J Neurosurg. 2022 Aug 26;138(3):768-784. doi: 10.3171/2022.6.JNS212907. Print 2023 Mar 1.
Anatomical triangles defined by intersecting neurovascular structures delineate surgical routes to pathological targets and guide neurosurgeons during dissection steps. Collections or systems of anatomical triangles have been integrated into skull base surgery to help surgeons navigate complex regions such as the cavernous sinus. The authors present a system of triangles specifically intended for resection of brainstem cavernous malformations (BSCMs). This system of triangles is complementary to the authors' BSCM taxonomy that defines dissection routes to these lesions.
The anatomical triangle through which a BSCM was resected microsurgically was determined for the patients treated during a 23-year period who had both brain MRI and intraoperative photographs or videos available for review.
Of 183 patients who met the inclusion criteria, 50 had midbrain lesions (27%), 102 had pontine lesions (56%), and 31 had medullary lesions (17%). The craniotomies used to resect these BSCMs included the extended retrosigmoid (66 [36.1%]), midline suboccipital (46 [25.1%]), far lateral (30 [16.4%]), pterional/orbitozygomatic (17 [9.3%]), torcular (8 [4.4%]), and lateral suboccipital (8 [4.4%]) approaches. The anatomical triangles through which the BSCMs were most frequently resected were the interlobular (37 [20.2%]), vallecular (32 [17.5%]), vagoaccessory (30 [16.4%]), supracerebellar-infratrochlear (16 [8.7%]), subtonsillar (14 [7.7%]), oculomotor-tentorial (11 [6.0%]), infragalenic (8 [4.4%]), and supracerebellar-supratrochlear (8 [4.4%]) triangles. New but infrequently used triangles included the vertebrobasilar junctional (1 [0.5%]), supratrigeminal (3 [1.6%]), and infratrigeminal (5 [2.7%]) triangles. Overall, 15 BSCM subtypes were exposed through 6 craniotomies, and the approach was redirected to the BSCM by one of the 14 triangles paired with the BSCM subtype.
A system of BSCM triangles, including 9 newly defined triangles, was introduced to guide dissection to these lesions. The use of an anatomical triangle better defines the pathway taken through the craniotomy to the lesion and refines the conceptualization of surgical approaches. The triangle concept and the BSCM triangle system increase the precision of dissection through subarachnoid corridors, enhance microsurgical execution, and potentially improve patient outcomes.
由神经血管结构相交定义的解剖三角形描绘了通向病理靶标的手术路径,并在解剖步骤中指导神经外科医生。解剖三角形集合或系统已被整合到颅底外科中,以帮助外科医生在诸如海绵窦等复杂区域进行导航。作者提出了一种专门用于切除脑干海绵状畸形(BSCM)的三角形系统。该三角形系统是作者 BSCM 分类法的补充,该分类法定义了通向这些病变的解剖路径。
对在 23 年期间接受治疗的同时具有脑部 MRI 和术中照片或视频可供审查的患者,通过显微镜下切除 BSCM 所经过的解剖三角形进行了确定。
符合纳入标准的 183 名患者中,50 名患者有中脑病变(27%),102 名患者有桥脑病变(56%),31 名患者有延髓病变(17%)。用于切除这些 BSCM 的颅切开术包括扩展的乙状窦后入路(66 [36.1%])、中线枕下入路(46 [25.1%])、远外侧入路(30 [16.4%])、翼点/眶颧入路(17 [9.3%])、旋前窝(8 [4.4%])和侧枕下入路(8 [4.4%])。BSCM 最常通过的解剖三角形是叶间(37 [20.2%])、 vallecular(32 [17.5%])、 vagoaccessory(30 [16.4%])、小脑上蚓部-小脑下蚓部(16 [8.7%])、枕下(14 [7.7%])、动眼神经-小脑幕(11 [6.0%])、 infratrigeminal(8 [4.4%])和小脑上-小脑幕上(8 [4.4%])三角形。新但很少使用的三角形包括椎基底动脉结合部(1 [0.5%])、三叉神经上(3 [1.6%])和三叉神经下(5 [2.7%])三角形。总体而言,通过 6 种颅切开术暴露了 15 种 BSCM 亚型,通过 14 种与 BSCM 亚型之一配对的三角形中的一种将手术入路重新定向到 BSCM。
引入了一种 BSCM 三角形系统,包括 9 个新定义的三角形,以指导对这些病变的解剖。解剖三角形的使用更好地定义了通过颅切开术到达病变的路径,并细化了手术入路的概念化。三角形概念和 BSCM 三角形系统增加了通过蛛网膜下腔通道进行解剖的精度,增强了显微手术的执行能力,并可能改善患者的预后。
