Neuromodulatie (ook wel neurostimulatie genoemd) kan door middel van elektriciteit de werking van het zenuwstelsel beïnvloeden, hierdoor kan de werking van het zenuwstelsel veranderen met een mogelijk therapeutisch effect als gevolg hebben. Er zijn verschillende vormen van neuromodulatie beschikbaar voor patiënten met clusterhoofdpijn. Occipitale zenuwstimulatie (ONS) wordt sinds 1 januari 2020 vergoed door de zorgverzekeraar bij patiënten met refractaire chronische clusterhoofdpijn. Non-invasieve nervus vagus stimulatie (NVS) lijkt in praktijk een effectieve acute therapie bij episodische clusterhoofdpijn, maar niet bij chronische clusterhoofdpijn. Hierbij wordt met een apparaat de nervus vagus gestimuleerd in de hals. Er is mogelijk een profylactisch effect bij chronische clusterhoofdpijn. Non-invasieve nervus vagus stimulatie wordt momenteel niet vergoed en niet toegepast in Nederland. Echter bestellen sommige patiënten soms zelf een apparaat. Sphenopalatine ganglion stimulatie (SPG) is mogelijk effectief zowel als acute behandeling en profylactische behandeling in chronische clusterhoofdpijn, echter is dit nog onvoldoende onderzocht.

Samenvattend, er zijn verschillende nieuwe therapieën beschikbaar waarbij de toegevoegde waarde nog niet goed onderzocht is bij clusterhoofdpijn. De invasieve behandelingen gaan gepaard met relatief hoge kosten. Een eenduidig beleid ontbreekt momenteel in de Nederlandse praktijk. In deze module worden aanbevelingen gedaan over de rol van de verschillende vormen neuromodulatie (ONS, NVS, SPG) in de behandeling van clusterhoofdpijn.

1.3 Attack frequency per week (ONS)

1.5 Severity of the attack (ONS)

1.6 50% responder rate (ONS)

1.7 30% responder rate (ONS)

1.8 Quality of life (ONS)

1.10 Adverse events (ONS)

1.11 Device related adverse events (ONS)

1.1 Pain free after 15 minutes, 1.2 Pain reduction after 15 minutes, 1.4 Use of acute medication, 1.9 Patient satisfaction (ONS)

Comparison with placebo/sham or usual care only

2. NVS: Results

2.1 Pain free after 15 minutes, acute treatment (critical)

Gaul (2016) studied NVS als profylactic treatment, and was not eligible for this outcome measure. Silberstein (2016) did not include this outcome measure.

In the RCT of Goadsby (2018), pain intensity was measured on a five-point ordinal scale (0-4). Freedom of pain in 15 minutes after treatment was defined as the proportion of all treated attacks for which pain-free status (score 0) was reported in 15 minutes (without use of rescue medication). After two weeks, 13.5% of all treated attacks (n=495) in the nNVS group (n=48) resulted in pain free status in 15 minutes. In the sham group (n=44), 11.5% of the attacks (n=400) reached pain-free status in 15 minutes. ORs were calculated using a generalized estimating equations model. The OR for freedom of pain in 15 minutes was 1.22 (95%CI 0.42 to 3.51). Since no raw data were provided, risk ratios could not be calculated. Despite the high amount of events, the clinical relevance of this odds ratio was estimated using the minimal clinical important difference of 10%. Considering an overestimation of the risk ratio, this effect was not considered clinically relevant.

2.2 Pain reduction after 15 minutes, acute treatment (critical)

Gaul (2016) studied NVS als prophylactic treatment, and was not eligible for this outcome measure.

Two studies reported on pain reduction in 15 minutes (Silberstein, 2016; Goadsby, 2018).

Silberstein (2016), defined pain reduction as the proportion of subjects who achieved a pain intensity score of 0 or 1 (on a 5-point Likert scale) without the use of acute medication. The outcome was reported for the first treated cluster headache-attack. In the nVNS-group, 16 out of 60 (26.7%) participants reported pain reduction in 15 minutes after treatment. In the sham-group, 11 out of 73 (15.1%) participants reported pain reduction.

This resulted in a risk ratio of 1.77 (95%CI 0.89 to 3.52), favouring the nVNS group. This difference was clinically relevant.

Goadsby (2018) assessed pain reduction in 15 minutes on a five-point ordinal scale (0-4). Pain reduction was measured in participants with at least one treated attack without the use of rescue medication. In the NVS group (n=36), mean intensity was 2.4 at attack onset and 1.1 after 15 minutes, resulting in a mean change of -1.3 (SE 0.2, SD 1.2). In the control group (n=31), mean pain intensity was 2.1 at attack onset and 1.2 after 15 minutes, resulting in a mean change of -0.9 (SE 0.1, SD 0.56). The mean difference between the change scores was -0.41 (95%CI -0.90 to 0.07). This difference was not clinically relevant.

2.3 Attack frequency, prophylactic treatment (critical)

Silberstein (2016) and Goadsby (2018) studied NVS as acute treatment, and were not eligible for this outcome measure.

In the RCT of Gaul (2016), attack-frequency was calculated by subtracting the number of attacks assessed before baseline (divided by two) from the number of attacks at follow-up. The baseline attack frequency in the four weeks before enrolment was 67.3 (SD 43.6) in the intervention group, and 73.9 (SD 115.8) in the control group. For follow-up data, attack frequency was evaluated in the second two weeks of the experimental phase. At follow-up, the attack-frequency change-score was -5.9 (SE 1.2) in the NVS group (n=45) and was -2.1 (SE 1.2) in the control group (n= 48). The mean difference between the change-scores of both groups was 3.9 (95%CI 0.5 to 7.2). This difference was not clinically relevant.

2.4.1 Use of acute medication (prophylactic treatment)

In the RCT of Gaul (2016), mean differences between baseline abortive medication use (either subcutaneous sumatriptan or inhaled oxygen) and abortive medication use during the randomized phase were reported. The mean times abortive medication was used was 24.5 at baseline and 9.3 in the last two weeks of the intervention phase in the NVS group (n=32), and 19.4 at baseline and 18.3 in the intervention phase for the control group. According to original analyses, the change-score in the NVS group was -15 (SD 26) and in the control group -2 (SD 28.5). Standard deviations of the change-scores were calculated from 95%CIs for the purpose of this guideline. The mean difference between the change-scores of both groups was -13.00 (95%CI -25.47 to -0.53), favouring nNVS. This effect was clinically relevant.

2.4.2 Use of acute medication (acute treatment)

In the RCT of Silberstein (2016), use of acute medication was measured by whether a participant used rescue medication in the first hour after treatment of their first attack. The proportion of participants using acute medication was 23/60 (38.3%) in the nNVS group and 37/73 (50.7%) in the control group. The risk ratio was 0.76 (95%CI 0.51 to 1.12). This effect was not clinically relevant.

Goadsby (2019) did not include this outcome measure.

2.5 Severity of the attack

The outcome severity of the attack was not reported in the included studies on NVS.

2.6 50% responder rate (prophylactic treatment)

Silberstein (2016) and Goadsby (2018) studied NVS als acute treatment, and were not eligible for this outcome measure.

In the RCT of Gaul (2016), 50% responder rate was defined as the proportion of participants with an experienced 50% reduction in mean number of attacks. At baseline, the mean attack frequency was the mean frequency in the four weeks prior enrolment. The number of 50% responders was assessed in the last two weeks of the randomization phase. At follow-up, the number of 50% responders in the NVS group was 18 out of 45 (40%), and in the control group 4 out of 48 (8,3%). This translates to an RR of 4.8 (95%CI 1.76; 13.10), favouring NVS. This effect was clinically relevant.

2.7 30% responder rate (prophylactic treatment)

The outcome 30% responder rate was not reported in the included studies on NVS.

2.8 Quality of life (prophylactic treatment)

In the RCT of Gaul (2016), quality of life was measured with three different questionnaires: The EQ-5D-3L Index score, the EQ-5D-3L VAS score and the HIT-6 score. All scores were used at the end of the baseline phase. The follow-up score was assessed at the end of the experimental phase. For the EQ-5D-3L Index score, the mean change from baseline in the nVNS group (n=35) was 0.145, and -0.049 in the control group (n=46). For the EQ-5D-3L VAS score, the mean change from baseline in the nVNS group (n=35) was 9.20, and 0.27 in the control group (n=45). For the HIT-6 score, the mean change from baseline in the nNVS group (n=37) was -2.78, and -0.47 in the control group (n=45). The mean difference between change scores for the EQ-5D-3L index score was 0.194 (95%CI 0.054 to 0.334), favouring nVNS. The mean difference between change scores for the EQ-5D-3L VAS score was 8.93 (95%CI 0.47 to 17.39), favouring nVNS. Both change scores were clinically relevant. The mean difference between change scores for the HIT-6 score was not reported. Data for the HIT-6 score could not be used for GRADE evaluation and conclusions.

No other studies on nNVS reported on quality of life.

2.9 Patient satisfaction

In the RCT of Silberstein (2016), patient satisfaction was measured on the participants willingness to recommend the device to friends or family-members on a scale from 1-5. 38.3% of the NVS group was satisfied, very satisfied or extremely satisfied with treatment. For the control-group, 31.9% of the participants shared this opinion. This was not a validated scale, so these data could not be used for GRADE evaluation and conclusions.

No other studies on nNVS reported on patient satisfaction.

2.10.1 (Device related) adverse events (prophylactic treatment)

In the RCT of Gaul (2016), adverse events (both device-related and not device-related) were measured at the end of the randomized phase. During the randomized phase, 18 out of 48 (37.5%) participants in the NVS group experienced adverse events, compared to 13 out of 49 (26.5) participants in the control group. This resulted in a risk ratio of 1.41 (95%CI 0.78 to 2.56), favouring the control group. This difference was clinically relevant.

Device related adverse events were seen in 11 out of 48 (22.9%) participants in the intervention group (15 events). Of these device-related adverse events, 13 were mild-moderate, 2 were considered serious. No device related adverse events in the control group (n=49) were reported at the end of the follow-up. This resulted in a risk ratio of 23.47 (95%CI 1.42 to 387.45), favouring the control group. This difference was clinically relevant.

2.10.2 (Device related) adverse events (acute treatment)

Regarding NVS as acute treatment, two studies reported on adverse events (Goadsby, 2018; Silberstein, 2016).

In the RCT of Goadsby (2018), adverse events (both device-related and not device-related) were measured at two time points. At the end of the follow-up, in the intervention group, 20 out of 50 (40%) persons reported at least one adverse event, and 14 out of 52 (26.9%) in the control group. This resulted in a risk ratio of 1.49 (95%CI 0.85 to 2.61), favouring the control group. This difference was clinically relevant.

Adverse events were device related in 9 out of 50 (18%) participants in the intervention group. In the control group, the events were device related in 10 out of 52 (19.2%) participants. This resulted in a risk ratio of 0.94 (95%CI 0.42 to 2.11). This difference was not clinically relevant.

In the RCT by Silberstein (2016), adverse events at the end of the follow-up (both device-related and not device-related) were reported in 18 out of 73 participants (24.7%) in the intervention group (one patient with serious adverse events), and in 31 out of 77 (40.3%) participants in the sham group. This resulted in a risk ratio of 0.61 (95%CI 0.38 to 0.99), favouring the nVNS group. This difference was clinically relevant.

Device related adverse events were reported in 11 out of 73 (15.1%) participants in the nNVS group, and in 24 out of 73 (32.9%) participants in the sham group. This resulted in a risk ratio of 0.46 (95%CI 0.24 to 0.87), favouring the control group. This difference was clinically relevant.
2. NVS: Level of evidence of the literature

2.1 Pain free after 15 minutes (critical)

The level of evidence regarding the outcome measure pain free in 15 minutes started as high and was downgraded by three levels to very low because of unblinded trainers providing devices and unknown blinding of outcome-assessors and analysts (Goadsby, 2018) (-1 risk of bias) and a small number of included patients and the confidence interval included both clinically relevant harm and benefit (-2 imprecision).

2.2 Pain reduction after 15 minutes (critical)

The level of evidence regarding the outcome measure pain reduction in 15 minutes started as high and was downgraded by three levels to very low because of imbalanced dropout in Silberstein (2016) with improper imputation and complete case analysis in Goadsby (2018) with imbalanced missings (-2 risk of bias) and a small number of included patients and the confidence intervals included no effect (-1 imprecision).

2.3 Attack frequency (critical)

The level of evidence regarding the outcome measure attack frequency started as high and was downgraded by three levels to very low because of using a modified intention to treat population and much influence by sponsor (Gaul, 2016) (-2 risk of bias), and no clinically relevant effect (-1 imprecision).

2.4.1 Use of acute medication (prophylactic treatment)

The level of evidence regarding the outcome measure use of acute medication started as high and was downgraded by three levels to very low because using a modified intention to treat population and much influence by sponsor (Gaul, 2016) (-2 risk of bias) and a small number of included patients, and confidence intervals include no effect (-1 imprecision).

2.4.2 Use of acute medication (acute treatment)

The level of evidence regarding the outcome measure use of acute medication started as high and was downgraded by three levels to very low because improper imputation by Silberstein (-1 risk of bias) and a small number of included patients, and confidence intervals include no effect (-2 imprecision).

2.5 Severity of the attack

The level of evidence regarding the outcome measure severity of the attack was not assessed for treatment with NVS.

2.6 50% responder rate

The level of evidence regarding the outcome measure 50% responder rate started as high and was downgraded by two levels to low because of using a modified intention to treat population and much influence by sponsor (Gaul, 2016) (-2 risk of bias).

2.7 30% responder rate

The level of evidence regarding the outcome measure 30% responder rate was not assessed for treatment with NVS.

2.8 Quality of life

The level of evidence regarding the outcome measure quality of life started as high and was downgraded by three levels to very low because of using a modified intention to treat population and much influence by sponsor (Gaul, 2016) (-2 risk of bias) and a small number of included patients and one confidence interval included no effect (-1 imprecision).

2.9 Patient satisfaction

The level of evidence regarding the outcome measure patient satisfaction was not assessed for treatment with NVS.

2.10.1 (device related) adverse events (prophylactic treatment)

The level of evidence regarding the outcome measure (device related) adverse events started as high and was downgraded by three levels to very low because much influence by sponsor (Gaul, 2016) (-1 risk of bias), and confidence interval includes both harm and benefit (-2 imprecision).

2.10.2 (Device related) adverse events (acute treatment)

The level of evidence regarding the outcome measure (device related) adverse events started as high and was downgraded by three levels to very low because confidence intervals including both harm and benefit (-2 imprecision), and conflicting results (-1 inconsistency).

2. NVS: Conclusions

2.1 Pain free after 15 minutes

2.2 Pain reduction after 15 minutes

2.3 Attack frequency per week

2.4 Use of acute medication (acute/prophylactic)

2.6 50% responder rate

2.8 Quality of life

2.10.1 (device related) adverse events (prophylactic treatment); 2.10.2 (Device related) adverse events (acute treatment)

2.5 Severity of the attack, 2.7 30% responder rate, 2.9 Patient satisfaction

3. 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.

3. 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.

3. SPG: Conclusions

3.1 Pain free after 15 minutes (SPG)

3.2 Pain reduction after 15 minutes (SPG)

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

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.

1. Occipital nerve stimulation (ONS)

Regarding treatment with ONS, one RCT was found (Wilbrink, 2021). In this RCT, 131 participants with medically resistant chronic cluster headache (international classification of headache disorders; ICHD-3) were randomly assigned to the intervention-group (100% ONS, n=65, mean age ± SD: 44 ± 13, 57% male) or the control-group (30% ONS, n=66, mean age ± SD: 44 ± 13, 71% male). The intervention-group received 100% occipital nerve stimulation (ONS) as prophylactic treatment and the control-group received 30% ONS. The use of acute medication or other preventive medication was allowed in both treatment groups. After a baseline phase of 12 weeks in which baseline variables were collected, patients were randomized and devices were implanted. During the intervention phase of 24 weeks, participants received the treatment as allocated.

Relevant outcome measures include mean attack frequency per week (weeks 1-4 compared to weeks 21-24), severity of the attack (scale 0-10 with 10 the worst pain possible), responder rate (both 50% and 30%), use of acute medication, quality of life and (device related) adverse events. The follow-up was 24 weeks.

2. Vagus nerve stimulation (NVS)

Three studies reported data on VNS (Gaul, 2016; Goadsby, 2018; Silberstein, 2016). In one RCT (Gaul, 2016), 97 participants with chronic cluster headache (ICHD-3) were randomly assigned to either non-invasive VNS (nVNS) as (adjunctive) prophylactic treatment with usual care (n=48, mean age ± SD: 45.4 ± 11.0, 71% male) or usual care alone (n=49, mean age ± SD: 42.3 ± 11.00, 67% male). After a baseline phase of two weeks in which all participants received standard of care, participants received treatment as allocated for four weeks. Relevant outcome measures include attack frequency, use of acute medication, 50% responder rate and quality of life. The follow-up was four weeks. The funder of the study (ElectroCore) provided support with data analysis and writing, and two authors are employed at the funder. For acute medication use and quality of life, follow-up data were presented only for participants who completed the open-label phase (= modified intention to treat population).

In the RCT by Silberstein (2016), 150 participants were randomly assigned to either nVNS for acute treatment of attacks (n=73, mean age ± SD: 47.1 ± 13.5, 59% male, episodic/chronic: 50/23) or sham treatment (n=77, mean age ± SD 48.6 ± 11.7, 67% male, episodic/chronic: 51/26). Relevant outcome measures include pain reduction in 15 minutes, use of acute medication, average pain intensity (at 15 minutes after treatment), and patient satisfaction. The follow-up was four weeks.

In the RCT by Goadsby (2018), 102 participants were randomly assigned to either nNVS for the acute treatment of attacks (n=50, mean age ± SD: 43.9 ± 10.6, 70% male, episodic/chronic 15/35) or sham treatment (n=52, mean age ± SD: 46.9 ± 10.6, 73.1% male, episodic/chronic 15/37) as addition to their usual care. After a baseline phase of one week, the two-week experimental phase started. Relevant outcome measures include freedom of pain in 15 minutes, pain intensity at 15 minutes. The follow-up was two weeks.

3. Stimulation of the sphenopalatine ganglion (SPG)

Two studies were found (Goadsby, 2019; Schoenen, 2013). In Schoenen (2013) 28 participants with chronic cluster headache (ICHD-2) were randomized between full stimulation of the SPG, sub-perception stimulation or sham as the acute treatment for every new attack (n=566). Mean age was 45 years (range 20-63) and 85% of the participants were male. Since all participants received multiple interventions, the baseline characteristics were not reported per group. Baseline values were retrospectively collected, for four weeks pre-implant. A stabilization phase of minimal three weeks followed implantation. After this phase, stimulation parameters and electrodes were further adjusted over a period of six weeks (therapy titration phase) before start of the experimental phase. Three weeks after initiation of the experimental phase or after the 30th attack, the experimental period ended. Relevant outcome measures include pain reduction in 15 minutes and freedom from pain in 15 minutes. The follow-up was up to three weeks. 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.

In the RCT by Goadsby (2019), 93 participants with chronic cluster headache (ICHD-3) were randomly assigned to either SPG for the acute treatment of attacks (n=45, mean age ± SD: 48 ± 11, 73% male), or sham stimulation (n=48, mean age ± SD: 48 ± 11, 73% male). All randomized participants underwent implantation of the device. After a baseline phase of at least 4 weeks, a stabilization phase of 12 weeks followed implantation. The 4-week experimental phase started afterwards. Relevant outcome measures include pain reduction and freedom from pain after 15 minutes. The follow-up was four weeks. The trial was funded by the manufacturer, which had roles in design, collecting, analysing and interpretation of data, and writing.

1. ONS: Results

1.1 and 1.2 Pain free after 15 minutes and pain reduction after 15 minutes

Wilbrink (2021) studied ONS as prophylactic treatment and was not eligible for these outcome measures.

1.3 Attack frequency (critical)

Wilbrink (2021) measured attack frequency every four weeks. Baseline data were skewed, thus medians and interquartile ranges (IQR’s) were provided. Median attack frequency in the 100% ONS group (n=65) was 17.58 (IQR 9.83 to 29.33) at baseline and 9.50 (IQR 3.00 to 21.25) in week 21-24. Median attack frequency in the 30% ONS group (n=65) was 15.00 (IQR 9.25 to 22.33) at baseline and 6.75 (IQR 1.50 to 16.50) in week 21-24. A linear regression analysis was performed using the logarithms of the mean attack frequency as dependent variable, the logarithm of baseline mean attack frequency as covariate and treatment as fixed variable. The difference between change scores was -2.42 (95%CI -5.17 to 3.33). This between-group difference was not clinically relevant.

1.4 Use of acute medication

Wilbrink (2021) did not report this outcome.

1.5 Severity of the attack

Wilbrink (2021) measured severity of the attack on a scale from 0-10, with 10 indicating the worst pain. The baseline Mean Attack Intensity (5.96, 95%CI 5.54 to 6.38) was the mean of the first four weeks for the complete population (n= 130). At week 21-24, the Mean Attack Intensity change-score in the 100% ONS group (n=65) was -1.85 (SD 2.51). Mean attack intensity change-score in the 30% ONS group (n=65) was -2.18 (SD 3.45). Standard deviations of the change-scores were calculated from 95%CIs for the purpose of this guideline. The mean difference between the change-scores of both groups was 0.33 (95%CI -0.71 to 1.37). This between-group difference was not clinically relevant.

1.6 50% responder rate

Wilbrink (2021) defined the 50% responder rate as participants with an experienced reduction in Mean Attack Frequency of 50% or more. At week 21-24, the percentage 50% responders in both groups was estimated 44.6% (n=29, 95%CI 36.3 to 53.2). This resulted in a risk ratio of 1 (95%CI 0.68 to 1.47), the difference between the groups was not clinically relevant.

1.7 30% responder rate

In the RCT of Wilbrink (2021), 30% responder rates were defined as participants with an experienced reduction in Mean Attack Frequency of 30% or more. This outcome was analysed post-hoc. At week 21-24, the percentage 30% responders in the 100% ONS group was estimated 53.8% (95%CI 41.9 to 65.4). This percentage translates to 35 participants. The percentage of 30% responders in the 30% ONS group was estimated 56.9% (44.8 to 68.2). This percentage translates to 37 participants. The risk ratio was 0.95 (95%CI 0.69 to 1.29), this difference was not clinically relevant.

1.8 Quality of life

Wilbrink (2021) measured quality of life using the mean physical health summary score, and the mean mental health summary score from the SF-36. Scores for this outcome were assessed from figure 1A and 1B, in the supplemental material of Wilbrink (2021). At week 21-24, mean physical health summary score in the 100% ONS group (n=65) was 56 (95%CI 49 to 63, SD 28.25). Mean physical health summary score in the 30% ONS group (n=65) was 61 (95%CI 56 to 66, SD 20.18). The mean difference between the groups was -5.00 (95%CI -13.44 to 3.44). This difference was not clinically relevant.

At week 21-24, mean mental health summary score in the 100% ONS group was 58 (95%CI 52 to 64, SD =4.21). Mean mental health summary score in the 30% ONS group was 57 (95%CI 51.5 to 62.5, SD 22.20). The mean difference between the groups was 1.00 (95%CI -6.99 to 8.99). This difference was not clinically relevant.

1.9 Patient satisfaction

Wilbrink (2021) did not report on this outcome using a validated scale.

1.10 Adverse events

In the RCT by Wilbrink (2021), both non-serious and serious adverse events were reported.

In the 100% ONS group (n=65), 48 participants reported one or more non-serious adverse events, and 15 participants reported one or more serious adverse events. In the 30% ONS group (n=65), 43 participants reported one or more non-serious adverse events, and 7 participants reported one or more adverse events. The RR for non-serious adverse events was 1.12 (95%CI 0.89 to 1.40). The RR for serious adverse events was 2.14 (95%CI 0.94 to 4.91).

1.11 Device related adverse events

In the RCT of Wilbrink (2021), in the 100% ONS group (n=65), 8 participants reported one or more hardware related adverse events. In the 30% ONS group (n=65), 4 participants reported one or more hardware related adverse events. The RR for hardware related adverse events was 2.00 (95%CI 0.63 to 6.32). This ratio was clinically relevant.

1. ONS: Level of evidence of the literature

1.1 and 1.2 Pain free after 15 minutes and pain reduction after 15 minutes

Wilbrink (2021) studied ONS als profylactic treatment, and was not eligible for these outcome measures.

1.3 Attack frequency

The level of evidence regarding the outcome measure attack frequency started as high as it was based on a RCT and was downgraded by two levels to low because of a small number of included patients and the confidence interval included beneficial effect for 100% stimulation and 30% stimulation. (-2 imprecision).

1.4 Use of acute medication

The level of evidence regarding the outcome measure use of acute medication was not assessed for treatment with ONS.

1.5 Severity of the attack

The level of evidence regarding the outcome measure severity of the attack started as high and was downgraded by one level to moderate because of a small number of included patients (-1 imprecision).

1.6 50% responder rate

The level of evidence regarding the outcome measure 50% responder rate started as high and was downgraded by two levels to low because of a small number of included patients and the confidence interval included both clinically relevant harm and benefit (-2 imprecision).

1.7 30% responder rate

The level of evidence regarding the outcome measure 30% responder rate started as high and was downgraded by one level to moderate because of a small number of included patients and the confidence interval included clinically relevant harm (-1 imprecision).

1.8 Quality of life

The level of evidence regarding the outcome measure quality of life (physical health summary score) started as high and was downgraded by two levels to low because of a small number of included patients and both confidence intervals crossed borders of clinical relevance (-2 imprecision).

The level of evidence regarding the outcome measure quality of life (mental health summary score) started as high and was downgraded by one level to moderate because of a small number of included patients (-1 imprecision).

1.9 Patient satisfaction

The level of evidence regarding the outcome measure patient satisfaction could not be assessed for treatment with ONS due to lack of data.

1.10 Adverse events

The level of evidence regarding the outcome measure adverse events started as high and was downgraded by two levels to low because of a small number of included patients and the confidence interval included both clinically relevant harm and benefit (-2 imprecision).

1.11 Device related adverse events

The level of evidence regarding the outcome measure device related adverse events started as high and was downgraded by two levels to low because of a small number of included patients and events, and the confidence interval included both clinically relevant and benefit (-2 imprecision).

A systematic review of the literature was performed to answer the following questions:

1. What is the effect of neuromodulation with ONS compared to standard care, different intensity of neuromodulation, or placebo/sham in the treatment of patients with chronic cluster headache?

2. What is the effect of neuromodulation with NVS compared to standard care, different intensity of neuromodulation, or placebo/sham in the treatment of patients with chronic cluster headache?

3. 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:

  1. ONS for prophylactic treatment; or

  2. NVS for acute or prophylactic treatment; or

  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.