Medical Policy
Subject: Surgical and Ablative Treatments for Chronic Headaches
Document #: SURG.00096Publish Date: 04/10/2024
Status: ReviewedLast Review Date: 02/15/2024
Description/Scope

This document addresses surgical and ablative treatments for chronic headaches, such as migraine and tension type headaches, and occipital neuralgia. A variety of procedures are proposed for this purpose and include, for example, identification of nerve trigger points in the forehead and surgically removing muscle tissue from these areas, and closure of a patent foramen ovale. This document does not address nasal or sinus surgery.

Note: Please see the following related documents for additional information:

Position Statement

Investigational and Not Medically Necessary:

Surgical treatment for chronic headaches (including but not limited to chronic migraine headache and chronic tension type headache) is considered investigational and not medically necessary. This includes, but is not limited to, the following procedures:

Surgical and ablative treatments of occipital neuralgia are considered investigational and not medically necessary. This includes, but is not limited to, the following procedures for treatment of occipital neuralgia:

Rationale

Surgical and Ablative Treatments of Chronic Headache

In 2012, the American Headache Society (AHS) released a statement urging caution when using surgical interventions for the treatment of headaches, which stated that surgery is a “last-resort” option and is not appropriate for most individuals. They cite a lack of sufficient data on long-term benefit and note that surgical interventions have risks, including that of irreversible side effects.

Resection, manipulation or repositioning of musculature surgery, or nerve resection:
Several randomized controlled trials (RCTs) evaluating surgical deactivation of migraine trigger sites have been published. Guyuron and colleagues (2005) conducted an RCT in 125 individuals diagnosed with migraine headaches. Of these, 100 were randomly assigned to the treatment group and 25 served as controls. The treatment group received sequential Botox injections for identification of headache triggers at the “four most common sites,” beginning with the most common site and proceeding at monthly intervals according to an injection algorithm until all potential trigger points were found. Trigger points were found in 91 individuals, 65% of whom had three or four trigger sites identified. A positive response was defined as at least a 50% reduction in intensity and/or frequency of migraine headache lasting at least 4 consecutive weeks, and these individuals were considered surgical candidates. The 25 controls received 0.5 ml. of saline as a “placebo,” however no information was provided regarding their responses and it is unclear which of the four common trigger points were injected in this group. For the treatment group with frontal triggers identified, the glabellar muscle group, including the corrugator supercilii, depressor supercilii and procerus muscles, was removed to relieve compression of the supraorbital and supratrochlear nerves traversing these muscles. Those with temporal migraine underwent endoscopic removal of 3 cm of the zygomaticotemporal branch of the trigeminal nerve to prevent its compression by the temporalis muscle. For those with occipital migraine, a portion of the semispinalis capitis muscle surrounding the greater occipital nerve was removed and the nerve shielded from the muscle with a subcutaneous flap. Participants with migraines triggered from the nasal septum and turbinates underwent septoplasty and inferior and/or middle turbinectomies based on the “intranasal abnormality.”

In the Guyuron (2005) study, there were 89 individuals in the treatment group who completed follow-up. Of these 89, 82 noted at least a 50% reduction in migraine headache frequency and intensity. Post-operatively, 31 reported elimination and 51 reported improvement over a follow-up period of 396 days. In comparison, 3 of the 19 in the control group who completed 1 year follow-up recorded reduction in migraine headaches and no participant observed elimination. Adverse effects from the surgery were minor and transient; however, 23% of those receiving Botox in the temporal area developed hollowing of the temples giving the face an “hour glass” appearance. It was concluded that surgical deactivation of migraine trigger sites can eliminate or significantly reduce migraine symptoms but that additional studies are necessary to clarify the mechanism of action and to determine the long-term results. Drawbacks of this study include lack of information regarding the response of the control group to placebo or sites of injection in this group, and no description of other migraine therapies or any changes in therapy received by either the control or treatment group during the study that might have influenced the outcomes.

In 2010, Guyuron and colleagues reported 5-year follow-up data on the prior study. A total of 79 of the 89 individuals in the treatment group who underwent surgery were followed for 5 years. Ten participants underwent deactivation of additional (different) trigger sites during the follow-up period and were not included in the 5-year analysis. The authors stated that these 10 participants did not affect statistical findings. At 5 years, 62 of the 69 participants (88%) had a positive response to the surgery; no data on the response rate in the control group was reported. Twenty individuals (29%) reported complete elimination of migraine headaches, while 41 (59%) noticed a significant decrease and 8 (11%) had no significant change. Compared to the baseline questionnaires of the SF-36 (short form 36 health survey), MSQ (Mental Status Questionnaire), and MIDAS (Migraine Disability Assessment) testing values, all measured variables at 60 months improved significantly (p<0.0001).

In 2009, Guyuron and colleagues conducted a single-center blinded randomized placebo-controlled trial for surgical treatment of frequent moderate to severe migraine headaches. Headache trigger sites were identified by a positive response to botulinum toxin injections. The participants were randomly assigned to a treatment group of actual surgery (n=49) or sham group (n=26). The treatment group had muscle or nerve tissue removed from their trigger site. The sham surgery group had exposure but not resection of the muscles and nerves through a similar incision. The authors did not specify one or several primary outcomes. They assessed multiple (over 30) outcomes at the p<0.05 level without adjustment for multiple comparisons and thus it is likely that some of the outcomes would have been statistically significant by chance. At 12 months, compared with baseline, the treatment group showed statistically superior outcomes compared to the sham group in 7 comparisons, and no statistical difference in 13 comparisons.

An additional small RCT by Guyuron and colleagues was published in 2015. This study compared two methods of trigger site deactivation: avulsion versus decompression of the zygomaticotemporal branch of the trigeminal nerve. A total of 19 subjects completed the study and were evaluated after a minimum 12 months of follow-up. All subjects experienced greater than 50% improvement in frequency, migraine days, severity, and duration in 34 of the 38 operative sites. There was no statistical significance reported in reduced migraine headache frequency, days, severity, and duration between the two groups. This study did not compare migraine surgery with a different intervention and, therefore, the efficacy of the procedure and a comparator intervention cannot be evaluated.

As summarized in a review by Mathew (2014), limitations of the above studies include “unclear patient selection, lack of sham group in some studies, and the omission of information regarding preventative/abortive medications utilized.” The author concluded, “future trials should address these issues, and should avoid using ambiguous and unclear primary outcomes such as number of migraines, pain intensity, duration, and migraine index which are not validated endpoints in migraine studies.”

In 2018, the American Society for Plastic Surgery (ASPS) released a position statement on peripheral nerve/trigger site/peripheral nerve surgery for chronic refractory migraine headache. The document concluded, “based on a comprehensive literature search…, peripheral nerve/trigger site surgery for refractory chronic MH [migraine headache] is safe and effective in the treatment of patients with a suspected peripherally-generated/centrally-conducted MH etiology”. The only RCT cited as support for the position was by Guyuron (2005), which is discussed above.

A 2019 meta-analysis by Vincent and colleagues pooled data from three RCTs on trigger site surgery for migraine and found significantly greater odds of elimination of migraine after 1 year in the group receiving surgery compared with a control group (Odds Ratio [OR], 21,46; 95% confidence interval [CI], 5.64 to 81.58, random effects model). There was a wide confidence interval, indicating a lack of precision in the pooled estimate; the pooled analysis has the same limitations as the individual trials, as discussed above by Mathew (2014).

Other systematic reviews of studies evaluating surgery for migraine surgery (Huayllani, 2022; Mangialardi, 2020; Nagori, 2019) did not conduct any pooled analyses comparing outcomes in individuals who had surgery compared with a comparison intervention.

In 2021, Ortiz and colleagues published an analysis of the association between headache surgery and medication use. The study included 129 individuals with a diagnosis of chronic headache who had failed conservative therapy and were about to undergo trigger site deactivation surgery. Participants were given surveys to complete before surgery and 12 months after surgery; questions included headache history and medication use. The primary study endpoint was the number of days per month an individual took prescription medication. Pre-surgery, 124 of 129 individuals (94%) reported taking prescription pain medication. The median number of days of medication use pre-surgery was 30, and 76 individuals (59%) reported daily medication use. At the pre-surgery screening, 39 (31%) individuals reported using opioid pain medication. A total of 97 individuals (75%) completed the 12-month follow-up survey. Among responders, the median frequency of prescription medication use was 10 days per month. This represented a statistically significant change from pre-surgical medication use (67% decrease, p<0.001). Individuals who reported opioid medication use pre-surgery reported a median of 11 days of medication use per month post-operatively. Limitations of this analysis include that it lacked a comparison group of individuals who did not undergo headache surgery, and 25% of study participants did not respond to the post-surgery follow-up survey.

A 2021 RCT by Bajaj and colleagues compared peripheral neurectomy and medical treatment in 26 individuals with migraine who had benefitted from a local bupivacaine block. The primary outcome was pain, assessed by a visual analogue scale (VAS) and by the migraine headache index (MHI). Compared with baseline, at 6 months the surgical group had significantly lower VAS and MHI scores (p<0.001 for both outcomes). The authors did not discuss blinding; lack of blinding of participants and/or outcome assessment could bias study results.

Closure of patent foramen ovale:
A higher prevalence of patent foramen ovale (PFO) in migraine sufferers compared to the general population has been observed. Foramen closure is theorized to eliminate paradoxical microemboli to the terminal branches of the basovertebral artery or prevent vasoactive substances triggering migraine to bypass the pulmonary filter.

The first RCT to evaluate PFO closure for treatment of migraine was the Migraine Intervention with STARFlex Technology (MIST) trial, published by Dowson and colleagues in 2008. The trial was double-blind and sham-controlled. Eligibility criteria included 18 to 60 years old, history of migraine with aura starting before age 50, at least 5 migraine days per month, at least 7 headache-free days per month and failure of at least 2 classes of migraine medication. A total of 147 individuals were included, 74 assigned to PFO closure and 73 assigned to a sham procedure. The primary efficacy endpoint was cessation of migraine headache at 3 months according to diary data. Three individuals in each group attained this endpoint and the difference between groups was not statistically significant (difference of -0.06%; 95% CI, -6.45 to 6.34; p=1.0). Secondary efficacy endpoints also did not differ significantly between groups. A total of 16 serious adverse events occurred, 8 of which were possibly or definitely related to the study device.

In 2016, Mattle and colleagues published an RCT comparing PFO closure and medical treatment in 107 individuals with migraine with aura. The study, known as the Percutaneous Closure of PFO in Migraine with Aura (PRIMA) trial,  had blinded endpoint evaluation but subjects and providers were not blinded. The trial recruited individuals with at least 3 migraine attacks or 5 migraine days per month and less than 15 migraine days per month who had failed at least 2 medications. A total of 107 participants were included, 53 in the treatment group and 54 in the medical management group. The primary efficacy endpoint was reduction in migraine days during months 9 to 12 after the intervention compared with the 3 months prior to the intervention, as recorded in a headache diary. There was not a statistically significant difference in the 2 groups on the primary endpoint (p=0.17). Moreover, most secondary endpoints did not differ significantly between the 2 groups.

A third RCT, the PREMIUM trial, was published in 2017 by Tobis and colleagues. This study was double-blind and compared PFO closure with medical management. The study included 230 individuals with 6 to 14 migraine days per month who had failed at least 3 migraine medications. The primary efficacy endpoint was a 50% reduction in migraine attacks at months 10-12 compared with a 2-month period at baseline, as measured by participant diaries. A total of 38.5% in the PFO closure group and 32% in the medical management group attained the primary endpoint. The difference between groups was not statistically significant (difference of 6.4%; 95% CI, -6.2 to 19.0). Findings on secondary outcomes were mixed. Several secondary endpoints, decrease in the mean number of migraine days per month and complete cessation of migraine, favored the PFO closure group. However, there were no significant differences between groups on other secondary outcomes, change in the migraine disability score and the proportion of participants with at least a 75% reduction in migraine attacks.

A meta-analysis of the three RCTs described above was published by Elbadawi and colleagues in 2019. Primary outcomes varied among the trials and meta-analyses were conducted on a number of outcomes. Findings of the meta-analyses were mixed. For example, a pooled analysis found a significantly greater reduction in monthly migraine attacks with PFO closure versus a control intervention (standardized mean difference [SMD], 0.25; 95% CI, 0.06 to 0.43; p=0.01). However, another pooled analysis did not find a statistically significant difference between groups in complete resolution of migraine headache attacks (OR, 3.67; 95% CI, 0.66 to 20.41; p=0.17).

In addition to the RCTs, a number of observational studies evaluating PFO closure for treatment of migraine have been published. A 2017 meta-analysis by Shi and colleagues included eight observational studies on the effect of PFO closure on migraine that distinguished between migraine with and without aura. Only one of the eight studies was prospective (Rigatelli, 2010). A meta-analysis of the eight studies found a significantly greater effect of PFO closure on migraine without aura compared with migraine with aura (OR, 2.5; 95% CI, 1.09 to 5.73). The meta-analysis did not compare PFO closure to other treatments for migraine so conclusions about the efficacy of PFO closure cannot be drawn from this analysis.

None of the three RCTs that studied PFO closure for migraine found a significant effect of the procedure on the study’s primary outcome (reduction or cessation of migraines). All RCTs were multicenter and had blinded endpoint evaluation. In addition, most secondary outcomes did not find a significant benefit of PFO closure. Observational studies that evaluate PFO closure in individuals with migraine are limited by lack of controls and blinding, and most studies were retrospective.

A 2022 meta-analysis by Zhang and colleagues included the MIST, PRIMA and PREMIUM RCTs, discussed above, as well as 8 retrospective case series. A meta-analysis of data from the three RCTs found statistically significant benefits of surgery versus the control intervention on reduction in the number of migraine attacks and resolution of migraine with aura, but no statistically significant difference between groups in reduction in complete resolution of migraine headache. The analysis did not take into consideration the primary versus secondary outcomes of the individual studies.

Surgical and Ablative treatments of Occipital Neuralgia

Various treatments and procedures have been proposed for treatment of occipital neuralgia, however, the published literature addressing these treatments consists of small, nonrandomized studies, case reports and case series, as well as retrospective studies and reviews.

Neurolysis
In a retrospective chart review, Ducic and colleagues (2009) reported on 206 consecutive subjects undergoing neurolysis of the greater or, less commonly, excision of the greater and/or lesser occipital nerves. Preoperative and postoperative visual analogue pain scores and migraine headache indices were measured. Success was defined as a reduction in pain of 50% or greater. Minimum duration of follow-up was 12 months. Of the 206 subjects, 190 underwent greater occipital nerve neurolysis (171 bilateral), 12 subjects underwent greater and lesser occipital nerve excision and 4 underwent lesser occipital nerve excision alone. The authors found that 80.5% of the subjects experienced at least 50% pain relief and 43.4% of the subjects experienced complete relief of headache. Mean preoperative pain score was 7.9 ± 1.4. Mean postoperative pain was 1.9 ± 1.8. This study is limited by lack of a control group.

A much smaller case series was published by Gille and colleagues in 2004. The investigators examined surgical treatment of greater occipital neuralgia by neurolysis of the greater occipital nerve and sectioning of the inferior oblique muscle in 10 individuals. Of this group, 3 individuals had anatomic anomalies. Mean follow-up was 37 months. The results of the treatment were assessed according to three criteria: (1) degree of pain on a VAS; (2) consumption of analgesics; and (3) the degree of satisfaction at follow-up. The mean VAS score was 80/100 before surgery and 20/100 at last follow-up. Consumption of analgesics decreased in all individuals. The small size, short follow-up and lack of a control group limits the validity of the results of this study.

Decompression
In 2011, Ducic and colleagues reported on 25 individuals with documented bilateral occipital neuralgia-related chronic headaches who underwent peripheral nerve surgery with decompression of the greater occipital nerve bilaterally, including the area of its intersection with the occipital artery. All individuals were evaluated intraoperatively for evidence of arterially mediated greater occipital nerve compression and the configuration of the nerve-vessel intersection. Pathologic evaluation of the occipital artery from 15 individuals showed vasculitis. The purpose of the study was to show that mechanical (and not primary inflammatory) irritation of the nerve by the occipital artery is an important theoretical cause for otherwise idiopathic cases. It was not designed to evaluate the efficacy of decompression surgery.

In 2023, Pietramaggiori and Scherer published a retrospective chart review of 87 individuals who underwent surgical decompression of the occipital nerves for treatment of headache at a single center. Outcome measures were those that were noted in the chart before surgery and at the time of the last visit (minimum duration since surgery was 12 months). Chronic pain days decreased from an average of 25 days per month to 4.3 days per month (p<0.01). Individuals reported that pain intensity decreased from an average of 3.7 out of 10 to 0.7 out of ten (p<0.01). In addition, use of nonsteroidal anti-inflammatory drugs decreased from 25 pills per month to 8 pills per month (p<0.01). Controlled studies are needed to determine whether decompression surgery improves outcomes in individuals with neuralgia-related chronic headaches.

Pulsed Radiofrequency
Vanelderen and colleagues (2010) conducted a prospective study on 19 participants receiving pulsed radiofrequency (PRF) for the treatment of occipital neuralgia with a 6-month follow-up. Participants with clinical findings suggestive of occipital neuralgia and a positive test block of the occipital nerves with 2 ml of local anesthetic underwent a PRF procedure of the culprit nerves. Mean scores for pain, quality of life, and medication intake were measured at 1, 2, and 6 months post procedure. Mean VAS and median Medication Quantification Scale scores declined by 3.6 units (p=0.002) and 8 units (p=0.006), respectively, during 6 months. Approximately 52.6% of the participants reported a score of six (pain improved substantially) or higher on the Likert scale after 6 months. No complications were reported. Study limitations include that it had a small sample size and did not include a control group.

Huang and colleagues (2012), in a retrospective data analysis, evaluated PRF for the treatment of occipital neuralgia. A total of 102 individuals with a primary diagnosis of occipital neuralgia were treated with PRF of the greater and/or lesser occipital nerve. A positive primary outcome was predefined as 50% or greater pain relief lasting at least 3 months. The secondary outcome measure was procedural satisfaction. Fifty-two (51%) subjects experienced 50% or greater relief of pain and satisfaction with treatment lasting at least 3 months. The study was uncontrolled and did not report on treatment efficacy beyond 3 months; larger controlled trials reporting longer-term outcomes are needed.

Background/Overview

According to the International Headache Society (IHS), primary headaches are those that are not associated with any demonstrable organic disease, structural or neurologic abnormality. Two types of primary headache are tension-type headache (also known as ordinary headache, stress headache and idiopathic headache) and migraine. Chronic headache, whether migraine or non-migraine, is defined as occurring on 15 or more days per month for more than 3 months.

Tension-type headaches are very common; estimates of lifetime prevalence range from 30% to 70% of the population. Migraines are present in about 28 million people in the United States. The exact pathology of migraines is unknown, but it is felt that a family history of migraine headaches, medications (for example, birth control pills, vasodilators), fatigue, emotional stress and specific foods or alcohol are probable triggers. Migraines manifest as a recurring attack usually lasting for 4-72 hours and involving pain of moderate to severe intensity, often with nausea, sometimes vomiting, sensitivity to light, sound and other sensory stimuli. Management of headaches has consisted largely of pharmacologic treatment (IHS, 2013).

Migraines are generally treated by two approaches: abortive and preventive. The goal of abortive therapy is to prevent a migraine attack or to stop it once it starts. Medications are prescribed to stop a headache during its prodrome stage or once it has begun and may be taken as needed. Preventive treatment is considered if an individual has more than one migraine per week. The goal is to lessen the frequency and severity of the migraine attacks with daily medication.

It has been proposed that activation of peripheral sensory nerves, including the trigeminal nerve, causes release of peptides, (for example, substance P, calcitonin gene-related peptide, neurokinins), resulting in vasodilatation and migraine headache. Also suggested is that trigger points can be identified, particularly in the region of the forehead, at which peripheral nerve activation occurs.

The American Academy of Neurology (AAN) does not address surgical treatment of migraines. Currently their goals of long-term migraine treatment, both pharmacologic and nonpharmacologic are as follows: (AAN, 2004)

Occipital neuralgia is classified as a secondary headache by the ICHD. Secondary headaches are usually associated with any disease, structural or neurologic abnormality. In this case, accurate diagnosing is important because treatment of the underlying problem usually eliminates the headache.

Definitions

Aura: Symptoms such as disturbances in vision, smell or perception that occur prior to a migraine that serve as a warning that the headache may follow.

Etiology: The cause or origin of disease.

Neuroplasty: Surgery to repair or restore nerve tissue.

Neurolysis: The release of a nerve sheath by cutting it longitudinally; operative breaking up of neural adhesions.

Neuralgia: An intense burning or stabbing pain caused by irritation or nerve damage from systemic disease, inflammation, infection, and compression or physical irritation of a nerve.

Nociceptive: Refers to specialized nerve endings that respond to pain or other unpleasant sensations and transmits information about those sensations to the central nervous system.

Occipital: Relating to the back of the head or skull.

Prodrome: The period of time preceding a migraine headache during which a person may feel irritable, out of sorts, moody, unusually sensitive to light or noise, and may notice some fluid retention; this may go on for one or two days or just a few hours before the actual headache begins.

Trigger point: Hyperirritable spots in skeletal muscle that are associated with palpable nodules in taut bands of muscle fibers; the palpable nodules are said to be small contraction knots and a common cause of pain. Compression of a trigger point may elicit local tenderness, referred pain, or motor dysfunction.

Coding

The following codes for treatments and procedures applicable to this document are included below for informational purposes. Inclusion or exclusion of a procedure, diagnosis or device code(s) does not constitute or imply member coverage or provider reimbursement policy. Please refer to the member's contract benefits in effect at the time of service to determine coverage or non-coverage of these services as it applies to an individual member.

When services are Investigational and Not Medically Necessary:
For the following procedure codes for the headache diagnoses listed, or when the code describes a procedure indicated in the Position Statement section as investigational and not medically necessary.

CPT

 

14040-14041

Adjacent tissue transfer or rearrangement, forehead, cheeks chin, mouth, neck, axillae, genitalia, hands and/or feet

14060-14061

Adjacent tissue transfer or rearrangement, eyelids, nose, ears and/or lips

15824

Rhytidectomy; forehead

15826

Rhytidectomy; glabellar frown lines

64640

Destruction by neurolytic agent; other peripheral nerve or branch [when specified as thermal or cryodenervation of occipital nerve]

64716

Neuroplasty and/or transposition, cranial nerve

64722

Decompression; unspecified nerve(s) [for example, occipital nerve]

64732

Transection or avulsion of; supraorbital nerve

64734

Transection or avulsion of; infraorbital nerve

64744

Transection or avulsion of; greater occipital nerve

64771

Transection or avulsion of other cranial nerve, extradural

64772

Transection or avulsion of other spinal nerve, extradural

64787

Implantation of nerve end into bone or muscle

64999

Unlisted procedure, nervous system [when specified as pulsed radiofrequency treatment]

67900

Repair of brow ptosis (supraciliary, mid-forehead or coronal approach)

93580

Percutaneous transcatheter closure of congenital interatrial communication (ie, Fontan fenestration, atrial septal defect) with implant

 

 

ICD-10 Procedure

 

00BK0ZZ-00BK4ZZ

Excision of trigeminal nerve [by approach; includes codes 00BK0ZZ, 00BK3ZZ, 00BK4ZZ]

01510ZZ-01514ZZ

Destruction of cervical nerve [by approach; includes codes 01510ZZ, 01513ZZ, 01514ZZ]

01810ZZ-01814ZZ

Division of cervical nerve [by approach; includes codes 01810ZZ, 01813ZZ, 01814ZZ]

01N10ZZ-01N14ZZ

Release cervical nerve [by approach; includes codes 01N10ZZ, 01N13ZZ, 01N14ZZ]

02U53JZ-02U54JZ

Supplement atrial septum with synthetic substitute [by approach; includes codes 02U53JZ, 02U54JZ]

0J010ZZ-0J013ZZ

Alteration of face subcutaneous tissue and fascia [by approach; includes codes 0J010ZZ, 0J013ZZ]

0KB00ZZ-0KB04ZZ

Excision of head muscle [by approach; includes codes 0KB00ZZ, 0KB03ZZ, 0KB04ZZ]

0KB10ZZ-0KB14ZZ

Excision of facial muscle [by approach; includes codes 0KB10ZZ, 0KB13ZZ, 0KB14ZZ]

 

 

ICD-10 Diagnosis

 

G43.001-G43.E19

Migraine

G44.001-G44.099

Cluster headaches and other trigeminal autonomic cephalgias(TAC)

G44.201-G44.229

Tension-type headache

G50.1

Atypical facial pain

M54.81

Occipital neuralgia

R51.0-R51.9

Headache

References

Peer Reviewed Publications:

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  32. Shi YJ, Lv J, Han XT, Luo GG. Migraine and percutaneous patent foramen ovale closure: a systematic review and meta-analysis. BMC Cardiovasc Disord. 2017; 17(1):203.
  33. Stovner LJ, Kolstad F, Helde G. Radiofrequency denervation of facet joints C2-C6 in cervicogenic headache: a randomized, double-blind, sham-controlled study. Cephalalgia. 2004; 24(10):821-830.
  34. Tobis JM, Charles A, Silbersten SD, et al. Percutaneous closure of patent foramen ovale in patients with migraine: the PREMIUM Trial. J Am Coll Cardiol. 2017; 70(22):2766-2774.
  35. Vanelderen P, Rouwette T, De Vooght P, et al. Pulsed radiofrequency for the treatment of occipital neuralgia: a prospective study with 6 months of follow-up. Reg Anesth Pain Med. 2010; 35(2):148-151.
  36. Vincent AJPE, van Hoogstraten WS, Maassen Van Den Brink A et al. Extracranial trigger site surgery for migraine: a systematic review with meta-analysis on elimination of headache symptoms. Front Neurol. 2019;10:89.
  37. Zhang Y, Wang H, Liu L. Patent foramen ovale closure for treating migraine: a meta-analysis. J Interv Cardiol. 2022;2022:6456272.

Government Agency, Medical Society, and Other Authoritative Publications:

  1. American Academy of Neurology (AAN). Practice parameter: Evidence-based guidelines for migraine headache (an evidence-based review): Report of the Quality Standards Subcommittee of the American Academy of Neurology. Neurology. 2000; 55(6):754-762.
  2. American Academy of Neurology (AAN). Practice Parameter: Pharmacological treatment of migraine headache in children and adolescents: Report of the American Academy of Neurology Quality Standards Subcommittee and the Practice Committee of the Child Neurology Society. Neurology. 2004; 63(12):2215-2224.
  3. American Headache Society. American Headache Society Urges Caution in Using Any Surgical Intervention in Migraine Treatment. 2012. Available at:  https://www.brighamandwomensfaulkner.org/assets/Faulkner/headache-center/documents/ahs-migraine-surgery-statement.pdf. Accessed on November 28, 2023.
  4. Chen PK, Chen HM, Chen WH, et al.; Treatment Guideline Subcommittee of the Taiwan Headache Society. Treatment guidelines for acute and preventive treatment of cluster headache. Acta Neurol Taiwan. 2011; 20(3):213-227.
  5. International Headache Society (IHS). Headache Classification Committee of the HIS. The International Classification of Headache Disorders. 3rd Edition. Cephalalgia. 2013; 33(9):629-808.
Websites for Additional Information
  1. National Headache Foundation. Available at: http://www.headaches.org/. Accessed on November 28, 2023.
  2. U.S. National Library of Medicine. Medline Plus: Migraine. Available at: http://www.nlm.nih.gov/medlineplus/migraine.html. Accessed on November 28, 2023.
Index

Aura
Cephalalgia
Headache, Migraine
Migraine
Neuralgia
Neurolysis
Neuroplasty
Occipital
Pulsed Radiofrequency
Radiofrequency Ablation

The use of specific product names is illustrative only. It is not intended to be a recommendation of one product over another, and is not intended to represent a complete listing of all products available.

Document History

Status

Date

Action

Reviewed

02/15/2024

Medical Policy & Technology Assessment Committee (MPTAC) review. Rationale and References section updated.

 

09/27/2023

Updated Coding section with 10/01/2023 ICD-10-CM changes; added G43.E19 to end of range.

Reviewed

02/16/2023

MPTAC review. Rationale and References sections updated.

Revised

02/17/2022

MPTAC review. Removed bullet point on nasal and sinus surgery from INV&NMN statement. Rationale and References sections updated. Updated Coding section to remove nasal and sinus procedure CPT codes 30130, 30140, 30520, 31200, 31201, 31205, 31254, 31255 and associated ICD-10-PCS codes no longer addressed.

Reviewed

02/11/2021

MPTAC review. Rationale and References sections updated.

 

10/01/2020

Updated Coding section with 10/01/2020 ICD-10-CM changes; added R51.0-R51.9 replacing R51 deleted 09/30/2020.

Reviewed

02/20/2020

MPTAC review. Rationale and References sections updated. Updated Coding section; added CPT 14040, 14041, 14060, 14061, 64716, 64771, 64772, 64787; expanded diagnosis range.

Reviewed

03/21/2019

MPTAC review. Rationale and References sections updated.

Reviewed

03/22/2018

MPTAC review. The document header wording updated from “Current Effective Date” to “Publish Date.” Rationale, Background/Overview and References sections updated.

Reviewed

05/04/2017

MPTAC review. Updated the formatting in the Position Statement section. The References section was updated.

Reviewed

05/05/2016

MPTAC review. Rationale and Reference sections updated. Removed ICD-9 codes from Coding section.

Reviewed

05/07/2015

MPTAC review. Description, Rationale and References sections updated.

Reviewed

05/15/2014

MPTAC review. Description, Rationale, Coding and References sections updated.

Reviewed

05/09/2013

MPTAC review. Rationale, References and Index sections updated.

Reviewed

05/10/2012

MPTAC review. No change to position statement. Rationale updated to address nasal contact point.

Revised

02/16/2012

MPTAC review. Title changed. Position statement revised to clarify nasal surgery criteria and the inclusion of surgical/ablative treatments of occipital neuralgia as investigational and not medically necessary. Description, Rationale, Background, Definitions, Coding and References updated.

Reviewed

02/17/2011

MPTAC review. Rationale and References updated.

Reviewed

02/25/2010

MPTAC review. Rationale and References updated.

Reviewed

02/26/2009

MPTAC review. References updated.

 

10/01/2008

Updated Coding section with 10/01/2008 ICD-9 changes.

Reviewed

02/21/2008

MPTAC review. References updated. The phrase “investigational/not medically necessary” was clarified to read “investigational and not medically necessary.” This change was approved at the November 29, 2007 MPTAC meeting.

New

03/08/2007

MPTAC review. Initial document development.

 


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