Ventriculomegaly and postoperative lateral/third ventricular blood as predictors of cerebrospinal fluid diversion following posterior fossa tumor resection.

OBJECTIVE: Postoperative hydrocephalus occurs in one-third of children after posterior fossa tumor resection. Although models to predict the need for CSF diversion after resection exist for preoperative variables, it is unknown which postoperative variables predict the need for CSF diversion. In this study, the authors sought to determine the clinical and radiographic predictors for CSF diversion in children following posterior fossa tumor resection. METHODS: This was a retrospective cohort study involving patients ≤ 18 years of age who underwent resection of a primary posterior fossa tumor between 2000 and 2018. The primary outcome was the need for CSF diversion 6 months after surgery. Candidate predictors for CSF diversion including age, race, sex, frontal occipital horn ratio (FOHR), tumor type, tumor volume and location, transependymal edema, papilledema, presence of postoperative intraventricular blood, and residual tumor were evaluated using a best subset selection method with logistic regression. RESULTS: Of the 63 included patients, 26 (41.3%) had CSF diversion at 6 months. Patients who required CSF diversion had a higher median FOHR (0.5 vs 0.4) and a higher percentage of postoperative intraventricular blood (30.8% vs 2.7%) compared with those who did not. A 0.1-unit increase in FOHR or intraventricular blood was associated with increased odds of CSF diversion (OR 2.9 [95% CI 1.3-7.8], p = 0.02 and OR 20.2 [95% CI 2.9-423.1], p = 0.01, respectively) with an overfitting-corrected concordance index of 0.68 (95% CI 0.56-0.80). CONCLUSIONS: The preoperative FOHR and postoperative intraventricular blood were significant predictors of the need for permanent CSF diversion within 6 months after posterior fossa tumor resection in children.

Visualization of Anatomic Variation of the Anterior Septal Vein on Susceptibility-Weighted Imaging.

BACKGROUND AND PURPOSE: Understanding the anatomy of the anterior septal vein (ASV) is critical for minimally invasive procedures to the third ventricle and for assessing lesion size and venous drainage in the anterior cranial fossa. Accordingly, this study evaluated topographic anatomy and anatomic variation of the ASV using susceptibility-weighted imaging (SWI). METHODS: Sixty volunteers were examined using a 3.0T MR system. The diameter of the ASV and distance between bilateral septal points were measured. ASVs were divided into types 1 (only drains frontal lobe) and 2 (drains both frontal lobe and head of the caudate nucleus). We evaluated the ASV-internal cerebral vein (ICV) junction based on its positional relationship with the appearance of a venous angle or a false venous angle and the foramen of Monro. Fused SW and T1-weighted images were used to observe positional relationships between the course of the ASV and the surrounding brain structures. RESULTS: The ASV and its small tributaries were clearly visualized in 120 hemispheres (100%). The average diameter of ASVs was 1.05±0.17 mm (range 0.9-1.6 mm). The average distance between bilateral septal points was 2.23±1.03 mm (range 1.3-6.6 mm). The ASV types 1 and 2 were in 77 (64.2%) and 43 (35.8%) hemispheres, respectively. In 83 (69.2%) hemispheres, the ASV-ICV junction was situated at the venous angle and the posterior margin of the foramen of Monro. In 37 (30.8%) hemispheres, the ASV-ICV junction was situated beyond the posterior margin of the foramen of Monro. The average distance between the posteriorly located ASV-ICV junction and the posterior margin of the foramen of Monro was 6.41±3.95 mm (range 2.4-15.9 mm). CONCLUSION: Using SWI, the topographic anatomy and anatomic variation of the ASV were clearly demonstrated. Preoperative assessment of anatomic variation of the ASV may be advantageous for minimally invasive neurosurgical procedures.

A new protocol to treat moderate to severe intraventricular hemorrhage with obstructive hydrocephalus.

OBJECTIVES: For patients with intraventricular hemorrhage (IVH) accompanied by obstructive hydrocephalus, external ventricular drainage (EVD) alone is proven to be often insufficient, and lumbar drainage (LD) is proven promising but considered contraindicative in the acute phase. The objective was to analyze the safety and feasibility of treatment for IVH with early continuous LD (CLD) in addition to open EVD regardless of the presence of acute obstructive hydrocephalus. METHODS: In this prospective study, 10 consecutive patients with moderate to severe IVH received emergency EVD and early CLD insertion regardless of the presence of obstructive hydrocephalus or blood clots in the third and fourth ventricles. During the whole course of treatment, the EVD was kept open at a safe height until replaced by CLD alone. When the drained CSF from CLD was nearly normal, gradual weaning of the CLD was attempted. Ventriculoperitoneal (VP) shunt would be performed if there was evidence of communicating hydrocephalus. RESULTS: In all the cases, EVD could be safely replaced by CLD alone. There was no evidence of axial herniation or infection, and no requirement of EVD revision. After CLD weaning, only two patients underwent VP shunt procedure. Follow-up study on 3 months and 6 months demonstrated that 7 (70%) patients had good (Glasgow Outcome Scale (GOS) 4 to 5) outcome and 1 (10%) patient died 1 month after discharge due to renal failure. CONCLUSIONS: RESULTS suggest that this new therapy which combines EVD with early CLD insertion is safe and easy to manage moderate to severe IVH with obstructive hydrocephalus.

Tuber cinereum proximity to critical major arteries: a morphometric imaging analysis relevant to endoscopic third ventriculostomy.

BACKGROUND: Arterial bleeding in the interpeduncular fossa is a dreaded complication of endoscopic third ventriculostomy (ETV). When the "safe zone" of the tuber cinereum (TC) is fenestrated, the basilar artery tip (BT) or its branches may be encountered below the third ventriclular floor. Major arterial injuries might be avoided by careful preoperative planning. We aimed to establish previously unavailable normal magnetic resonance imaging (MRI) and MR angiographic (MRA) morphometry and configuration of the BT and posterior cerebral artery P1 segments relative to the TC. METHODS: We analyzed images of 82 patients with non-dilated ventricles (mean Evans' index 0.26), and lying in a neutral head position (mean cervico-medullary angle 141°). We cross-referenced axial MRAs with sagittal MRIs to measure distances of BT and P1 segments from the TC, and to classify the location of the BT in the interpeduncular and suprasellar cisterns. We correlated the sagittal areas of these cisterns and patients' ages with the TC-to-artery distances using regression analysis. RESULTS: The BT, right P1 and left P1 segments were a mean 4.9 mm, 5.5 mm, and 5.7 mm respectively from the TC. Seventy-four percent of BTs were anterior to the mammillary bodies. These distances and locations did not correlate with age (mean 53 years) or size of basal cisterns. CONCLUSIONS: The normal BT and P1 segments are anatomically close to the TC and potentially at risk during ETV in adults of all ages. The new morphometric data presented, along with cross-referencing of preoperative multiplanar images, could help reduce vascular complications during ETV.

Analysis of blood flow in a third ventricular ependymoma and an olfactory bulb meningioma by using perfusion computed tomography.

Brain perfusion computed tomography (CT) scanning was performed in a mongrel dog and a golden retriever that were diagnosed with third ventricular tumor and olfactory bulb tumor, respectively, by contrast-enhanced CT. The tumors were pathologically diagnosed as ependymoma and meningioma, respectively. Perfusion CT results revealed that the ependymoma in this study had a lower blood flow, higher blood volume, and greater transit time of blood than the adjacent brain tissue. Further, the meningioma in this study had a higher blood flow, higher blood volume, and greater transit time of blood than the adjacent brain tissue. Perfusion CT can potentially be used for the grading of brain tumors and narrowing differential diagnosis, provided the perfusion CT data of animals are accumulated.

Microsurgical and endoscopic anatomy of Liliequist's membrane: a complex and variable structure of the basal cisterns.

OBJECTIVE: Descriptions of Liliequist's membrane, as reported in the literature, vary considerably. In our cadaveric study of Liliequist's membrane, we attempted to clarify and define its anatomic features and boundaries, as well as its relationship with surrounding neurovascular structures. We describe the embryology of this membrane as a remnant of the primary tentorium. The clinical significance of our findings is discussed with respect to third ventriculostomy and surgical approaches to basilar tip aneurysms, suprasellar arachnoid cysts, and perimesencephalic hemorrhage. METHODS: Thirteen formalin-fixed adult cadaveric heads were injected with colored silicone. After endoscopic exploration of Liliequist's membrane, a bilateral frontal craniotomy was performed, and the frontal lobes were removed to fully expose Liliequist's membrane. RESULTS: Liliequist's membrane is a complex and highly variable structure that is composed of either a single membrane or two leaves. The membrane was absent in two specimens without any clear demarcation between the interpeduncular, prepontine, and chiasmatic cisterns. CONCLUSION: Understanding the variable anatomy of Liliequist's membrane is important, particularly to improve current and forthcoming microsurgical and endoscopic neurosurgical procedures. It is important as a surgical landmark in various neurosurgical operations and in the physiopathology of several pathological processes (suprasellar arachnoid cysts and perimesencephalic hemorrhage).

The middle perforated substance of the diencephalon.

The diencephalon, upper brain stem and other basal brain structures are supplied chiefly by penetrating branches of the cerebral arteries. We examined the retrochiasmatic space between the superior border of the pons and posterior edge of the optic chiasm in six randomly selected adult fresh brain specimens. Lateral or anterolateral to the mamillary bodies, two small quadrangular spaces (2.5 x 3.5 mm) were found that were limited laterally by the junction of the optic tract and crus cerebri. These spaces were pierced on each side by 1 to 5 small penetrating branches (premamillary arterial complex) of the posterior communicating artery. A single, large and obliquely oriented penetrating branch of the posterior communicating artery (the so-called premamillary, thalamotuberal or mamillothalamic artery) was found to pierce this area in all specimens. Based on our findings, the above-mentioned vessels of this perforating substance supply the floor of third ventricle, hypothalamus and ventral thalamic nuclei. Hence, special attentions should be made during surgery in this area such as third ventriculostomy for hydrocephalus.

Description of endoscopic ventricular anatomy in myelomeningocele.

OBJECTIVE: The purpose of this work is to present our endoscopic neuroanatomical findings of a series of myelomeningocele and hydrocephalus patients, treated with endoscopic third ventricular cisternostomy (ETVC), in order to describe ventricular configuration abnormalities in this group of patients, in which this neurosurgical procedure has limited performance. METHOD: We checked the videos of 10 endoscopic third ventricular cisternostomies of myelomeningocele patients taken during 24 months as from December 1998. A previous guideline is designed to record anatomic variables in the lateral ventricles, IIIrd ventricle, and basal cisterns. The topic is analyzed in view of the necropsy and imaging background data. RESULTS: The ETVC of lateral ventricles showed: absence of septum (9/10); absence of anteroseptal vein (8/10); absence of choroid plexus and thalamostriate vein (0/10); absence of fornix (1/10): small foramen of Monro (4/10). The ETVC of the IIIrd ventricle showed: impossibility of recognizing any mammillary bodies (4/10); presence of septations (5/10); presence of atypical veins in the floor (6/10); translucent floor (5/10); floor umbilications (5/10); absence of infundibulum (4/10); arachnoid adherences (7/10); and visual contact of basilar artery (4/10). CONCLUSION: There are categorical structural alterations in the ventricular system of myelomeningocele patients that are well correlated with previous necropsy and imaging reports. The ventricular system of dysraphic children presents severe anatomic alterations, which alter the reference points of the classical endoscopic third ventricular cisternostomy.

Microsurgical anatomy of the venous drainage of the mesencephalodiencephalic junction.

OBJECTIVE: The veins draining the posterior wall of the third ventricle and its adjacent structures and the posterior part of the midbrain have been the most neglected of the intracranial vascular structures in both the anatomic and neurosurgical literature. During our dissections of the pineal region and the quadrigeminal cistern, we did not always encounter topographic anatomy as described in previous articles. The purpose of this study is to describe the topographic anatomy and normal variations of the specific veins that drain the collicular plate and the pineal body and their adjacent structures with a view to better defining neurosurgical approaches to the pineal region. METHODS: The deep cerebral veins draining the pineal body, the collicular plate, and their surrounding neural structures were examined on both sides of 25 adult cadaveric brains. In all specimens, the carotid and vertebral arteries and the jugular veins were perfused with red or blue silicone, respectively, to facilitate dissection under x3 to x40 magnification. RESULTS: The venous plexus on the dorsal aspect of the collicular plate drains via collicular veins according to three different patterns. These types of drainage are closely related to the existence or absence of the basal vein on one or both sides. CONCLUSION: The veins draining the superior and inferior aspects of the pineal body form a superior and an inferior pineal vein that usually drain into the internal or great cerebral vein.

Venous variations in the region of the third ventricle: the role of MR venography.

In this study, we examined the anatomical variations of the subependymal veins in the region of the foramen of Monro and the third ventricle by MR time of flight (TOF) venography. Fifty healthy subjects, ten patients with third-ventricle tumors, and four patients with lateral-ventricle tumors were included in the study. The courses of the anterior septal vein (ASV), thalamostriate vein (TSV), and internal cerebral vein (ICV) were studied. The proximity of the venous angle, the false venous angle, and the ASV-ICV junction to the posterior margin of the foramen of Monro was measured. In 69 (53.9%) sides, the ASV-ICV junction was located at the venous angle and at the posterior margin of the foramen of Monro. In 59 (46.1%) sides, the ASV-ICV junction was located beyond the foramen of Monro. Our study shows the high incidence of posteriorly located ASV-ICV junctions, which can be crucial in the planning of a better surgical approach. We strongly recommend that MR venography, which is a short radiological examination, be used before one operates on third-ventricle and lateral-ventricle tumors.

Third ventricle cavernoma associated with venous angioma. Case report and review of the literature.

A case of third ventricle cavernous angioma associated with venous angioma is reported. By a transventricular approach, the cavernoma was totally removed with successful preservation of the venous malformation. After review of the literature, the clinical characteristics and the surgical approach to third ventricle cavernous angioma are discussed; the importance of preservation of associated venous angioma is also underlined.