Clusterhoofdpijn: Sphenopalatine ganglion stimulatie (SPG)
Uitgangsvraag
Wat is de plaats van sphenopalatine ganglion stimulatie (SPG) in de behandeling bij patiënten met clusterhoofdpijn?
Aanbeveling
Bespreek samen met de patiënt de beschikbare en mogelijke behandelopties.
ONS
Overweeg een verwijzing naar een centrum dat ONS uitvoert bij patiënten met medicamenteus (verapamil, lithium en topiramaat) onbehandelbare chronische clusterhoofdpijn (met 4 of meer aanvallen per week). Overweeg behandeling ter overbrugging bijvoorbeeld met een GON injectie.
NVS, SPG
Behandeling met niet-invasieve nervus vagus stimulatie (NVS) en sphenopalatine ganglion stimulatie (SPG) lijken alternatieven, echter zijn beide therapieën niet beschikbaar in Nederland.
Overwegingen
In de module 'neuromodulatie' staan de overwegingen gerapporteerd.
Onderbouwing
Conclusies
3.1 Pain free after 15 minutes (SPG)
|
Very low GRADE |
The evidence is very uncertain about the effect of SPG as an acute treatment on freedom of pain after 15 minutes when compared with sham treatment in patients with cluster headache.
Sources: Goadsby (2019) and Schoenen (2013) |
3.2 Pain reduction after 15 minutes (SPG)
|
Very low GRADE |
The evidence is very uncertain about the effect of SPG as an acute treatment on pain reduction after 15 minutes when compared with sham treatment in patients with cluster headache.
Sources: Goadsby (2019) and Schoenen (2013) |
3.3-3.11 Attack frequency, use of acute medication, severity of the attack, 50% responder rate, 30% responder rate, quality of life, patient satisfaction and (device related) adverse events
|
- GRADE |
No evidence was found regarding the effect of SPG on attack frequency, use of acute medication, severity of the attack, 50% responder rate, 30% responder rate, quality of life, patient satisfaction and (device related) adverse events were not assessed for treatment with SPG in patients with cluster headache.
Sources: - |
Samenvatting literatuur
Description of studies
After a randomized phase, in which assignment to treatment-arms was maintained, all RCTs reported results of an open label extension period. Since only comparative designs were used for the purpose of this guideline, only study-endpoints for the experimental phase were included. Two studies were found on SPG (Goadsby, 2019; Schoenen, 2013).
SPG: Results
3.1 Pain free after 15 minutes (critical)
Two studies reported on freedom of pain after 15 minutes (Goadsby, 2019; Schoenen, 2013).
In the RCT of Goadsby (2019), freedom of pain after 15 minutes was measured on a five-point ordinal scale (0-4), on which a reduction of pain from 2-4 to 0 without use of medication, was considered freedom of pain. In the four-week experimental phase, 30% of all treated attacks (n=410) in the SPG group, resulted in pain free status in 15 minutes. In the control group, 21% of all treated attacks (n=582) reached pain-free status in 15 minutes. Odds ratios were calculated using a generalized estimated equation model. The odds ratio was 2.32 (95%CI 1.06 to 5.08), favouring the SPG group. Since no raw data were provided, risk ratios could not be calculated. Despite the high amount of events, the clinical relevance of this OR was estimated using the minimal clinical important difference of 10%. This effect was considered clinically relevant.
In the RCT of Schoenen (2013), freedom of pain after 15 was measured on a five-point ordinal scale (0-4). Freedom of pain was defined as a reduction from pain scores (scores 2-4) to a score of 0. Freedom of pain was measured in all participants with at least one treated attack (n=22) during the experimental phase. At the end of the experimental phase, 566 attacks were treated. After full stimulation, 65 out of 190 the treatments resulted in freedom from pain at 15 minutes. After sham stimulation, 3 out of 192 of the treatments resulted in freedom from pain at 15 minutes. Probabilities were calculated using a generalized estimating equation model. Probability for freedom from pain 15 minutes after full stimulation was 34.1% (95%CI 18.6 to 54.1). Probability for freedom from pain 15 minutes after sham stimulation was 1.5% (95%CI 0.5 to 4.9), favouring full stimulation with SPG. Since no raw data were provided, risk ratios could not be calculated. The clinical relevance of this outcome was estimated using the minimal clinical important difference of 10%. The difference between the two probabilities implies clinical relevance.
3.2 Pain reduction after 15 minutes (critical)
Two studies reported on pain relive in 15 minutes (Goadsby, 2019; Schoenen, 2013).
Goadsby (2019) measured pain reduction on a five-point ordinal scale (0-4). Pain reduction in 15 minutes after treatment was defined as a reduction from pain (scores 2-4) to a score of 0 or 1 (without acute medication). In the SPG group (n=36), 189 out of 410 (46%) attacks resulted in pain relief. In the control group (n=40), 226 out of 482 (39%) attacks resulted in pain relief. Odds ratios were calculated using a generalized estimated equation model. This resulted in an odds ratio of 2.62 (95%CI 1.28 to 5.34), with a p-value of 0.008, favouring the SPG group. Since no raw data were provided, risk ratios could not be calculated. Despite the high amount of events, the clinical relevance of this OR was estimated using the minimal clinical important difference of 30%. This effect was considered clinically relevant.
Schoenen (2013) measured pain reduction after 15 minutes on a five-point ordinal scale (0-4: 0 no pain; 4 worst pain). Pain reduction was defined as a reduction from pain scores (scores 2-4) to a score of 0 or 1. At the end of the experimental phase, 566 attacks in 22 participants were treated. After SPG, 127 out of 190 the treatments resulted in pain reduction at 15 minutes. After sham stimulation, 15 out of 192 of the treatments resulted in pain reduction at 15 minutes. Probability for pain reduction 15 minutes after full stimulation was 67.1% (95%CI 50.2 to 80.5). Probability for pain reduction 15 minutes after sham stimulation was 7.4% (95%CI 3.9 to 13.7), favoring full stimulation with SPG. Since no raw data were provided, risk ratios could not be calculated. The clinical relevance of this oucome was estimated using the minimal clinical important difference of 30%. The difference between the two probabilities implies clinical relevance.
3.3 Attack frequency (critical)
Schoenen (2013) and Goadsby (2019) studied SPG as acute treatment, and were not eligible for this outcome measure.
3.8 Quality of life
Difference between two groups in quality of life were not reported in the RCT by Schoenen (2013). Also Goadsby (2019) did not include this outcome measure.
3.4 Use of acute medication, 3.5 severity of the attack, 3.6 50% responder rate, 3.7 30% responder rate and 3.9 patient satisfaction
The outcome measures use of acute medication, severity of the attack, 50% responder rate, 30% responder rate, quality of life and patient satisfaction were not reported in the included studies on SPG.
3.10 Adverse events
In the RCT by Schoenen (2013), at 30 days after implantation, a total of 92 adverse events were reported. After one year, 36 adverse events were reported. Five serious adverse events were reported in five patients (16%). No information was provided which proportion of the adverse events were considered device related, and comparisons between groups were not reported.
In the RCT by Goadsby (2019), at day 30 of the stabilization phase, 340 adverse events were reported, of which 23 events were not assumed to be device or procedure related. At the end of the open label phase, another 171 adverse events were reported, of which 110 were not device or procedure related. Of these adverse events, nine were serious adverse events (measured in nine participants). The amount of participants reporting adverse events was not specified per group. Comparisons between groups were not reported.
3.11 Device related adverse events
Device related adverse events were reported by one study (Goadsby ,2019). Of the 340 adverse events which occurred within 30 days after implantation of the device, 317 were assumed to be device or procedure related. Of the 171 adverse events which occurred 31 days after implantation, 61 were assumed to be device or procedure related. Four out of nine serious adverse events were considered device related. The amount of participants reporting adverse events was not specified per group. Comparisons between groups were not reported.
SPG: Level of evidence of the literature
3.1 Pain free after 15 minutes (acute treatment)
The level of evidence regarding the outcome measure pain free after 15 minutes started as high and was downgraded by three levels to very low because of much influence by sponsoring manufacturer in both studies and unknown carry-over effects (Schoenen, 2013) (-2 risk of bias, and confidence intervals including no effect (Goadsby, 2019) (-1 imprecision).
3.2 Pain reduction after 15 minutes (acute treatment)
The level of evidence regarding the outcome measure pain reduction after 15 minutes started as high and was downgraded by three levels to very low because of much influence by sponsoring manufacturer in both studies and unknown carry-over effects (Schoenen, 2013) (-2 risk of bias) and confidence intervals including no effect (Goadsby, 2019) (-1 imprecision).
3.3-3.10 Attack frequency, use of acute medication, severity of the attack, 50% responder rate, 30% responder rate, quality of life, patient satisfaction, and (device related) adverse events
The level of evidence regarding the outcome measures severity of the attack, 50% responder rate, 30% responder rate, quality of life, patient satisfaction, and (device related) adverse events were not assessed for treatment with SPG.
Zoeken en selecteren
A systematic review of the literature was performed to answer the following questions:
What is the effect of neuromodulation with SPG compared to standard care, different intensity of neuromodulation, or placebo/sham in the treatment of patients with chronic cluster headache?
P: Patients with episodic or chronic cluster headache
I: Neuromodulation with:
2.3.1. ONS for prophylactic treatment; or
2.3.2. NVS for acute or prophylactic treatment; or
2.3.3. SPG for acute or prophylactic treatment
C: Usual care, different intensity of neuromodulation, placebo/sham
O: For acute treatment (SPG, NVS): Pain free after 15 minutes, pain reduction after 15 minutes and adverse events (device related, patient related).
For prophylactic treatment (ONS, SPG, NVS): attack-frequency (per week), use of acute/abortive medication, severity of the attack, 50% responder rate, 30% responder rate, quality of life, patient satisfaction, and adverse events
Relevant outcome measures
The guideline development group considered attack frequency (for prophylactic treatment), pain free after 15 minutes (for acute treatment) and pain reduction after 15 minutes (for acute treatment) as critical outcome measures for decision making; and use of acute/abortive medication, severity of the attack, 50% responder rate, 30% responder rate, quality of life, patient satisfaction and adverse events as an important outcomes measure for decision making.
A priori, the working group did not define the outcome measures listed above but used the definitions used in the studies. Patient satisfaction and quality of life had to be assessed using validated instruments.
Per outcome, the working group defined the following differences as a minimal clinically (patient) important differences:
Dichotomous outcomes (relative risk; yes/no):
- Pain free after 15 minutes: ≥10%
- Pain reduction after 15 minutes: for NVS ≥10%; for SPG: ≥30%
- Use of acute/abortive medication: ≥25%
- 50% responder rate: 30%
- 30% responder rate: 30%
- Adverse events (device related, patient related): ≥10%
Continuous outcomes:
- Pain reduction after 15 minutes: ≥20%; 2 points on a 0-10 scale
- Attack frequency: ≥30% (prophylactic treatment) and n.a. for acute treatment
- Use of acute/abortive medication: ≥25%
- Severity of the attack: ≥20%; 2 points on a 0-10 scale (prophylactic treatment) and ≥30%; 3 points on a 0-10 scale (acute treatment)
- Quality of life: ≥10% difference on a scale, or previously defined minimal importand differences (e.g. 0.07 for EQ-5D-3L, 1 on SF-12 physical scale, 4 on SF-12 mental scale (Hao, 2019))
- Patient satisfaction: ≥10% difference on a validated scale
Search and select (Methods)
The databases Medline (via OVID) and Embase (via Embase.com) were searched with relevant search terms until 5 October 2021. The detailed search strategy is depicted under the tab Methods. Due to overlap between the subjects of module 1 ‘greater occipital nerve-injections’ and module 2 ‘neuromodulation’ in this guideline, the two subjects were combined in one search strategy. The systematic literature search resulted in 451 hits. Studies were selected based on the following criteria:
- systematic review (searched in at least two databases, and detailed search strategy, risk of bias assessment and results of individual studies available), randomized controlled trial, or observational comparative studies;
- full-text English language publication;
- including ≥ 20 (ten in each study arm) patients; and
- studies according to the PICO.
Based on titles and abstracts, 54 studies were initially selected. After reading the full text, 48 studies were excluded (see the table with reasons for exclusion under the tab Methods), and six studies were included.
Results
Six studies were included in the analysis of the literature, of which six randomized controlled trials. No observational studies with comparative character were a match with the PICO. Important study characteristics and results are summarized in the evidence tables. The assessment of the risk of bias is summarized in the risk of bias tables.
One study was found regarding ONS (Wilbrink, 2021), three studies reported data on VNS (Gaul, 2016; Goadsby, 2018; Silberstein, 2016), and two studies were found on SPG (Goadsby, 2019; Schoenen, 2013).
Referenties
- Burns B, Watkins L, Goadsby PJ. Treatment of intractable chronic cluster headache by occipital nerve stimulation in 14 patients. Neurology. 2009 Jan 27;72(4):341-5. doi: 10.1212/01.wnl.0000341279.17344.c9. PMID: 19171831.
- de Coo IF, Wilbrink LA, Haan J. Effective occipital nerve stimulation during pregnancy in a cluster headache patient. Cephalalgia. 2016 Jan;36(1):98-9. doi: 10.1177/0333102415580111. Epub 2015 Apr 1. PMID: 25834272.
- Fontaine D, Christophe Sol J, Raoul S, Fabre N, Geraud G, Magne C, Sakarovitch C, Lanteri-Minet M. Treatment of refractory chronic cluster headache by chronic occipital nerve stimulation. Cephalalgia. 2011 Jul;31(10):1101-5. doi: 10.1177/0333102411412086. Epub 2011 Jul 4. PMID: 21727143.
- Gaul C, Diener HC, Silver N, Magis D, Reuter U, Andersson A, Liebler EJ, Straube A; PREVA Study Group. Non-invasive vagus nerve stimulation for PREVention and Acute treatment of chronic cluster headache (PREVA): A randomised controlled study. Cephalalgia. 2016 May;36(6):534-46. doi: 10.1177/0333102415607070. Epub 2015 Sep 21. PMID: 26391457; PMCID: PMC4853813.
- Goadsby PJ, de Coo IF, Silver N, Tyagi A, Ahmed F, Gaul C, Jensen RH, Diener HC, Solbach K, Straube A, Liebler E, Marin JC, Ferrari MD; ACT2 Study Group. Non-invasive vagus nerve stimulation for the acute treatment of episodic and chronic cluster headache: A randomized, double-blind, sham-controlled ACT2 study. Cephalalgia. 2018 Apr;38(5):959-969. doi: 10.1177/0333102417744362. Epub 2017 Dec 12. PMID: 29231763; PMCID: PMC5896689.
- Goadsby PJ, Sahai-Srivastava S, Kezirian EJ, Calhoun AH, Matthews DC, McAllister PJ, Costantino PD, Friedman DI, Zuniga JR, Mechtler LL, Popat SR, Rezai AR, Dodick DW. Safety and efficacy of sphenopalatine ganglion stimulation for chronic cluster headache: a double-blind, randomised controlled trial. Lancet Neurol. 2019 Dec;18(12):1081-1090. doi: 10.1016/S1474-4422(19)30322-9. PMID: 31701891.
- Hao Q, Devji T, Zeraatkar D, Wang Y, Qasim A, Siemieniuk RAC, Vandvik PO, Lähdeoja T, Carrasco-Labra A, Agoritsas T, Guyatt G. Minimal important differences for improvement in shoulder condition patient-reported outcomes: a systematic review to inform a BMJ Rapid Recommendation. BMJ Open. 2019 Feb 20;9(2):e028777. doi: 10.1136/bmjopen-2018-028777. PMID: 30787096; PMCID: PMC6398656.
- Magis D, Gerardy PY, Remacle JM, Schoenen J. Sustained effectiveness of occipital nerve stimulation in drug-resistant chronic cluster headache. Headache. 2011 Sep;51(8):1191-201. doi: 10.1111/j.1526-4610.2011.01973.x. Epub 2011 Aug 16. PMID: 21848953.
- Mueller OM, Gaul C, Katsarava Z, Diener HC, Sure U, Gasser T. Occipital nerve stimulation for the treatment of chronic cluster headache - lessons learned from 18 months experience. Cent Eur Neurosurg. 2011 May;72(2):84-9. doi: 10.1055/s-0030-1270476. Epub 2011 Mar 29. PMID: 21448856.
- Schoenen J, Jensen RH, Lantéri-Minet M, Láinez MJ, Gaul C, Goodman AM, Caparso A, May A. Stimulation of the sphenopalatine ganglion (SPG) for cluster headache treatment. Pathway CH-1: a randomized, sham-controlled study. Cephalalgia. 2013 Jul;33(10):816-30. doi: 10.1177/0333102412473667. Epub 2013 Jan 11. PMID: 23314784; PMCID: PMC3724276.
- Silberstein SD, Mechtler LL, Kudrow DB, Calhoun AH, McClure C, Saper JR, Liebler EJ, Rubenstein Engel E, Tepper SJ; ACT1 Study Group. Non-Invasive Vagus Nerve Stimulation for the ACute Treatment of Cluster Headache: Findings From the Randomized, Double-Blind, Sham-Controlled ACT1 Study. Headache. 2016 Sep;56(8):1317-32. doi: 10.1111/head.12896. PMID: 27593728; PMCID: PMC5113831.
- Wilbrink LA, de Coo IF, Doesborg PGG, Mulleners WM, Teernstra OPM, Bartels EC, Burger K, Wille F, van Dongen RTM, Kurt E, Spincemaille GH, Haan J, van Zwet EW, Huygen FJPM, Ferrari MD; ICON study group. Safety and efficacy of occipital nerve stimulation for attack prevention in medically intractable chronic cluster headache (ICON): a randomised, double-blind, multicentre, phase 3, electrical dose-controlled trial. Lancet Neurol. 2021 Jul;20(7):515-525. doi: 10.1016/S1474-4422(21)00101-0. PMID: 34146510.
- Zorginstituut Nederland 2019. Standpunt occipitale neurostimulatie (ONS) bij medicamenteus onbehandelbare chronische clusterhoofdpijn, via https://www.zorginstituutnederland.nl/publicaties/standpunten/2019/12/10/standpunt-ons geraadpleegd op 20-12-2022
Evidence tabellen
|
Study reference |
Study characteristics |
Patient characteristics 2 |
Intervention (I) |
Comparison / control (C) 3
|
Follow-up |
Outcome measures and effect size 4 |
Comments |
|
Gaul, 2016 |
Type of study: RCT
Setting and country: 10 European sites (five Germany, three UK, one Belgium, one Italy)
Funding and conflicts of interest: Funded by electroCore, two authors work at electroCore. Also, electrocore provided support with writing, editorial support, and data analysis. |
Inclusion criteria: 18-70 years with diagnosed chronic CH, ≥ 1 year before enrolment
Exclusion criteria: change in prophylactic medication (type/dosage), history of intracranial/carotid aneurysm/haemorrhage, brain tumors/lesions, significant head trauma, previous surgery or abnormal anatomy at nVNS treatment site, known/suspected cardiac/cardiovascular disease, implantation with electrical or neurostimulation devices, history of carotid endarterectomy/vascular neck surgery, implantation with metallic hardware and recent history of syncope/seizures
N total at baseline: Intervention: 48 Control: 49
Important prognostic factors2: age ± SD: I: 45.4 ± 11.0 C: 42.3 ± 11.00
Sex: I: 71% M C: 67% M
Groups comparable at baseline? yes |
Describe intervention (treatment/procedure/test): non-invasive VNS (nVNS) as (adjunctive) prophylactic treatment with usual care
|
Describe control (treatment/procedure/test): usual care alone
|
Length of follow-up: 4 weeks
Loss-to-follow-up: Intervention: 4 Reasons: participant decision
Control: 1 Reasons: participant decision
Incomplete outcome data: Not reported
|
Outcome measures and effect size (include 95%CI and p-value if available):
Attack frequency: mean difference 3.9 (0.5 to 7.2)
Use of acute medication: mean difference -13.00 (-25.47 to -0.53)
50% responder rate: RR 4.8 (1.76 to 13.10)
Quality of life: EQ-5D-3L index mean difference 0.194 (0.054 to 0.334) EQ-5D-3L VAS mean difference 8.93 (0.47 to 17.39)
Patient satisfaction: RR 1.41 (0.78 to 2.56) |
|
|
Goadsby, 2018 |
Type of study: RCT
Setting and country: four EU tertiary sites
Funding and conflicts of interest: all authors received grants from pharmaceutical companies |
Inclusion criteria: ≥ 18 years, diagnosis of episodic/chronic CH.
Exclusion criteria: starting new treatment or changing dose of existing treatment during run-in phase, not in a bout at the time of screening, pregnancy, nursing or thinking of becoming pregnant during the study, or abnormal baseline ECG
N total at baseline: Intervention: 50 Control: 52
Important prognostic factors2: age ± SD: I: 43.9 ± 10.6 C: 46.9 ± 10.6
Sex: I: 70% M C: 73.1% M
Groups comparable at baseline? yes
|
Describe intervention (treatment/procedure/test): nNVS
|
Describe control (treatment/procedure/test): sham treatment
|
Length of follow-up: 2 weeks
Loss-to-follow-up: Intervention: 3 Reasons: 1 protocol violation, 2 other
Control: 6 Reasons: 2 withdrawal, 2 lost to follow-up, 2 adverse events
Incomplete outcome data: Intervention: 2 Reasons: 2 missing diary
Control: 8 Reasons: 6 missing diary, 2 no attacks treated |
Outcome measures and effect size (include 95%CI and p-value if available):
Pain free after 15 minutes: OR 1.22 (0.42 to 3.51)
Pain reduction after 15 minutes: mean difference: -0.41 (-0.90 to 0.07)
Device related adverse events: RR 0.46 (0.24 to 0.87) |
|
|
Silberstein, 2016 |
Type of study: RCT
Setting and country: 20 US centers, including university-based/ academic medical centers and headache/pain/neuro- logical clinics and institutes
Funding and conflicts of interest: |
Inclusion criteria: nonpregnant/nonlactating 18-75 years old diagnosed with episodic/chronic CH
Exclusion criteria: history of aneurysm, intercranial hemorrhage, brain tumors, significant head trauma, prolonged QT interval, arrhythmia, ventricular tachycardia/fibrillation (syncope/seizure), structural intercranial/cervical vascular lesions, another significant pain disorder, cardiovascular disease, uncontrolled hypertension, abnormal baseline ECG, botulinum toxin injections in the past three mohts, nerve blocks in the past month, previous CH surger, bilateral/right cervical vagotomy, carotid endarterectomy, right vascular neck surgery, electrical device implantation, current use of prophylactic medications for indications other than CH
N total at baseline: Intervention: 73 Control: 77
Important prognostic factors2: age ± SD: I: 47.1 ± 13.5 C: 48.6 ± 11.7
Sex: I: 59% M C: 67% M
Groups comparable at baseline? yes |
Describe intervention (treatment/procedure/test): nVNS for acute treatment of attacks |
Describe control (treatment/procedure/test): sham treatment
|
Length of follow-up: 4 weeks
Loss-to-follow-up: Intervention: 2 Reasons: not reported
Control: 3 Reasons: not reported
Incomplete outcome data: Intervention: 12 Reasons: 3 nonadherence, 8 no CH/CH ended, 1 other
Control: 5 Reasons: 2 nonadherence, 1 no CH/CH ended, 2 other
|
Outcome measures and effect size (include 95%CI and p-value if available):
Pain reduction after 15 minutes: RR 1.77 (0.89 to 3.52)
Use of acute medication: RR 0.76 (0.51 to 1.12)
Adverse events: RR 0.61 (0.38 to 0.99) device related RR 0.46 (0.24 to 0.87) |
|
|
Goadsby, 2019 |
Type of study: RCT
Setting and country: 21 headache-centers in USA
Funding and conflicts of interest: The trial was funded by the manufacturer, which had roles in the design of the trial, and all authors were consultant or employee for the funder. |
Inclusion criteria: ≥22 years old, chronic CH, previously or currently inadequately controlled with available therapies.
Exclusion criteria: change in type/dose/dose frequency of preventive headache durgs within the month before enrolment, previous diagnosis of trigeminal neuralgia/other trigeminal autonomic cephalalgias
N total at baseline: Intervention: 45 Control: 48
Important prognostic factors2: For example age ± SD: I: 48 ± 11 C: 48 ± 11
Sex: I: 73% M C: 73% M
Groups comparable at baseline? yes |
Describe intervention (treatment/procedure/test): full stimulation of the SPG
|
Describe control (treatment/procedure/test): sub-perception stimulation or sham as the acute treatment for every new attack
|
Length of follow-up: up to 3 weeks
Loss-to-follow-up: Intervention: 9 Reasons: no acute attacks during experimental phase
Control: 8 Reasons: no acute attacks during experimental phase
Incomplete outcome data: Not reported
|
Outcome measures and effect size (include 95%CI and p-value if available):
Pain free after 15 minutes: OR 2.32 (1.06 to 5.08)
Pain reduction after 15 minutes: OR 2.62 (1.28 to 5.34) |
|
|
Schoenen, 2013 |
Type of study: RCT
Setting and country: in six European clinical sites
Funding and conflicts of interest: The trial was funded by the manufacturer, which had roles in design, collecting, analysing and interpretation of data, and writing. All authors have been consultants at sponsor (ATI) or are employees at ATI (n=2).
|
Inclusion criteria: 18-65 years old, with chronic CH, reporting dissatisfaction with current treatments, able to distinguish cluster headaches from other headache types
Exclusion criteria: change in type/dosage of preventive headache medications within one month of enrolment, pregnant/nursing women, or women not using contraception of childbearing age, patients who had undergone facial surgery in specified areas within the last four months, previous treatment with radiation in last six months, patients undergone lesional radiofrequency ablation of the ipsilateral SPG/block of ipsilateral SPG or botox injection in head/neck in last three months, patients with other significant pain problems which could confound (opinion of the investigator)
N total at baseline: Intervention: - Control: -
Important prognostic factors2: age ± SD: Total: mean age 45 years (range 20-63 Sex: Total: 85% M
Groups comparable at baseline? yes |
Describe intervention (treatment/procedure/test): SPG for the acute treatment of attacks
|
Describe control (treatment/procedure/test): sham stimulation
|
Length of follow-up: 4 weeks
Loss-to-follow-up: None reported
Incomplete outcome data: 4 Reasons: 1 failure to implant, 2 explanted, 1 skipped experimental period due to pregnancy
|
Outcome measures and effect size (include 95%CI and p-value if available):
Pain free after 15 minutes: probability freedom from pain 15 minutes after full stimulation: 34.1% (18.6 to 54.1) after sham stimulation 1.5% (0.5 to 4.9).
Pain reduction after 15 minutes: OR 2.62 (1.28 to 5.34) |
|
Risk of bias table for intervention studies (randomized controlled trials; based on Cochrane risk of bias tool and suggestions by the CLARITY Group at McMaster University)
|
Study reference
|
Was the allocation sequence adequately generated? |
Was the allocation adequately concealed?
|
Blinding: Was knowledge of the allocated interventions adequately prevented? |
Was loss to follow-up (missing outcome data) infrequent?
|
Are reports of the study free of selective outcome reporting?
|
Was the study apparently free of other problems that could put it at a risk of bias?
|
Overall risk of bias If applicable/necessary, per outcome measure
|
|
Wilbrink, 2021 |
Definitely yes;
Reason: randomly varying block design |
Definitely yes;
Independent statistician |
Definitely yes;
Medical professionals implanting devices, participants and outcome assessors were all masked. |
Probably no
Low loss to follow-up (1 from intervention, 1 from control, total 1.5%), risk of bias due to LOCF considered very low |
Probably no;
Use of acute medication was only reported for baseline data, while protocol suggests 6-mnt FU data. Patient satisfaction not reported per group. |
Probably yes;
“The funder of the study had no role in study design, data collection, data analysis, data interpretation, or writing of the report.” Corresponding author had final responsibility in decision for publication. |
Low (Mean attack frequency, mean attack intensity, 50% responder rate) Some concerns (use of acute medication, patient satisfaction) |
|
Gaul, 2016 |
Probably yes
Reason: participants were randomly assigned 1:1 by standard block design. |
Probably no
Reason: No information about block sizes or concealment provided. |
Definitely no
Reason: Participants were not blinded for the intervention, no sham control was used.
(blinding of data collectors, outcome assessors and analysts not reported)” |
Probably yes
Reason: for acute medication use and quality of life, follow-up data were presented for participants who completed the open-label phase (= modified ITT). Loss to follow-up was imbalanced: four persons in the NVS group withdrew without reason given, 1 person in control group dropped out for unknown reason. For attack frequency and 50% responder rate, missing data was imputed with 0. |
Probably no
Reason: analyses for differences between mean changes of HIT-6 are not provided. |
Probably no
Reason: Funded by electroCore, two authors work at electroCore. Also, electrocore provided support with writing, editorial support, and data analysis. |
HIGH (use of acute medication, quality of life) Some concerns (Attack frequency, 50% responder rate, adverse events)
|
|
Goadsby, 2018 |
Probably yes
Reason: standard design with block size 4, central randomization, using envelopes. |
Probably no
Reason: sealed envelopes were used, but trainers providing the devices were unblinded. |
Probably no
Reason: Patients were blinded, trainers were not blinded. It is not stated whether outcome assessors or analysts were blinded. |
Probably no
Reason: For all outcomes but adverse events, the ITT population was used. The ITT population did not include participants with missing diaries, since there was no efficacy assessment (-2 in NVS, -6 in sham). Also, if attacks were not treated, participants were not included in ITT population (-2 in sham). |
Probably yes
Reason: For all outcomes matching the PICO of this guideline, results were prespecified in the methods and reported in the result section. |
Probably yes
Reason: no serious bias appeared to be present. |
Some concerns (freedom of pain in 15, pain intensity in 15, adverse events) |
|
Silberstein (2016) |
Definitely yes
Reason: Using independent statistician–generated randomization sched- ules, variable block design, stratified by site |
Probably yes
Reason: a variable block design was used. |
Probably yes
Reason: Patients, investigator, study coordinators were blinded. |
Probably yes
Reason: missing data for pain reduction were imputed as failure. There were more drop-outs in the NVS group (n=13), than in the control group (n= 5) |
Probably yes
Reason: For all outcomes matching the PICO of this guideline, results were prespecified in the methods and reported in the result section. |
Probably yes
Reason: no serious bias appeared to be present. |
Some concerns: Pain reduction in 15, adverse events |
|
Schoenen (2013) |
Probably no;
Not stated whether the randomization sequence was in variable blocks or otherwise not trackable for participants. |
Probably yes;
Stimulation doses were delivered randomly (1:1:1) using pre-specified, randomization sequences that were programmed into the remote controller. |
Probably no;
Full stimulation could probably be perceived due to paraesthesia’s.
|
Probably yes;
Due to design, no disproportional dropout was reported. |
Probably yes;
Reason: For all outcomes matching the PICO of this guideline, results were prespecified in the methods and reported in the result section. |
Probably no;
All authors have been consultants at sponsor (ATI) or are employees at ATI (n=2).
Investigation/controlling for crossover effect was not mentioned by the authors. |
Some concerns (Freedom of pain after 15 minutes, pain reduction after 15 minutes) |
|
Goadsby (2019) |
Probably yes;
Computer generated (Bracket Global software) |
Probably no;
Randomization was not central, and stratified for investigational site, sex and weekly attack frequency. Might be predictable for the unblinded study coordinator |
Probably yes;
Patients, outcome assessor and statistician were blinded.
Study coordinator at sites were unblinded. |
Probably yes;
Except for the outcomes of pain relief/freedom of pain, which were not measured in 17 participants (9 SPG, 8 control). |
Probably yes,
Reason: For all outcomes matching the PICO of this guideline, results were prespecified in the methods and reported in the result section. |
Definitely no;
The funder had roles in design, collecting, analysing and interpretation of data, and writing. |
HIGH (Freedom of pain after 15 minutes, pain reduction after 15 minutes) |
Randomization: generation of allocation sequences have to be unpredictable, for example computer generated random-numbers or drawing lots or envelopes. Examples of inadequate procedures are generation of allocation sequences by alternation, according to case record number, date of birth or date of admission.
Allocation concealment: refers to the protection (blinding) of the randomization process. Concealment of allocation sequences is adequate if patients and enrolling investigators cannot foresee assignment, for example central randomization (performed at a site remote from trial location). Inadequate procedures are all procedures based on inadequate randomization procedures or open allocation schedules..
Blinding: neither the patient nor the care provider (attending physician) knows which patient is getting the special treatment. Blinding is sometimes impossible, for example when comparing surgical with non-surgical treatments, but this should not affect the risk of bias judgement. Blinding of those assessing and collecting outcomes prevents that the knowledge of patient assignment influences the process of outcome assessment or data collection (detection or information bias). If a study has hard (objective) outcome measures, like death, blinding of outcome assessment is usually not necessary. If a study has “soft” (subjective) outcome measures, like the assessment of an X-ray, blinding of outcome assessment is necessary. Finally, data analysts should be blinded to patient assignment to prevents that knowledge of patient assignment influences data analysis.
Lost to follow-up: If the percentage of patients lost to follow-up or the percentage of missing outcome data is large, or differs between treatment groups, or the reasons for loss to follow-up or missing outcome data differ between treatment groups, bias is likely unless the proportion of missing outcomes compared with observed event risk is not enough to have an important impact on the intervention effect estimate or appropriate imputation methods have been used.
Selective outcome reporting: Results of all predefined outcome measures should be reported; if the protocol is available (in publication or trial registry), then outcomes in the protocol and published report can be compared; if not, outcomes listed in the methods section of an article can be compared with those whose results are reported.
Other biases: Problems may include: a potential source of bias related to the specific study design used (e.g. lead-time bias or survivor bias); trial stopped early due to some data-dependent process (including formal stopping rules); relevant baseline imbalance between intervention groups; claims of fraudulent behavior; deviations from intention-to-treat (ITT) analysis; (the role of the) funding body (see also downgrading due to industry funding. Note: The principles of an ITT analysis implies that (a) participants are kept in the intervention groups to which they were randomized, regardless of the intervention they actually received, (b) outcome data are measured on all participants, and (c) all randomized participants are included in the analysis.
Overall judgement of risk of bias per study and per outcome measure, including predicted direction of bias (e.g. favors experimental, or favors comparator). Note: the decision to downgrade the certainty of the evidence for a particular outcome measure is taken based on the body of evidence, i.e. considering potential bias and its impact on the certainty of the evidence in all included studies reporting on the outcome.
Table of excluded studies
|
Author and year |
Reason for exclusion |
|
de Coo 2019 |
Geen systematische review, geen RCT, gepoolde analyse van Goadsby2018 en Silberstein2016 (wrong design) |
|
Burns 2007 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Burns 2009 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Miller 2017 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Aibar-Durán 2020 |
Dubbel (Aibar-Durán 2021) |
|
Jürgens 2017 |
Extention phase of Schoenen (2013), observationeel niet vergelijkend onderzoek (wrong design) |
|
Tronnier 2010 |
Verkeerde taal, lijkt geen systematische review (wrong language, wrong design) |
|
Magis 2011 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Magis 2007 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Láinez 2014 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Morris 2016 |
Geen match met PICO: Cost-effectiveness results of Gaul2016 (wrong outcome) |
|
Mwamburi 2018 |
Geen match met PICO: migraine population (wrong population) |
|
Mwamburi 2017 |
Geen match met PICO: cost-effectiveness results of Goadsby2018 en Silberstein2016 (wrong outcome) |
|
Fontaine 2018 |
Geen systematische review over SPG (wrong design) |
|
Marin 2018 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Barloese 2018 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Sánches-Gomez 2021 |
Dubbel (Sánches-Gomez, 2021) |
|
Fontaine 2011 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Marin 2018 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Marin 2018 |
Dubbel (Marin, 2018) |
|
Mauskop 2005 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Schwedt 2007 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Mueller 2011 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Lainez 2016 |
Geen systematische review (narrative review) |
|
Gaul 2017 |
Extention phase of Gaul (2016), observationeel niet-vergelijkend onderzoek (wrong design) |
|
Lepus 2021 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Leone 2017 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Fontaine 2010 |
Geen match met PICO: unilateral hypothalamic DBS (wrong intervention) |
|
Nowacki 2020 |
Geen match met PICO: DBS for CCH (wrong intervention) |
|
Stilling 2019 |
Geen match met PICO: TMS and tDCS (wrong intervention) |
|
Aibar-Durán 2021 |
Geen match met PICO: ONS vergeleken met DBS (wrong control) |
|
Mammis 2011 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Diaz-de-Teran 2021 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Magis 2016 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Chen 2020 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Guo 2021 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Sciacca 2014 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Kelderman 2019 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Narouze 2009 |
Observationeel niet-vergelijkend onderzoek (wrong design) |
|
Silberstein 2017 |
Geen systematische review (wrong design) |
|
Lai 2020 |
Systematic review did not include all critical/important outcome measures |
|
Cadalso 2018 |
Systematic review did not include RCTs or comparative observational studies for PICO |
|
Jasper 2008 |
Systematic review did not include RCTs or comparative observational studies for PICO |
|
Reuter 2019 |
Systematic review did not include all critical/important outcome measures |
|
Ho 2017 |
Systematic review did not include Goadsby2019 |
|
Sanchez-Gomez 2018 |
Systematic review did not include Goadsby (2019) |
|
Robbins 2016 |
Systematic review did not include Goadsby (2019) |
|
Vukovic Cvetkovic 2018 |
Systematic review did not include Goadsby (2019) and Wilbrink (2021) |
Verantwoording
Autorisatiedatum en geldigheid
Laatst beoordeeld : 18-10-2023
Laatst geautoriseerd : 18-10-2023
Geplande herbeoordeling :
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