5th ANNUAL EANS VASCULAR SECTION MEETING

7 – 8 SEPTEMBER 2018

NICE, FRANCE

http://vascular.squarespace.com/

The meeting is being held in conjunction with the annual ESMINT Congress.  A joint EANS/ESMINT session, also featuring a number of prominent speakers from both Europe and the US, will be organized again and we encourage as many as possible of you to support and attend this joint meeting as well.

The EANS Vascular Section Meeting provides an interdisciplinary platform for neurosurgeons, neurointerventionalists, neuroradiologists, neurologists, and others who are interested in the treatment of cerebrovascular diseases.

UpToDate: Decompressive craniectomy for intracerebral hemorrhage

Decompressive craniectomy for intracerebral hemorrhage

Systematic review

Yao et al. conducted a systematic review to verify the effects of decompressive craniectomy (DC) on improving outcome in spontaneous intracerebral hemorrhage.

Through searching several electronic databases, they screened eligible publications. Respective risk ratio (RR) and its 95% confidence interval (CI) were calculated, data were synthesized with a fixed-effect model, and sensitivity analyses and subgroup analyses were performed. Publication bias was measured with Begg and Egger tests.

Overall effect showed that DC significantly reduced the poor outcome compared with the control group (RR, 0.91; 95% CI, 0.84-0.99; P = 0.03). But in the subgroup analyses, only studies published after 2010, studies using hematoma evacuation as control, and studies measuring outcome with Glasgow outcome score showed better outcomes in the DC group than in the control group. The other subgroup analyses and sensitivity analyses achieved inconsistent results. Compared with the control group, DC effectively decreased mortality (RR, 0.67; 95% CI, 0.53-0.85; P = 0.0008). The sensitivity analyses and subgroup analyses achieved consistent results.

The application of DC effectively reduced mortality in patients with sICH. DC might improve functional outcomes in certain populations and needs further verification. DC is not associated with increased incidences of postoperative rebleeding and hydrocephalus 1).

Experimental work

Marinkovic et al. from Helsinki, Finland, used the model of autologous blood injection into the basal ganglia in rats. After induction of ICH and then magnetic resonance imaging, animals were randomly allocated to groups representing no craniectomy (n = 10) or to craniectomy at 1, 6, or 24 hours. A fifth group without ICH underwent craniectomy only. Neurological and behavioral outcomes were assessed on days 1, 3, and 7 after ICH induction. Furthermore, terminal deoxynucleotidyl transferase dUTP nick-end labeling-positive cells were counted.

After 7 days, compared with the ICH + no craniectomy group, all craniectomy groups had strikingly lower mortality (P < 0.01), much better neurological outcome (P < 0.001), and more favorable behavioral outcome. A trend occurred in the ICH + no craniectomy group toward more robust apoptosis.

Decompressive craniectomy performed up to 24 hours improved outcome after experimental ICH, with earlier intervention of greater benefit 2).

Case series

Rasras et al. from the Department of Neurosurgery, Ahvaz Jundishapur University of Medical Sciences, AhvazIran, sought to assess the preliminary utility of decompressive hemicraniectomy (DHC) without clot evacuation in patients with deep-seated supratentorial ICH.

Patients with deep seated spontaneous intracerebral hemorrhage who were admitted to the Golestan Hospital, of Ahvaz, from November 2014 to February 2016, were prospectively enrolled in a study. A prospective clinical trial where 30 patients diagnosed having large hypertensive ICH was randomly allocated to either group A or B using permuted-block randomization. These patients (n = 30), who all had large deep seated supratentorial ICH with surgery indications, were randomly divided to two groups. ultimately, in one group (n = 13), large DHC was performed without clot evacuation, while in the other (n = 17), craniotomy with clot evacuation was done. Data pertaining to the patients characteristics and treatment outcomes were prospectively collected.

There was no statistically significant difference between two treatment groups (P > 0.05). No significant difference was observed between the two groups in terms of mortality and GOS at 6 months (P > 0.05); nevertheless, the good outcome (Glasgow Outcome Scale = 4-5) for patients with hematoma evacuation was slightly higher (35.3%) as compared to the DHC patients without clot evacuation (30.7%).

Decompresive craniectomy without clot evacuation in deep seated ICH can be accomplished with identical mortality and outcome in comparison to patient that undergone clot evacuation 3).


A total of 54 eligible patients with spontaneous supratentorial hemorrhage (median age, 55 years; interquartile range, 47-64 years) who underwent decompressive craniectomy were retrospectively matched to 72 patients managed with best medical treatment (median age, 58 years; interquartile range, 32-74 years). Glasgow Outcome Scale (GOS) scores were dichotomized into favorable and unfavorable outcomes. Survival and functional outcomes were analyzed at discharge, 3, 6, and 12 months.

Survival in the craniectomy group was significantly higher compared with the medical treatment group at 30 days, 6, and 12 months (76%, 70%, and 70% vs. 60%, 57%, and 52% respectively; all P ≤ 0.05). There was no difference in functional outcomes at discharge, 3, 6, or 12 months after hemorrhage (all P > 0.05). Decompressive craniectomy was associated with longer hospital stay (median of 30 days vs. 7 days in the control group; P < 0.001). Hospital adverse events were more frequent in the craniectomy group than in the control group (76% vs. 33%; P < 0.001), the commonest adverse events being pneumonia and urinary tract infections.

They showed that decompressive craniectomy significantly improved survival compared with medical treatment with lasting benefits. This improvement came at a cost of increased length of hospital stay and related adverse events. There was no improvement in functional outcome 4).


Decompressive craniectomy is associated with a significant increase in perihematomal edema compared to patients who have been treated conservatively. Perihematomal edema itself lasts about 60 days if it is not treated, but decompressive craniectomy ameliorates the mass effect exerted by the intracerebral hemorrhage plus the perihematomal edema, as reflected by the reduced midline shift 5).


Of 21 patients who underwent DC for hemispheric hypertensive ICH in the Department of Neurosurgery, National Defense Medical College, Tokorozawa, Saitama, Japan, eleven of the patients were male and 10 were female, with an age range of 22-75 years (mean, 56.6 years). Their preoperative Glasgow Coma Scale scores ranged from 3 to 13 (mean, 6.9). The hematoma volumes ranged from 33.4 to 98.1 mL (mean, 74.2 mL), and the hematoma locations were the basal ganglia in 10 patients and the subcortex in 11 patients. Intraventricular extensions were observed in 11 patients. With regard to the complications after DC, postoperative hydrocephalus developed in ten patients, and meningitis was observed in three patients. Six patients had favorable outcomes and 15 had poor outcomes. The mortality rate was 10 %. A statistical analysis showed that the GCS score at admission was significantly higher in the favorable outcome group than that in the poor outcome group (P = 0.029). Our results suggest that DC with hematoma evacuation might be a useful surgical procedure for selected patients with large hemispheric hypertensive ICH 6).


Fung et al. compared consecutive patients (November 2010-January 2012) with supratentorial ICH treated with DC without hematoma evacuation and matched controls treated by best medical treatment. DC measured at least 150 mm and included opening of the dura. We analyzed clinical (age, sex, pathogenesis, Glasgow Coma Scale, National Institutes of Health Stroke Scale), radiological (signs of herniation, side and size of hematoma, midline shift, hematoma expansion, distance to surface), and surgical (time to and indication for surgery) characteristics. Outcome at 6 months was dichotomized into good (modified Rankin Scale 0-4) and poor (modified Rankin Scale 5-6).

Twelve patients (median age 48 years; interquartile range 35-58) with ICH were treated by DC. Median hematoma volume was 61.3 mL (interquartile range 37-83.5 mL) and median preoperative Glasgow Coma Scale was 8 (interquartile range 4.3-10). Four patients showed signs of herniation. Nine patients had good and 3 had poor outcomes. Three patients (25%) of the treatment group died versus 8 of 15 (53%) of the control group. There were 3 manageable complications related to DC.

DC is feasible in patients with ICH. Based on this small cohort, DC may reduce mortality. Larger prospective cohorts are warranted to assess safety and efficacy 7).


Records of 12 consecutive patients with hypertensive ICH treated with decompressive hemicraniectomy were reviewed. The data collected included Glasgow Coma Scale (GCS) score at admission and before surgery, ICH volume, ICH score, and a clinical grading scale for ICH that accurately risk-stratifies patients regarding 30-day mortality. Outcome was assessed as immediate mortality and modified Rankin Score (mRS) at the last follow-up.

Of the 12 patients with decompressive hemicraniectomy, 11 (92%) survived to discharge; of those 11, 6 (54.5%) had good functional outcome, defined as a mRS of 0 to 3 (mean follow-up: 17.13 months; range: 2-39 months). The mean age was 49.8 years (range: 19-76 years). Three of the 7 patients with pupillary abnormalities made a good recovery; of the 11 patients with intraventricular extensions (IVEs), 7 made a good recovery. The clinical finding (which was present in all 3 patients with mRS equal to 5 and which was not present in patients with mRS less than 5) was abnormal occulocephalic reflex. Of the 10 patients with an ICH score of 3, 9 (90%) survived to discharge, 4 (44%) had good functional outcome (mRS: 1-3). Hematoma volume was 60 cm3 or greater in eight patients, four (50%) of whom had good functional outcome (mRS: 0-3).

Decompressive hemicraniectomy with hematoma evacuation is life-saving and improves unfavorable outcomes in a select group of young patients with large right hemispherical ICH 8).

References

1)

Yao Z, Ma L, You C, He M. Decompressive Craniectomy for Spontaneous Intracerebral Hemorrhage: A Systematic Review and Meta-analysis. World Neurosurg. 2018 Feb;110:121-128. doi: 10.1016/j.wneu.2017.10.167. Epub 2017 Nov 10. Review. PubMed PMID: 29129764.
2)

Marinkovic I, Strbian D, Pedrono E, Vekovischeva OY, Shekhar S, Durukan A, Korpi ER, Abo-Ramadan U, Tatlisumak T. Decompressive craniectomy for intracerebral hemorrhage. Neurosurgery. 2009 Oct;65(4):780-6, 1 p following 786; discussion 786. doi: 10.1227/01.NEU.0000351775.30702.A9. PubMed PMID: 19834384.
3)

Rasras S, Safari H, Zeinali M, Jahangiri M. Decompressive hemicraniectomy without clot evacuation in supratentorial deep-seated intracerebral hemorrhage. Clin Neurol Neurosurg. 2018 Aug 23;174:1-6. doi: 10.1016/j.clineuro.2018.08.017. [Epub ahead of print] PubMed PMID: 30172088.
4)

Lo YT, See AAQ, King NKK. Decompressive Craniectomy in Spontaneous Intracerebral Hemorrhage: A Case-Control Study. World Neurosurg. 2017 Jul;103:815-820.e2. doi: 10.1016/j.wneu.2017.04.025. Epub 2017 Apr 17. PubMed PMID: 28427977.
5)

Fung C, Murek M, Klinger-Gratz PP, Fiechter M, Z’Graggen WJ, Gautschi OP, El-Koussy M, Gralla J, Schaller K, Zbinden M, Arnold M, Fischer U, Mattle HP, Raabe A, Beck J. Effect of Decompressive Craniectomy on Perihematomal Edema in Patients with Intracerebral Hemorrhage. PLoS One. 2016 Feb 12;11(2):e0149169. doi: 10.1371/journal.pone.0149169. eCollection 2016. PubMed PMID: 26872068; PubMed Central PMCID: PMC4752325.
6)

Takeuchi S, Takasato Y, Masaoka H, Hayakawa T, Yatsushige H, Shigeta K, Nagatani K, Otani N, Nawashiro H, Shima K. Decompressive craniectomy with hematoma evacuation for large hemispheric hypertensive intracerebral hemorrhage. Acta Neurochir Suppl. 2013;118:277-9. doi: 10.1007/978-3-7091-1434-6_53. PubMed PMID: 23564148.
7)

Fung C, Murek M, Z’Graggen WJ, Krähenbühl AK, Gautschi OP, Schucht P, Gralla J, Schaller K, Arnold M, Fischer U, Mattle HP, Raabe A, Beck J. Decompressive hemicraniectomy in patients with supratentorial intracerebral hemorrhage. Stroke. 2012 Dec;43(12):3207-11. doi: 10.1161/STROKEAHA.112.666537. Epub 2012 Oct 30. PubMed PMID: 23111437.
8)

Murthy JM, Chowdary GV, Murthy TV, Bhasha PS, Naryanan TJ. Decompressive craniectomy with clot evacuation in large hemispheric hypertensive intracerebral hemorrhage. Neurocrit Care. 2005;2(3):258-62. PubMed PMID: 16159072.

UpToDate: Spontaneous posterior fossa subdural hematoma

Spontaneous posterior fossa subdural hematoma

Posterior fossa subdural hematomas may be spontaneous, with no previous trauma. These cases are usually secondary to bleeding from an underlying pathology such as arteriovenous malformation (AVM), aneurysm 1),tumor or coagulation disorder2) 3).

see also Spontaneous retroclival subdural hematoma.

Posterior fossa craniectomy may be preferable in terms of diagnosis and safe treatment 4).

Outcome

Prognosis seems to be related to the clinical condition of the patient at the moment of surgery, according to the GCS. Patients with mild symptomatology usually have a good outcome, whereas, in most cases, there is no improvement if a moderate or severe neurologic deficit has already been established 5) 6).

Case reports

Finger G, Martins OG, Basso LS, Ludwig do Nascimento T, Schiavo FL, Cezimbra Dos Santos S, Stefani MA. Acute spontaneous subdural hematoma in posterior fossa: case report with great outcome. World Neurosurg. 2018 Aug 1. pii: S1878-8750(18)31700-5. doi: 10.1016/j.wneu.2018.07.220. [Epub ahead of print] PubMed PMID: 30077031.


A 69-year-old woman was admitted with nausea, headache, and mild consciousness disturbance. Computed tomography and magnetic resonance imaging showed bilateral pCSH. To prevent further neurological deterioration, we performed surgery under general anesthesia by midline suboccipital craniectomy. Unexpected bleeding from a developed circuitous occipital sinus was stopped with hemoclips. After hematoma removal, she recovered and was transferred to a rehabilitation hospital. By the 19(th) postoperative day, she had developed no neurologic deficits.

This experience demonstrates the risk of blind surgical therapy in patients with pCSH. In such patients, posterior fossa craniectomy may be preferable in terms of diagnosis and safe treatment 7).


A 83-year-old woman was admitted with recent sudden headache and dizziness. Magnetic resonance imaging showed a thin collection of blood in the subdural space adjacent to the clivus, along the wall of the posterior fossa, and at the cervical spine level. A right posterior communicating artery aneurysm was diagnosed using computed tomography angiography and digital subtraction angiography. The aneurysm had two lobes, one of which was attached to the right dorsum sellae. The aneurysm was occluded by stent-assisted coil embolization. The patient was discharged 3 weeks after admission with absence of neurological deficit.

A ruptured aneurysm of the posterior communicating artery may cause an acute SDH 8).


A rare case of concomitant cranial and spinal subdural haematoma (SDH) in a 12-year-old boy with severe thrombocytopenia due to aplastic anaemia, and review the available literature. Magnetic resonance (MR) imaging at presentation revealed a cranial SDH confined to the posterior fossa, and spinal SDH extending from the C1 to S3 segments. The child was managed conservatively due to his poor general condition and lack of any neurological deficit. Repeat MR imaging done at six weeks showed complete resolution of the spinal SDH and partial resolution of the cranial SDH. Although rare, a spontaneous spinal SDH can occur simultaneously with a cranial SDH. Urgent surgical decompression is considered the treatment of choice for spinal SDH; however, a conservative approach may succeed in patients with poor general condition, and/or mild/no neurological deficit 9).


Berhouma M, Houissa S, Jemel H, Khaldi M. Spontaneous chronic subdural hematoma of the posterior fossa. J Neuroradiol. 2007 Jul;34(3):213-5. PubMed PMID: 17572494 10).


Usul et al., present a spontaneous posterior fossa subdural hematoma in a term neonate and discuss conservative management 11).


A case of spontaneous acute subdural haematoma in the posterior fossa following anticoagulation 12).


The association of the posterior fossa chronic subdural hematoma with spontaneous parenchymal hemorrhage without anticoagulation therapy was never related in the literature. Costa et al., describe a case of a 64 year-old woman who suffered a spontaneous cerebellar hemorrhage, treated conservatively, and presented 1 month later with a chronic subdural posterior fossa hematoma 13).


Miranda et al., present a case of a posterior fossa acute subdural hematoma occurring in an anticoagulated patient who was preoperatively misdiagnosed as an intracerebellar hemorrhage 14).


A 52-year-old woman treated for acute myeloproliferative disease developed progressive stupor. CT showed obstructive hydrocephalus resulting from unexplained mass effect on the fourth ventricle. MRI revealed bilateral extra-axial collections in the posterior cranial fossa, giving high signal on T1- and T2-weighted images, suggesting subacute subdural haematomas. Subdural haematomas can be suspected on CT when there is unexplained mass effect. MRI may be essential to confirm the diagnosis and plan appropriate treatment 15).


A 70 year old female presented with progressive dizziness, vertigo and gait ataxia. She was on anticoagulation therapy for heart disease. Neuro-imaging revealed bilateral infratentorial subdural masses. The subdural masses were suspects for chronic subdural haematomas by neuroradiological criteria. Because of the progressive symptomatology, the haematomas were emptied through burrhole trepanations. Chocolate-colored fluid, not containing clotted components, gushed out under great pressure. The source of bleeding could not be identified. The patient recovered well from surgery, but died 4 months later shortly after admission to another hospital from heart failure.

The chronic subdural haematomas in this patient may have been due to rupture of bridging veins caused by a very mild trauma not noticed by the patient and possibly aggravated by the anticoagulation therapy. Infratentorial chronic subdural haematoma should at least be a part of the differential diagnosis in elderly patients with cerebellar and vestibular symptomatology even without a history of trauma 16).


A case of spontaneous acute subdural hematoma complicated with idiopathic thrombocytopenic purpura was reported. He was hospitalized complaining of sudden onset of headache and nasal bleeding without neurological deficit. CT scan revealed subdural hematoma in the posterior fossa especially below the tentorium cerebelli. Further hematological examination proved very low platelet count (1,000/mm3) and antiplatelet antibody in confirmation of a diagnosis of idiopathic thrombocytopenic purpura. As his neurological status was good, he was treated medically. His symptoms and platelet count improved gradually with corticosteroid therapy. Reviewing the literature, acute subdural hematoma with idiopathic thrombocytopenic purpura was quite rare and only three cases reported 17).


Aicher KP, Heiss E, Gawlowski J. [Spontaneous subdural hematoma in the posterior cranial fossa]. Rofo. 1988 Dec;149(6):669-70. German. PubMed PMID: 2849170 18).


Kanter et al., report a patient in whom a spontaneous subdural hematoma developed in the posterior fossa during anticoagulation therapy for mitral valve disease. This rare complication of anticoagulation has been reported in only three other patients 19).


A case of spontaneous posterior fossa subdural hematoma secondary to anticoagulation therapy with definitive diagnosis made by vertebral angiography is reported. Vertebral angiographic findings are illustrated and demonstrate primarily mass effect from posterior compartment of posterior fossa and avascular area. Carotid angiography did not show hydrocephalus. A review of the literature was made and this appears to be the first reported case in which a posterior fossa subdural hematoma has been diagnosed by vertebral angiography 20).


A report of spontaneous posterior fossa subdural haematoma associated with anticoagulation therapy. The possibility of posterior fossa lesions related to spontaneous haemorrhage is suggested by the combination of severe headache and increasing disturbance of consciousness associated with signs of brain-stem decompensation. A thorough neurological evaluation including appropriate contrast studies will help rule out a supratentorial lesion. This is a neurological emergency which can be successfully treated by early detection and prompt surgical decompression. This is the second reported case of spontaneous subdural haematoma of the posterior fossa occurring during anticoagulant therapy 21).

References

1) , 8)

Kim MS, Jung JR, Yoon SW, Lee CH. Subdural hematoma of the posterior fossa due to posterior communicating artery aneurysm rupture. Surg Neurol Int. 2012;3:39. doi: 10.4103/2152-7806.94287. Epub 2012 Mar 24. PubMed PMID: 22530173; PubMed Central PMCID: PMC3327002.
2) , 16)

Stendel R, Schulte T, Pietilä TA, Suess O, Brock M. Spontaneous bilateral chronic subdural haematoma of the posterior fossa. Case report and review of the literature. Acta Neurochir (Wien). 2002 May;144(5):497-500. Review. PubMed PMID: 12111507.
3) , 10)

Berhouma M, Houissa S, Jemel H, Khaldi M. Spontaneous chronic subdural hematoma of the posterior fossa. J Neuroradiol. 2007 Jul;34(3):213-5. PubMed PMID: 17572494.
4) , 7)

Takemoto Y, Matsumoto J, Ohta K, Hasegawa S, Miura M, Kuratsu J. Bilateral posterior fossa chronic subdural hematoma treated with craniectomy: Case report and review of the literature. Surg Neurol Int. 2016 May 6;7(Suppl 10):S255-8. doi: 10.4103/2152-7806.181979. eCollection 2016. PubMed PMID: 27213111; PubMed Central PMCID: PMC4866054.
5) , 14)

Miranda P, Alday R, Lagares A, Pérez A, Lobato RD. Posterior fossa subdural hematoma mimicking intracerebellar hemorrhage. Neurocirugia (Astur). 2003 Dec;14(6):526-8. PubMed PMID: 14710308.
6) , 15)

Pollo C, Meuli R, Porchet F. Spontaneous bilateral subdural haematomas in the posterior cranial fossa revealed by MRI. Neuroradiology. 2003 Aug;45(8):550-2. Epub 2003 May 22. PubMed PMID: 12761603.
9)

Jain V, Singh J, Sharma R. Spontaneous concomitant cranial and spinal subdural haematomas with spontaneous resolution. Singapore Med J. 2008 Feb;49(2):e53-8. Review. PubMed PMID: 18301828.
11)

Usul H, Karaarslan G, Cakir E, Kuzeyl K, Mungan L, Baykal S. Conservative management of spontaneous posterior fossa subdural hematoma in a neonate. J Clin Neurosci. 2005 Feb;12(2):196-8. PubMed PMID: 15749432.
12)

Pal D, Gnanalingham K, Peterson D. A case of spontaneous acute subdural haematoma in the posterior fossa following anticoagulation. Br J Neurosurg. 2004 Feb;18(1):68-9. PubMed PMID: 15040720.
13)

Costa LB Jr, de Andrade A, Valadão GF. Chronic subdural hematoma of the posterior fossa associated with cerebellar hemorrhage: report of rare disease with MRI findings. Arq Neuropsiquiatr. 2004 Mar;62(1):170-2. Epub 2004 Apr 28. PubMed PMID: 15122456.
17)

Saito K, Sakurai Y, Uenohara H, Seki K, Imaizumi S, Katakura R, Niizuma H. [A case of acute subdural hematoma in the posterior fossa with idiopathic thrombocytopenic purpura]. No To Shinkei. 1992 Apr;44(4):377-81. Review. Japanese. PubMed PMID: 1633035.
18)

Aicher KP, Heiss E, Gawlowski J. [Spontaneous subdural hematoma in the posterior cranial fossa]. Rofo. 1988 Dec;149(6):669-70. German. PubMed PMID: 2849170.
19)

Kanter R, Kanter M, Kirsch W, Rosenberg G. Spontaneous posterior fossa subdural hematoma as a complication of anticoagulation. Neurosurgery. 1984 Aug;15(2):241-2. PubMed PMID: 6483141.
20)

McClelland RR, Ramirez-Lassepas M. Posterior fossa subdural hematoma demonstrated by vertebral angiography. Neuroradiology. 1976;10(1):181-5. PubMed PMID: 1256644.
21)

Capistrant T, Goldberg R, Shibasaki H, Castle D. Posterior fossa subdural haematoma associated with anticoagulant therapy. J Neurol Neurosurg Psychiatry. 1971 Feb;34(1):82-5. PubMed PMID: 5313648; PubMed Central PMCID: PMC493691.

UpToDate: Internal carotid artery segments

Internal carotid artery segments

The course of the internal carotid artery (ICA) and its segment classifications were reviewed by means of a new and freely available interactive 3D model of the artery and the skull base, based on human neuroimages, that can be freely downloaded at the Public Repository of the University of Barcelona ( http://diposit.ub.edu/dspace/handle/2445/112442 ) and runs under Adobe Acrobat Reader in Mac and Windows computers and Windows 10 tablets. The 3D-PDF allows zoom, rotation, selective visualization of structures, and a predefined sequence view. Illustrative images of the different classifications were obtained 1).

In 1938 Fischer, described five internal carotid artery segments in the opposite direction to the blood flow 2).

These segments were based on the angiographic course of the intracranial ICA rather than its arterial branches or anatomic compartments. Subsequent attempts to apply modern nomenclature to these numerical segments failed to recognize Fischer’s original intent of describing patterns of arterial displacement by tumors and, therefore, resulted in a nomenclature that was anatomically inaccurate. Fischer’s system was further limited, because segments were numbered opposite the direction of blood flow and the extracranial ICA was excluded 3).


Gibo et al. in 1981 studied the microsurgical anatomy of the supraclinoid portion of the internal carotid artery (ICA) in 50 adult cadaver cerebral hemispheres using X 3 to X 40 magnification. The ICA was divided into four parts: the C1 or cervical portion; the C2 or petrous portion; the C3 or cavernous portion; and the C4 or supraclinoid portion.

The C4 portion was divided into three segments based on the origin of its major branches: the ophthalmic segment extended from the origin of the ophthalmic artery to the origin of the posterior communicating artery (PCoA); the communicating segment extended from the origin of the PCoA to the origin of the anterior choroidal artery (AChA); and the choroidal segment extended from the origin of the AChA to the bifurcation of the carotid artery. Each segment gave off a series of perforating branches with a relatively constant site of termination. The perforating branches arising from the ophthalmic segment passed to the optic nerve and chiasminfundibulum, and the floor of the third ventricle. The perforating branches arising from the communicating segment passed to the optic tract and the floor of the third ventricle. The perforating branches arises from the choroidal segment passed upward and entered the brain through the anterior perforated substance. The anatomy of the ophthalmic, posterior communicating, anterior choroidal, and superior hypophyseal branches of the C4 portion was also examined. Gibo-Rothon (J Neurosurg 55:560-574, 1981) follow the blood flow, incorporated the cervical and petrous portions, and divided the subarachnoid course-supraclinoid-in ophthalmic, communicating, and choroidal segments, enhancing transcranial microscopic approaches 4).


see Bouthillier classification.

Bouthillier et al. described in 1996 a seven segment internal carotid artery (ICA) classification system. It remains the most widely used system for describing ICA segments.


The Kassam’s group (2014), with an endoscopic endonasal perspective, introduces the “paraclival segment,” including the “lacerum segment” and part of the intracavernous ICA, and details surgical landmarks to minimize the risk of injury 5).

see also Carotid Siphon

AC: anterior clinoid process; ICA: internal carotid artery; LT: lamina terminalis; ON: optic nerve; OlN; olfactory nerve; SW: sphenoid wing; TS: tuberculum sellae; A1: A1 segment of the Anterior Cerebral Artery; A2: A2 segment of the Anterior Cerebral Artery; M1: M1 segment of the Middle Cerebral Artery

Endoscopic classification

Based on anatomic correlations, the ICA may be described as 6 distinct segments:

(1) parapharyngeal (common carotid artery bifurcation to carotid canal)

(2) petrous (carotid canal to posterolateral aspect of foramen lacerum)

(3) paraclival (posterolateral foramen lacerum to the superomedial aspect of the petrous apex)

(4) parasellar (superomedial petrous apex to the proximal dural ring)

(5) paraclinoid (from the proximal to the distal dural rings)

(6) intradural (distal ring to ICA bifurcation).

Corresponding surgical landmarks included the Eustachian tube, the fossa of Rosenmüller, and levator veli palatini for the parapharyngeal segment; the vidian canal and V3 for the petrous segment; the fibrocartilage of foramen lacerumforamen rotundummaxillary strut, lingular process of the sphenoid bone, and paraclival protuberance for the paraclival segment; the sellar floor and petrous apex for the parasellar segment; and the medial and lateral opticocarotid and lateral tubercular recesses, as well as the distal osseous arch of the carotid sulcus for the paraclinoid segment 6).

see Intracavernous internal carotid artery.

References

1)

Melé MV, Puigdellívol-Sánchez A, Mavar-Haramija M, Juanes-Méndez JA, Román LS, De Notaris M, Catapano G, Prats-Galino A. Review of the main surgical and angiographic-oriented classifications of the course of the internal carotid artery through a novel interactive 3D model. Neurosurg Rev. 2018 Jul 26. doi: 10.1007/s10143-018-1012-7. [Epub ahead of print] Review. PubMed PMID: 30051302.
2)

Fischer E. Die Lageabweichungen der vorderen hirnarterie im gefässbild. Zentralbl Neurochir. 1938;3:300–313.
3)

Bouthillier A, van Loveren HR, Keller JT. Segments of the internal carotid artery: a new classification. Neurosurgery. 1996 Mar;38(3):425-32; discussion 432-3. PubMed PMID: 8837792.
4)

Gibo H, Lenkey C, Rhoton AL Jr. Microsurgical anatomy of the supraclinoid portion of the internal carotid artery. J Neurosurg. 1981 Oct;55(4):560-74. PubMed PMID: 7277004.
5) , 6)

Labib MA, Prevedello DM, Carrau R, Kerr EE, Naudy C, Abou Al-Shaar H, Corsten M, Kassam A. A road map to the internal carotid artery in expanded endoscopic endonasal approaches to the ventral cranial base. Neurosurgery. 2014 Sep;10 Suppl 3:448-71. doi: 10.1227/NEU.0000000000000362. PubMed PMID: 24717685.

UptoDate: Indocyanine green videoangiography for intracranial aneurysm

Indocyanine green videoangiography for intracranial aneurysm

Indocyanine green videoangiography for intracranial aneurysm is applied in order to assess intra-operatively both aneurysm sac obliteration and vessel patency after clipping.

Although digital subtraction angiography (DSA) may be considered the gold standard for intraoperative vascular imaging, many neurosurgical centers rely only on indocyanine green videoangiography (ICG-VA) for the evaluation of clipping accuracy.

In a Systematic Review and Meta-Analysis of Riva et al., from BrusselsLeuvenBelgiumMonzaItaly and ChicagoIllinois because a proportion of mis-clippings cannot be identified with ICG-VA, this technique should still be considered complementary rather than a replacement to DSA during aneurysm surgery. Incorporating other intraoperative tools, such as flowmetry or electrophysiological monitoring, can obviate the need for intraoperative DSA for the identification of vessel stenosis. Nevertheless, DSA likely remains the best tool for the detection of aneurysm remnants 1).

Its a safe and effective modality of intraoperative blood flow assessment and reduces the incidence of postoperative ischaemic complications 2).

However, ICGV-derived data have been reported to be misleading at times. Della Puppa et al., noted that a simple intra-operative maneuver (the “squeezing maneuver”) allows the detection of deceptive ICGV data on aneurysm exclusion and allows potential clip repositioning. The “squeezing maneuver” is based on a gentle pinch of the dome of a clipped aneurysm when ICGV documents its apparent exclusion.

Data from 23 consecutive patients affected by intracranial aneurysms who underwent the “squeezing maneuver” were retrospectively analyzed. The clip was repositioned in all cases when the dyeing of the sac was visualized after the maneuver.

In 22% of patients, after an initial ICGV showing the aneurysm exclusion after clipping, the squeezing maneuver caused the prompt dyeing of the sac; in all cases the clip was consequently repositioned. A calcification/atheroma of the wall/neck was predictive of a positive maneuver (p= 0.0002). The aneurysm exclusion rate at post-operative radiological findings was 100%.

With the limits of this small series, the “squeezing maneuver” appears helpful in the intra-operative detection of misleading ICGV data, mostly when dealing with aneurysms with atheromasic and calcified walls 3).

In selected cases, endoscopic ICG angiographies (e-ICG-A) provides the neurosurgeon with information that cannot be obtained by microscopic ICG angiography (m-ICG-A). E-ICG-A is capable of emerging as a useful adjunct in aneurysm surgery and has the potential to further improve operative results 4).

Indocyanine green (ICG) videoangiography (VA) in cerebral aneurysm surgery allows confirmation of blood flow in parent, branching, and perforating vessels as well as assessment of remnant aneurysm parts after clip application. A retrospective analysis from Two hundred forty-six procedures were performed in 232 patients harboring 295 aneurysms. The patients, whose mean age was 54 years, consisted of 159 women and 73 men. One hundred twenty-four surgeries were performed after subarachnoid hemorrhage, and 122 were performed for incidental aneurysms. Single aneurysms were clipped in 185 patients, and multiple aneurysms were clipped in 47 (mean aneurysm diameter 6.9 mm, range 2-40 mm). No complications associated with ICG-VA occurred. Intraoperative microvascular Doppler ultrasonography was performed before ICG-VA in all patients, and postoperative digital subtraction angiography (DSA) studies were available in 121 patients (52.2%) for retrospective comparative analysis. In 22 (9%) of 246 procedures, the clip position was modified intraoperatively as a consequence of ICG-VA. Stenosis of the parent vessels (16 procedures) or occlusion of the perforators (6 procedures), not detected by micro-Doppler ultrasonography, were the most common problems demonstrated on ICG-VA. In another 11 procedures (4.5%), residual perfusion of the aneurysm was observed and one or more additional clips were applied. Vessel stenosis or a compromised perforating artery occurred independent of aneurysm location and was about equally common in middle cerebral artery and anterior communicating artery aneurysms. In 2 procedures (0.8%), aneurysm puncture revealed residual blood flow within the lesion, which had not been detected by the ICG-VA. In the postoperative DSA studies, unexpected small (< 2 mm) aneurysm neck remnants, which had not been detected on intraoperative ICG-VA, were found in 11 (9.1%) of 121 patients. However, these remnants remained without consequence except in 1 patient with a 6-mm residual aneurysm dome, which was subsequently embolized with coils.

Its a helpful intraoperative tool and led to a significant intraoperative clip modification rate of 15%. However, small, < 2-mm-wide neck remnants and a 6-mm residual aneurysm were missed by intraoperative ICG-VA in up to 10% of patients. Results in this study confirm that DSA is indispensable for postoperative quality assessment in complex aneurysm surgery 5).

References

1)

Riva M, Amin-Hanjani S, Giussani C, De Witte O, Bruneau M. Indocyanine Green Videoangiography in Aneurysm Surgery: Systematic Review and Meta-Analysis. Neurosurgery. 2018 Aug 1;83(2):166-180. doi: 10.1093/neuros/nyx387. PubMed PMID: 28973404.
2)

Lai LT, Morgan MK. Use of indocyanine green videoangiography during intracranial aneurysm surgery reduces the incidence of postoperative ischaemic complications. J Clin Neurosci. 2014 Jan;21(1):67-72. doi: 10.1016/j.jocn.2013.04.002. Epub 2013 Oct 1. PubMed PMID: 24090515.
3)

Della Puppa A, Rustemi O, Rossetto M, Gioffrè G, Munari M, Charbel FT, Scienza R. The “Squeezing Maneuver” in Microsurgical Clipping of Intracranial Aneurysms Assisted by Indocyanine Green Video-angiography (ICGV). Neurosurgery. 2014 Mar 3. [Epub ahead of print] PubMed PMID: 24594928.
4)

Mielke D, Malinova V, Rohde V. Comparison of Intraoperative Microscopic and Endoscopic ICG-angiography in Aneurysm Surgery. Neurosurgery. 2014 Mar 10. [Epub ahead of print] PubMed PMID: 24618802.
5)

Roessler K, Krawagna M, Dörfler A, Buchfelder M, Ganslandt O. Essentials in intraoperative indocyanine green videoangiography assessment for intracranial aneurysm surgery: conclusions from 295 consecutively clipped aneurysms and review of the literature. Neurosurg Focus. 2014 Feb;36(2):E7. doi: 10.3171/2013.11.FOCUS13475. PubMed PMID: 24484260.

UpToDate: Agitation

Agitation

Hyperactive delirium (agitation) is an emotional state of excitement or restlessness.

Hyperactive delirium (agitation) is a common complication in patients on intensive care units.

Psychomotor agitation, an extreme form of the above, which can be part of a mental illness or a side effect of anti-psychotic medication.

Assesment

Sedation Agitation Scale.


Postoperative agitation frequently occurs after general anesthesia and may be associated with serious consequences. However, studies in neurosurgical patients have been inadequate.

Huang et al., from the Beijing Tiantan Hospital and the Mongolia People’s Hospital, China. aimed to investigate the incidence and risk factors for early postoperative agitation in patients after craniotomy, specifically focusing on the association between postoperative pneumocephalus and agitation. Adult intensive care unit admitted patients after elective craniotomy under general anesthesia were consecutively enrolled. Patients were assessed using the Sedation Agitation Scale during the first 24 hours after operation. The patients were divided into two groups based on their maximal Sedation-Agitation Scale: the agitation (Sedation-Agitation Scale ≥ 5) and non-agitation groups (Sedation-Agitation Scale ≤ 4). Preoperative baseline data, intraoperative and intensive care unit admission data were recorded and analyzed. Each patient’s computed tomography scan obtained within six hours after operation was retrospectively reviewed. Modified Rankin Scale and hospital length of stay after the surgery were also collected. Of the 400 enrolled patients, agitation occurred in 13.0% (95% confidential interval: 9.7-16.3%). Body mass index, total intravenous anesthesia, intraoperative fluid intake, intraoperative bleeding and transfusionconsciousness after operation, endotracheal intubation kept at intensive care unit admission and mechanical ventilation, hyperglycemia without a history of diabetes, self-reported pain and postoperative bi-frontal pneumocephalus were used to build a multivariable model. Bi-frontal pneumocephalus and delayed extubation after the operation were identified as independent risk factors for postoperative agitation. After adjustment for confounding, postoperative agitation was independently associated with worse neurologic outcome (odd ratio: 5.4, 95% confidential interval: 1.1-28.9, P = 0.048).

The results showed that early postoperative agitation was prevalent among post-craniotomy patients and was associated with adverse outcomes. Improvements in clinical strategies relevant to bi-frontal pneumocephalus should be considered 1).


Sauvigny et al., from the University Medical Centre Hamburg-Eppendorf Germany, performed a retrospective analysis in three hundred thirty-eight patients with aneurysmal subarachnoid hemorrhage resulting in 212 patients which reached at least once a Richmond Sedation Agitation Scale(RASS) of 0 and were eligible for further analysis. Clinical characteristics were analysed towards the occurrence of a hyperactive delirium. Neurological outcome at discharge and follow-up was assessed using the Glasgow Outcome Scale. Seventy-eight of 212 patients (36.8%) developed a hyperactive delirium; the duration ranged from 1 to 11 days. Multivariate regression revealed initial hydrocephalus (odds ratio (OR) 3.21 95% confidence interval (CI) [1.33-7.70]; p = 0.01), microsurgical clipping (OR 3.70 95%CI 1.71-8.01]; p = 0.001), male gender (OR 1.97 95%CI [1.05-3.85]; p = 0.047) and a higher Graeb score (OR 1.11 95%CI [1.00-1.22]; p = 0.043) to be significantly associated with the development of agitation. Medical history of psychiatric disorders, alcohol or nicotine abuse showed no correlation with agitation. Cox regression analysis revealed no significant influence of agitation towards unfavourable outcome at discharge or follow-up.

They provided four independent risk factors for the development of agitation in SAH patients. The study emphasizes the specific entity of agitation in patients with SAH and underscores its relevance in neurological patients 2).

References

1)

Huang HW, Yan LM, Yang YL, He X, Sun XM, Wang YM, Zhang GB, Zhou JX. Bi-frontal pneumocephalus is an independent risk factor for early postoperative agitation in adult patients admitted to intensive care unit after elective craniotomy for brain tumor: A prospective cohort study. PLoS One. 2018 Jul 19;13(7):e0201064. doi: 10.1371/journal.pone.0201064. eCollection 2018. PubMed PMID: 30024979.
2)

Sauvigny T, Mohme M, Grensemann J, Dührsen L, Regelsberger J, Kluge S, Schmidt NO, Westphal M, Czorlich P. Rate and risk factors for a hyperactivity delirium in patients with aneurysmal subarachnoid haemorrhage. Neurosurg Rev. 2018 Jun 9. doi: 10.1007/s10143-018-0990-9. [Epub ahead of print] PubMed PMID: 29948495.

UptoDate: Medulla Oblongata Cavernous Malformation

Medulla Oblongata Cavernous Malformation

see also Brainstem cavernous malformation.

53 patients underwent surgical treatment for Medulla Oblongata Cavernous Malformations between 2011 and 2017 in the Beijing Tiantan Hospital with a male-to-female ratio of 1.4 and a mean age of 32.6 years. Eighteen patients (34.0%) had respiratory failure, and two patients (3.8%) had cardiac instabilities, preoperatively. The mean mRS score was 2.7 upon admission. Gross total resection was achieved in 52 patients (98.1%). Postoperatively, twenty-three patients (43.4%) had respiratory dysfunction, and sixteen patients (30.2%) had dysphagia or coughing. The mean follow-up duration was 35.7 months. At the last follow-up evaluation, the mean mRS score was 1.7, and 42 patients (84%) had favorable outcomes, with mRS scores ≤ 2. The conditions of the patients improved in 34 cases (68%), remained unchanged in 10 cases (20%), and worsened in 6 cases (12%) relative to the preoperative baseline. The independent adverse factors for long-term outcome were age ≥ 50 years old and increased time of reservation of tracheal intubationafter surgery.

Surgical treatment of CMs involving the medulla oblongata was very challenging, notably, perioperative respiratory dysfunction, with which patients tend to have unfavorable long-term outcomes, especially for elderly patients 1).


A 28-year-old man who was presented with intractable hiccup for 15 days. It developed suddenly, then aggravated progressively and did not respond to any types of medication. On magnetic resonance images, a well-demarcated and non-enhancing mass with hemorrhagic changes was noted in the left medulla oblongata. Intraoperative findings showed that the lesion was fully embedded within the brain stem and pathology confirmed the diagnosis of cavernous hemangioma. The hiccup resolved completely after the operation. Based on the presumption that the medullary cavernoma may trigger intractable hiccup by displacing or compression the hiccup arc of the dorsolateral medulla, surgical excision can eliminate the symptoms, even in the case totally buried in brainstem 2).


A 61-year-old woman presented with vertigo and swallowing disturbance. T1-weighted magnetic resonance image (MRI) showed a low intensity mass in the dorsolateral portion of the medulla oblongata, and T2-weighted imaging revealed a hemosiderin rim surrounding the lesion. Angiography showed no abnormalities. Surgery using far lateral approach achieved complete removal of the mass and hematoma. Histological examination of the surgical specimen disclosed cavernous angioma. This case suggests that direct surgery can be recommended for cavernous angioma located in the dorsal or lateral medulla oblongata to remove the hematoma and angioma if bleeding clearly provokes neurological symptoms 3).

1)

Xie MG, Xiao XR, Li D, Guo FZ, Zhang JT, Wu Z, Zhang LW. Surgical Treatment of Cavernous Malformations Involving the Medulla Oblongata: 53 Cases. World Neurosurg. 2018 Jul 4. pii: S1878-8750(18)31429-3. doi: 10.1016/j.wneu.2018.06.213. [Epub ahead of print] PubMed PMID: 29981463.
2)

Lee KH, Moon KS, Jung MY, Jung S. Intractable hiccup as the presenting symptom of cavernous hemangioma in the medulla oblongata: a case report and literature review. J Korean Neurosurg Soc. 2014 Jun;55(6):379-82. doi: 10.3340/jkns.2014.55.6.379. Epub 2014 Jun 30. PubMed PMID: 25237438; PubMed Central PMCID: PMC4166338.
3)

Abe M, Ogawa A, Yoshida Y, Hidaka T, Suzuki M, Takahashi S. Surgical removal of cavernous angioma in the medulla oblongata. A case report. Neurosurg Rev. 1997;20(2):128-31. Review. PubMed PMID: 9226673.
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