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Microvascular decompression

Microvascular decompression (MVD) is a neurosurgical procedure that relieves symptoms of neurovascular compression by separating and padding blood vessels that are abnormally pressing on at the , most commonly treating —a severe, episodic facial pain disorder—and , an involuntary twitching of facial muscles, as well as glossopharyngeal neuralgia in select cases. First conceptualized in the early and advanced by Peter Jannetta in the 1970s, it targets the root entry zone of the nerve near the . Indicated primarily when conservative treatments like medications (e.g., ) fail or cause intolerable side effects, MVD requires preoperative MRI or (MRA) to confirm vascular compression, which is present in approximately 75-80% of cases. It is considered the gold standard for long-term relief in idiopathic cases, though it is not suitable for pain related to or tumors. Detailed surgical technique, outcomes, recovery, and risks are covered in subsequent sections.

Overview and Indications

Definition and Mechanism

Microvascular decompression (MVD) is a neurosurgical designed to treat cranial disorders by relieving neurovascular through a posterior , allowing access to the cerebellopontine angle where offending blood vessels are identified and separated from the affected using inert padding material, such as Teflon felt, without damaging either structure. The targets the root entry zone () of the cranial , the transitional segment between central and peripheral near the entry point, typically within 2-3 mm of the or medulla, where most commonly occurs. This approach aims for an etiological cure by eliminating the mechanical irritation while preserving the integrity of both the and vessel. The underlying mechanism involves the alleviation of pulsatile compression exerted by aberrant blood vessels, such as the in cases of , on the vulnerable , which leads to focal demyelination of nerve fibers due to chronic mechanical stress and ischemia. Demyelination at this site, characterized by thinner sheaths and limited glial support compared to more distal segments, results in ephaptic transmission and ectopic impulse generation, manifesting as paroxysmal pain or spasms. By mobilizing the offending vessel and interposing padding to prevent recontact, MVD restores normal nerve conduction and halts abnormal firing, addressing the root cause of symptoms in conditions like . The term "microvascular decompression" was coined by Peter Jannetta in the 1960s, reflecting intraoperative observations of microvascular conflicts at during early procedures he performed in 1966. Jannetta's innovation built on prior concepts of vascular-nerve interactions, emphasizing precise microvascular manipulation under the operating microscope to achieve decompression.

Conditions Treated

Microvascular decompression is primarily indicated for neurovascular compression syndromes affecting , where a vascular loop compresses the root entry zone (REZ), leading to debilitating symptoms refractory to medical management. The most common condition treated is (TN), characterized by sudden, sharp, electric-shock-like pain in one or more divisions of the (V1-V3 distributions), often triggered by light touch, chewing, or speaking. Classical TN presents with brief, paroxysmal attacks lasting seconds to minutes, while atypical TN involves constant background aching or burning pain interspersed with sharp exacerbations. The annual incidence of TN ranges from 4 to 13 per 100,000 person-years, with higher rates in women over 50 years old. Hemifacial spasm (HFS) is another primary indication, featuring involuntary, intermittent tonic-clonic contractions of facial muscles on one side, typically beginning with eyelid twitching () and progressing over months to years to involve the cheek, mouth, and lower hemiface. The worldwide prevalence of HFS is approximately 7.4 per 100,000 in men and 14.5 per 100,000 in women, predominantly affecting those over 40. Glossopharyngeal neuralgia (GPN) represents a less frequent but established indication, manifesting as severe, stabbing pain in the throat, tongue, tonsils, or ear, often provoked by swallowing, coughing, or yawning. In some cases, GPN is associated with syncope due to vagal causing or . Secondary or rare indications include , which involves sharp pain in the region of the and has shown favorable response to MVD in refractory cases. Vestibular paroxysmia, marked by brief episodic vertigo from eighth cranial nerve compression, is an emerging application, with recent studies reporting symptom resolution post-MVD in medication-resistant patients. Additionally, investigations from 2020 to 2025 have explored MVD for linked to rostral ventrolateral medullary compression, demonstrating blood pressure reduction in selected cohorts, and for disorders causing palsy, demonstrating nerve function improvement in selected cohorts.

Historical Development

Early Concepts

The foundational concepts of microvascular decompression emerged in the early through intraoperative observations during procedures for (TN), a condition characterized by paroxysmal facial pain. In 1925, Walter E. Dandy introduced the suboccipital approach for partial sectioning of the trigeminal sensory root and made initial observations of aberrant vascular structures compressing the nerve root. In his 1934 analysis of 215 cases, he reported such compressions by the in approximately 31% and petrosal veins in 14%. These findings, documented in his case series, represented the first linkage between vascular-nerve contacts and TN symptoms, suggesting that such compressions could irritate the nerve and precipitate pain, though Dandy primarily focused on rather than decompression. By the mid-20th century, these observations evolved into targeted decompression attempts. In 1952, Palle Taarnhøj introduced a subtemporal approach for intradural decompression of the and posterior at the porus trigeminus, aiming to relieve pressure from surrounding structures without full sectioning; he reported pain relief in a majority of cases, attributing success to alleviating . Building on this, W. James Gardner in 1962 proposed a mechanistic , positing that vascular at the entry (REZ)—the transitional area between central and peripheral —could induce irritation leading to aberrant activity, triggering TN paroxysms; these ideas were further developed into concepts of demyelination and ephaptic in later works. Gardner's work, based on surgical explorations, emphasized decompressing offending vessels to restore normal conduction. Early conceptual frameworks were constrained by technological limitations, including reliance on partial decompressions without comprehensive visualization of the and the absence of operative , which hindered precise and separation of compressing vessels. These approaches prioritized gross over meticulous neurovascular , often resulting in incomplete interventions. Influential publications, such as Dandy's 1925 preliminary in the Johns Hopkins Hospital Bulletin and his subsequent analyses, laid the groundwork by highlighting vessel-nerve interactions in TN . This pre-1970s era set the stage for later refinements, culminating in Peter Jannetta's formalized microvascular decompression technique in the 1970s.

Modern Advancements

Peter Jannetta introduced microvascular decompression (MVD) in 1966, initially for (HFS) via suboccipital with the aid of an operative microscope to identify and relieve vascular compression at the root entry zone, and soon expanded it to (TN). This innovation built on earlier theories of neurovascular conflict but marked the first systematic use of microsurgical techniques to transpose offending vessels away from the nerve. In the 1970s, Jannetta expanded MVD to HFS, publishing his initial series of eight HFS cases in 1970, which included long-term follow-up demonstrating sustained symptom relief in most patients. Technique refinements in the 1980s included the adoption of , such as brainstem auditory evoked potentials, to assess nerve function in real-time and reduce the risk of during cerebellopontine angle exposure. By the , the use of Teflon felt as a standardized padding material became widespread for interposing between vessels and , minimizing direct contact while promoting long-term stability, as evidenced in large case series from that era. Recent advancements from 2020 to 2025 have focused on enhanced visualization and planning tools. Endoscopic-assisted MVD has gained traction for its ability to access narrow surgical corridors, with studies showing comparable efficacy to microscopic approaches in pain relief for TN patients. Exoscope systems have improved ergonomics by allowing upright positioning and high-definition visualization without the need for traditional eyepieces, as demonstrated in initial clinical applications for both TN and HFS. Additionally, AI-enhanced preoperative planning using MRI reconstructions has enabled precise modeling of neurovascular , aiding in vessel identification and surgical . A 2025 comparative study confirmed the equivalence of endoscopic MVD to microscopic methods in long-term efficacy for TN, with success rates exceeding 85% in both.

Patient Evaluation

Diagnostic Imaging

Diagnostic imaging plays a crucial role in confirming neurovascular compression (NVC) at the root entry zone (REZ) prior to microvascular decompression, particularly for conditions like (TN). High-resolution MRI sequences, such as 3D-FIESTA (Fast Imaging Employing Steady-state Acquisition) and CISS (Constructive Interference in Steady State), serve as the gold standard for visualizing NVC by providing detailed contrast between , , and adjacent vessels. These heavily T2-weighted sequences enable precise identification of compressive vessels at the REZ, the transitional zone between central and peripheral where nerves are most vulnerable. Preoperative MRI is recommended for all surgical candidates, typically performed on a 3-T scanner with thin-section (1 mm) multiplanar T2-weighted views in axial, coronal, and sagittal planes to optimize visualization. The sensitivity of these steady-state free precession (SSFP) sequences, including FIESTA and CISS, for detecting vascular compression in TN ranges from 94% to 97%. Complementary techniques enhance diagnostic accuracy; for instance, 3D-TOF-MRA (Time-of-Flight Magnetic Resonance Angiography) is used for detailed vessel mapping, often combined with high-resolution T2-weighted imaging to delineate arterial and venous structures. This combination yields a pooled sensitivity of 96% and specificity of 92% for NVC detection in TN and hemifacial spasm. Additionally, virtual endoscopy reconstructions derived from MRI data, such as MRVE integrated with 3D-FIESTA and 3D-TOF-MRA, provide simulated intraoperative views and improve overall accuracy to 94.17% in preoperative planning. Despite these advances, MRI has limitations, including false positives from age-related neurovascular contacts observed in up to 36.3% of nerves, which underscores the need for clinical symptom correlation to distinguish symptomatic NVC. REZ-specific changes, like nerve indentation or , increase specificity when present alongside symptoms.

Selection Criteria

Selection criteria for microvascular decompression (MVD) primarily target patients with classical (TN) or (HFS) that is refractory to optimal medical management, such as failure of or therapy. Ideal candidates are those under 70 years of age with or without confirmed neurovascular compression (NVC) on preoperative MRI, given the limited sensitivity of imaging, no significant comorbidities impairing surgical tolerance, and classical symptoms without atypical features like constant burning pain. These factors ensure a high likelihood of durable pain relief, with initial success rates exceeding 90% in appropriately selected cases. Prognostic scoring systems guide patient selection by integrating clinical and radiographic variables to predict long-term pain freedom. Seminal work from Jannetta's group identified favorable outcomes in patients with classical TN symptoms and pain duration under 10 years, with immediate relief rates of 80% and 5-year pain-free rates of 73% in such cohorts. Updated systems, such as the Panczykowski score (also termed Score A), assign points for classical symptoms (1 point), positive response to carbamazepine (1 point), and NVC severity (1-3 points based on venous, arterial, or compressive contact), yielding scores of 1-5; scores of 4-5 predict 5-10 times higher odds of pain freedom without medication at 5 years compared to lower scores. A complementary Hardaway score incorporates TN pain type (1 point for type 1 only), vessel involvement (1 point), and compression grade (1 point for distortion), with scores of 3 associated with significantly longer pain-free intervals (p=0.007). Recent 2025 evaluations of an enhanced Score B, refining prior models with MRI compression grading, confirm predictive accuracy for 80% pain freedom in high-score patients at extended follow-up. Contraindications include secondary TN due to without evident NVC, atypical pain patterns lacking a vascular , and severe cardiopulmonary precluding posterior . These exclusions mitigate risks of suboptimal outcomes, as MVD efficacy drops below 50% in non-classical cases without compression. In special populations, elderly patients over 70 may achieve approximately 75-85% success rates with MVD but face elevated perioperative risks, making it less preferable in those with multiple comorbidities despite comparable safety to younger cohorts in select studies. For recurrent TN post-initial MVD, redo procedures yield 80-90% efficacy in pain relief, with 2023-2025 analyses showing durable outcomes when adhesions or residual NVC are addressed, though complication rates rise to 10-15%.

Surgical Technique

Preoperative Preparation

Preoperative preparation for microvascular decompression (MVD) begins with a multidisciplinary involving neurologists and neurosurgeons to confirm patient suitability based on high-resolution MRI demonstrating neurovascular compression. is obtained through detailed counseling, discussing expected outcomes such as an initial success rate of approximately 90% for pain relief in , alongside risks including major complications in 5-10% of cases, such as or leakage. General anesthesia is induced using total intravenous anesthesia (TIVA) with agents like and to facilitate stable neuromonitoring conditions and minimize interference with evoked potentials. is avoided, as it can prolong latencies in brainstem auditory evoked potentials (BAEP), potentially complicating auditory pathway assessment. The patient is positioned in the lateral decubitus or park-bench orientation to optimize access to the via the retromastoid approach, with the head secured in a Mayfield three-pin clamp to maintain stability and alignment. Neuromonitoring electrodes are placed for (EMG) to track activity and BAEP to monitor the auditory pathway, enabling real-time feedback during setup. Adjunctive measures include intravenous antibiotic prophylaxis, typically with administered within 60 minutes of incision to reduce surgical site risk, and perioperative steroids such as dexamethasone to mitigate . The operative site behind the undergoes minimal or a , followed by skin preparation to ensure sterility.

Operative Procedure

Microvascular decompression is performed through a retrosigmoid suboccipital approach, typically involving a small of 2-3 cm in diameter at the junction of the transverse and sigmoid sinuses to access the . The patient is positioned in the lateral decubitus or park-bench position under general , with the head fixed in a Mayfield clamp and rotated 45-60 degrees away from the surgical side to optimize exposure. A curvilinear or linear incision, approximately 4-6 cm long, is made 1-2 cm behind the mastoid process, centered on the imaginary line from the external auditory canal to the inion, allowing muscle dissection to expose the bone. Following retraction, a burr hole is placed, and a small craniectomy is performed using a high-speed and Kerrison rongeurs, with any opened mastoid air cells sealed using or muscle to prevent CSF leakage. The dura is then opened in a cruciate fashion and tacked up to reveal the , where gentle retraction of the is applied using cottonoids padded with rubber dams to minimize traction. Arachnoid adhesions are sharply dissected with microscissors and dissectors to expose the cranial entry or exit zone, preserving surrounding neurovascular structures. Under high-magnification visualization with an operating or exoscope, the offending vessel—such as a (SCA) loop compressing the in cases of —is identified through a 360-degree circumferential of the nerve. Compressive vessels are mobilized using microinstruments, with small veins coagulated and divided if necessary, while larger arteries are gently dissected free. Pieces of Teflon felt (typically 2-4 mm in size) soaked in saline are then placed between the nerve and vessel to prevent recontact, ensuring the padding is secure without excessive pressure on the nerve. Intraoperative neuromonitoring, including brainstem auditory evoked potentials (BAEP), is employed to detect traction-related changes, such as latency shifts greater than 1 ms in wave V, prompting immediate adjustment of retraction. Confirmation of decompression may involve neuroendoscopy in select cases for enhanced visualization of hidden conflicts. The operative field is irrigated with saline, and is verified before closure. The dura is closed in a watertight manner using interrupted sutures, often reinforced with dural sealant or grafts if needed. The craniectomy defect is reconstructed with or autologous bone fragments to seal the site and reduce CSF leak risk, followed by multilayer closure of the muscle, , and skin without routine placement unless a high risk of CSF accumulation is present. Variations in the procedure include endoscopic-assisted techniques, particularly for , where a fully endoscopic approach in 2025 practices allows for smaller exposures (1-2 cm), reduced cerebellar retraction, and improved illumination of the root exit zone, though it requires specialized endoscopes angled at 30-45 degrees.

Outcomes and Recovery

Efficacy and Success Rates

Microvascular decompression (MVD) demonstrates high for (TN), with immediate pain relief achieved in 90-95% of patients, often measured using the (BNI) pain intensity scale, where BNI I indicates no pain without medications. For (HFS), initial rates range from 85-95%, with most patients experiencing significant symptom resolution shortly after surgery. These outcomes are attributed to the precise decompression of neurovascular conflicts, enabling rapid symptomatic improvement in well-selected cases. Long-term data further support MVD's durability, particularly for TN, where 70-80% of patients remain pain-free at 5 years post-procedure, based on recent meta-analyses. Recurrence rates for TN are typically 10-20% over 10 years, with lower rates observed when complete is achieved. For HFS, long-term spasm freedom exceeds 85% in many cohorts, underscoring MVD's role as a curative option. Compared to percutaneous rhizotomy techniques, such as rhizotomy, MVD offers superior long-term efficacy, with rhizotomy providing initial relief in about 70% of cases but recurrence rates approaching 50% at 5 years. Additionally, approximately 75% of TN patients achieving initial success with MVD maintain a medication-free status long-term. Several factors influence these outcomes, including shorter preoperative symptom duration and the presence of clear neurovascular compression (NVC), as assessed by validated 2024 scoring systems that predict pain-free rates based on and clinical features.

Postoperative Management

Following microvascular decompression (MVD), patients are typically admitted to the neurointensive care unit for overnight observation, with monitoring of vital signs, hemodynamic parameters, and serial neurological examinations to detect any early deficits such as cranial nerve dysfunction or changes in consciousness. Pain control in the immediate postoperative period relies on multimodal analgesia, including acetaminophen for mild headaches and opioids such as fentanyl or non-opioid agents such as ketorolac for moderate to severe pain via patient-controlled analgesia, while minimizing opioid use to reduce risks like postoperative nausea and vomiting. During the hospital course, patients are transferred to a regular neurosurgical ward after stabilization, where activity is gradually increased, such as sitting up and short walks, to promote while continuing serial neuro checks. usually occurs 2 to 5 days postoperatively, depending on symptom and absence of complications, with instructions for incision care, including gentle washing and avoiding submersion in water. medications, such as used preoperatively for , are gradually tapered over weeks if pain relief is sustained, typically starting in the hospital and continuing outpatient. Activity restrictions include avoiding straining, heavy lifting over 5 pounds, and strenuous exertion for at least 2 weeks to prevent leaks or increased . Follow-up clinic visits are scheduled at approximately 1 week to assess the incision and initial symptom relief, followed by evaluations at 1 month and 6 months to monitor long-term outcomes and adjustment. Repeat is recommended if symptom recurrence is suspected, to evaluate for persistent vascular compression or other issues. is tailored to the underlying condition; for glossopharyngeal cases, speech may address postoperative swallowing difficulties, potentially requiring temporary feeding tubes until function improves. In hemifacial spasm patients, can help manage balance issues or vertigo arising from neurotologic effects of the surgery.

Complications and Risks

Intraoperative Complications

Intraoperative complications during microvascular decompression (MVD) are uncommon, with major morbidity rates ranging from 2% to 5% across large series, though rates can be higher in redo procedures as reported in recent studies. Vascular injuries constitute a key intraoperative risk, encompassing arterial bleeding such as laceration of the (AICA), which occurs in less than 1% of cases (overall arterial injury rate of 0.25%). Venous injuries, including damage to the transverse sinus, are slightly more frequent at 0.46% and are typically managed with local or hemostatic agents to achieve rapid control. Direct nerve trauma, particularly to the , arises in 1-2% of procedures and may result in immediate temporary weakness, often due to manipulation or stretch during decompression. Stretch of the auditory pathway can lead to transient changes in brainstem auditory evoked potentials (BAEP), signaling potential reversible compromise that prompts intraoperative adjustments. Cerebellar complications, such as secondary to prolonged retraction, are rare with an incidence below 1%, and immediate mitigation strategies include administration of for reduction or elevation of the head to improve venous . Intraoperative neuromonitoring, including BAEP, aids in early detection and prevention of these events.

Postoperative Complications

Postoperative complications following microvascular decompression (MVD) can include (CSF) leaks, , hearing impairment, and neurological deficits, though major adverse events are relatively uncommon with experienced surgical teams. These issues typically arise in the immediate postoperative period or emerge over time due to factors such as implant materials or surgical site healing. Management focuses on early detection and targeted interventions to minimize long-term morbidity. CSF leak is one of the more frequent postoperative complications, occurring in 0.9% to 12% of cases, often due to dural closure challenges in the posterior fossa. It manifests as clear fluid drainage from the incision or subcutaneous accumulation, potentially leading to or infection if untreated. Initial management involves conservative measures such as , wound reinforcement, and serial imaging (e.g., or MRI) to assess for or leak persistence; persistent cases may require lumbar drainage or reoperation for dural repair. In a series of 134 patients, only 3.7% experienced leaks, all resolved without long-term sequelae using these protocols. Aseptic meningitis, often linked to an inflammatory response from Teflon felt used for , affects approximately 3% of patients (95% CI 1.3–5.8%) and presents with fever, nuchal rigidity, and headache within days to weeks postoperatively. This chemical reaction arises from formation or implant debris irritating the , distinguishable from bacterial via CSF analysis showing pleocytosis without organisms. Treatment typically involves corticosteroids to reduce , with most cases resolving within weeks; prolonged steroid dependence is rare but reported in isolated instances. Hearing loss occurs in 3% to 7% of MVD cases, primarily due to traction on the cochlear nerve or vascular compromise during , with permanent deficits in about 1%. Transient high-frequency sensorineural loss is more common (up to 6.8%), often resolving with steroids or observation, while permanent cases may require auditory rehabilitation. Intraoperative neuromonitoring, such as brainstem auditory evoked potentials, helps mitigate this risk but does not eliminate it entirely. New or worsened facial numbness affects around 5% of patients, usually mild and transient, resulting from manipulation of the root during decompression. In glossopharyngeal neuralgia cases, transient dysphagia occurs in up to 10%, stemming from glossopharyngeal or irritation, typically resolving within 2 months with supportive care like speech therapy. Long-term risks include symptom recurrence in 5% to 10% of cases at 5 years, frequently attributed to Teflon migration or formation re-compressing the . Postoperative infections, such as wound or intracranial abscesses, are rare at less than 1%, managed with antibiotics and drainage if needed; prophylactic measures during surgery significantly reduce this incidence. For persistent deficits or recurrences, reoperation via redo MVD is safe and effective, with 2025 data showing comparable outcomes to initial procedures when performed by experienced surgeons, though facial numbness risk increases slightly.

Alternative Treatments

Pharmacological Therapies

Pharmacological therapies serve as the initial management strategy for conditions treatable by microvascular decompression, such as (TN) and (HFS), offering non-invasive relief before considering surgical options. For TN, anticonvulsants are the cornerstone of first-line treatment, with typically initiated at 200 mg twice daily, titrated as needed up to 1200 mg per day, achieving initial pain relief in 70-80% of patients by stabilizing neuronal membranes and reducing ectopic firing. serves as a suitable alternative, starting at similar doses (600-1800 mg per day), with comparable but a lower incidence of side effects such as and due to its autoinduction profile. In HFS, injections provide targeted symptomatic relief by inhibiting release at neuromuscular junctions, yielding an 80-95% response rate with effects lasting 3-6 months, necessitating repeat administrations every 12-16 weeks on average. Oral , a GABA-B , is occasionally used for control at doses of 10-80 mg per day, though its efficacy is inconsistent and limited by and . As adjunctive or rescue therapies, gabapentinoids like (150-300 mg per day, divided into two or three doses) are employed for cases, modulating calcium channels to reduce release and providing pain reduction in 50-70% of patients intolerant to first-line agents. Long-term use is generally avoided due to risks of dependence, tolerance, and inadequate control. Despite initial benefits, pharmacological approaches face limitations, including development of where approximately 50% of TN patients experience failure within 5 years, often requiring dose escalation or switching agents. Common side effects encompass drowsiness, , , and , particularly with (affecting 20-30% of users), leading to discontinuation in up to 25% of cases. When medications fail to provide sustained relief, patients may progress to interventions like microvascular decompression.

Other Interventional Procedures

Other interventional procedures for conditions treatable by microvascular decompression (MVD), such as (TN) and (HFS), include rhizotomy variants and , which target neural structures destructively or through to alleviate symptoms. These approaches are often considered when MVD is contraindicated due to patient comorbidities or anatomical challenges. Rhizotomy procedures, such as percutaneous rhizolysis (PGR), (RFA), and balloon compression (PBC), involve percutaneous access to the or root to induce selective nerve damage, providing an alternative for TN patients seeking less invasive options than open surgery. Percutaneous glycerol rhizolysis entails injecting into the trigeminal via a needle inserted through the foramen ovale, leading to osmotic demyelination and relief in TN. Initial relief rates for PGR in TN patients range from 82% to 92%, with approximately 90% achieving freedom at 6 months post-procedure. Long-term outcomes show sustained relief in about 54% at 3 years and 59% at 5 years, though recurrence rates can reach 29-40% over time due to regeneration. Complications include facial hypesthesia in up to 25% of cases and rare instances of corneal or . Percutaneous balloon compression involves inflating a in Meckel's cave to compress the , causing selective damage to pain fibers. Initial pain relief rates are 90-95%, with about 70-80% maintaining relief at 1 year. Long-term success is around 50-60% at 5 years, with recurrence in 30-40%. Complications include facial numbness in 20-30% and transient masseter weakness in 10-20%, often resolving within months. Radiofrequency ablation targets the Gasserian ganglion using a radiofrequency probe to create thermal lesions, selectively ablating pain fibers while sparing motor function in TN. Initial success rates for exceed 85-92%, with pain relief achieved in 88% of patients at 1 year. At 5 years, approximately 72% maintain excellent pain control, though recurrence occurs in 20-30% due to incomplete lesioning or collateral nerve involvement. Targeting specific divisions (V1-V3) of the ganglion minimizes , but risks include in 10-20% and masticatory weakness in 5-10%. Radiosurgery, particularly Gamma Knife radiosurgery (GKRS), delivers focused radiation to the trigeminal root entry zone for TN, causing gradual axonal degeneration without incision. Pain reduction occurs in about 70-90% of patients at 1 year, but onset is delayed by 3-6 months in most cases, with complete relief in 70%. Long-term efficacy wanes, with 40-55% maintaining relief at 3 years and recurrence in approximately 20-30% due to incomplete radiosensitive response. Facial numbness develops in 10-20%, and new-onset pain in 5-10%; GKRS avoids general , suiting high-risk patients. For HFS, destructive procedures like myectomy or partial facial nerve section are reserved for cases where vascular compression decompression fails or is not feasible, involving resection of hyperactive muscles or selective nerve fibers. Unilateral myectomy, targeting orbicularis oculi and other , yields excellent or good control in 94% of patients at 1-7 years follow-up, with 75% showing improvement in lower facial contractions. Partial section, which cuts aberrant nerve branches intracranially or extracranially, achieves relief in 80-90% but carries a high risk of permanent facial (House-Brackmann III-IV in 20-50%), making it less favored than MVD. Complications for myectomy include transient edema and , occurring in under 10%. These procedures are generally less invasive than MVD, avoiding and offering outpatient feasibility, but they exhibit higher recurrence rates (20-50% at 5 years) compared to MVD's 70-80% long-term freedom from symptoms. A 2024 retrospective study of TN patients demonstrated MVD's superiority over GKRS, with 94.5% good outcomes at 1 year versus 85.1% and better sustained freedom at 3-5 years for MVD (p < 0.01), attributed to addressing the underlying vascular . Sustained freedom is approximately 80% at 3-5 years for MVD versus 50-60% for or alternatives.