{"paper_id":"59a06184-80ff-499a-89db-f5fdd02df79f","body_text":"Adenomyosis is a prevalent gynecological disease characterized by the presence of endometrial glands and stroma within the myometrium and affects approximately 20% of women worldwide [ 1 ]. Traditionally, adenomyosis has been diagnosed using histopathology following hysterectomy in perimenopausal women experiencing abnormal uterine bleeding or pelvic pain. However, this condition is not as well-known as other gynecologic conditions, such as endometriosis, which introduces challenges in obtaining an accurate diagnosis. In addition, patients with adenomyosis may have future pregnancy plans or a desire to preserve their uteruses owing to recent trends of delayed marriage and pregnancy; therefore, many may choose uterine-preserving surgeries rather than hysterectomies. Recent advances in imaging techniques, including ultrasound (US) and magnetic resonance imaging (MRI), have enabled widespread noninvasive diagnosis of the condition. Adenomyosis has garnered increasing attention owing to its high prevalence on US and MRI and its variable clinical symptoms, including pelvic pain, abnormal uterine bleeding, and pregnancy-related disorders [ 2 , 3 ].\nThe spectrum of adenomyosis ranges from the thickening of the junctional zone to focal or diffuse lesions involving the entire uterine wall, resulting in diverse manifestations and complex diagnostic classifications. Furthermore, no consensus on shared clinical and imaging diagnostic criteria exists, and data from previous studies are heterogeneous and not fully comparable. Few studies have aimed to establish a correlation between the MRI phenotypes of adenomyosis and clinical outcomes [ 4 , 5 , 6 , 7 ]. However, most MRI studies lack satisfactory multiparametric imaging and validation, and the relationship between the imaging features of adenomyosis and symptoms or other adverse outcomes, such as infertility or pregnancy loss, remains unclear.\nMRI is an accurate and objective imaging modality for obtaining anatomical information about adenomyosis. However, universal criteria for predicting disease severity are currently unavailable. Consequently, the clinical importance of MRI in assessing disease severity, predicting clinical risk factors, and evaluating symptomatology remains unknown. A comprehensive understanding of the relationship between imaging features and clinicopathological characteristics is crucial for determining disease severity and enabling tailored therapeutic approaches for each adenomyosis subtype. Therefore, our study aimed to investigate the correlation between the MRI features and clinical presentation of the disease, including risk factor profiles, signs, and symptoms.\n\nThe study was approved by the appropriate Institutional Review Board, and the requirement for informed consent was waived owing to the retrospective design. We consecutively investigated 112 patients with adenomyosis who underwent uterine-preserving surgery at our tertiary academic center from December 2011 to January 2020. Surgeries included conservative laparotomic uterine-sparing surgery ( n  = 36) and robot-assisted uterine-sparing surgery ( n  = 76). Indications for surgical treatment included progressive anemia, exacerbation of clinical symptoms that caused abdominal compression and discomfort in daily life, and severe pelvic pain that was difficult to control. Additionally, 131 patients with adenomyosis who underwent active surveillance and wanted to preserve their uterus, including management with hormone therapy, were included. Women with coexisting malignancies were excluded ( Figure 1 ). All patients underwent routine pelvic MRI examinations, except during the menstrual phase. Demographic data were retrieved from the electronic medical records linked to centralized computer systems. Data on patient age, gravidity, parity, and adenomyosis-related findings, including dysmenorrhea, as measured by the visual analog score (VAS), initial hemoglobin level, and serum cancer antigen 125 (CA-125) levels, were collected.\nAll MRI examinations were performed using a 3.0-T scanner (Verio, Siemens Healthcare, Erlangen, Germany) with a pelvic phased-array coil. The patients fasted for 3 h and received an antispasmodic drug (Buscopan, Boehringer Ingelheim, Ingelheim, Germany) intravenously immediately before imaging to reduce bowel peristalsis. The MRI protocol included turbo spin-echo T2-weighted sequences acquired in the sagittal, axial, and coronal planes with radial blades (BLADE: repetition time/echo time (TR/TE), 4000 ms/118 ms; slice thickness, 6 mm; flip angle, 138°; matrix, 320 × 320; field of view (FOV), 240 × 240 mm). Axial T1-weighted sequences were acquired with and without fat suppression (TR/TE, 650 ms/12 ms; slice thickness, 6 mm; flip angle, 150°; matrix, 320 × 224; FOV, 240 × 240 mm). Diffusion-weighted imaging sequences were axial single-shot isotropic echo-planar sequences with fat saturation. Free-breathing diffusion-weighted imaging was acquired with b-values of 0, 50, and 1000 s/mm2 (TR/TE, 6200 ms/80 ms; slice thickness, 6 mm; flip angle, 90°; matrix, 100 × 100; FOV, 240 × 240 mm). An apparent diffusion coefficient map was automatically generated. Gadoteridol (ProHance, Bracco, Milan, Italy) at a dose of 0.2 mM/kg was injected intravenously at a rate of 1.0 mL/s, followed by a 20 mL saline flush. After contrast injection, sagittal and axial T1-weighted fat-suppressed gradient-echo images (TR/TE, 650 ms/12 ms; slice thickness, 6 mm; flip angle, 150°; matrix, 320 × 224; FOV, 240 × 240 mm) were obtained.\nMRI images were retrospectively reviewed based on size and classification (internal, diffuse, external) parameters. Adenomyosis was classified based on the affected area and the degree of myometrial infiltration, according to the references [ 7 , 8 ]. Adenomyosis was classified into the following types according to the degree of infiltration: internal type, defined as that occurring in the inner uterine myometrium without affecting the outer structures of the myometrium; external type, defined as that arising in the outer myometrium, including adenomyomas, or that invading from outside the uterus, disrupting the serosa but not affecting the junctional zone; and diffuse type, defined as that being in an advanced stage that could not be classified as an internal or external type. Regarding the affected area, adenomyosis was classified according to localization (anterior, posterior, lateral, fundal, or entire), presence of a concomitant pathology (ovarian endometrioma (OMA), deep infiltrating endometriosis (DIE), or fibroid), margin (ill-defined or clearly demarcated), presence of myometrial cysts, presence of diffusion restriction, and degree of enhancement compared to the myometrium (less, equal, or more enhancement).\nAssociations between MRI parameters and adenomyosis-related clinical presentations were assessed using the chi-squared, Fisher’s exact, Wilcoxon rank-sum, or Kruskal–Wallis tests, whenever appropriate. All statistical analyses were performed using SAS version 9.4 (SAS Institute, Cary, NC, USA). Statistical significance was set at  p  < 0.05. Pairwise deletion was applied to the missing data.\n\nThe MRI findings and clinicodemographic characteristics of patients with operated adenomyosis (adenomyomectomy) ( n  = 112, 39.5 ± 5.2 years old) compared to those with non-operated adenomyosis ( n  = 131, 44.3 ± 7.1 years old) are summarized in  Table 1 . Age, size, classification, posterior and entire localization, coexisting OMA, DIE, and fibroid, myometrial cysts, diffusion restriction, enhancement degree, VAS scores, CA-125 levels, and parity showed statistically significant differences between the two groups. The operated group appeared to be younger and presented with larger lesions than the non-operated group. Posterior localization, presence of OMA, DIE, and myometrial cysts, and diffusion restriction were more frequently observed in the operated group than in the non-operated group. The proportions of internal, diffuse, and external adenomyosis were 4.5%, 53.6%, and 42%, respectively, in the operated group. In addition, the proportions of adenomyosis with less, equal, and more enhancement than the myometrium were 24.3%, 71.2%, and 4.5%, respectively, in the operated group. Regarding clinical parameters, the operated group exhibited higher VAS scores and CA-125 levels than the non-operated group. In addition, the operated group presented with a nulliparous state more frequently than the non-operated group. Entire localization and fibroids were more frequently observed in the non-operated group than in the operated group ( Figure 2 ).\nTable 2  shows the association between the MRI parameters and VAS scores. Size and classification were associated with VAS scores in both the non-operated and operated groups ( p  = 0.004, 0.001, and  p  = 0.007, 0.001, respectively). The VAS score was higher for lesions > 5 cm than those < 5 cm in both groups. The VAS scores tended to increase in the order of diffuse, external, and internal adenomyosis in both groups. The VAS scores appeared to be associated with posterior localization, coexisting fibroids, and myometrial cysts in the operated group ( p  = 0.008, 0.009, and 0.001, respectively). The VAS scores tended to be higher with posterior localization, no fibroids, and the presence of myometrial cysts.\nTable 3  shows the association between the MRI parameters and CA-125 levels. Size, classification, and myometrial cysts were associated with CA-125 levels in both the non-operated and operated groups ( p  < 0.001,  p  < 0.001,  p  < 0.001 and  p  < 0.001,  p  < 0.001,  p  = 0.002, respectively). CA-125 levels were higher in lesions > 5 cm than those < 5 cm in both groups. CA-125 tended to increase in the order of diffuse, external, and internal adenomyosis in both groups.CA-125 levels were higher with the presence of myometrial cysts in both groups. CA-125 levels were associated with posterior localization and coexisting fibroids in the non-operated group ( p  = 0.041 and 0.003). CA-125 levels tended to be higher in patients with posterior localization and no fibroids.\nTable 4  shows the association between the MRI parameters and hemoglobin levels. Classification was associated with hemoglobin levels in both the non-operated and operated groups ( p  = 0.017 and  p  = 0.029, respectively). In the non-operated group, hemoglobin levels tended to be lower in cases of diffuse adenomyosis than in those of external or internal adenomyosis. Hemoglobin levels tended to be lower in cases of internal adenomyosis compared to those of diffuse or external adenomyosis in the operated group. Hemoglobin levels appeared to be associated with myometrial cysts and diffusion restriction in the non-operated group ( p  = 0.004 and 0.019, respectively). Hemoglobin levels tended to be lower in the presence of myometrial cysts and diffusion restriction. Hemoglobin levels appeared to be associated with size and anterior localization in the operated group ( p  = 0.014 and 0.032, respectively). Hemoglobin levels tended to be lower with lesions > 5 cm and anterior localization.\nTable 5  shows the association between the MRI parameters and parity. Posterior localization was associated with parity in both the non-operated and operated groups ( p  = 0.041 and  p  = 0.031, respectively). A nulliparous status tended to correlate with posterior localization in both groups. Classification, and coexisting OMA, DIE, and myometrial cysts, were associated with parity in the non-operated group ( p  = 0.027, 0.002, 0.04, and 0.04, respectively). Nulliparous patients presented more frequently with external adenomyosis, had a higher frequency of coexisting OMA and DIE, and presented with more myometrial cysts than multiparous patients. Fundal localization significantly correlated with parity in the operated group ( p  = 0.027). Multiparous patients presented more frequently with lesions with fundal localization than nulliparous patients.\n\nWe aimed to identify the imaging findings associated with adenomyosis-related clinicopathological characteristics, including pain, tumor marker levels, bleeding, and parity. Notably, patients with operated adenomyosis exhibited several distinct characteristics compared to those with non-operated adenomyosis: they tended to be younger and have larger lesions, which were mostly of a diffuse type and with posterior localization, coexisting OMA, DIE, and myometrial cysts, and diffusion restriction. Additionally, patients who underwent surgery for adenomyosis had higher VAS scores and CA-125 levels, with nulliparity being more common in this group. Adenomyosis often coexists with other pelvic pathologies, including endometriosis and fibroids. Fibroids are present in approximately 37% of adenomyosis cases in women undergoing hysterectomy and may mask the presence of adenomyosis [ 9 ]. Adenomyosis accompanied by fibroids is commonly observed in the absence of surgery. In our study, the non-operated group had a higher prevalence of entire localization or fibroids, indicating a preference for medication-based treatments over surgery.\nOur study found that lesion size and classification were associated with the VAS scores and CA-125 levels. The severity of symptoms, such as dysmenorrhea, is associated with the number or density of ectopic endometrial glands, mainly based on lesion size [ 10 , 11 , 12 , 13 ]. Our results support these findings and highlight the relationship between tumor size and CA-125 levels. Furthermore, the posterior localization of adenomyosis was more likely to be associated with a higher VAS score in the operated group. Previous studies have suggested that a thickened posterior myometrial layer is a risk factor for painful cramping during menstruation [ 14 , 15 ]. Myometrial cysts are highly characteristic of adenomyosis; however, they were only identified on MRI in approximately half of the cases [ 16 ]. Some studies have not observed a correlation between the presence of myometrial cysts and clinical manifestations [ 5 , 17 , 18 ]. However, we found a significant association between myometrial cysts and CA-125 levels. Additionally, we observed a clear association between myometrial cysts and higher VAS scores in the operated group, suggesting that the relative number of glands within the adenomyotic mass can affect the clinical symptoms and influence the choice of surgical treatment. Additionally, our results demonstrate that hemoglobin levels were associated with adenomyosis classification. The diffuse type was associated with lower hemoglobin levels than the external or internal type. These findings are consistent with those of previous studies that reported heavier menstrual bleeding in patients with diffuse adenomyosis [ 11 , 13 , 19 ]. However, other studies did not find a relationship between the depth of myometrial involvement and menorrhagia [ 10 , 20 , 21 ]. Patients with adenomyosis are believed to have lower pregnancy and implantation rates [ 22 ]. However, the specific adenomyosis phenotype resulting in infertility remains unclear. In our study, nulliparous women tended to present with adenomyosis in a posterior localization. Bourdon et al. noted that infertility was related to focal adenomyosis of the outer myometrium, but not to diffuse internal adenomyosis [ 5 ]. However, no statistically significant differences in pregnancy rates were identified between patients with localized and diffuse adenomyosis [ 22 ]. Limited evidence exists regarding the association between infertility and the adenomyosis phenotype.\nAdenomyosis is a heterogeneous condition and comprises multiple subtypes with distinct imaging features. Recently, several subtype classifications based on MRI findings have been proposed. Clinically, classifications can assist in diagnosis and prognosis assessments and guide the selection of an appropriate management modality, which ranges from conservative approaches to surgical interventions. Classifications differ in terms of terminology and categories; nevertheless, adenomyosis is commonly classified into three types: internal/intrinsic, external/extrinsic, and diffuse [ 7 , 8 , 23 , 24 ]. Our study found that the diffuse type was associated with higher VAS scores, elevated CA-125 levels, lower hemoglobin levels, and a higher likelihood of requiring surgery. In clinical practice, diffuse adenomyosis is often associated with more severe menstrual symptoms than focal localized disease [ 25 ]. The pain becomes more intense and intralesional bleeding more widespread when adenomyotic lesions deeply infiltrate the myometrial layer [ 11 , 26 , 27 ]. Elevated CA-125 levels have also been identified as a characteristic feature of diffuse adenomyosis.\nFormerly, the diagnosis of adenomyosis lacked importance since it was considered a benign condition without specific treatment. However, the lack of accurate diagnosis may have led to unnecessary and ineffective procedures. Previously, patients who had completed their family plans and had severe symptoms of adenomyosis underwent a hysterectomy. However, the incidence of adenomyosis in women of childbearing age has been increasing due to recent trends in late marriage and delayed pregnancy. Therefore, the need for uterus- and fertility-preserving surgery is increasing. Early diagnosis is currently considered crucial for effective adenomyosis management, particularly in women seeking fertility preservation and symptomatic control. Recent attempts have been made to develop classification systems that integrate imaging findings with clinical symptoms and associated treatments [ 28 ]. For instance, internal/intrinsic adenomyosis is associated with bleeding symptoms and is less likely to respond to progestin therapy, whereas external/extrinsic lesions are linked to endometriosis and dysmenorrhea, and may have a better response to such therapy. Furthermore, the adenomyosis phenotype depicted by MRI can guide the selection of appropriate surgical treatments, such as adenomyomectomies for adenomyomas and cytoreductive surgeries for diffuse/internal adenomyosis [ 29 ]. Early diagnosis can be achieved by increasing awareness of the disease and implementing accurate diagnostic pathways, enabling timely intervention and improving patient outcomes.\nNo MRI-based classification for adenomyosis has been validated to date. Conflicting results from previous studies, which are often attributed to small sample sizes, variations in patient populations, and different definitions, cause difficulty in interpreting the clinical significance of the disease’s patterns. Comparative studies investigating imaging features are necessary to predict specific symptoms, assess disease severity, and evaluate treatment efficacy for adenomyosis. The establishment of a definite, evidence-based link between the MRI phenotype of adenomyosis and clinical outcomes would benefit both patients and clinicians. The standardized phenotype categorization would facilitate meaningful comparisons of symptoms and treatment outcomes, thereby enabling more tailored therapeutic approaches. In our study, multiparametric MRI parameters showed weaker associations with the clinical presentation than anticipated. Despite these limitations, we believe that our study addresses the pressing need for comprehensive research on the correlation between the MRI features of adenomyosis and its clinical presentation. We aimed to enhance our understanding of this prevalent gynecologic disorder by elucidating the relationship between its imaging findings, clinical risk factors, and symptomatology. The outcomes of this study may address the current knowledge gap, provide valuable insights into the clinical significance of MRI findings, and pave the way for improved diagnostic and therapeutic strategies for patients with adenomyosis.\nDiffusion-weighted imaging visualizes water diffusion in tissues, which aids in malignancy assessment due to higher cellularity in malignant tumors. Most adenomyosis exhibits a low signal on high-b diffusion-weighted imaging, consistent with non-neoplastic features, and no diffusion restriction. Previous studies have highlighted the enhanced diagnostic accuracy of diffusion-weighted imaging compared to conventional MRI [ 30 ]. Adenomyosis may have a lower signal than the junctional zone and myometrium, with varied contrast enhancement, limiting diagnostic utility. Nonetheless, understanding these parameters could drive research on the correlation between MRI findings, adenomyosis severity and clinical outcomes.\nThe strength of our study is the detailed analysis of the MRI data, allowing for the description of specific phenotypic patterns, such as diffusion restriction, enhancement, and myometrial cysts. However, several limitations may have impacted our results. First, our broad inclusion criteria resulted in a heterogeneous study population, challenging the application of MRI parameters to specific patient groups based on menopausal status, symptomatology, and the presence of comorbidities, such as fibroids or endometriosis. Second, our analysis focused solely on patients who presented with symptoms, potentially overlooking individuals with asymptomatic adenomyosis. Nonetheless, these inclusion criteria were deemed appropriate considering our aim of evaluating the relationship between MRI features and clinical presentation.\n\nIn conclusion, we identified the MRI findings associated with adenomyosis-related clinicopathological characteristics. Among the parameters, lesion size was associated with the VAS scores and CA-125 levels. Myometrial cysts were associated with CA-125 levels. Classification was associated with the VAS scores and CA-125 and hemoglobin levels. The posterior localization of adenomyosis was associated with parity. This precise understanding of the spectrum of MRI features in adenomyosis is of great importance for enabling an accurate diagnosis, and facilitating individualized and appropriate management strategies for affected patients.","source_license":"CC0","license_restricted":false}