De Perrot Thomas, Sadjo Zoua Christine, Glessgen Carl G, Botsikas Diomidis, Berchtold Lena, Salomir Rares, De Seigneux Sophie, Thoeny Harriet C, Vallée Jean-Paul
Division of Radiology, Geneva University Hospitals and University of Geneva, 1205 Geneva, Switzerland.
Division of Nephrology, Geneva University Hospitals, 1205 Geneva, Switzerland.
J Clin Med. 2022 Mar 30;11(7):1921. doi: 10.3390/jcm11071921.
Diffusion weighted imaging (DWI) constitutes a major functional parameter performed in Magnetic Resonance Imaging (MRI). The DW sequence is performed by acquiring a set of native images described by their b-values, each b-value representing the strength of the diffusion MR gradients specific to that sequence. By fitting the data with models describing the motion of water in tissue, an apparent diffusion coefficient (ADC) map is built and allows the assessment of water mobility inside the tissue. The high cellularity of tumors restricts the water diffusion and decreases the value of ADC within tumors, which makes them appear hypointense on ADC maps. The role of this sequence now largely exceeds its first clinical apparitions in neuroimaging, whereby the method helped diagnose the early phases of cerebral ischemic stroke. The applications extend to whole-body imaging for both neoplastic and non-neoplastic diseases. This review emphasizes the integration of DWI in the genitourinary system imaging by outlining the sequence's usage in female pelvis, prostate, bladder, penis, testis and kidney MRI. In gynecologic imaging, DWI is an essential sequence for the characterization of cervix tumors and endometrial carcinomas, as well as to differentiate between leiomyosarcoma and benign leiomyoma of the uterus. In ovarian epithelial neoplasms, DWI provides key information for the characterization of solid components in heterogeneous complex ovarian masses. In prostate imaging, DWI became an essential part of multi-parametric Magnetic Resonance Imaging (mpMRI) to detect prostate cancer. The Prostate Imaging-Reporting and Data System (PI-RADS) scoring the probability of significant prostate tumors has significantly contributed to this success. Its contribution has established mpMRI as a mandatory examination for the planning of prostate biopsies and radical prostatectomy. Following a similar approach, DWI was included in multiparametric protocols for the bladder and the testis. In renal imaging, DWI is not able to robustly differentiate between malignant and benign renal tumors but may be helpful to characterize tumor subtypes, including clear-cell and non-clear-cell renal carcinomas or low-fat angiomyolipomas. One of the most promising developments of renal DWI is the estimation of renal fibrosis in chronic kidney disease (CKD) patients. In conclusion, DWI constitutes a major advancement in genitourinary imaging with a central role in decision algorithms in the female pelvis and prostate cancer, now allowing promising applications in renal imaging or in the bladder and testicular mpMRI.
扩散加权成像(DWI)是磁共振成像(MRI)中的一项主要功能参数。DW序列通过采集一组由其b值描述的原始图像来执行,每个b值代表该序列特定的扩散MR梯度强度。通过将数据与描述组织中水分子运动的模型进行拟合,可以构建表观扩散系数(ADC)图,并用于评估组织内水分子的流动性。肿瘤的高细胞密度限制了水分子扩散,降低了肿瘤内ADC值,这使得肿瘤在ADC图上呈低信号。该序列的作用现在已大大超出了其在神经影像学中的首次临床应用,当时该方法有助于诊断脑缺血性中风的早期阶段。其应用扩展到全身成像,用于肿瘤性和非肿瘤性疾病。本综述通过概述该序列在女性盆腔、前列腺、膀胱、阴茎、睾丸和肾脏MRI中的应用,强调了DWI在泌尿生殖系统成像中的整合。在妇科成像中,DWI是宫颈肿瘤和子宫内膜癌特征性诊断以及区分子宫平滑肌肉瘤和良性平滑肌瘤的重要序列。在卵巢上皮性肿瘤中,DWI为异质性复杂卵巢肿块中实性成分的特征性诊断提供关键信息。在前列腺成像中,DWI成为多参数磁共振成像(mpMRI)检测前列腺癌的重要组成部分。前列腺影像报告和数据系统(PI-RADS)对显著前列腺肿瘤的可能性进行评分,对这一成功做出了重大贡献。其贡献使mpMRI成为前列腺活检和根治性前列腺切除术规划的强制性检查。采用类似方法,DWI被纳入膀胱和睾丸的多参数检查方案中。在肾脏成像中,DWI不能可靠地区分恶性和良性肾肿瘤,但可能有助于对肿瘤亚型进行特征性诊断,包括透明细胞和非透明细胞肾癌或低脂血管平滑肌脂肪瘤。肾脏DWI最有前景的发展之一是对慢性肾脏病(CKD)患者肾纤维化的评估。总之,DWI是泌尿生殖系统成像的一项重大进展,在女性盆腔和前列腺癌的决策算法中发挥核心作用,现在在肾脏成像或膀胱和睾丸mpMRI中有着前景广阔的应用。
