Nerve Compression Syndromes in the Posterior Cranial Fossa
Diagnosis and treatment
Background: Nerve compression syndromes in the posterior cranial fossa can severely impair patients’ quality of life. There is often uncertainty about the best treatment. In this article, we provide an overview of these conditions and the corresponding treatment strategies.
Methods: This review is based on pertinent publications retrieved by a selective search in PubMed and on a scientific analysis of the authors’ patient collective.
Results: These syndromes are caused by compression of a cranial nerve by an artery or vein at the zone of the nerve’s entry to or exit from the brainstem. The best-known neurovascular compression syndrome is trigeminal neuralgia, followed by hemifacial spasm. Less well known are glossopharyngeal neuralgia, nervus intermedius neuralgia, and vestibular paroxysmia. The initial treatment of trigeminal neuralgia is medical: the first line of treatment is with sodium-blocking anticonvulsants, such as carbamazepine. For patients with hemifacial spasm, botulinum toxin injection is the recommended initial treatment and often leads to a satisfactory regression of the spasms. If these treatments fail, a microvascular decompression operation is indicated. The aim of the procedure is to separate the irritating vessel from the nerve and to keep these structures apart permanently. There is hardly any available evidence on these treatment strategies from randomized controlled trials.
Conclusion: Nerve compression syndromes in the posterior cranial fossa can generally be treated nonsurgically at first. Over the course of the condition, however, treatment failure or intolerable side effects may arise. In such cases, a microvascular decompression operation is indicated. This is a causally directed form of treatment that generally yields very good results.
Neurovascular compression syndromes are clinically characterized by functional disturbances of individual cranial nerves. The most common compression syndrome affects the trigeminal nerve and leads to trigeminal neuralgia, followed by hemifacial spasm, which is caused by vascular compression of the facial nerve. Less well-known nerve compression syndromes affect the glossopharyngeal nerve, the nervus intermedius and the vestibulocochlear nerve. Very rarely, the oculomotor nerve or the abducens nerve is involved.
A single pathophysiological mechanism underlies all of these compression syndromes. In the area of the root entry zone or root exit zone (REZ) of the relevant cranial nerve at the brainstem, the nerve comes into contact with a blood vessel—usually an artery, less commonly a vein. This is a natural weak point of the nerve, the site of transition between central and peripheral myelin. The nerve is especially sensitive to mechanical irritation here, which provokes the clinical symptoms of nerve compression.
In this review, we discuss the individual neurovascular compression syndromes of the posterior fossa and various corresponding modes of treatment.
A literature search was carried out in PubMed with the following search terms: “neurovascular compression syndrome,” “cranial neuralgia,” “trigeminal neuralgia,” “hemifacial spasm,” “glossopharyngeal neuralgia,” “vestibular nerve compression,” “vestibular paroxysmia,” “intermedius neuralgia” and “microvascular decompression.” For this review, we mainly considered large-scale studies carried out in the past 20 years. There is hardly any evidence available from randomized controlled trials on treatment strategies for these compression syndromes. In particular, the evidence for the utility of interventional and invasive treatments is based mainly on longitudinal follow-up studies evaluating the long-term results in patient cohorts of variable sizes.
Whenever a nerve compression syndrome is suspected, magnetic resonance imaging (MRI) of the brain should be performed, with particular attention to the posterior fossa. High-resolution 3D-T2-weighted sequences, such as the CISS (constructive interference in steady-state) sequence, should be obtained, as well as 3D-TOF (time-of-flight) MR angiography, in order to distinguish reliably between arterial and venous compression (Figure 1) (1, 2, e1). MRI also serves to rule out other processes that might cause the same clinical manifestations, such as a tumor or aneurysm.
Trigeminal neuralgia is the most common neurovascular compression syndrome in the posterior fossa, with an incidence of 4–5 cases per 100 000 persons per year (among persons over age 60: up to 20 per 100 000 persons per year ) (3, 4). It can thus be estimated that some 4200 people newly develop symptoms of trigeminal neuralgia in Germany each year. The pain is generally strictly unilateral, lasting a few seconds to minutes. It is generally described as attacks of stabbing (lancinating) pain and is usually located in the distribution of the second or third division of the trigeminal nerve (the maxillary or mandibular nerve). The attacks arise spontaneously and can also be evoked by external stimuli, including touching the face or chewing. Spontaneous remission for months or years can occur. Over the course of time, the attacks may become more frequent and the pain longer-lasting (5). A distinction is drawn between classic (idiopathic) trigeminal neuralgia and the much less common symptomatic form of the condition. Classic trigeminal neuralgia is usually due to a neurovascular conflict in which the trigeminal nerve is compressed at its REZ by a blood vessel, often the superior cerebellar artery (e2). Symptomatic trigeminal neuralgia is defined as trigeminal neuralgia due to another disease; it is found, for example, among patients with multiple sclerosis, who often have typical demyelinating foci in the brainstem (e3, e4). It can also be caused by a tumor.
The primary treatment of both types of trigeminal neuralgia is with drugs, primarily sodium-channel blockers that are also used as antiepileptic drugs. The scientific evidence supports the use of carbamazepine as the drug of first choice (6, 7). In symptomatic trigeminal neuralgia, the underlying disease should be treated if possible (e.g., resection of a tumor). If pharmacotherapy brings inadequate relief or causes unacceptable side effects (e.g., fatigue, dizziness, cognitive disturbances), then a neurosurgical procedure can be recommended, such as microvascular decompression (MVD), percutaneous procedures (thermocoagulation, glycerol rhizolysis, balloon compression of the gasserian ganglion), or a radiosurgical procedure (e5, e6). In our opinion, percutaneous techniques should only be considered if there is no demonstrable neurovascular conflict, because, when such a conflict is present, MVD provides better and longer-lasting success and is associated with fewer complications (8–10).
MVD (also called “the Jannetta procedure,” after the American neurosurgeon Peter Jannetta [1932–2016]) is considered a causally directed treatment for classic trigeminal neuralgia and has the highest long-term success rate (11). In large-scale case series, MVD yielded relief or improvement of pain in 68% to more than 90% of cases (12–15, e7–e9). Moreover, meta-analyses have shown MVD to be clearly superior to radiosurgical treatment with respect to early as well as long-term pain relief (16, 17). Well over 80% of patients are still free of pain five years after MVD, and the success rate at 10 years has been reported at over 70% (14, 15). Our experience to date has shown comparably good to very good results (Table 1) (e10). There is no age limit to MVD surgery; good results are achievable even in elderly patients (>75 years old) (e11). Complications of the operation are rare, including ipsilateral hearing loss or deafness and sensory deficits. Multiple studies with long-term follow-up have revealed permanent impairment of hearing in 0.1–3% of patients (18). The risk of cerebellar infarction is reported as less than 1% in most case series (12, 15, 19). The mortality, across multiple studies, is approximately 0.3% (12, 15, 18).
Finally, partial sensory rhizotomy (PSR) should be mentioned as well. This is, in our opinion, a treatment of last resort for intractable trigeminal neuralgia. Patients who have already undergone multiple types of treatment without lasting relief of pain may benefit from this surgical procedure. We have had favorable results from it in patients with multiple sclerosis (among others). In PSR, up to two-thirds of the sensory fibers of the trigeminal nerve are cut (13, e12). The first division of the trigeminal nerve must not be cut, because of the danger of neuroparalytic keratitis; thus, PSR should only be used to treat trigeminal neuralgia of the second and/or third divisions. The patient must be informed preoperatively that PSR will cause numbness in the corresponding area of the face. Our patients have not found this distressing. There is a risk that PSR may be followed by burning dysesthesia in the numb cutaneous area (anesthesia dolorosa) or by difficulty eating or chewing (20), but our patients have not experienced these negative sequelae to date. Anesthesia dolorosa, a rare complication of neuroablative techniques, is difficult to treat (6).
In summary, it must be stated that the current evidence base is inadequate for a satisfactory direct comparison of the invasive and operative treatments for trigeminal neuralgia (21). An extensive Cochrane analysis published in 2011 additionally documents this fact (22).
The epidemiology of hemifacial spasm has not been extensively studied to date. In a study from Olmsted County, Minnesota, the mean annual incidence was found to be 0.81 and 0.74 cases per 100 000 persons per year among women and men, respectively, with a mean prevalence of 11 per 100 000 persons (23). It can thus be calculated that some 9000 persons in Germany now suffer from this condition. Hemifacial spasm is characterized by involuntary, strictly unilateral tonic and/or clonic contractions of the facial musculature, typically including the platysma (e13). The spasms cannot be voluntarily suppressed, and they persist during sleep. Examination reveals the Babinski-2 sign: during the contractions, the eyebrow rises while the eye is closed (Figure 2). This pattern of movement cannot be reproduced in persons without the condition (e14). The diagnosis of hemifacial spasm can generally be made immediately on inspection, but it can also be confirmed electrophysiologically by the demonstration of pathological lateral spreading of activation (24). A source of additional distress to persons with this condition is that the facial spasms are often wrongly thought to be psychogenic (e15). The differential diagnosis of hemifacial spasm includes blepharospasm, facial dystonia, tardive dyskinesia, motor tics, and synkinesia after facial nerve injury, among other conditions (25, 26, e16, e17).
The current state of the evidence on the treatment of hemifacial spasm is poor. For drug therapy, anticonvulsants are usually recommended, but they often fail to provide adequate benefit. Botulinum neurotoxin (BTX) injections have become the standard symptomatic treatment. The efficacy of BTX is based on blockade of calcium-dependent acetylcholine release at the neuromuscular junction, leading to reversible paralysis of the affected muscles (e18). BTX is injected into the affected muscles directly; the clinically visible effect is first seen 3–6 days after injection and lasts approximately three months. Transient side effects arise in approximately 20% of patients, including ptosis, facial palsy, (rarely) diplopia, and headache (e19).
The only causally directed form of treatment is MVD. In patients with marked symptoms, we recommend early surgery, because some of our patients who already displayed structural damage of the facial nerve did not experience satisfactory regression of the spasms. Large-scale studies have yielded very good success rates, with postoperative freedom from spasms in 85–90% of cases (27). These figures are also consistent with our experience (Table 2). The main risk of MVD for hemifacial spasm is ipsilateral hearing loss or deafness, with a reported frequency of 1.5–8% in large case series (28, 29, e20). The rate of deafness among our patients was 3%. We have not seen a permanent, high-grade facial palsy over the long term in any of our patients, but 7% of our patients have had a delayed postoperative facial palsy arising 10–14 days after surgery—a phenomenon also reported by other authors (30, 31, e20). It is conceivable that reactivation of herpes zoster plays a role in this phenomenon, but its cause has not yet been clearly identified (31). Fortunately, this delayed facial palsy generally regresses completely. In current reviews of MVD for hemifacial spasm including data from large numbers of patients, the risk of stroke is estimated at 0.1%, and the mortality is also estimated at 0.1% (27, 32, e21).
The microvascular decompression operation
In our institution, microvascular decompression is performed as an endoscopically assisted microsurgical procedure (33). This means that the main operative moves are carried out under the operating microscope, while the endoscope is used at certain points during the operation as an aid to the inspection of the local anatomy at the REZ, which often (mainly in operations for hemifacial spasm) is less well seen under the microscope alone (Figure 3). The goal of microvascular decompression surgery is to eliminate the neurovascular conflict by separating the nerve and the compressing vessel from each other and preventing recurrent contact over the long term.
The procedure is carried out under general anesthesia through a retrosigmoid craniotomy. Continuous neuromonitoring with facial nerve EMG and auditory evoked potentials is mandatory (26). This enables the early recognition of, and response to, any changes in the function of the facial or auditory nerve. Under microscopic vision, the cerebellopontine angle is opened, and the target cranial nerve is exposed. Endoscopic inspection at this point in the operation reveals the vascular compression very well (Figure 4). The vessel is mobilized away from the affected nerve and a Teflon pledget is inserted between the vessel and the nerve to keep these two structures apart (Figure 4). In some cases, a Teflon sling containing the compressing vessel is sewn up to the dura mater to keep the vessel away from the nerve (Figure 4 d).
Glossopharyngeal neuralgia (vago-glossopharyngeal neuralgia)
This is a rare entity, accounting for only 0.2–1.3% of all cases of “facial pain syndrome” (34, e22). Its incidence has been estimated at 0.7 cases per 100 000 persons per year (4). A neurovascular conflict at the REZ of the glossopharyngeal nerve can lead to attacks of sudden, lancinating pain in the sensory distribution of the auricular and pharyngeal branches of the ninth and tenth cranial nerves (the glossopharyngeal nerve and the vagus nerve). The pain is typically felt in the posterior portion of the tongue, the tonsils, the pharynx, the larynx, the middle ear, and the angle of the jaw. It can be precipitated by triggers such as swallowing or chewing. In rare cases, vagus involvement leads to attacks of bradycardia, asystole, cramps, or syncopal episodes (35). Like trigeminal neuralgia, this disorder can go into remission and possibly relapse at a later time (36).
The diagnosis of (vago-)glossopharyngeal neuralgia is made on clinical grounds; it can be additionally confirmed by immediate suppression of pain during an attack by local anesthesia of the throat. In differential diagnosis, this disorder may be difficult to distinguish from trigeminal neuralgia, because the affected areas are adjacent and the pain is of similar quality. Further differential diagnoses include superior laryngeal neuralgia and nervus intermedius neuralgia. The main form of conservative treatment is with anticonvulsant drugs, which can also be combined with antidepressants (e23). Surgical treatment by microvascular decompression should be considered the gold standard of treatment (37); further options include radiofrequency ablation and radiosurgery (38). The reported success rate of microvascular decompression is over 90% (34, 39, 40).
Neurovascular compression of the eighth cranial nerve
A series of microvascular decompression operations to relieve compression of the eighth cranial nerve was already reported on by Jannetta, who popularized the MVD procedure in the 1970s and -80s (11, e24). He found that some patients with vertigo profit from the operation, but that it was ineffective against tinnitus. It is still debated whether either of these symptoms is ever caused by neurovascular compression. Any potential case requires very precise neurophysiological, neuroradiological, and clinical evaluation (e25). Only a few studies have been dedicated to this topic (e26, e27). A clinically significant entity is vestibular paroxysmia, which is characterized by attacks of rotational or swaying vertigo lasting from a few seconds to one minute (e26). Drugs (mainly carbamazepine) are the first line of treatment, and MVD can be considered in intractable cases. No statement can be made about a potential association of chronic tinnitus with a neurovascular conflict. In a systematic review by Nash et al., the success rate for the treatment of tinnitus as an isolated symptom was 60%—a figure based on a total of only 43 cases culled from an extensive literature search (e27).
Nervus intermedius neuralgia
Nervus intermedius neuralgia, also called geniculate neuralgia, is a very rare condition. Only 174 cases were described from 1932 to 2018 (e28–e30). It is characterized by brief attacks of stabbing deep-seated ear pain (e31). The pain may be accompanied by lacrimation and taste sensations. The condition is usually due to vascular compression of the nervus intermedius, but can also be caused by herpes zoster. Aside from microvascular decompression, transection of the nervus intermedius is also recommended as a treatment for medically intractable cases. Unfortunately, because of the rarity of nervus intermedius neuralgia, the evidence base for its treatment is very small (e28–30).
The most common neurovascular compression syndrome is trigeminal neuralgia, followed by hemifacial spasm. High-resolution 3D-MRI is now available and enables reliable confirmation of the diagnosis in patients with typical clinical manifestations. Microvascular decompression can then be carried out as a causally directed treatment. Patients for whom conservative therapy is insufficiently effective should be informed early about the option of surgical treatment. (Vago-)glossopharyngeal neuralgia, a rare condition, can also be treated surgically with MVD; the operation is indicated for patients with medically intractable symptoms.
Vestibular paroxysmia is due to compression of the eighth cranial nerve. Tinnitus, too, has been relieved by MVD in a few reported cases, but the evidence available from the literature does not permit any clear recommendation. A neurovascular conflict involving the eighth cranial nerve that has been revealed by an imaging study should be considered critically, as such findings are common in asymptomatic persons as well. The current state of knowledge suggests that nervus intermedius neuralgia and carbamazepine-responsive vestibular paroxysmia are potential indications for MVD.
The authors thank Marc Matthes for processing the images and for the statistical analysis of the authors’ own data, as presented in this paper.
Conflict of interest statement
Dr. Baldauf has received reimbursement of travel and accommodation expenses as well as lecture honoraria from the Karl Storz company.
Prof. Schroeder has served as a paid consultant for the Karl Storz company, from which he has also recieved reimbursement of travel and accommodation expenses as well as lecture honoraria.
Dr. Rosenstengel states that he has no conflict of interest.
Manuscript received on 29 March 2018; revised version accepted on 4 October 2018.
Translated from the original German by Ethan Taub, M.D.
PD Dr. med. Jörg Baldauf
Klinik für Neurochirurgie der Universitätsmedizin Greifswald
17475 Greifswald, Germany
For eReferences please refer to:
Dr. med. Christian Rosenstengel, Prof. Dr. med. Henry W. S. Schroeder
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A multivariable prediction model for recovery patterns and time course of symptoms improvement in hemifacial spasm following microvascular decompressionActa Neurochirurgica, 202210.1007/s00701-022-05133-w