ABSTRACT
BACKGROUND AND AIMS: Myxoid liposarcoma is classified in the group of sarcomas with adipose differentiation, which is the second most common group of sarcomas. However, myxoid liposarcoma is not a homogeneous entity, because the behavior and clinical course of these tumours can vary widely. This study aimed to describe the magnetic resonance imaging (MRI) features of myxoid liposarcomas and to determine whether the MRI features are associated with the histologic grade and can differentiate between low-grade and high-grade tumours and thus help in clinical decision making. MATERIAL AND METHODS: We studied 36 patients with myxoid liposarcomas treated at our centre between 2010 and 2018. We analysed clinical variables (age, sex, and tumour site) and MRI features (size, depth, borders, fatty component, myxoid component, non-fatty/non-myxoid component, apparent diffusion coefficient (ADC), and type of enhancement after the administration of intravenous contrast material). We correlated the MRI features with the histologic grade and the percentage of round cells. RESULTS: In our series, patients with myxoid liposarcomas were mainly young adults (median age, 43 years). There were no differences between sexes; 97.2% were located in the lower limbs, 86.1% were deep, and 77.8% had well-defined borders. Of the 23 myxoid liposarcomas that contained no fat, 16 (69.6%) were high grade (pâ¯=â¯0.01). All the tumors with a myxoid component of less than 25% were high grade (pâ¯=â¯0.01); 83.3% of those with a non-fatty/non-myxoid component greater than 50% were high grade (pâ¯=â¯0.03) and 61.5% had more than 5% round cells (pâ¯=â¯0.01). Diffusion sequences were obtained in 14 of the 36 patients; ADC values were high (median, 2â¯×â¯10-3â¯mm2/s), although there were no significant associations between low-grade and high-grade tumours. Contrast-enhanced images were available for 30 (83.3%) patients; 83.3% of the tumours with heterogeneous enhancement were high grade (pâ¯=â¯0.01). CONCLUSIONS: MRI can be useful for differentiating between high- and low-grade myxoid liposarcomas and can help in clinical decision making.
Subject(s)
Liposarcoma, Myxoid , Soft Tissue Neoplasms , Young Adult , Humans , Adult , Liposarcoma, Myxoid/diagnostic imaging , Liposarcoma, Myxoid/pathology , Soft Tissue Neoplasms/diagnostic imaging , Magnetic Resonance Imaging , Retrospective StudiesABSTRACT
Bone sarcoma are infrequent diseases, representing < 0.2% of all adult neoplasms. A multidisciplinary management within reference centers for sarcoma, with discussion of the diagnostic and therapeutic strategies within an expert multidisciplinary tumour board, is essential for these patients, given its heterogeneity and low frequency. This approach leads to an improvement in patient's outcome, as demonstrated in several studies. The Sarcoma European Latin-American Network (SELNET), aims to improve clinical outcome in sarcoma care, with a special focus in Latin-American countries. These Clinical Practice Guidelines (CPG) have been developed and agreed by a multidisciplinary expert group (including medical and radiation oncologist, surgical oncologist, orthopaedic surgeons, radiologist, pathologist, molecular biologist and representatives of patients advocacy groups) of the SELNET consortium, and are conceived to provide the standard approach to diagnosis, treatment and follow-up of bone sarcoma patients in the Latin-American context.
Subject(s)
Bone Neoplasms , Osteosarcoma , Sarcoma , Soft Tissue Neoplasms , Adult , Bone Neoplasms/diagnosis , Bone Neoplasms/pathology , Bone Neoplasms/therapy , Humans , Osteosarcoma/diagnosis , Osteosarcoma/pathology , Osteosarcoma/therapy , Practice Guidelines as Topic , Sarcoma/diagnosis , Sarcoma/pathology , Sarcoma/therapy , Soft Tissue Neoplasms/pathologyABSTRACT
BACKGROUND AND AIMS: Myxoid liposarcoma is classified in the group of sarcomas with adipose differentiation, which is the second most common group of sarcomas. However, myxoid liposarcoma is not a homogeneous entity, because the behavior and clinical course of these tumors can vary widely. This study aimed to describe the magnetic resonance imaging (MRI) features of myxoid liposarcomas and to determine whether the MRI features are associated with the histologic grade and can differentiate between low-grade and high-grade tumors and thus help in clinical decision making. MATERIAL AND METHODS: We studied 36 patients with myxoid liposarcomas treated at our center between 2010 and 2018. We analyzed clinical variables (age, sex, and tumor site) and MRI features (size, depth, borders, fatty component, myxoid component, non-fatty / non-myxoid component, apparent diffusion coefficient (ADC), and type of enhancement after the administration of intravenous contrast material). We correlated the MRI features with the histologic grade and the percentage of round cells. RESULTS: In our series, patients with myxoid liposarcomas were mainly young adults (median age, 43 years). There were no differences between sexes; 97.2% were located in the lower limbs, 86.1% were deep, and 77.8% had well-defined borders. Of the 23 myxoid liposarcomas that contained no fat, 16 (69.6%) were high grade (p=0.01). All the tumors with a myxoid component of less than 25% were high grade (p=0.01); 83.3% of those with a non-fatty / non-myxoid component greater than 50% were high grade (p=0.03) and 61.5% had more than 5% round cells (p=0.01). Diffusion sequences were obtained in 14 of the 36 patients; ADC values were high (median, 2 x 10-3 mm2/s), although there were no significant associations between low-grade and high-grade tumors. Contrast-enhanced images were available for 30 (83.3%) patients; 83.3% of the tumors with heterogeneous enhancement were high grade (p=0.01). CONCLUSIONS: MRI can be useful for differentiating between high- and low-grade myxoid liposarcomas and can help in clinical decision making.
ABSTRACT
The greater temporal resolution provided in ultrafast dynamic contrast-enhanced magnetic resonance imaging sequences makes it possible to know the physiological phenomenon of the distribution of the contrast material through a time-signal intensity curve. Analyzing these curves enables us to deduce information relevant to the vascularization and perfusion of tissues, capillary permeability, and the interstitial space in the tumor. A steep curve with early washout in a space-occupying lesion greatly increases the possibility of histological malignancy, although this type of curve is not rare in benign lesions and relatively flat curves are not rare in malignant tumors. Nevertheless, dynamic studies of the uptake of contrast material provide important information for the characterization of neoplasms that, together with the usual signs, can help to differentiate between benign and malignant tumors of adipocyte, chondroid, or neural lineage, clearing up diagnostic uncertainty in certain benign lesions such as osteoid osteoma and ischemic musculoskeletal disease. Furthermore, it enables the accurate determination of the response to chemotherapy, detecting recurrence within the treated tumor early, delimiting more precisely the margins between the tumor and peritumoral edema, and helping in diagnostic planning by determining the most vascularized areas of the tumor, which are more likely to be malignant.
Subject(s)
Bone Neoplasms/diagnosis , Magnetic Resonance Imaging , Muscle Neoplasms/diagnosis , Humans , Magnetic Resonance Imaging/methodsABSTRACT
La mayor resolución temporal que ofrece la secuencia de imágenes ultrarrápidas de la resonancia magnética contrastada dinámica (RMD), permite conocer el fenómeno fisiológico de la distribución del contraste mediante una curva de intensidad de señal-tiempo (TIC), de cuyo análisis puede deducirse información relevante sobre la vascularización y perfusión tisular, la permeabilidad capilar y el espacio intersticial del tumor. El hallazgo de una curva de pendiente elevada con lavado precoz de contraste en una lesión ocupante de espacio aumenta sensiblemente la posibilidad de malignidad histológica, aunque no es raro el hallazgo de curvas de este tipo en lesiones histológicamente benignas y de curvas de perfil relativamente plano en tumores de reconocida malignidad. A pesar de todo, los estudios dinámicos de captación pueden aportar información de gran interés en el proceso de caracterización de las lesiones neoformativas, ayudando a los restantes datos semiológicos habituales a diferenciar las formas malignas de las benignas en las tumoraciones de estirpe adipocítica, condroide o neural, confirmando dudas diagnósticas en determinadas lesiones benignas como el osteoma osteoide y la patología isquémica osteomuscular, permitiendo determinar con precisión el grado de respuesta a la quimioterapia, detectando con precocidad la recidiva en el seno del tumor tratado, delimitando con mayor exactitud los márgenes del tumor frente al edema peritumoral y ayudando a la planificación diagnóstica al determinar las áreas más vascularizadas y, por tanto, más probablemente malignas del tumor (AU)
The greater temporal resolution provided in ultrafast dynamic contrast-enhanced magnetic resonance imaging sequences makes it possible to know the physiological phenomenon of the distribution of the contrast material through a time-signal intensity curve. Analyzing these curves enables us to deduce information relevant to the vascularization and perfusion of tissues, capillary permeability, and the interstitial space in the tumor. A steep curve with early washout in a space-occupying lesion greatly increases the possibility of histological malignancy, although this type of curve is not rare in benign lesions and relatively flat curves are not rare in malignant tumors. Nevertheless, dynamic studies of the uptake of contrast material provide important information for the characterization of neoplasms that, together with the usual signs, can help to differentiate between benign and malignant tumors of adipocyte, chondroid, or neural lineage, clearing up diagnostic uncertainty in certain benign lesions such as osteoid osteoma and ischemic musculoskeletal disease. Furthermore, it enables the accurate determination of the response to chemotherapy, detecting recurrence within the treated tumor early, delimiting more precisely the margins between the tumor and peritumoral edema, and helping in diagnostic planning by determining the most vascularized areas of the tumor, which are more likely to be malignant (AU)
