Neurosurgery in Turkey — Brain Tumour Surgery, Awake Craniotomy, Spinal Surgery and Pituitary Surgery at Eyeglow Istanbul
Neurosurgical consultation, second opinion, and treatment coordination in Istanbul — brain tumour resection (gliomas, meningiomas, metastases) with awake craniotomy, intraoperative MRI, neuronavigation, and 5-ALA fluorescence-guided resection; spinal surgery (discectomy, decompression, fusion); endoscopic transsphenoidal pituitary surgery; and cerebral aneurysm clipping. Coordinated through Eyeglow Health's accredited partner neurosurgical network at JCI-aligned hospitals. Honest disclosure: craniotomy carries 1–3% mortality and 5–25% neurological deficit risk depending on location — stated explicitly in every written care plan.
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Neurosurgery — scope and approach
Neurosurgery encompasses surgical procedures on the brain, spinal cord, vertebral column, peripheral nervous system, and cerebral vasculature. It requires one of the most specialised surgical training pathways in medicine — typically 6–8 years of postgraduate residency followed by subspecialty fellowship. Modern neurosurgery integrates advanced intraoperative technology: neuronavigation (GPS-precision instrument tracking relative to pre-operative MRI), intraoperative MRI or CT (real-time imaging during resection), awake craniotomy for eloquent area mapping, and fluorescence-guided surgery (5-ALA for glioma margin identification).
A second opinion before elective intracranial or spinal surgery is standard at major academic centres internationally — neurosurgery is irreversible, and the right approach, timing, and indication matter as much as technical execution.
From imaging review to surgical recovery
- 01
Online consultation + imaging review
You share your MRI brain (with and without gadolinium contrast — full sequences including FLAIR, DWI, perfusion, spectroscopy if available), CT spine, or cerebrovascular imaging (CTA, DSA) as applicable. Clinical history: symptoms and timeline (headache, seizures, focal neurological deficit, visual changes, weakness, speech difficulty), prior neurosurgical procedures, prior radiotherapy to head/spine, current neurological status, performance status. Our neurosurgery coordinator flags completeness of imaging — standard MRI protocol is not always adequate for surgical planning; 3T MRI with thin-slice volumetric MPRAGE is optimal. The partner neurosurgeon receives a full pre-clinic imaging summary before your consultation.
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Neurosurgeon assessment + MDT brain tumour board
For brain tumours: the partner board-certified neurosurgeon reviews your imaging with neuroradiology. Your case is presented at the multi-disciplinary neuro-oncology tumour board including neurosurgeon, neuro-oncologist, radiation oncologist, neuroradiologist, and neuropathologist. The board determines resection extent (gross total resection vs subtotal resection vs biopsy-only vs watchful waiting), need for intraoperative functional mapping, adjuvant treatment pathway (Stupp protocol for GBM — concurrent temozolomide + radiotherapy, then adjuvant temozolomide), and rehab needs. For spinal surgery: neurosurgeon reviews MRI/CT with neurophysiology, pain clinic, and physiotherapy MDT. For vascular lesions: neurointerventional radiologist and vascular neurosurgeon joint assessment.
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Pre-operative workup and surgical planning
Brain surgery pre-op: functional MRI (fMRI) for eloquent area mapping if lesion is near motor, language, or visual cortex — determines awake vs asleep craniotomy approach. Diffusion tensor imaging (DTI) / tractography to map white matter tracts (corticospinal tract, arcuate fasciculus, optic radiation). Neuropsychological baseline assessment (important for post-operative comparison and medico-legal documentation). Seizure management review (levetiracetam, dexamethasone preoperatively for oedema). Baseline neurology assessment. Anaesthesiology consultation — awake craniotomy requires specific anaesthetic protocol (asleep-awake-asleep or conscious sedation technique). Spinal surgery pre-op: neurophysiology consultation, pain quantification (VAS, ODI), physiotherapy assessment, anaesthesiology.
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Surgical procedure
Craniotomy (brain tumour): bony flap removal to expose underlying brain, dural opening, tumour identification with neuronavigation (GPS-based tracking of surgical instruments relative to pre-operative MRI), intraoperative MRI/CT (available at partner hospital — allows real-time imaging to confirm resection extent before closing), fluorescence guidance with 5-ALA (aminolevulinic acid) where indicated (glioma resection — 5-ALA causes malignant glioma cells to fluoresce pink under violet light, improving margin identification). Awake craniotomy: patient is woken during the resection phase for real-time cortical mapping — neuropsychologist or speech therapist conducts tasks (name objects, move hand, count) while neurosurgeon monitors for function disruption; correlates directly with reduced post-operative neurological deficit rate in eloquent-area tumours. Spinal surgery: discectomy (single-level minimally invasive via tubular retractor or microscope-assisted), laminectomy/laminoplasty for decompression, spinal fusion (TLIF, PLIF, ALIF — choice depends on segment and pathology), neuromonitoring (MEP/SSEP intraoperative).
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Post-operative care and neurological monitoring
Post-craniotomy: neurocritical care unit (NCU) or high-dependency unit for 24–48 hours minimum. Neurological monitoring: GCS, focal deficit assessment, pupillary response every 1–2 hours. CT head within 24 hours of surgery to rule out haematoma or hydrocephalus. Dexamethasone wean (oedema reduction). Seizure prophylaxis review. Early physiotherapy and speech therapy assessment from day 1. Neuropathology result typically available within 5–7 working days — determines adjuvant oncology pathway. MRI brain (post-operative, with contrast) at 24–72 hours post-surgery for early resection extent confirmation. Discharge planning includes neurological rehabilitation facility if needed, and local neurology/neuro-oncology follow-up arrangement.
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Follow-up and adjuvant treatment coordination
Post-operative MRI at 3 months, 6 months, then annually (GBM: every 3 months per Stupp protocol surveillance). For glioblastoma (GBM): coordination of concurrent chemoradiotherapy (Stupp protocol — 60 Gy radiotherapy + temozolomide 75 mg/m²/day for 6 weeks, followed by 6 cycles adjuvant temozolomide) through partner neuro-oncology team. MGMT promoter methylation status from neuropathology determines response to temozolomide. For meningioma: post-operative WHO grade determines observation vs radiosurgery. For pituitary adenoma: endocrinology coordination for hormonal axis assessment post-surgery. For spinal surgery: structured physiotherapy programme from week 2, return-to-work timeline, long-term activity guidance.
Awake craniotomy vs Asleep craniotomy vs Endoscopic pituitary vs Radiosurgery
The choice of neurosurgical approach is determined by lesion type, location relative to eloquent cortex, and patient factors. Here is how the four main pathways compare:
| Aspect | Awake craniotomy | Asleep craniotomy (GA) | Endoscopic transsphenoidal (pituitary) | Stereotactic radiosurgery (Gamma Knife) |
|---|---|---|---|---|
| Primary indication | Eloquent cortex tumours — near motor strip, speech (Broca/Wernicke), visual cortex — where real-time function testing reduces neurological deficit risk | Non-eloquent area tumours, deep-seated lesions not requiring cortical mapping, patients unable to cooperate with awake protocol (anxiety, young children, cognitive impairment) | Pituitary adenoma (non-functioning, GH-secreting, prolactinoma refractory to medical therapy, ACTH-secreting Cushing's) — transnasal approach, no visible scar, shorter recovery | Radiosurgery (Gamma Knife) — small (<3 cm) benign/metastatic brain tumours, arteriovenous malformations (AVM), acoustic neuromas, essential tremor (thalamic); no open surgery; coordinated through Eyeglow partner radiation oncology team |
| Neurological deficit risk reduction | Demonstrated reduction in post-operative permanent deficit (motor, speech) in eloquent area tumours — randomised data (De Witt Hamer 2012, Lancet Oncology) | Standard anaesthesia; neuromonitoring (MEP/SSEP) provides indirect monitoring of motor tracts but not real-time cortical language mapping | Not applicable for cortical mapping; endoscopic approach reduces need for nasal packing, reduces CSF leak vs microscopic transsphenoidal in meta-analyses | No surgical deficit risk; radiation-specific risks (radiation necrosis 5–10%, hair loss at entry point, oedema) |
| Tumour resection extent | Higher gross total resection rate in eloquent area tumours — associated with improved survival in glioma (EORTC data) | Neuronavigation + intraoperative MRI — resection extent similar for non-eloquent tumours | Pituitary: comparable or superior remission rates vs microscopic for most adenoma subtypes in high-volume centres | Not a resection — radiosurgery targets abnormal tissue without removal; tumour control rate for meningiomas 90–95% at 5 years |
| Duration + hospital stay | 3–6 hours surgery; NCU 24–48h; total stay 7–10 days | 2–5 hours; NCU 24–48h; total stay 7–10 days | 2–3 hours; standard ward 3–5 days; lumbar drain if CSF leak risk | Single outpatient session (Gamma Knife, 1–6 hours frame or mask); home day of treatment |
| Recovery | 4–6 weeks to functional recovery; neuropsychological monitoring at 3 months | 4–6 weeks; similar to awake for non-eloquent lesions | Nasal congestion 2–4 weeks; return to work 2–3 weeks typical; endocrine follow-up 6 weeks | 24–48h mild headache; no recovery period in most cases; response assessed at 3–6 months imaging |
Personalised pricing
Every treatment plan is priced individually after your consultation. Request a written, all-inclusive quote — clear, itemised, and with no obligation.
Request a written quoteWhat's included in your neurosurgery coordination
Included in coordination
- Neurosurgical second opinion consultation with board-certified neurosurgeon (partner network)
- Imaging review (MRI, CT, CTA, DSA) by partner neuroradiology
- Multi-disciplinary neuro-oncology tumour board presentation (brain tumours)
- Written care plan: diagnosis, surgical approach, intraoperative techniques, expected resection extent, post-operative pathway, adjuvant treatment coordination
- Explicit neurological deficit risk and mortality disclosure by procedure type
- Surgical procedure at JCI-aligned partner hospital — neurosurgeon, neurophysiologist, neuroanaesthesiologist, neurointensive care team
- Intraoperative neuromonitoring (MEP/SSEP) as standard for spinal and eloquent area cases
- Neuronavigation as standard for intracranial procedures
- Neurocritical care unit (NCU) post-operative monitoring
- Neuropathology (if tissue resection — WHO 2021 CNS tumour classification including molecular markers)
- Post-operative MRI at 24–72 hours for resection extent confirmation
- Physiotherapy, speech therapy, and neuropsychological assessment coordination from post-operative day 1
- Multilingual care coordinator — from first imaging review to discharge and follow-up plan
- Complication insurance policy (Türkiye Ministry of Health certified, covers surgical complications including infection, retreatment, and emergency intervention up to package value)
Quoted separately
- Adjuvant radiotherapy (radiation oncology — coordinated through partner radiation oncology team if indicated by tumour board)
- Adjuvant chemotherapy (temozolomide for GBM — coordinated through partner neuro-oncology team)
- Spinal implants cost (pedicle screws, cages, plates — quoted separately based on level and implant type)
- Intraoperative imaging (iMRI) supplementary cost where applicable to case complexity
- Neuropsychological rehabilitation programme beyond acute hospital stay
- Hotel and accommodation (quoted separately — typical stay 10–14 days for craniotomy)
- Flights to/from Istanbul
- Travel insurance (recommended — covers flight cancellation, baggage, non-surgical medical emergencies abroad; we coordinate referral if needed)
Is neurosurgery coordination at Eyeglow Health appropriate for you?
You may benefit from coordination if
- You have a brain tumour (glioma, meningioma, metastasis, acoustic neuroma, pituitary adenoma) confirmed on MRI and are seeking a surgical second opinion or treatment.
- You have intractable back or neck pain or radiculopathy after failed conservative management (minimum 6–8 weeks physiotherapy + appropriate analgesia) with correlating imaging pathology (disc herniation, stenosis, spondylolisthesis).
- You have a cerebrovascular anomaly (unruptured aneurysm, AVM) and are seeking specialist assessment of treatment options (surgical clipping, endovascular coiling, radiosurgery, or observation).
- You are seeking a second opinion on the recommended neurosurgical approach, timing of surgery, or need for surgery at all (many spinal and some brain cases have non-surgical alternatives that should be explored first).
- You have been recommended craniotomy near eloquent cortex and want access to awake craniotomy with cortical mapping at a centre experienced in this technique.
Coordination may not be appropriate if
- You require emergency neurosurgery (ruptured aneurysm, acute subdural haematoma, acute spinal cord compression with rapidly progressive deficit) — arrange emergency transfer to your nearest neurosurgical centre; elective evaluation timelines do not apply to emergency presentations.
- You have been offered standard-of-care spinal or cranial surgery at a well-resourced local centre without significant wait-time delay — if your local option is appropriate and accessible, we will tell you this.
- You expect surgery to provide complete pain relief or function restoration as a certainty — neurological outcomes after surgery are probabilistic, not guaranteed; we state realistic outcome ranges explicitly.
- You have systemic disease (active cancer with short prognosis, severe cardiac or respiratory comorbidity) that makes elective surgery higher risk than the natural history of the lesion — an honest risk-benefit discussion may result in a recommendation against surgery.
Disclaimer. Information on this page is consistent with WFNS (World Federation of Neurosurgical Societies) guidelines, Congress of Neurological Surgeons (CNS) practice guidelines, and NICE clinical guidelines for neurosurgery. Complication statistics are derived from peer-reviewed published registry data and randomised trial publications. Individual outcomes depend on lesion characteristics, patient factors, and surgical team expertise. Treatment decisions require assessment by a board-certified neurosurgeon with access to your full imaging and medical records.
What every neurosurgery patient must understand before consenting
Neurosurgery carries mortality and permanent neurological deficit risk that is unique in magnitude among elective specialties. We state this plainly — the same way our partner neurosurgeon does before every consent discussion:
Craniotomy mortality — 1–3% procedure-dependent
Craniotomy (brain surgery) carries a reported all-cause 30-day mortality of approximately 1–3% in elective cases at high-volume neurosurgical centres — higher for malignant glioma, posterior fossa tumours, and vascular procedures. Per WFNS and CNS published neurosurgical outcome data: craniotomy for meningioma 0.5–1%; craniotomy for glioblastoma 1–2%; posterior fossa surgery 2–3%; aneurysm clipping (unruptured) 1–2%; ruptured aneurysm 3–5+%. These figures are procedure-type- and centre-volume-dependent. We state the applicable mortality range for your specific procedure in the written care plan before you consent to surgery.
Neurological deficit — permanent new deficit in 5–25% depending on tumour location and technique
Any intracranial procedure carries risk of new permanent neurological deficit: motor weakness, language impairment (dysphasia), visual field defect (hemianopia), memory change, or personality change — depending on lesion location. Eloquent cortex proximity is the primary risk factor. Published data for glioma surgery in eloquent areas: permanent new deficit 10–20% without cortical mapping; 5–10% with awake craniotomy and functional mapping. Neuronavigation reduces risk by improving resection precision. Intraoperative MRI reduces risk by avoiding inadvertent violation of adjacent eloquent structures. We use all available risk-reduction techniques at our partner hospital — but we also state frankly that these techniques reduce risk, not eliminate it.
Spinal surgery — complication rate 0.3–5% by procedure, with re-operation risk
Spinal surgery complication rates per published registry data (Scoliosis Research Society, National Inpatient Sample): single-level lumbar discectomy — infection 0.3–0.5%, neurological complication 0.1–1%, re-herniation 5–10% at 10 years; lumbar fusion — infection 1–3%, hardware failure requiring reoperation 3–5%, adjacent segment disease at 5–10 years (15–30% radiographic, 5–10% symptomatic requiring surgery); cervical surgery — dysphagia 10–30% (mostly transient), vocal cord injury (recurrent laryngeal nerve) 0.5–1%, C5 nerve palsy 2–4% after laminoplasty. Realistic outcome expectations for spinal surgery: radicular leg/arm pain — typically good improvement (70–90% with disc herniation); back/neck pain — less predictable (40–60% meaningful improvement; fusion does not reliably cure axial pain).
Second opinion recommendation — we recommend against surgery in a proportion of cases
Neurosurgery is irreversible. For many lesions where patients present expecting surgery, our partner tumour board recommends against immediate surgical intervention: small asymptomatic meningiomas — radiological surveillance rather than surgery (NICE CG guidance); incidental pituitary microadenomas with normal hormones — observation; lumbar disc herniation — non-surgical management with time (80% resolve without surgery over 6–12 weeks); small unruptured aneurysms in elderly patients — observation risk-benefit favours non-surgery. We will tell you if surgery is not in your interest, even when you have sought us for surgery. That conversation is part of our clinical duty.