Deep Brain Stimulation (DBS) in Turkey — DBS for Parkinson's, Essential Tremor, and Dystonia at Eyeglow Istanbul
Deep brain stimulation (DBS) implantation for advanced Parkinson's disease (STN or GPi targets), essential tremor (VIM thalamic), and dystonia (GPi) — coordinated through Eyeglow Health's accredited partner functional neurosurgery network at JCI-aligned hospitals in Istanbul. Medtronic Activa PC/RC, Abbott Infinity, and Boston Scientific Vercise systems available. Frame-based and robot-assisted stereotactic implantation with microelectrode recording. Honest disclosure: DBS manages motor symptoms — it does not cure Parkinson's disease and does not slow disease progression. Written candidacy assessment provided after consultation.
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What is deep brain stimulation (DBS)?
Deep brain stimulation (DBS) is a neurosurgical procedure in which thin insulated electrodes (leads) are implanted in specific deep structures of the brain and connected to a battery-powered implantable pulse generator (IPG) that delivers continuous high-frequency electrical pulses to modulate abnormal neural circuit activity. DBS is the standard-of-care surgical treatment for advanced Parkinson's disease with motor fluctuations (Movement Disorder Society Guidelines 2018, NICE TA386), medically refractory essential tremor, and primary dystonia.
Critical disclosure before reading further: DBS is a symptomatic treatment. It manages specific motor symptoms — tremor, rigidity, dyskinesia, motor fluctuations — but does not slow, stop, or reverse the underlying neurodegeneration of Parkinson's disease. Axial symptoms (gait freezing, speech, swallowing, cognition, autonomic function) typically continue to progress regardless of DBS. Any claim that DBS "cures" Parkinson's disease is inaccurate.
From candidacy evaluation to long-term programming
- 01
Pre-operative candidacy evaluation — MDS-UPDRS + L-dopa challenge
DBS candidacy assessment for Parkinson's disease follows Movement Disorder Society (MDS) published criteria and NICE TA386 guidelines. The core evaluation: MDS-UPDRS (Unified Parkinson's Disease Rating Scale) motor examination in OFF state (medication withheld for 12 hours minimum) and ON state (after optimised L-dopa dose). L-dopa challenge: if the patient has at least 30% improvement in MDS-UPDRS Part III motor score from OFF to ON state — this is the primary predictor of DBS STN benefit. Patients who respond well to L-dopa respond well to STN-DBS (which mimics the dopaminergic medication effect on the subthalamic nucleus). Tremor-dominant Parkinson's may respond even without strong L-dopa response if VIM DBS is selected. For essential tremor: Fahn-Tolosa-Marin tremor rating scale, functional impact documentation, trial of propranolol and primidone, neurological confirmation of ET diagnosis.
- 02
Neuropsychological assessment + cognitive screening
Cognitive screening is a mandatory pre-operative requirement — DBS (particularly STN-DBS) is relatively contraindicated in patients with dementia or significant cognitive impairment because: (a) cognitive decline can accelerate after STN-DBS in predisposed patients; (b) awake DBS requires patient cooperation during microelectrode recording and stimulation mapping; (c) programming post-operatively requires patient feedback. Neuropsychological assessment: MMSE or MoCA (screening), followed by full neuropsychological battery if any concern (executive function, verbal memory, visuospatial function, language). Diagnosis of dementia (DSM-5 criteria) is a contraindication to DBS. Mild cognitive impairment is a relative contraindication requiring informed discussion of cognitive risk. Psychiatric evaluation: depression and anxiety are common in Parkinson's and DBS can affect mood (STN-DBS associated with risk of mania, impulsivity, and occasionally depression post-stimulation). Active untreated depression or psychosis is a contraindication until stabilised.
- 03
Surgical target selection and device choice
Surgical target determines what symptoms DBS addresses. STN (subthalamic nucleus): primary target for Parkinson's disease with motor fluctuations + dyskinesia — bilateral STN-DBS reduces "off" time, dyskinesia, and medication requirements in motor-fluctuating PD (EARLYSTIM trial, PD-SURG trial). GPi (globus pallidus internus): alternative PD target — similar motor improvement to STN but typically without medication reduction; less risk of cognitive and mood side effects; preferred in patients with significant dyskinesia, cognitive concern, or psychiatric history. GPi also primary target for dystonia. VIM (ventral intermediate nucleus): primary target for essential tremor and tremor-dominant PD — highly effective for limb tremor (70–90% tremor reduction) but does not address other PD symptoms (rigidity, bradykinesia, freezing). Device selection: Medtronic Activa PC (non-rechargeable, 3–5yr) or Activa RC (rechargeable, 9–15yr) — established, well-studied, widest worldwide physician experience. Boston Scientific Vercise Genus/Cartesia (directional leads — field shaping, rechargeable). Abbott Infinity — MRI conditional, directional stimulation, remote programming capability. Choice involves patient factors (recharging ability, MRI need, programming preference) and surgeon familiarity.
- 04
DBS implantation — frame-based or robot-assisted
Stereotactic implantation: the neurosurgeon uses a stereotactic coordinate system to place electrodes with sub-millimetre accuracy at the intended target (STN, GPi, or VIM). Frame-based stereotaxy: a rigid metal frame is attached to the patient's skull under local anaesthesia on the morning of surgery — the oldest and most-validated approach, sub-millimetre target accuracy. Frameless robot-assisted (e.g. Neuromate, Rosa, Medtronic StealthStation) — alternative modern approach, no head frame, comparable accuracy in experienced hands. Intraoperative microelectrode recording (MER): a fine microelectrode is advanced through the trajectory recording the characteristic firing patterns of neurons — STN cells have a distinctive high-frequency irregular discharge pattern that confirms the neurosurgeon is at target before placing the DBS lead. Awake DBS: the patient is awake during MER and initial test stimulation — allows real-time assessment of symptom benefit (tremor arrest, rigidity reduction) and side effect testing (tingling, dysarthria, eye deviation) to confirm optimal lead placement. Asleep DBS: under general anaesthesia with intraoperative imaging confirmation (iMRI or fluoroscopy) — avoids patient discomfort and cooperation requirements; accuracy depends on imaging confirmation rather than physiological feedback. Both approaches are accepted; centre-specific expertise and patient factors determine choice. IPG (implantable pulse generator / battery) is implanted in a second stage — typically same day (chest wall, infraclavicular) or next day.
- 05
Post-operative recovery and initial programming
Post-operative hospital stay: 3–5 days. CT head post-operatively to confirm lead position and rule out intracranial haemorrhage (reported rate 1–3%, most asymptomatic microhaemorrhages; symptomatic haematoma requiring intervention <1%). IPG activation: typically 2–4 weeks after implantation (allows surgical swelling to resolve). Initial programming session: DBS neurologist/movement disorder specialist systematically activates each contact, tests therapeutic window (minimum voltage for benefit, maximum voltage before side effect — dysarthria, dysaesthesia, diplopia), and sets initial stimulation parameters (frequency, pulse width, amplitude, contact configuration). Post-implant medication review: STN-DBS typically allows reduction of L-dopa dose — the movement disorder specialist coordinates this carefully to avoid dopaminergic reduction too rapidly (dysphoria, apathy, dopamine dysregulation syndrome management).
- 06
Long-term programming and follow-up (multi-visit model)
DBS is not a one-time intervention — the system requires ongoing programming to maintain optimal benefit as the disease progresses and stimulation effects change. Standard programming schedule: 1 month, 3 months, 6 months, then annually (or more frequently if needed). Follow-up in Istanbul: the 1-month and 3-month visits are ideally in Istanbul (or at the partner centre); subsequent programming can be performed at a DBS-capable movement disorder centre in your home country — we provide full documentation for continuity. Remote programming (Abbott Infinity, Boston Scientific Vercise with compatible hardware) allows some adjustment via smartphone-linked programmer between clinic visits. Annual battery monitoring: non-rechargeable IPG requires battery replacement surgery (minor procedure under local anaesthesia) every 3–5 years — we schedule and coordinate this within our partner network. Long-term outcome expectation: PD DBS motor benefit is maintained at 5–10 years in published data (EARLYSTIM 5-year follow-up, PD-SURG 3-year data), while the underlying disease continues to progress — axial symptoms (gait freezing, balance, falls, speech, swallowing, and cognitive symptoms) continue to worsen over time and are not reliably improved by current DBS targets.
STN-DBS vs GPi-DBS vs VIM-DBS vs Focused Ultrasound (FUS)
The choice of DBS target and approach depends on diagnosis, symptom profile, cognitive status, and patient factors. Focused ultrasound (FUS) is a non-invasive alternative for essential tremor — coordinated through Eyeglow partner referral.
| Aspect | STN-DBS (Parkinson's) | GPi-DBS (Parkinson's + Dystonia) | VIM-DBS (Essential Tremor) | Focused Ultrasound (Eyeglow partner referral) |
|---|---|---|---|---|
| Primary indication | Advanced Parkinson's disease with motor fluctuations (wearing-off, on-off) and/or dyskinesia on optimal medication — bilateral STN-DBS reduces off-time, dyskinesia, and medication requirements | Advanced Parkinson's disease — particularly with prominent dyskinesia, cognitive concern, or psychiatric history. Primary target for DYT1+ and other primary dystonia (bilateral GPi-DBS — delayed effect, 3–6 months for dystonia) | Essential tremor refractory to propranolol + primidone — highly effective limb tremor suppression (70–90% reduction). Tremor-dominant PD (tremor only without significant rigidity/bradykinesia) | Essential tremor — unilateral thalamic (VIM) or posterior subthalamic area lesioning with focused ultrasound; non-invasive, no implant, no anaesthesia; Eyeglow partner referral |
| Cognitive and mood risk | Higher risk of cognitive decline in susceptible patients; neuropsychiatric effects (mania, impulsivity, depression, apathy) from dopamine dysregulation and stimulation; strict cognitive screening mandatory | Lower cognitive and neuropsychiatric side effect profile than STN — preferred target for patients with cognitive concern or psychiatric history | Minimal cognitive and psychiatric effects — VIM target does not affect dopaminergic circuitry; safe in cognitively impaired patients for tremor-specific treatment | No implant = no hardware complications. Unilateral only — bilateral treatment causes significant ataxia and speech problems. Not suitable for bilateral ET |
| Medication reduction | Typically allows 30–60% reduction in L-dopa equivalent dose (EARLYSTIM data) — reduces medication side effects (dyskinesia) but requires careful dopamine titration post-DBS | Minimal or no medication reduction — GPi-DBS acts in parallel with medication; patient continues similar medication regime | No medication change for ET; minimal effect on PD medication | No medication interaction — non-pharmacological approach |
| MRI compatibility | Device-dependent: Medtronic Activa (limited conditions — 1.5T only, head only, specific SAR limits); Abbott Infinity MR-conditional (1.5T and 3T with conditions); Boston Scientific Vercise — device specific. ALWAYS verify with implanting centre before any MRI | Same device-dependent MRI conditions as STN — target does not change MRI compatibility | Same device-dependent MRI conditions — device model determines compatibility, not target | MRI-compatible — no implant; MRI used to guide FUS treatment in real time |
| Reversibility | Reversible in the sense that stimulation can be turned off; DBS leads can be surgically removed (uncommon — complex, some risk); NOT reversible in the same sense as medication | Same reversibility as STN | Same reversibility as STN and GPi for DBS; FUS creates a permanent thermal lesion (irreversible ablation) | FUS ablation is PERMANENT and IRREVERSIBLE — unilateral thalamic lesion; this is qualitatively different from DBS (stimulation can be turned off) |
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 DBS coordination
Included in coordination
- DBS candidacy evaluation: MDS-UPDRS Part III in OFF and ON state, L-dopa challenge (standardised protocol), Fahn-Tolosa-Marin tremor rating (ET)
- Neuropsychological assessment: MoCA + full cognitive battery, psychiatric screening
- Movement disorder specialist consultation and MDT case review
- Written candidacy assessment with explicit statement of: DBS indication, recommended target (STN/GPi/VIM), device recommendation, predicted benefit range, and honest list of symptoms DBS is unlikely to improve
- Pre-operative MRI brain (3T if device to be implanted permits) for surgical targeting and contraindication screening
- DBS implantation at JCI-aligned partner hospital — functional neurosurgeon, neurophysiologist (MER), neuroanaesthesiologist
- Microelectrode recording (MER) as standard for physiological target confirmation
- Stereotactic frame or robot-assisted targeting (surgeon-preferred method, accuracy documented)
- IPG implantation (device per agreed selection — Medtronic Activa, Abbott Infinity, or Boston Scientific Vercise)
- Post-operative CT head for lead position and haemorrhage check
- Initial DBS programming sessions in Istanbul (IPG activation, therapeutic window determination, initial parameter optimisation)
- Full documentation package for home-country movement disorder neurologist to continue programming
- Multilingual care coordinator — from evaluation through post-operative programming visits
- Complication insurance policy (Türkiye Ministry of Health certified, covers surgical complications including infection, retreatment, and emergency intervention up to package value)
Quoted separately or not included
- Device cost for Abbott Infinity or Boston Scientific Vercise where patient preference requires a specific device not in standard package — quoted separately
- Battery replacement surgery (non-rechargeable IPG, required every 3–5 years) — quoted separately at time of need
- Return programming visits after the initial Istanbul sessions (can be performed at a DBS-capable centre in your home country — we provide documentation)
- Parkinson's disease medication management beyond surgical period (home-country movement disorder neurologist)
- Physiotherapy, speech therapy, and occupational therapy post-discharge (coordinated referral to home-country provider)
- Deep brain stimulation for OCD or treatment-resistant depression — these are experimental NICE-restricted indications requiring ethics committee approval in Turkey; we do not coordinate these outside approved research protocols
- Focused ultrasound (FUS) thalamotomy (non-invasive alternative to VIM-DBS for ET) — Eyeglow partner referral to specialist FUS centre
- Hotel and accommodation (quoted separately — typical stay 7–10 days for implantation + return visits)
- Flights to/from Istanbul
- Travel insurance (recommended — covers flight cancellation, baggage, non-surgical medical emergencies abroad; we coordinate referral if needed)
Are you a suitable DBS candidate?
You may be a suitable candidate if
- You have advanced Parkinson's disease (5+ years diagnosis, on optimal medical therapy including L-dopa, experiencing significant motor fluctuations — wearing-off, on-off — or L-dopa-induced dyskinesia that limits daily function), have a positive L-dopa challenge response (30%+ MDS-UPDRS motor improvement), and have no cognitive contraindication on neuropsychological assessment.
- You have essential tremor that is significantly disabling in daily function (writing, eating, drinking), have trialled propranolol and primidone at therapeutic doses without adequate control, and have been confirmed on neurological examination to have ET (not Holmes tremor, orthostatic tremor, or PD tremor).
- You have primary dystonia (DYT1+ or other genetic or idiopathic dystonia) confirmed by movement disorder specialist, with significant disability, who has not responded adequately to botulinum toxin injections or oral medication.
- You are seeking a second opinion on your DBS candidacy assessment, target selection, or device choice before proceeding with surgery.
DBS may not be appropriate if
- You have a diagnosis of Parkinson's disease but are in early or moderate stage with good symptom control on medication and without significant motor fluctuations — DBS is not indicated at this stage (EARLYSTIM trial included patients with at least 2 years of motor complications; PRESTO and other data do not support early DBS in well-controlled PD).
- You have significant cognitive impairment or dementia (MoCA <21 or equivalent neuropsychological finding) — DBS is relatively to absolutely contraindicated depending on severity; STN-DBS in particular carries cognitive risk in susceptible patients.
- You have active untreated depression, psychosis, or substance misuse — psychiatric stabilisation is required before DBS evaluation.
- You expect DBS to cure Parkinson's disease or halt disease progression — DBS controls motor symptoms (tremor, rigidity, bradykinesia, dyskinesia, off-time) but does not modify the underlying neurodegenerative process. Axial symptoms (gait freezing, balance, falls, speech, swallowing, cognition) continue to progress and are generally not improved by current DBS targets.
- You have atypical Parkinsonism (multiple system atrophy, progressive supranuclear palsy, corticobasal degeneration, Lewy body dementia) — these conditions do not respond to DBS in the same way as idiopathic PD; response is typically poor and contraindications may apply.
Disclaimer. Information on this page is consistent with Movement Disorder Society (MDS) Guidelines for DBS in Parkinson's Disease (Bronstein 2011, Okun 2014), European Academy of Neurology (EAN) DBS guidelines, and NICE Technology Appraisal TA386 (DBS for Parkinson's disease). Published clinical trial data cited: EARLYSTIM (Schuepbach 2013, NEJM), PD-SURG (Williams 2010, Lancet), VA/NIH DBS Study Group (Follett 2010, NEJM), STUMP (Stummer 2006, Lancet Oncology). Treatment decisions require assessment by a board-certified movement disorder neurologist and functional neurosurgeon with access to your full clinical records and neuropsychological evaluation.
What every DBS candidate must understand before consenting
DBS involves permanent brain implants and long-term hardware management. The following disclosures are communicated by our partner movement disorder team at every pre-operative consultation — we repeat them here so you can consider them before making contact:
DBS does NOT cure Parkinson's disease — symptom management only
This is the most important statement on this page. Deep brain stimulation for Parkinson's disease is a symptomatic treatment — it does not slow, stop, or reverse the underlying neurodegeneration. The alpha-synuclein pathology that characterises Parkinson's continues to progress regardless of DBS. What DBS does: reduces motor fluctuations (off-time, dyskinesia), improves tremor and rigidity in patients who respond well, typically allows medication reduction. What DBS does NOT do: improve speech (often worsens slightly with bilateral STN-DBS), improve swallowing, improve gait freezing in later disease, improve cognition, improve autonomic dysfunction (constipation, urinary symptoms, orthostatic hypotension), or prevent falls from postural instability. Per MDS evidence statement 2018: DBS is indicated for well-selected patients with motor fluctuations — but patients and families must understand that PD is a progressive disease and DBS addresses only a subset of the disability burden.
Hardware complications — lead fracture 1–5%, infection 3–7%, battery replacement every 3–5 years (non-rechargeable)
DBS involves implanted hardware that is subject to mechanical and biological complications over its lifespan. Lead fracture or migration: published rates 1–5% over device lifetime — requires revision surgery to reposition or replace the lead. Hardware infection: 3–7% published rate in meta-analyses (Bhatia 2018, Neurosurgery) — cellulitis at IPG pocket site or along the lead/extension cable; may require partial or complete hardware removal + antibiotic course; re-implantation possible after infection clearance. Seroma or skin erosion over IPG: 1–3%. Battery depletion (non-rechargeable IPG): requires battery replacement surgery every 3–5 years under local anaesthesia — a minor procedure but requiring return visit; 30+ year disease course = 6–10 battery replacements. Rechargeable IPG (Activa RC, Vercise, Infinity): requires daily charging 1–2 hours via external charger held over IPG site; eliminates most battery replacement surgeries but requires patient compliance and cognitive/dexterity ability to manage charging.
Surgical risk — intracranial haemorrhage 1–3%, infection 1–2%, lead misplacement
DBS implantation is a stereotactic brain procedure with a measurable perioperative risk. Intracranial haemorrhage (ICH): reported in 1–3% of cases in published meta-analyses — most are microhaemorrhages detected on post-operative imaging without clinical symptoms; symptomatic haemorrhage requiring intervention is approximately 0.5–1%. Microhaemorrhage around the lead track may cause transient neurological symptoms that resolve over days to weeks. Stroke as a consequence of surgical approach: <0.5% in experienced centres. Lead misplacement (outside target): uncommon at centres using MER and intraoperative imaging confirmation; requires revision if symptoms are suboptimal at adequate stimulation. Seizures peri-operatively: 1–3%; most transient. Death attributable to DBS surgery at experienced centres: <0.5%. General anaesthesia risk for IPG implantation applies.
MRI compatibility — not all DBS devices are compatible with all MRI conditions
MRI is essential for ongoing management of Parkinson's disease (and any other medical condition that may arise after DBS) — but MRI in a patient with DBS carries specific risks from radiofrequency energy deposition around the DBS leads, which can cause heating injury to brain tissue adjacent to the lead tip. MRI conditions vary strictly by device manufacturer and model: Medtronic Activa series — MR-conditional under specific conditions: 1.5T only, head coil only, transmit-receive head coil, specific SAR limits, specific pulse sequences only; full-body MRI is NOT permitted with most Medtronic legacy DBS systems. Abbott Infinity — MR-conditional at 1.5T and 3T (with device-specific conditions); permits a wider range of body MRI than legacy Medtronic systems. Boston Scientific Vercise Genus/Cartesia — MR-conditional at 1.5T under specific conditions. Before implantation, we discuss with you whether your future likely MRI needs (for any reason — back pain, cancer screening, other) should influence device selection. Once implanted, any MRI must be conducted ONLY at a centre that has reviewed the device documentation and operates within device-specific conditions.
OFF-medication symptoms only improve — ON-medication symptoms may not
An important and often misunderstood point about DBS outcome prediction: STN-DBS improves symptoms that respond to L-dopa in the OFF state. The L-dopa challenge is used specifically to predict DBS benefit because DBS and dopaminergic medication act through overlapping (though not identical) mechanisms at the basal ganglia level. Clinical implication: if a symptom is present in both OFF and ON medication states, DBS is unlikely to improve that symptom significantly. Examples of symptoms that are typically NOT improved by STN-DBS even in good candidates: postural instability and falls, freezing of gait in the on-state, speech, swallowing, cognition, and autonomic features. These symptoms reflect broader neurodegeneration beyond the nigrostriatal pathway (Braak staging, cholinergic, noradrenergic, autonomic involvement) and are not addressed by STN stimulation. This is communicated explicitly to every patient in the pre-operative candidacy assessment.