it is measured during maximum straining and evacuation (Fig 4). Typically, a line drawn through the anterior wall of the anal canal is extended upward, and a rectal bulge of greater than 2 cm anterior to this line is described as a rectocele (consensus 100 %) [28, 34]. The anorectal angle (ARA) should be drawn along the posterior border of the rectum and a line along the central axis of the anal canal on sagittal plane (Fig. 4b) at rest, squeezing and maximum straining (consensus 100 %) [20, 27].

Pelvic floor relaxation (PFR) often coexists with POP, but it is a different pathologic entity. For quantification of the weakness of the levator ani and to reflect pelvic floor laxity, five measurements can be performed [15] , however, it reached no consensus to measure it routinely. The length of the hiatus (H-line), the descent of the levator plate (M-line) and the levator plate angle are evaluated in the sagittal plane (Fig 4a, c), whereas the transverse width of the levator hiatus and the iliococcygeus angle are assessed in the axial and coronal plane during maximum straining(Fig. 4e,d) [15]. Table 6 provides an overview of the entire spectrum of the published reference values for quantitative MR-measurements of the pelvic floor.

Table 6

Overview of the published reference values for quantitative MR-measurements of the pelvic floor

Parameters	Reference value ± standard deviation	Reference
Anterior compartment
Bladder base position (according to PCL) at rest	−2.3 ± 0.46 cm	[39]
Bladder base position (according to PCL) during straining	0.81 ± 1.11 cm	[39]
Middle compartment
Anterior cervical lip position (according to PCL) at rest	4.31 ± 0.78 cm	[39]
Anterior cervical lip position (according to PCL) during straining	−0.79 ± 1.65 cm	[39]
Posterior compartment
Anterior bulge of the rectal wall during straining (rectocele)	2.6 ± 0.6 cm	[39]
Ano rectal junction (ARJ) at rest	≤3 cm below the PCL 0.53 ± 0.99 cm	[34, 39]
ARJ during squeezing	Elevation of ARJ	[36]
ARJ during straining	2.99 ± 1.03 cm	[39]
Anorectal angle (ARA) at rest	85-95° 93° ± 4.8°	[31, 39]
ARA during squeezing	71° sharpening of 10-15°	[16, 27]
ARA during straining or defecation	103° 15-25° more obtuse 108° ± 14.7°	[16, 27, 39]
Measurements for quantification of the pelvic floor laxity
H-line (hiatus) during straining	5.8 ± 0.5 cm	[15]
M-line (descent of H-line to PCL) during straining	1.3 ± 0.5 cm	[15]
Levator plate angle during straining	11.7 ± 4.8°	[15]
Iliococcygeus angle at rest	20.9 ± 3.5°	[15]
Iliococcygeus angle during straining	33.4 ± 8.2°	[15]
Transverse diameter of levator hiatus at rest	3.3 ± 0.4	[15]
Transverse diameter of levator hiatus during straining	4.5 ± 0.7 cm	[15]

Grading

The “Rule of three’ is the recommended grading system in the anterior and middle compartment starting at 1 cm below the PCL (Table 4) [15, 16, 32, 34, 40]. This is based on the fact that the pelvic floor may descend and widen up to 2 cm during abdominal pressure. Consequently, the pelvic organs follow the movement of the pelvic floor inferiorly but without protrusion through their respective hiatuses [4]. The bladder base, particularly, may descend up to 1 cm below the PCL during straining in continent women and should not be stated as a cystocele (consensus 100 %) [24, 34].

The “Rule of two” is recommended for grading the anterior rectal wall bulge in rectoceles (consensus 100 %) (Table 4) [16; 23; 25; 26; 31]. It should be reported as pathological from grade °II, as a grade °I rectocele can be observed in nearly 78-99 % of parous women, while rarely in men [20, 28, 41].

Anorectal junction descent (ARJD) is graded (grade °I) between 3 and 5 cm below the PCL, and (grade °II) with at least 5 cm (consensus 100 %) [36].

Small intussusceptions of the rectal wall are considered to be normal findings during defecation, observed in nearly 80 % of healthy subjects [41].

Reporting other functional abnormalities and structural defects

Functional abnormalities on dynamic MR images

Loss of urine through the urethra during maximum straining records urinary incontinence (UI) and should be reported if present (consensus 88 %)[15]. Urethral hypermobility as a predictor for UI should be reported if present (consensus 88 %) [29]. If a cystocele is present, the differentiation of a distention or a displacement cystocele can be made, which is helpful for therapy planning, however it reached no consensus for general reporting [42].

If an enterocele is present, the report should include the content of the peritoneal sac, as clinical examination alone may have shortcomings in identifying the content (consensus 100 %) [5, 20, 22, 31, 43].

The end of evacuation phase is important to identify intussuception (Fig. 3c) [30].

The change of the ARA during dynamic and evacuation sequence compared to the ARA at rest expresses the functioning of the puborectal muscle. In particular, the ARA should sharpen during squeezing and should become more obtuse during straining and evacuation [16, 27, 39]. We recommend to report the individual function, as the literature presents with a widespread of normal reference values (consensus 100 %).

Structural defects on static MR images

Description of structural defects and anatomical abnormalities, that are assessed in static T2WI are more likely specialty-based PFD-related questions from the referrer (Table 5). The functional three-part pelvic supporting system (Fig. 5) includes the urethral support system, which maintains urinary continence; the vaginal support system, which prevents prolapse; and the anal sphincter complex that maintains anal continence. Urethral support system defects may include urethral ligament defect and / or distortion, level III endopelvic fascial defects, or puborectalis muscle detachment(Fig. 5b), disruption, atrophy or avulsion [15, 18, 21, 33, 44‐46]. The spectrum of vaginal support system abnormalities includes level I and II paravaginal fascial defects and/or iliococcygeus diffuse or focal muscle abnormality [35].

Limitations of the study

The study has few limitations. Four panelists who participated in Step 1 and 2 of the study were from the same institution. Therefore, only 1 out of their 4 completed questionnaire was included in the final analysis to avoid biased results. Nevertheless, since all 8 panelists who have completed the questionnaire were from different institutions these recommendations can be considered to represent the entire spectrum of expert opinions in the field of pelvic floor MRI. Second, the recommendations given in this study with regard to technical aspects of MRI of the pelvic floor relate to conventional closed-configuration magnets for MR imaging allowing patient positioning in lying body position only. However, this is the most agreed upon scanner, in addition several studies have shown that patient positioning does not significantly influence diagnostic performance of MR imaging of the pelvic floor [17, 19, 47, 48].

Conclusion

Based on an extensive literature review and analysis and of expert consensus, these proposed recommendations can be used as guidance for standardized MR imaging and reporting of PFD. Nevertheless, our joint ESUR-ESGAR pelvic floor-working group is aware about the complexity of the topic and that further studies are mandatory to achieve additional refinements of guidelines for MR imaging, diagnosing and reporting of PFD.

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Unsere Produktempfehlungen

e.Med Interdisziplinär

Kombi-Abonnement

Für Ihren Erfolg in Klinik und Praxis - Die beste Hilfe in Ihrem Arbeitsalltag

Mit e.Med Interdisziplinär erhalten Sie Zugang zu allen CME-Fortbildungen und Fachzeitschriften auf SpringerMedizin.de.

Jetzt testen ¹

e.Med Radiologie

Kombi-Abonnement

Mit e.Med Radiologie erhalten Sie Zugang zu CME-Fortbildungen des Fachgebietes Radiologie, den Premium-Inhalten der radiologischen Fachzeitschriften, inklusive einer gedruckten Radiologie-Zeitschrift Ihrer Wahl.

Jetzt testen ²

Appendix 1 Data sheet created to collect the details of the technical protocols of the group members and for literature review

General
Institution Name	Author	Referrer 1 = gynecologist 2 = urologist 3 = proctologist 4 = other	Indication for MRI of the pelvic floor	Compartment examined 1 = anterior 2 = middle 3 = posterior 4 = anterior and middle 5 = all of them

Patient preparation
Preparation of upper GI-tract 0 = no 1 = yes	Rectal enema 0 = no preparation 1 = cleansing enema	Rectal filling 0 = no filling 1 = ultrasonic gel 2 = potato starch 3 = air	Volume of rectal filling (ml)	Use of urethral Folys catheter 0 = no 1 = yes	Bladder filling 0 = empty 1 = moderately filled 2 = full 3 = 1 h void 4 = 2 h void	Vaginal filling 0 = no filling 1 = sterile gel 2 = normal gel	Use of IV contrast 0 = no 1 = yes

Patient instruction and positioning
Patient Training 0 = on grades of straining 1 = on evacuation 2 = on withholding	patient positioning 1 = supine 2 = sitting 3 = lateral right 4 = lateral left 5 = prone 6 = upright	patient positioning 0 = legs side by side 1 = legs separated 2 = knees elevated 3 = upright

MR scanner
MR-scanner 1 = 1.0 T 2 = 1.5 T 3 = 3 T 4 = <1	MR-scanner 0 = conventional scanner 1 = open scanner 2 = upright scanner	Coil Selection

Imaging protocol
Static MRI sequences	Dynamic cine MRI sequence during different patients' maneuvers Number of phases A = 3 phases (rest, squeezing, strain) B = 4 (rest, squeezing, moderate- max strain) C = 5 (rest, squeezing, mild- moderate -max strain)	MR Defecography 1 = real time fluoroscopy 2 = multiple repetitions

Geometry (for every sequence)
Sequence 1 = T1w 2 = T2w	Plane 1 = tra 2 = sag 3 = cor	FOV (mm) RFOV(%) Fold over suppression	Matrix scan Matrix recon-struction Scan percentage	Number of slices Slice thickness (mm)	Slice gap Slice orientation	Fold over direction	REST slabs 1 = free 2 = parallel

Contrast (for every sequence)
Scan mode 1 = 2D 2 = 3D	Technique 1 = SE 2 = GE	Echoes	TE (msec) TR (msec)	Flip Angle	Half Scan	Number of signal acquisition	Total scan duration

Appendix 2 Questionnaire for ESUR/ESGAR pelvic floor recommendations

Jacobsen LA, Kent M, Lee M, Mather M (2011) America’s aging population. Popul Bull 66:1–18CrossRef

Gerten KA, Markland AD, Lloyd LK, Richter HE (2008) Prolapse and incontinence surgery in older women. J Urol 179:2111–2118CrossRefPubMedPubMedCentral

Samuelsson EC, Victor A, Tibblin G, Svardsudd KF (1999) Signs of genital prolapse in a Swedish population of women 20 to 59 years of age and possible related factors. Am J Obstet Gynecol 180:299–305CrossRefPubMed

Boyadzhyan L, Raman SS, Raz S (2008) Role of static and dynamic MR imaging in surgical pelvic floor dysfunction. Radiographics 28:949–967CrossRefPubMed

Comiter CV, Vasavada SP, Barbaric ZL et al (1999) Grading pelvic prolapse and pelvic floor relaxation using dynamic magnetic resonance imaging. Urology 54:454–457CrossRefPubMed

Hoyte L, Schierlitz L, Zou K et al (2001) Two- and 3-dimensional MRI comparison of levator ani structure, volume, and integrity in women with stress incontinence and prolapse. Am J Obstet Gynecol 185:11–19CrossRefPubMed

Maglinte DD, Kelvin FM, Fitzgerald K et al (1999) Association of compartment defects in pelvic floor dysfunction. AJR Am J Roentgenol 172:439–444CrossRefPubMed

Alt CD, Brocker KA, Lenz F et al (2014) MRI findings before and after prolapse surgery. Acta Radiol 55:495–504CrossRefPubMed

Etlik O, Arslan H, Odabasi O et al (2005) The role of the MR-fluoroscopy in the diagnosis and staging of the pelvic organ prolapse. Eur J Radiol 53:136–141CrossRefPubMed

10.

Grassi R, Lombardi G, Reginelli A et al (2007) Coccygeal movement: assessment with dynamic MRI. Eur J Radiol 61:473–479CrossRefPubMed

11.

Gufler H, DeGregorio G, Dohnicht S et al (2002) Dynamic MRI after surgical repair for pelvic organ prolapse. J Comput Assist Tomogr 26:734–739CrossRefPubMed

12.

El Sayed RF, Fielding JR, El Mashed S et al (2005) Preoperative and postoperative magnetic resonance imaging of female pelvic floor dysfunction: correlation with clinical findings. J Women’s Imag 7:163–180CrossRef

13.

Kaufman HS, Buller JL, Thompson JR et al (2001) Dynamic pelvic magnetic resonance imaging and cystocolpoproctography alter surgical management of pelvic floor disorders. Dis Colon Rectum 44:1574–1575CrossRef

14.

Betschart C, Chen L, Ashton-Miller JA, Delancey JO (2013) On pelvic reference lines and the MR evaluation of genital prolapse: a proposal for standardization using the Pelvic Inclination Correction System. Int Urogynecol J 24:1421–1428CrossRefPubMedPubMedCentral

15.

El Sayed RF, El Mashed S, Farag A et al (2008) Pelvic floor dysfunction: assessment with combined analysis of static and dynamic MR imaging findings. Radiology 248:518–530CrossRefPubMed

16.

Maccioni F (2013) Functional disorders of the ano-rectal compartment of the pelvic floor: clinical and diagnostic value of dynamic MRI. Abdom Imaging 38:930–951CrossRefPubMed

17.

Fielding JR, Versi E, Mulkern RV et al (1996) MR imaging of the female pelvic floor in the supine and upright positions. J Magn Reson Imaging 6:961–963CrossRefPubMed

18.

Bartram CI, Goh V, Halligan S et al (2000) Dynamic MR imaging of the pelvic floor in asymptomatic subjects. AJR Am J Roentgenol 174:661–666CrossRefPubMed

19.

Fielding JR, Griffiths DJ, Versi E et al (1998) MR imaging of pelvic floor continence mechanisms in the supine and sitting positions. Am J Roentgenol 171:1607–1610CrossRef

20.

Elshazly WG, El Nekady AA, Hassan H (2010) Role of dynamic magnetic resonance imaging in management of obstructed defecation case series. Int J Surg 8:274–282CrossRefPubMed

21.

Nichols DH, Randall CL (1989) Vaginal surgery. Williams & Wilkins, Baltimore

22.

Bertschinger KM, Hetzer FH, Roos JE et al (2002) Dynamic MR imaging of the pelvic floor performed with patient sitting in an open-magnet unit versus with patient supine in a closed-magnet unit. Radiology 223:501–508CrossRefPubMed

23.

Elsayed RF (2015) Pelvic floor imaging. In: Shaaban AM (ed) Diagnostic imaging gynecol, 2nd edn. Elsevier, Amirsys, pp 8/30–8/39

24.

Felt-Bersma RJ, Cuesta MA (2001) Rectal prolapse, rectal intussusception, rectocele, and solitary rectal ulcer syndrome. Gastroenterol Clin North Am 30:199–222CrossRefPubMed

25.

Singh K, Jakab M, Reid WM et al (2003) Three-dimensional magnetic resonance imaging assessment of levator ani morphologic features in different grades of prolapse. Am J Obstet Gynecol 188:910–915CrossRefPubMed

26.

Mortele KJ, Fairhurst J (2007) Dynamic MR defecography of the posterior compartment: indications, techniques and MRI features. Eur J Radiol 61:462–472CrossRefPubMed

27.

Shorvon PJ, McHugh S, Diamant NE et al (1989) Defecography in normal volunteers: results and implications. Gut 30:1737–1749CrossRefPubMedPubMedCentral

28.

Morren GL, Balasingam AG, Wells JE et al (2005) Triphasic MRI of pelvic organ descent: sources of measurement error. Eur J Radiol 54:276–283CrossRefPubMed

29.

Halligan S, Bartram CI, Park HJ, Kamm MA (1995) Proctographic features of anismus. Radiology 197:679–682CrossRefPubMed

30.

Broekhuis SR, Kluivers KB, Hendriks JC et al (2009) Dynamic magnetic resonance imaging: reliability of anatomical landmarks and reference lines used to assess pelvic organ prolapse. Int Urogynecol J Pelvic Floor Dysfunct 20:141–148CrossRefPubMed

31.

Elsayed RF (2015) Middle compartment. In: Shaaban AM (ed) Diagnostic imaging gynecol, 2nd edn. Elsevier, Amirsys, pp 8/68–8/88

32.

Woodfield CA, Krishnamoorthy S, Hampton BS, Brody JM (2010) Imaging pelvic floor disorders: trend toward comprehensive MRI. AJR Am J Roentgenol 194:1640–1649CrossRefPubMed

33.

Kelvin FM, Maglinte DD, Hornback JA, Benson JT (1992) Pelvic prolapse: assessment with evacuation proctography (defecography). Radiology 184:547–551CrossRefPubMed

34.

Bump RC, Mattiasson A, Bo K et al (1996) The standardization of terminology of female pelvic organ prolapse and pelvic floor dysfunction. Am J Obstet Gynecol 175:10–17CrossRefPubMed

35.

Alt CD, Hampel F, Hallscheidt P, et al. (2014) 3 T MRI-based measurements for the integrity of the female pelvic floor in 25 healthy nulliparous women. Neurourol Urodyn

36.

Halligan S, Bartram C, Hall C, Wingate J (1996) Enterocele revealed by simultaneous evacuation proctography and peritoneography: does “defecation block” exist? Am J Roentgenol 167:461–466CrossRef

37.

Healy JC, Halligan S, Reznek RH et al (1997) Dynamic MR imaging compared with evacuation proctography when evaluating anorectal configuration and pelvic floor movement. Am J Roentgenol 169:775–779CrossRef

38.

Elsayed RF (2015) Overview of posterior compartemnt. In: Shaaban AM (ed) Diagnostic imaging gynecol, 2nd edn. Elsevier, Amirsys, pp 8/88–8/101

39.

Yang A, Mostwin JL, Rosenshein NB, Zerhouni EA (1991) Pelvic floor descent in women: dynamic evaluation with fast MR imaging and cinematic display. Radiology 179:25–33CrossRefPubMed

40.

Fletcher JG, Busse RF, Riederer SJ et al (2003) Magnetic resonance imaging of anatomic and dynamic defects of the pelvic floor in defecatory disorders. Am J Gastroenterol 98:399–411CrossRefPubMed

41.

Woodfield CA, Hampton BS, Sung V, Brody JM (2009) Magnetic resonance imaging of pelvic organ prolapse: comparing pubococcygeal and midpubic lines with clinical staging. Int Urogynecol J Pelvic Floor Dysfunct 20:695–701CrossRefPubMed

42.

Elsayed RF (2015) Anterior compartment. In: Shaaban AM (ed) Diagnostic imaging gynecol, 2nd edn. Elsevier, Amirsys, pp 8/40–8/68

43.

Kruyt RH, Delemarre JB, Doornbos J, Vogel HJ (1991) Normal anorectum: dynamic MR imaging anatomy. Radiology 179:159–163CrossRefPubMed

44.

Lienemann A, Sprenger D, Janssen U et al (2004) Assessment of pelvic organ descent by use of functional cine-MRI: which reference line should be used? Neurourol Urodyn 23:33–37CrossRefPubMed

45.

Schreyer AG, Paetzel C, Fürst A et al (2012) Dynamic magnetic resonance defecography in 10 asymptomatic volunteers. World J Gastroenterol 18:6836–6842CrossRefPubMedPubMedCentral

46.

Shorvon PJ, Marshall MM (2005) Evacuation proctography. complex anorectal. Disord Investig Manag

47.

El-Sayed RF, Morsy MM, el-Mashed SM, Abdel-Azim MS (2007) Anatomy of the urethral supporting ligaments defined by dissection, histology, and MRI of female cadavers and MRI of healthy nulliparous women. AJR Am J Roentgenol 189:1145–1157CrossRefPubMed

48.

Huddleston HT, Dunnihoo DR, Huddleston PM 3rd, Meyers PC Sr (1995) Magnetic resonance imaging of defects in DeLancey’s vaginal support levels I, II, and III. Am J Obstet Gynecol 172:1774–1778CrossRef

Titel: Magnetic resonance imaging of pelvic floor dysfunction - joint recommendations of the ESUR and ESGAR Pelvic Floor Working Group
verfasst von: Rania Farouk El Sayed
Celine D. Alt
Francesca Maccioni
Matthias Meissnitzer
Gabriele Masselli
Lucia Manganaro
Valeria Vinci
Dominik Weishaupt
On behalf of the ESUR and ESGAR Pelvic Floor Working Group
Publikationsdatum: 03.08.2016
Verlag: Springer Berlin Heidelberg
Erschienen in: European Radiology / Ausgabe 5/2017
Print ISSN: 0938-7994
Elektronische ISSN: 1432-1084
DOI: https://doi.org/10.1007/s00330-016-4471-7

Update Radiologie

Bestellen Sie unseren Fach-Newsletter und bleiben Sie gut informiert.

Newsletter bestellen

Die Highlights vom Kongress des American College of Cardiology 2024

Springer Medizin

Magnetic resonance imaging of pelvic floor dysfunction - joint recommendations of the ESUR and ESGAR Pelvic Floor Working Group

Abstract

Objective

Methods

Results

Conclusion

Key points

Introduction

Materials and methods

Results

Indications for MR imaging of pelvic floor dysfunction

Patients’ preparation and hardware requirements

MR-imaging protocol

Image analysis, measurements, grading and MRI report

Image analysis

Measurements

Grading

Reporting other functional abnormalities and structural defects

Functional abnormalities on dynamic MR images

Structural defects on static MR images

Limitations of the study

Conclusion

Unsere Produktempfehlungen

e.Med Interdisziplinär

e.Med Radiologie

Appendix 1 Data sheet created to collect the details of the technical protocols of the group members and for literature review

Appendix 2 Questionnaire for ESUR/ESGAR pelvic floor recommendations

Neu im Fachgebiet Radiologie

„Übersichtlicher Wegweiser“: Lauterbachs umstrittener Klinik-Atlas ist online

Klinikreform soll zehntausende Menschenleben retten

Darf man die Behandlung eines Neonazis ablehnen?

Ein Drittel der jungen Ärztinnen und Ärzte erwägt abzuwandern

Update Radiologie

Die Highlights vom Kongress des American College of Cardiology 2024

Springer Medizin

Abstract

Objective

Methods

Results

Conclusion

Key points

Introduction

Materials and methods

Results

Indications for MR imaging of pelvic floor dysfunction

Patients’ preparation and hardware requirements

MR-imaging protocol

Image analysis, measurements, grading and MRI report

Image analysis

Measurements

Grading

Reporting other functional abnormalities and structural defects

Functional abnormalities on dynamic MR images

Structural defects on static MR images

Limitations of the study

Conclusion

Unsere Produktempfehlungen

e.Med Interdisziplinär

e.Med Radiologie

Appendix 1 Data sheet created to collect the details of the technical protocols of the group members and for literature review

Appendix 2 Questionnaire for ESUR/ESGAR pelvic floor recommendations

Weitere Artikel der Ausgabe 5/2017

Investigating the prediction value of multiparametric magnetic resonance imaging at 3 T in response to neoadjuvant chemotherapy in breast cancer

Diffusion-weighted imaging of breast lesions: Region-of-interest placement and different ADC parameters influence apparent diffusion coefficient values

Osteonecrosis detected by whole body magnetic resonance in patients with Hodgkin Lymphoma treated by BEACOPP

Feasibility of spectral shaping for detection and quantification of coronary calcifications in ultra-low dose CT

Assessment of deep myometrial invasion of endometrial cancer on MRI: added value of second-opinion interpretations by radiologists subspecialized in gynaecologic oncology

Prognostic aspects of dynamic contrast-enhanced magnetic resonance imaging in synchronous distant metastatic rectal cancer

Neu im Fachgebiet Radiologie

„Übersichtlicher Wegweiser“: Lauterbachs umstrittener Klinik-Atlas ist online

Klinikreform soll zehntausende Menschenleben retten

Darf man die Behandlung eines Neonazis ablehnen?

Ein Drittel der jungen Ärztinnen und Ärzte erwägt abzuwandern

Update Radiologie