Headaches are one of the most common medical complaints worldwide, and treatment is often made difficult because of misclassification. Peripheral nerve stimulation has emerged as a novel treatment for the treatment of intractable headaches in recent years. While high-quality evidence does exist regarding its use, efficacy is generally limited to specific nerves and headache types. While much research remains to bring this technology to the mainstream, clinicians are increasingly able to provide safe yet efficacious pain control.
Headaches are one of the most common medical complaints worldwide, with a prevalence rate of 46% in the general population [1]. A majority of headaches are of the migraine, tension, and cluster subtype, but many other forms exist. The healthcare burden of this is profound, as headaches consistently rank as the fourth or fifth most common reason for emergency-department visits in the United States, and they make it into the top 10 most disabling conditions according to the World Health Organization (WHO) [2]. There is also a significant economic impact from the burden of disease and the often-high cost of treatment. Unfortunately, diagnosis can be difficult, due in part to the complexity of its classification, contributions of referred pain from the spine, and presence of craniofacial pain syndromes. As our knowledge of the nervous system and pathophysiology of headaches and craniofacial pain has advanced, therapeutics have steadily moved towards directly targeting nerves of interest. After conservative measures have been exhausted, peripheral nerve stimulation (PNS) and field stimulation (PNFS) have emerged as a novel therapy for intractable headaches. Given the relatively recent advent of neuromodulation, this entry seeks to help clinicians better understands the efficacy of PNS for headaches, summarize the high-yield evidence for the physician caring for these patients and provide an evidence-based overview of treatment strategies.
Headache disorders and craniofacial pain are often difficult to treat due to the confluence of the spine and both ascending/descending neural pathways in the region. Based on the International Classification of Headache Disorders (ICHD), headaches are generally classified as primary (migraine, tension-type, and cluster headaches) and secondary (caused by underlying systemic or neurologic conditions, trauma, medication overuse, substance withdrawal, and others) (Table 1) [3]. The location, duration, intensity, and characteristics of headache, along with associated symptoms, such as photophobia, phonophobia, nausea, and vomiting, are important in establishing a suitable diagnosis. Craniofacial pain includes lesions of specific nerves, such as the trigeminal, occipital, or vagus, which can lead to neuropathic pain. This overlap complicates the ability to tease out specific diagnoses from history alone, as presentations are often complex. Increasingly, physicians have utilized interventional techniques like PNS to treat all categories of headache disorders [4]. While some have shown promise, further data are needed to determine their true efficacy.
Table 1. Classification of headaches.
Primary Headaches |
Secondary Headaches |
· Migraine |
· Medication overuse headache |
· Tension-type headaches |
· Trauma |
· Trigeminal autonomic cephalalgias |
· Neurological disorders |
o Cluster headache |
· Vascular disorders |
o SUNCT * and SUNA ** |
· Underlying systemic causes (hypertension, fever, and sinusitis) |
o Hemicrania continua |
· Posttraumatic headache |
* SUNCT: short-lasting unilateral neuralgiform headache attacks with conjunctival injection and tearing. ** SUNA: short-lasting unilateral neuralgiform headache attacks with cranial autonomic symptoms.
Due to the complexity in etiology and presentation of headaches and craniofacial pain, treatment can be challenging. Typically, the first step in management is to explore and avoid known triggers, often in the form of caffeine, stress, poor sleep hygiene, and aspartame [3]. If pain continues despite this, the next step is typically pharmacological treatment in the form of oral medications, due to their relatively safe side-effect profile and simplicity of use.
Typically trialed in a stepwise fashion, escalations in management are made if no improvement in symptoms is seen. These are often measured by pain scoring (visual or otherwise) and by measures of disability, including days off work and days with symptoms. Oral pain medications are typically classified as either preventative (prior to an acute episode) or abortive (during an attack) [4]. While specific pharmaceuticals are used for the different headache subtypes, nonsteroidal anti-inflammatory drugs, anticonvulsants, selective serotonin reuptake inhibitors, tricyclic antidepressants, triptans, and corticosteroids are typically used as abortive medications [4][5]. Conversely, preventative therapies often include beta blockers, calcium channel blocks, and other anticonvulsants.
Despite multimodal approaches in management, many refractory cases resistant to conventional treatments subsist. Interestingly, medication overuse headaches have become increasingly prevalent, leading to a need for non-pharmacological interventions. Novel treatments pioneered and trialed in recent years include botulinum injections, nerve blocks, acupuncture, physical therapy, trigger-point injections, deep brain stimulation, and facet joint radiofrequency ablation for cervicogenic headaches [6][5]. While a thorough discussion of the evidence behind the techniques is outside the scope of this review, it is clear that there is no one-size-fits-all approach. Increasingly, PNS has been utilized as a minimally invasive intervention for these complex disorders. Evidence for its use is the primary focus of this review.
While specific guidelines are sparse, the use of PNS has generally been indicated for chronic neuropathic pain disorders originating from specific peripheral nerves. The source of pain should logically follow that of a specific nerve distribution. While the exact mechanism of pain relief is unclear, it is thought to involve activation of central endogenous pain-modulation pathways [7]. As with any other pain modality, the success of PNS relies largely on patient selection. A typical patient for PNS is one who has failed conventional medical treatments and one for whom surgery has been deemed inappropriate [8]. After establishing a diagnosis and exhausting conservative treatment measures, patients are typically referred to a specialist for further discussion of symptoms, physician examination, and review of relevant imaging. Comorbid psychological illnesses should also be explored, as these can significantly reduce intervention success rates [9][10][11]. PNFS indications are even more nebulous, as these involve targeted stimulation of smaller mostly unnamed nerves at the site of pain [10]. Various targets and techniques are outlined below, in addition to the high-yield evidence for each.
There are generally few absolute contraindications for PNS. These typically include medical allergies, local infections, coagulopathies, immunocompromised status, comorbidities preventing fluoroscopic needle guidance, and patient refusal [10][12]. As these are peripheral procedures, the risk of permanent damage is relatively low. Complications are also similarly mild, but they can include headaches, muscle cramping, subcutaneous hematomas, seromas, and local skin infections [7]. Other common complications, along with their incidence seen in literature, are highlighted in Table 2 below. One of the most common themes in preventing success of treatment is improper lead placement or post-operative migration, causing displacement of electrodes from their target nerves [13]. While correctable, this is often frustrating for the patient and can worsen outcomes.
Type | Incidence |
---|---|
Infection | 3.6–17.9% |
Erosion | 4.5–50% |
Migration | 9–25% |
Mechanical Failure | 3.6% |
Lack of Efficacy | 21% |
One of the most well-studied targets for neurostimulation is the occipital nerve ( Table 3 ). The occipital nerves are a group of nerves that originate from the C2/C3 spinal nerves and innervate a significant portion of the scalp, ear, and other nearby structures. The three major occipital nerves include the greater occipital nerve (GON), lesser (or small) occipital nerve (LON), and third (least) occipital nerve (TON) [20][21]. Common pathologies treated by occipital nerve stimulation include occipital neuralgia, chronic migraines, and cluster headaches ( Table 4 ).
Treatment | Quality of Evidence | High Yield Summary |
---|---|---|
Occipital Nerve Stimulation (ONS) |
|
|
Supraorbital Nerve Stimulation (SON) |
|
|
Infraorbital Stimulation |
|
|
Transcutaneous Supraorbital Nerve Stimulation |
|
|
Transcutaneous Supraorbital and Supratrochlear |
|
|
SON and Occipital Stimulation |
|
|
Invasive Vagus Nerve Stimulation (VNS) |
|
|
Noninvasive Vagus Nerve (nVNS) |
|
|
Author | Study | Design | Results |
---|---|---|---|
Weiner and Reed (1999) [40] | Occipital Neuralgia n = 13 |
Observational | 12/17 with >50% pain relief, follow-up 1.5–6 years |
Oh et al. (2004) [28] | N = 20 (10 for ON, 10 for migraine) | Observational | >50% pain relief achieved in 100% at 1 month, 94% at 6 months |
Kapural et al. (2005) [36] | Occipital Neuralgia n = 6 |
Observational | Significant decrease in VAS and PDI seen at 3 months |
Slavin et al. (2006) [39] | Occipital Neuralgia n = 14 |
Observational | 10/14 with successful PNS trial (>50% pain relief), 7/10 with improved pain control and decrease pain medication intake at follow-up |
Johnstone et al. (2006) [35] | Occipital Neuralgia n = 7 |
Observational | 5/7 (71%) with >50% VAS reduction, reduced opioid doses in all patients |
Melvin et al. (2007) [37] | Occipital Neuralgia n = 11 |
Prospective pilot study | 91% with reduced medication use, 73% with good to excellent relief |
Salmasi et al. (2020) [38] | Occipital Neuralgia n = 3 |
Observational | Average pain reduction of 50% after 8 months |
Vadivelu et al. (2012) [76] | Occipital headaches with Chari I n = 15 |
Observational | 87% with continued pain relief at follow-up (avg 19 months), all with >50% VAS reduction |
Popeney et al. (2003) [29] | Chronic migraine n = 25 |
Observational | Average 89% improvement in MIDAS score, all patients reported headaches well controlled |
Matharu et al. (2003) [26] | Chronic migraine n = 8 |
Observational | 100% had good to great pain relief |
Lipton et al. PRISM (2009) [24] | Chronic migraine n = 140 |
Multicenter, double-blinded RCT | Abstract only, no statistically significant difference |
Saper et al. ONSTIM (2011) [31] | Chronic migraine n = 67 |
Multicenter, single-blinded RCT | 51 implanted devices, 39% response rate had >50% VAS improvement |
Dodick et al. (2014) [7] | Chronic migraine n = 157 |
Multicenter, double-blinded RCT | 52 week results showing significantly reduction of headache days by 6.7, excellent or good headache relief in 65%, significantly decreased MIDAS + Zung pain/distress scores |
Serra and Marchioretto (2012) [33] | Chronic migraine n = 30 |
Single center crossover RCT | Significant improvement in headache intensity/frequency, MIDAS, quality of life for all. Decreased drug use |
Slotty et al. (2014) [34] | Chronic migraine n = 8 |
Single center crossover RCT | Improved VAS, no change in SF-36 |
Miller et al. (2016) [27] | Chronic migraine n = 53 |
Observational | 45% with >30% reduction in moderate-severe headache days |
Mekhail et al. (2017) [16] | Chronic migraine n = 20 |
Single center double-blinded RCT | 60% of patients with >30% reduction in pain, 35% with >50% reduction |
Schoenen et al. (2016) [32] | Chronic migraine n = 23 |
Observational | >30% response in 42% for transcutaneous ONS. Significantly decreased total headache days and migraine days |
Liu et al. (2017) [25] | Chronic migraine n = 110 |
Single center single-blinded RCT | >50% response in group treated with both transcutaneous ONS and topiramate. Significant reduction in headache intensity in all groups vs. sham |
Rodrigo et al. (2017) [30] | Chronic migraine n = 37 |
Observational | Substantial pain reduction in most patients, average VAS decrease of 4.9 |
Garcia-Ortega et al. (2019) [23] | N = 17 (12 with migraine, 5 cluster) | Observational | Burst ONS with mean reduction 10.2 headache days per month in CM, significant mean reduction in frequency and intensity for cluster |
Ashkan et al. (2020) [22] | Chronic migraine n = 112 |
Observational | Decrease in MIDAS, HIT-6 at follow-up, decreased headache days. 46.7% were satisfied/very satisfied at 24 months |
Schwedt et al. (2007) [47] | N = 15 (8 for CM, 3 for cluster, 2 for hemicrania, 2 for post-traumatic HA) | Observational | Improvement in frequency, severity, MIDAS |
Trentman et al. (2008) [48] | Cluster Headache n = 10 |
Observational | 50% of patients with >50% reduction in headache frequency or severity |
Burns et al. (2009) [41] | Cluster Headache n = 14 |
Observational | 71% with improvement in symptoms |
Magis et al. (2011) [45] | Cluster Headache n = 15 |
Observational | 80% with <90% improvement in symptoms |
Fontaine et al. (2011) [43] | Cluster Headache n = 13 |
Observational | 77% with >50% improvement in symptoms |
Mueller et al. (2011) [46] | Cluster Headache n = 10 |
Observational | Frequency, duration, severity of attacks reduced in 90% of patient. 100% with improvement in quality of life |
Leone et al. (2017) [44] | Cluster Headache n = 35 |
Observational | 66.7% of patients with >50% reduction in frequency at mean 6.1 years follow-up |
Fontaine et al. (2017) [42] | Cluster Headache n = 44 |
Observational | 59% with >50% improvement in attack frequency. 70% responsive, 47.8% excellent responders |
VAS = pain visual analog scale, PDI = pain disability index, MIDAS = migraine disability assessment score, Zung = pain and distress score (PAD), SF-36 short form health surgery (measure of quality of life).
The trigeminal nerve carries sensory components for much of the head and innervates muscles in the lower jaw. It then divides into the ophthalmic (V1), maxillary (V2), and mandibular (V3) branches [77]. The ophthalmic further divides into the supraorbital nerve and the supratrochlear nerve, while the auriculotemporal nerve is a branch of the mandibular nerve.
Jiang et al. completed a RCT evaluating the combination of flunarizine and transcutaneous supraorbital neurostimulation (tSNS) on episodic migraines on patients randomized to flunarizine only, tSNS only, or both flunarizine and tSNS [57]. They found that while monthly migraine days was decreased in all three groups, pain reduction by >50% was greatest (78%) in the combination therapy group than either flunarizine (46%) or tSNS (39%) alone, showing the efficacy of pharmacological and interventional therapies in treating migraines (Table 5).
In 2019, Chou et al. conducted a multicenter RCT with 109 patients evaluating the efficacy of tSNS for acute migraine attacks. They found that one hour of tSNS treatment resulted in a 59% decrease in VAS versus a 30% decrease with sham [56]. Overall, these studies help support the efficacy of external neuromodulation as viable treatment for migraine headaches.
Several studies have also been conducted on the efficacy of neuromodulation on multiple concurrent nerve targets (Table 6). The first RCT to show the effectiveness of non-invasive supraorbital and supratrochlear PNS for migraines was completed by Schoenen et al. in 2013 [59]. In this study, 67 patients with at least two migraine attacks per month were randomized to either sham or stimulation with daily sessions of tSNS with Cefaly device. After 3 months of treatment, the stimulation group experienced a significant reduction in the average number of migraine days, with 38% achieving a >50% response. This study overall demonstrated a 26% therapeutic gain, which is within the range of those reported for other commonly used migraine treatments.
Table 5. Summary of studies reviewed regarding trigeminal nerve stimulation.
Author |
Nerve |
Study |
Design |
Results |
Simopoulos et al (2010) [79] |
Auriculotemporal |
Chronic Migraine n = 1 |
Observational |
Case report, pain score decrease from 8-9/10 to 5/10 at 16 months, improved MIDAS
|
Vaisman et al (2012) [55] |
Supraorbital/supratrochlear |
Trigeminal Autonomic Cephalgia n = 5 |
Observational |
Decrease in average VAS of 1.6. 100% reported improvement in functional status for ADLs. 60% weaned off opioids |
Johnson and Burchiel (2004) [51] |
Supraorbital or infraorbital |
Trigeminal Neuropathic Pain n = 10 |
Observational |
70% of patients with >50% pain relief and medication use decline |
Slavin et al (2006) [53] |
Supraorbital or infraorbital |
Craniofacial Pain n = 7 |
Observational |
68% with complete pain relief, although some patients received concurrent ONS
|
Amin et al (2008) [50] |
Supraorbital |
Supraorbital Neuralgia n = 10 |
Observational |
Overall, decreased headache scores, 50% decrease in opioid consumption up to 30 weeks
|
Stidd et al (2012) [54] |
Supraorbital or infraorbital (or both) |
Trigeminal Neuropathic Pain n = 3 |
Observational |
Postsurgical and posttraumatic patients with 100% resolution of pain, postherpetic neuralgia with 60% |
Narouze and Kapural (2007) [52] |
Supraorbital |
Cluster Headache n = 1 |
Observational |
Complete ission 14 months after implantation |
Russo et al (2015) [58] |
Transcutaneous supraorbital |
Migraine n = 24 |
Observational |
75% of patients with >50% reduction of monthly migraine attacks and migraines days. Significant reduction in pain intensity and HIT-6
|
Jiang et al (2018) [57] |
Transcutaneous supraorbital |
Episodic Migraine n = 154 |
Single center RCT |
39% of patients with >50% reduction in migraine days with tSNS. 78% with >50% reduction with flunarizine with tSNS
|
Chou et al ACME (2019) [56] |
Transcutaneous supraorbital |
Acute Migraine n = 106 |
Multicenter double-blinded RCT |
59% decrease in acute migraine VAS for transcutaneous trigeminal nerve stimulation vs 30% for sham |
tSNS = transcutaneous supraorbital neurostimulation.
Table 6. Summary of studies reviewed regarding combined PNS.
Author |
Nerve |
Study |
Design |
Results |
Reed et al (2010) [61] |
Occipital and supraorbital |
Chronic migraine n = 7
|
Observational |
Full therapeutic response at 1-35 month follow-up |
Deshpande and Wininger (2011) [81] |
Occipital and auriculotemporal |
Complicated migraine and occipital neuralgia n = 1
|
Observational |
>50% reduction in headache onset at 24 month follow-up |
Mammis et al (2011) [82] |
Occipital, supraorbital, infraorbital |
Cluster headache n = 1
|
Observational |
Decrease from 3-4 episodes per day to 3-4 per month at 36 month follow-up |
Hann and Sharan (2013) [60] |
Occipital and supraorbital |
Chronic migraine n = 14 |
Observational |
71% of patients with >50% reduction in pain severity |
Schoenen et al (2013) [59] |
Transcutaneous supraorbital and supratrochlear |
Chronic Migraine n = 67 |
Multicenter double-blinded RCT |
Decrease in mean migraine days, >50% relief greater in intervention arm, reduced monthly attacks, monthly acute antimigraine medication use
|
Reed et al (2015) [62] |
Occipital and supraorbital |
Hemiplegic migraine n = 4 |
Observational |
Average headache frequency decreased by 92%, VAS by 44%, MIDAS by 98%, medication use by 96% |
The vagus nerve plays a major role in the autonomic nervous system, regulating metabolic homeostasis, control of various organs/glands/muscles in the body, and mediating the transfer of sensory information throughout the body [80]. Historically, neuromodulation of this nerve has played a role in treating epilepsy and depression. In more recent years, there has been a movement towards both invasive and noninvasive methods of vagus nerve stimulation for the treatment of migraine and cluster headaches (Table 7).
Gaul et al. conducted a large multicenter PREVA RCT in the UK, evaluating the use of noninvasive VNS as an adjunct to standard of care (oxygen and triptans) for chronic cluster headaches [71]. As one of the largest RCTs with a total of 97 patients, this study found a significantly greater reduction in the mean number of attacks per month (5.9 vs. 2.1) compared to standard of care. In addition, 40% of patients with the adjunct nVNS reported a greater than 50% reduction in pain as compared to just 8.3% for the control. Overall, this study suggests that nVNS has a beneficial role as an adjunct to standard of care for cluster headaches.
Silberstein et al. conducted the multicenter double-blinded RCT called ACT1 to evaluate the use of nVNS on acute treatment of episodic and chronic cluster headaches [75]. Interestingly, the study found a significantly higher response rate (pain relief based on scoring) for episodic cluster headaches versus the sham, but not for the chronic cohort. Goadsby et al. conducted a similar study on the European population and found comparable results [72]. This suggest that nVNS is more effective at treating episodic cluster headache than chronic cluster headache.
Subsequently, Silberstein completed the EVENT RCT to assess the use of nVNS for chronic-migraine prevention [69]. Patients were randomized to nVNS or sham, with treatments administered personally at a specific time of the day. Overall, they found no statistically significant difference at the 2-month follow-up. Following this, a small subset of patients completed a further 6 months of open-label treatment, where statistical significance (decreased headache days) was achieved. While limited, this suggests that continued nVNS use may have a benefit for chronic-migraine prevention.
Finally, Tassorelli et al. completed the PRESTO RCT to evaluate nVNS as an acute treatment for migraines [76]. Overall, this found that nVNS was superior to the sham in aborting the first treated attack of acute migraine at 30 and 60 min, with repeat-measures testing supporting superiority in pain freedom from 30 to 120 min. The pain-free response rate at 120 min was also similar to those achieved by oral triptans and NSAIDs, suggesting their usefulness for acute migraines.
Table 7. Summary of studies reviewed regarding vagus nerve stimulation.
Author |
Nerve |
Study |
Design |
Results |
Hord et al (2003) [63] |
Invasive Vagus |
Chronic migraine n = 4 |
Observational |
All patients reported reductions in headache frequency and pain score |
Mauskop (2005) [65] |
Invasive Vagus |
Chronic migraine, cluster headache n = 6 |
Observational |
Significant reduction in cluster headaches in 2 patients, 2/4 migraine patients |
Lenaerts et al (2008) [64] |
Invasive Vagus |
Chronic migraine n = 10 |
Observational |
80% of patients had >50% reduction in headache frequency, 50% completely headache free |
Cecchini et al (2009) [66] |
Invasive Vagus |
Chronic headache associated with depression n = 4 |
Observational |
2/4 patients with improved headache and depression |
Nesbitt et al (2015) [74] |
Noninvasive Vagus |
Cluster Headache n = 19 |
Observational |
79% of patients with improved headache intensity, 47% of attacks aborted after average of 11 min |
Gaul et al PREVA (2016) [71] |
Noninvasive Vagus |
Cluster Headache n = 97 |
Multicenter open-label RCT |
Adjunct noninvasive VNS lead to significant reduction in attacks vs standard of care, 40% patients >50% response vs 8.3% for standard of care |
Marin et al (2018) [73] |
Noninvasive Vagus |
Cluster Headache n = 30 |
Observational |
Mean attack frequency decreased from 26.6 per week to 9.5 per week after nVNS. Significant decrease in attack frequency, severity, duration |
Goadsby et al (2014) [83] |
Noninvasive Vagus |
Acute Migraine n = 27 |
Observational |
Pain free rate at 2 hours 21% for first attack, treated at 15 minute intervals with nVNS |
Barbanti et al (2015) [67] |
Noninvasive Vagus |
Acute Episodic and Chronic Migraine n = 50 |
Observational |
56% of patients with >50% reduction in VAS at 1 hr, 64.6% at 2 hr. 33% were pain free at 2 hr |
Straube et al (2015) [70] |
Auricular Transcutaneous Vagus |
Chronic Migraine n = 40 |
Single center double-blinded RCT |
Patients in 1Hz group with significantly larger reduction in headache days than 25Hz. 29% with >50% response for 1Hz |
Kinfe et al (2015) [68] |
Noninvasive Vagus |
N = 20 (10 for episodic migraine, 10 for chronic migraine |
Observational |
Significant reduction in VAS, mean headache days per month, and mean migraine attacks |
Silberstein et al ACT 1 (2015) [75] |
Noninvasive Vagus |
Cluster Headache n = 133 |
Multicenter double-blinded RCT |
Significant response in pain score for those with episodic cluster headache vs sham. However, no total population difference found |
Goadsby et al ACT 2 (2018) [72] |
Noninvasive Vagus |
Cluster Headache n = 48 |
Multicenter double-blinded RCT |
Confirmation study in Europe, nVNS superior to sham for episodic cluster headache, no difference for total population |
Silberstein et al EVENT (2016) [69] |
Noninvasive Vagus |
Chronic Migraine n = 59 |
Multicenter double-blinded RCT |
No significant difference in number headache days at 2 mos. Statistically significant decrease from baseline (-7.9%) was seen after 8 months |
Tassorelli et al PRESTO (2018) [76] |
Noninvasive Vagus |
Episodic Migraine n = 248 |
Multicenter double-blinded RCT |
nVNS superior to sham for freedom from pain 30 and 60 min after attack, repeat tested showed superiority at 120 min |
Peripheral nerve field stimulation involves the placement of electrodes near the area of the pain without direct contact to a specific peripheral neve [84]. While research in this area is relatively new, several observational studies have been completed to evaluate this treatment’s efficacy. Verrills et al. evaluated 83 patients who had undergone PNFS targeting the occipital, supraorbital, and infraorbital nerves for chronic daily headache, chronic migraines, and occipital neuralgia [20]. Overall, they found a mean NRS decrease of 4.8, with 68% of the patients experiencing >50% reduction in pain. Furthermore, 23/35 of the patients at follow-up reported a moderate-to-extreme decrease in analgesic use at follow-up, highlighting its possibility for headache treatment.
In 2018, Ishiyama et al. applied C2 PNFS, using electroacupuncture for primary headache [85]. In this observational study of 54 patients, significant decreases in NRS pain was found with C2 PNFS use, alongside decreases in HIT-6 and SDS (self-rating depressing scale), and decreases in monthly headache days. While more research needs to be done for PNFS, this remains a safe and exciting field for further study.
Remote electrical neuromodulation (REN) is a novel technique for the treatment of acute migraine. The device is placed on the upper arm and stimulates peripheral nerves in the region to induce conditioned pain modulation. Yarnitsky et al. published a randomized, double-blinded, sham-controlled multicenter study across 12 sites with 252 adults to evaluate pain relief at 2 h post-stimulation [86]. They found that active stimulation was more effective in pain relief at 2 h versus the sham, sustained up to 48 h after treatment. While further research remains, this suggests REN can be an effective treatment for acute migraines.
Peripheral nerve stimulation offers promising treatments for intractable headaches. Their success relies on accurate diagnosis and appropriate patient selection. While high-quality evidence does exist regarding its use, additional research is needed in the field. For the physician wishing to utilize PNS in practice, the strongest up-to-date evidence for its use is ONS for treatment of chronic migraines, transcutaneous supraorbital nerve stimulation for migraines, and nVNS for cluster headaches. Preliminary evidence also suggests that interventional therapies may be beneficial as adjuncts to standard-of-care therapies (oxygen, triptans, etc.), thus forming a potential area of study. Looking towards the future, much work remains to bring PNS into the mainstream for headache intervention.
This entry is adapted from the peer-reviewed paper 10.3390/biomedicines9111588