Abstract
Background
Pineal region tumours remain challenging neurosurgical pathologies.
Methods
Detailed anatomical knowledge of the posterior incisural space and its variations is critical. An opaque arachnoidal membrane seals the internal cerebral and basal veins, leading to thalamic, basal ganglia, mesencephalic/pontine infarctions if injured. Medium-size tumours can be removed en-bloc with all traction/manipulation applied on the tumour side, virtually without contact of ependymal surfaces of the pulvinars or third ventricle. Sacrifice of the cerebello-mesencephalic fissure vein may be required.
Conclusions
The sitting position offers superior anatomical orientation and remains safe with experienced teams. Meticulous microsurgical techniques and detailed anatomical knowledge are likely to secure safe outcomes.
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Relevant surgical anatomy
The complex pineal region can be accessed by the supracerebellar/infratentorial (SC/IT) approach, occipital transtentorial, posterior interhemispheric transcallosal and the combined supra-/IT approach, for giant tumours. Although off midline (lateral and far-lateral) approaches are available for pineal region tumours, the midline IT/SC approach offers optimal surgical orientation in the region of posterior incisura, bounded superiorly by the inferior aspect of the splenium, the forniceal crura and the hippocampal commissure and inferiorly by the vermian culmen, and medially and laterally, by the central and quadrangular lobules, respectively [7]. The posterior incicura extends inferior to the cerebellomesencephalic fissure that accomodates its corresponding vein, also termed precentral vein, a key, midline venous landmark (Fig. 4b, c).
Vascular anatomy
The second (P2) and third (P3) segments of the posterior cerebral artery (PCA) lie between the thalamic pulvinar and superior colliculi, while loops of the superior cerebellar artery (SCA) are often visible anterior to pineal gland. The surgical venous anatomy of the pineal region is complex and are covered by an arachnoid layer of varied thickness, ranging from thick and opaque to thin and translucent (Fig. 4b). The vein of Galen (VG) is the most dorsal part of the venous complex, joining the straight sinus (SS) while the paramedian, paired basal veins of Rosenthal (BvRo) exit the ambient cistern and converge to the VG. The internal cerebral veins (ICv) lie deeper, laterally and slightly underneath the BvRo exiting through the cistern of the velum interpositum, also converging to the VG [4].
Cisternal anatomy
The unpaired quadrigeminal cistern contains all three major venous systems, VG, the confluences of both BvRo and ICvs, P4 and the posterior medial choroidal artery. The paired ambient cisterns contain P2 and P3, the anterior choroidal artery, the CvRo and SCA segments. The cistern of the velum interpositum, extending from the foramen of Monroe anteriorly to the habenula encloses the ICvs and the posterior medial choroidal artery. The quadrigeminal and velum interpositum cisterns communicate with the posterior pericallosal cistern [4] (Fig. 1).
Description of the technique
Preoperative work-up
The SC/IT approach in the sitting position (SP) offers optimal surgical field without cerebellar retraction but is fraught with the most feared systematic complication, venous air embolism [2, 3] (Tables 1 and 2). Reported incidence of VAE varies significantly as accurate diagnostic criteria are not standardised. In addition, not all transoesophageal echo-detected VAE are clinically significant (Table 1). A bubble echo can exclude patent foramen ovale, detected in 30% of population, a SP contraindication.
Anaesthetic technique
Routine monitoring includes ECG, continuous end-tidal CO2 (ETCO2), oxygen saturations, spirometry, continuous invasive pressure monitoring and right internal jugular vein cannulation (CVC), allowing use of vasopressors, in cardiovascular collapse [8]. Patients are ventilated with an inspired concentration of oxygen (FiO2) 40–50%. Indications of potential VAE include hypotension, sudden drop in ETCO2 with no change in ventilation settings or drop in oxygen saturations depending on FiO2. The neurosurgeon is alerted while the FiO2 is increased to 100%, and the surgical field is covered with wet swabs, irrigated with saline. The operating table is tilted head-down to prevent further air entrainment and aid with the VAE-associated hypotension treated with vasopressors and fluid resuscitation. Aspiration of air from the CVC can be performed if its tip is positioned at the superior vena cava/right atrial junction.
Positioning
The SP is assumed gradually aiming for midline head position with neck flexion (Table 2 and Fig. 2). Neuronavigation can be employed but is of limited assistance, due to depth and proximity of small, key structures.
Opening
Following a midline muscle dissection from the external occipital protuberance to C2, a craniectomy is performed exposing completely the inferior half of the transverse sinus, initially thinning the bone with a diamond drill and completing the removal with 2-mm Kerrison’s rongeurs. A craniotomy can, alternatively, be performed, provided that the transverse sinus exposure is performed in a controlled and gradual way to avoid inadvertent sinus injury. Adequate lateral and inferior bony removals are critical during exposure allowing wide angle approach and cerebellar fall under gravity, respectively (Fig. 3). The foramen magnum remains intact to avoid cerebellar slump.
Tumour exposure
The dura is opened in a standard “Y” fashion. Cortical veins suspending the superior cerebellar surface from the tentorium are diathermised at their tentorial attachment, allowing the cerebellum to fall freely, inferiorly. The vermian culmen is followed directly inferiorly until the tentorial edges are identified (Fig. 4a) with an opaque arachnoid membrane stretching over the pineal region, thalami and tectal plate. The thickness of the arachnoid varies according to pathology, from significant to thin (Fig. 4b). Sharp dissection is avoided as the BvRos are directly vulnerable.
Tumour resection
Prior to any tumour resection, a clear understanding of the surgical field with the position of the vCMF, BvRo, ICv, VG, P3, P4, SCA, superior colliculi and pulvinars (Fig. 4b, c) is required; the pineal gland is not discernible. In addition, the consistency, vascularity, adherence to thalami and tectal plate of the tumour are assessed. The vCMF can be sacrificed in larger tumours.
Although a large tumour can be debulked, our technique is attempting en-bloc removal, as the safest way to distinguish tumoral from normal tissue. A microdissector Rhoton #8 (Integra, Plainsboro, NJ) is used to circumferentially develop a plane with all traction applied to the tumour rather than adjacent brain. The circumferential plane develops easier initially laterally from the pulvinar of the thalami (Fig. 5a), then inferiorly from the tectal plate and finally superiorly from the splenium of the corpus callosum (Fig. 5b).
No bipolar diathermy is used unless for rare selective vessel coagulation. Once the majority of the tumour is dissected, it can be manipulated as one block revealing its interface and final attachments which are again released with Rhoton #8. The posterior third ventricle is exposed last; the ependymal surfaces remain impeccable with no evidence of manipulation injury (Fig. 5c). A watertight closure with dural patch and dural sealant minimises the risk of CSF leak or pseudomeningocele. Postoperative MRI scan shows complete tumour removal (Fig. 6).
Indications
Tumours originating from the pineal gland (pineocytomas, pineoblastomas); germ cells (teratoma, embryonal carcinoma, choriocarcinoma); non-germ cell (tectal glioma, falcotentorial meningioma).
Limitations
Despite the uncommon frequency of these tumours, the IT/SC approach should be undertaken by teams on a relatively regular basis, as anaesthetic and surgical aspects can be challenging.
How to avoid complications
Carefully planned, layer-by-layer dissection of the pineal region is critical, as major venous injury cannot be repaired and most likely will result in stroke. Sound knowledge of the surgical venous, arterial and neural anatomy of the pineal region is critical.
Information given to the patient
The patient is consented for systemic complications including VAE, and neurological complications including arterial or venous injury and stroke.
Change history
19 May 2021
The ESM is missing and is now corrected.
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Additional information
10 Key Points summary
1. The sitting position requires team experience.
2. Bone-waxing during exposure reduces VAE risk.
3. The surgical anatomy of the pineal region requires regular exposure.
4. The slope of the tentorium is acute in the majority of cases, without precluding the IT/SC approach.
5. In a dry surgical field, the risk of air embolism is greater compared to a haemorrhagic field.
6. Curved, vs straight, micro-scissors in deep, narrow spaces offer better depth appreciation.
7. Dissection should take place manipulating the tumour rather than the adjacent pulvinars or colliculi.
8. Sharp dissection of the arachnoid membrane covering the pineal carries risk of venous injury.
9. Arterial injury of P4, P3, P2 or SCA is less likely as they are laterally placed but not impossible.
10. Care should be taken to identify and protect the ICvs or BvRo to avoid deep venous infarctions.
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Sharma, P., Abdul, M., Waraich, M. et al. Pineal region tumours in the sitting position: how I do it. Acta Neurochir 164, 79–85 (2022). https://doi.org/10.1007/s00701-021-04821-3
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DOI: https://doi.org/10.1007/s00701-021-04821-3