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Clinical utility, safety, and efficacy of pregabalin in the treatment of fibromyalgia

Authors Bhusal S, Diomampo S, Magrey M

Received 1 September 2015

Accepted for publication 18 December 2015

Published 17 February 2016 Volume 2016:8 Pages 13—23

DOI https://doi.org/10.2147/DHPS.S95535

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 2

Editor who approved publication: Professor Chul Ahn



Santosh Bhusal,1 Sherilyn Diomampo,1 Marina N Magrey2

1Division of Rheumatology, Metrohealth Medical Center, 2Case Western Reserve University School of Medicine at Metrohealth Medical Center, Cleveland OH, USA

Abstract: Fibromyalgia is a chronic debilitating medical syndrome with limited therapeutic options. Pregabalin, an anticonvulsant and α-2-Δ subunit receptor ligand, is one of the anchor drugs approved by the US Food and Drug Administration for the treatment of fibromyalgia. The drug has shown clinically meaningful benefits across multiple symptom domains of fibromyalgia. Efficacy of pregabalin in fibromyalgia pain has been evaluated in at least five high-quality randomized trials, two long-term extension studies, a meta-analysis, a Cochrane database systematic review, and several post hoc analyses. These studies also hint towards a meaningful benefit on sleep, functioning, quality of life, and work productivity. Side effects of pregabalin, although common, are mild to moderate in intensity. They are noted early during therapy, improve or disappear with dose reduction, and are not usually life- or organ threatening. In most patients, tolerance develops to the most common side effects, dizziness, and somnolence, with time. With close clinical monitoring at initiation or dose titration, pregabalin can be effectively used in primary care setting. Pregabalin is cost saving with long-term use and its cost-effectiveness profile is comparable, if not better, to that of other drugs used in fibromyalgia. In the present era of limited therapeutic options, pregabalin undoubtedly retains its role as one of cardinal drugs used in the treatment of fibromyalgia. This review intends to discuss the clinical utility of pregabalin in the management of fibromyalgia with a focus on efficacy, safety, and cost-effectiveness.

Keywords: fibrositis, myofascial pain, diffuse pain syndrome, lyrica

Introduction

Fibromyalgia is a clinical syndrome characterized by chronic widespread pain (pain in all body quadrants – right and left side, above and below waist, as well as axial skeleton) associated with several other symptoms such as fatigue, waking unrefreshed, and cognitive complaints. Using the American College of Rheumatology (ACR) 1990 criteria, its prevalence is estimated to be 0.5%–4%1 with ~9:1 female-to-male ratio. It is the third most common rheumatologic condition after low back pain and osteoarthritis2 and the most common reason for work-related disability leave in the developed world.3

The etiology and pathogenesis of fibromyalgia is uncertain. Genetic studies suggest an association with polymorphisms in serotonergic, dopaminergic, and catecholaminergic pathways involved in pain transmission and modulation.4 The disease is likely expressed in the presence of environmental trigger/triggers (eg, emotional trauma, acute illness, physical injury),5 which lead to expression of multiple genes that amplify pain perception in the pain processing pathway. Although a pain disorder by etymology, fibromyalgia is heterogeneous and may have several subgroups; these subgroups differ clinically and in response to drug therapy.6,7 Turk et al7 showed that patients with fibromyalgia could be classified into three subgroups based on multidimensional pain inventory self-reports: dysfunctional, interpersonally distressed, and adaptive copers. Similarly, Giesecke et al6 also purposed three subgroups based on predominant symptoms from one of the following domains: psychosocial (depression/anxiety), cognitive (catastrophizing/control over pain), and neurobiologic (tenderness). The heterogeneity of symptoms in pain syndromes including fibromyalgia could perhaps be better explained by the pain neuromatrix theory,8 which proposes the neurosignature of pain experience as one of the “action outputs” of brain from the so-called neuromatrix rather than a “passive response” to nociception (the traditional Cartesian view). Accordingly, the “action outputs” consist of pain perception with its sensory, affective, and cognitive domains in addition to voluntary as well involuntary action programs and stress regulation responses. In this context, an updated 2010 ACR preliminary diagnostic criteria for fibromyalgia which incorporates fatigue, waking unrefreshed, and cognitive symptoms in addition to pain and other somatic symptoms allow further cognizance of the multiple domains of this disease.

Burden of fibromyalgia

Fibromyalgia carries a global burden in patient’s health – at individual, interpersonal, occupational, and socioeconomic levels. At an individual level, pervasive effects in all domains of health-related quality of life (HRQoL) measures are noted. In short form (SF) 36 questionnaires, patients with fibromyalgia have significant deficits in all eight components of physical and mental health compared to controls,9 whereas greater deficits in the scales measuring mental health (mental health, role limitations due to emotional health, social functioning, and vitality) over functional disability (physical functioning and role limitations due to physical function)9 are noted compared to rheumatoid arthritis patients. In interpersonal relationships, these patients receive less support from their partners compared to osteoarthritis patients and have higher caregiver burden at times of higher functional disability.10 Phenomenologically, fibromyalgia pain means living with chronic pain as well as pain during exacerbations with a simultaneous feeling that they are doubted because of the invisible nature of pain.11

At work, employees with fibromyalgia have a higher percentage of both work time missed (absenteeism) and on-the-job impairment (presenteeism) compared to patients with arthritis pain or back pain; they are two to three times more likely to miss work compared to normal controls.12,13 On average, they miss 15% of workdays (29.8 days in a year), which is higher than osteoarthritis patients (25.7 days; P<0.0001).13 Furthermore, those with a high load of fibromyalgia symptoms are more likely to retire earlier than their asymptomatic twin counterparts (cumulative incidence: 25.7% vs 6.8%, respectively).14 Receipt of social security disability in patients fulfilling the ACR 2010 criteria for fibromyalgia is comparable to patients with osteoarthritis and rheumatoid arthritis (42% vs 42.4% vs 54.6%, respectively).15

At a socioeconomic level, fibromyalgia is costly. Mean annual direct costs to the payers and patients amount to US$7,973 (standard deviation [SD] US$7,341) per subject in the USA, US$2,234 (SD US$2,261) in Germany, and US$924 (SD US$862) in France; the primary drivers of costs are prescription medications, physician office visits (~10/year), and out of pocket expenses.16 Indirect costs due to lost productivity, absenteeism, and disability are much higher and approximates about two-third to three-fourth of total costs. For example, mean annual indirect costs were US$10,697 in the USA, US$7,898 in Germany, and US$9,819 in France.13,16 Not surprisingly, the costs increase with increasing severity of disease.13

Fibromyalgia and sleep

Sleep difficulties are pervasive in fibromyalgia. In all, 88% report sleep difficulty in one of the following domains: difficulty falling asleep, difficulty staying asleep, or waking too early; 63.05% report difficulty in two or more domains.17 Blocks of 2–3 hours of sleep followed by wakefulness in a “hyperarousal” mode (feeling very alert on awakening with difficulty going back to sleep for the next several hours) is the most common pattern.18 The experience of pain is in a bidirectional relationship with sleep disturbance – more sleep disturbance is associated with more pain and vice versa19 and is affirmed by an association of slow-wave sleep disruption with decreased pain threshold, increased fatigue, and increased discomfort in healthy volunteers.20 A path analysis model has demonstrated specific causal sequence involving sleep, pain, functional disability, and depression where baseline sleep predicted 1-year pain, baseline pain predicted 1-year physical functioning, and baseline physical functioning predicted 1-year depression.21 Sleep disturbance, in addition, has an independent effect on HRQoL and disability, beyond any effect contributed by pain experience alone.22

Objective studies of sleep disturbance in fibromyalgia have yielded variable results. The original study of patients in “fibrositis” syndrome23 reported polysomnographic abnormalities that consist of delta waves periodically intruded by alpha waves (delta waves indicate restorative non-rapid eye movement (REM) sleep and alpha waves indicate drowsy wakefulness). Several other abnormalities have been reported since then which include disruption of sleep continuity from frequent arousals, reduced stage 2 sleep spindles, a shorter duration of stage 2 sleep, and high frequency of cyclical alternating pattern.24 Further studies are needed to discern the interrelationship between the abnormal sleep patterns and ascertain how they relate to pain, fatigue, and cognitive abnormalities in fibromyalgia.

Current therapy of fibromyalgia

Heterogeneity of symptoms in fibromyalgia deserves individualized treatment. Components of therapy include patient education, physical therapy, psychotherapy, and pharmacotherapy. Identifying potential subtypes based on predominant symptoms and customizing therapy may improve outcomes.25 Three medications are approved by the US Food and Drug Administration (FDA) for fibromyalgia – pregabalin, duloxetine, and milnacipran. A multimodal approach using one of the FDA-approved medications as an “anchor” drug, like methotrexate in rheumatoid arthritis, and subsequent tailoring of treatment with a “fatigue, insomnia, blues (depression), rigidity (stiffness), and Ow! (pain) (FIBRO)” model based on predominant symptom has been suggested.26 The ideal treatment strategy could be a combination of treatments, often in lower doses than used in clinical trials with medications such as modafenil (for fatigue), cyclobenazepril (for stiffness), zolpidem (for insomnia), and tramadol (for pain) added sequentially with a close monitoring for adherence and adverse events.27

Pregabalin: mechanism of action and pharmacokinetics

Pregabalin is a gamma-aminobutyric acid (GABA) analog. Although a structural analog, its mechanism of action does not directly relate to interaction with GABA receptor or significant alteration of GABA concentration in brain.28,29 Two different, and possibly interdependent, pathways of action are possible: presynaptic voltage-gated calcium channel-dependent action and direct postsynaptic NMDA receptor activation. In the former, pregabalin binds with presynaptic α-2-Δ subunit delta type 1 subunit of voltage-gated calcium channel and modifies the allosteric interaction between the calcium channel and presynaptic vesicle proteins (eg, syntaxin) reducing the ability of docked vesicles to fuse and release neurotransmitters.30 In regard to the latter, it was noted that postsynaptic NMDA receptor antagonists block pregabalin-mediated changes in vesicle release.30 Postsynaptic NMDA receptors may alter presynaptic transport of vesicles containing neurotransmitters using a nitric oxide pathway in which the newly synthesized nitric oxide (in response to postsynaptic NMDA receptor activation) diffuses to presynaptic membrane and alters vesicle trafficking.30 The final effect is a reduction of tonic release of several neurotransmitters, both excitatory and inhibitory, including GABA, which alters neuronal responsiveness leading to reduction of hyper-excitability in pain processing pathway.31

Pregabalin is rapidly absorbed after oral administration with a mean oral bioavailability of 90%.32 Time to reach maximum plasma concentration is 0.7–1.3 hours and the elimination half-life is 4.6–6.6 hours. It is excreted unchanged in urine.32 A controlled release preparation of pregabalin (330 mg) once a day retains major pharmacokinetic profiles of 300 mg pregabalin in terms of bioavailability and elimination half-life,33 which may potentially improve drug adherence.

Clinical utility of pregabalin

Clinical utility is a judgment about usefulness, benefits, and drawbacks of an intervention. A model for clinical utility34 has been postulated to consist of the following: appropriateness (is the intervention relevant? is it effective? is it safe?); accessibility (what are the costs and cost-effectiveness?); acceptability (is it acceptable to clinicians, patients, and public?); and practicability (does it do what we need it to do in actual everyday situations? are practitioners skilled and capable enough for its use or do they need further training?). These aspects will be discussed with a focus on efficacy, safety, and cost-effectiveness across various symptom domains (Table 1).

Table 1 MCID in various measures in fibromyalgia: comparison of pregabalin therapy with placebo in randomized trials*
Notes: *Variables meeting MCID thresholds with P-values <0.05 compared to placebo are listed with respective P-values. All P-values less than 0.01 listed as <0.01. **For pain, >30% response is considered MCID.
Abbreviations: FIQ, fibromyalgia impact questionnaire; MCID, minimally clinical important difference; MOSS, medical outcome sleep study; PBO, placebo; SF-36, short form 36; N/A, not applicable.

Efficacy of pregabalin therapy: evidence from randomized trials

The relevance of pregabalin therapy in fibromyalgia treatment cannot be overstated. It was the first medicine approved by the FDA for fibromyalgia treatment in 2007. Since then, only two other medications, duloxetine and milnacipran, have been approved. The usefulness of pregabalin as an “anchor drug”, discussed earlier, is relevant not only for its benefit in pain, but also for its benefits in sleep and HRQoL.

Efficacy in treatment of pain

Several randomized trials and two meta-analyses have demonstrated the efficacy of pregabalin in treatment of pain in fibromyalgia. Most trials3537 involved a sample of: >90% white females who meet the ACR 1990 criteria for fibromyalgia; average age of 49–50 years; and median pain score of 6.7–7.1/10. In this context, a multicenter double-blind trial35 with 529 participants randomized to take 150, 300, and 450 mg of pregabalin or placebo for 8 weeks demonstrated that patients taking pregabalin 450 mg had significant improvement in pain as evidenced by: 1) reduction of endpoint mean pain scores at all weeks from 1 to 7 (baseline mean pain score 6.9 for placebo and 7 for pregabalin 450 mg/day; least square mean pain score at week 8: 5.88 for placebo and 4.94 for pregabalin 450 mg/day; mean change: –1.02 for placebo and –1.96 for pregabalin 450 mg/day [P=0.0009]) and 2) reports of more than 50% improvement of pain from baseline (28.9% pregabalin vs 13.2% placebo; P=0.003). However, there was no significant difference in the endpoint mean pain scores and the proportion of patients achieving >30% reduction of pain in patients taking 300 and 150 mg of pregabalin compared to placebo. Another randomized, double-blind control trial36 involving 745 patients which used a higher dose of pregabalin (300, 450, and 600 mg) for a period of 14 weeks revealed a statistically significant reduction of endpoint mean pain scores in all treatment groups compared to placebo (baseline pain scores: 6.6, 6.7, 6.6, and 6.7 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; least square mean pain scores at week 14: 5.64, 4.93, 4.66, and 4.64 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; mean change –1.04 for placebo, −1.75 for pregabalin 300 mg/day [P=0.009], –2.03 for pregabalin 450 mg/day [P<0.001], and −2.05 for pregabalin 600 mg/day [P<0.001]). The proportion of patients achieving >50% reduction of pain from baseline was also significantly higher in all treatment groups (15% for placebo, 24% for 300 mg/day, 27% for 450 mg/day, and 30% in 600 mg/day [P=0.0372, P=0.038, and P=0.010, respectively]) as was the proportion of patients achieving >30% improvement (30% for placebo, 42% for 300 mg/day, 50% for 450 mg/day, and 48% for 600 mg/day [P=0.0172, P=0.002, and P=0.006, respectively]). A very similar study37 of 748 patients randomized to take similar dosages of pregabalin (300, 450, and 600 mg) or placebo for 13 weeks revealed statistically significant improvement in endpoint mean pain scores for all the dosages compared with placebo (baseline mean pain scores: 7.2, 7.1, 7.1, and 7 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; mean pain scores at week 13: 5.7, 5.26, 5.23, and 5.04 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; mean change −1.4 for placebo, −1.84 for pregabalin 300 mg/day [P=0.0449], −1.87 for pregabalin 450 mg/day [P=0.0449], and −2.06 for pregabalin 600 mg/day [P=0.007]). In this study, however, statistical significance was not reached between the pregabalin-treated patients and placebo in terms of the proportion of patients achieving >30% reduction in pain. Nevertheless, there was a trend toward higher proportion of patients achieving >30% reduction in pain with pregabalin therapy (43%, 43%, and 44% among patients receiving 300, 450, and 600 mg/day of pregabalin, respectively) compared to placebo (35%).

An international, randomized, double-blinded trial38 evaluated the efficacy of pregabalin in 747 patients, randomly assigned to receive 300, 450, and 600 mg/day of pregabalin or placebo (a total of 73 centers across Europe, Canada, Asia, and Australia). The patient population was more diverse but still representative of general population with fibromyalgia (51% from European countries, 49% non-European; meeting the ACR 1990 criteria, 91% females, 76% white, mean age 48.5 years, mean duration of fibromyalgia 8.2 years, and baseline mean pain score of 6.65/10). Statistically significant reduction on endpoint mean pain scores were noted only in the patients taking pregabalin 450 mg/day (baseline mean pain scores: 6.68, 6.76, 6.59, and 6.65 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; mean pain scores at week 14: 5.92, 5.59, 5.36, and 5.69 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; mean change: −0.73 for placebo and −1.29 for pregabalin 450 mg/day [P=0.0132]) when last observation carried forward method was used. However, with duration adjusted average change sensitivity analysis, all three dosages showed significant reduction of the endpoint mean pain scores (mean difference with placebo: −0.47 for pregabalin 300 mg/day [P=0.0024]; −0.61 for pregabalin 450 mg/day [P<0.0001]; and −0.47 for pregabalin 600 mg/day [P=0.0023]). Patients achieving >30% reduction with 300, 450, and 600 mg/day of pregabalin were 33%, 34%, and 26%, respectively, as compared to 19% for placebo; those achieving >50% reduction of pain with 300, 450, and 600 mg of pregabalin were 18%, 18%, and 15%, respectively, as compared to 9% for placebo. With pregabalin 300 and 450 mg/day and placebo, the difference was statistically significant (P<0.05) for both >30% and >50% responders but with 600 mg/day, it was not. Similarly, a randomized double-blind trial involving 498 Japanese patients39 (meeting the ACR criteria, 89% females, mean age 47 years, mean disease duration 6.5 years, mean pain scores 6.5) using 300 or 450 mg/day of pregabalin revealed a statistically significant improvement of endpoint mean pain scores at 15 weeks of treatment (baseline pain score 6.4 and 6.5 for placebo and pregabalin groups, respectively; mean pain scores at week 15: 5.45 and 5.01 for placebo and pregabalin, respectively; mean change: −1.03 for placebo and −1.48 for pregabalin, P=0.0046). Similar to most prior studies, patients achieving >50% and >30% improvement in pain were significantly higher in pregabalin group compared to placebo (50% responders: 22.8% and 12.1% in pregabalin and placebo, respectively, P=0.0017; 30% responders: 40.4% and 30.6% in pregabalin and placebo, respectively, P=0.0230). The latter study also had a 53-week open-label extension phase to address the long-term efficacy and safety, which will be discussed later.

The fibromyalgia relapse evaluation and efficacy for durability of meaningful relief (FREEDOM) trial40 enriched for responders with placebo-controlled discontinuation evaluated the durability of response in pregabalin-treated patients. An initial 6-week open-label treatment (n=1,051) phase was carried out for optimization of dosage (300, 450, and 600 mg/day) and identification of responders (which was defined by >50% reduction in pain visual analog scale [VAS] from baseline and a self-rating of overall improvement on the patient global impression of change scale of “much improved” or “very much improved”). Responders (n=566 of 1,051) then entered a double-blind phase where they were randomized to continue pregabalin or receive placebo for 26 weeks. The primary endpoint was time to loss of therapeutic response measured in days, and defined as either <30% reduction in pain VAS score relative to open-label baseline value at two consecutive visits or worsening of fibromyalgia necessitating alternative treatment. Among 566 randomized patients, 162 completed the trial (19% for placebo; 48%, 33% and 37% for 300, 450, and 600 mg/day, respectively). The time to loss of therapeutic response was significantly longer for all pregabalin-treated patients as compared to placebo (half of placebo-treated group had loss of therapeutic response by day 19 whereas more than half of all pregabalin-treated patients still had not lost therapeutic response at the end of the trial). At the end of the trial, 61% of placebo-treated patients had lost therapeutic response as compared to 32% in pregabalin-treated patients (P<0.001). An open-label extension study from Japan41 involving 106 patients also revealed similar findings in regard to the durability of response. In this study, the mean pain VAS scores at week 15 (4.8/10) and week 53 (4.9/10) were similar; only 6.6% of the patients had discontinued pregabalin due to lack of therapeutic response. Hence, most patients who initially respond to pregabalin (which may begin as early as 1 week of therapy, when responders start to separate from placebo in randomized trials3840) will continue to do so and loss of therapeutic response over time is unlikely.

In reference to the benefits in fibromyalgia pain, it has to be noted that a 2-point numeric reduction in the VAS scale (0–10) or >30% reduction in pain from baseline represents a clinically meaningful difference42 (Table 1). In regard to the former, the endpoint mean pain scores after treatment with pregabalin closely approached this threshold in most of the aforementioned trials3537,39 (range: −1.29 to −2.06), especially with dosages higher than 450 mg/day. In regard to the latter, a meta-analysis of clinical trials of pregabalin in fibromyalgia43 and a Cochrane database systematic review on the use of pregabalin in acute and chronic pain,44 including fibromyalgia, revealed that on an average approximately 30%–50% of patients treated with pregabalin were able to achieve >30% reduction of pain from baseline and 20%–30% patients achieved >50% reduction of pain. The number needed to treat ranged from 9 to 14. Furthermore, in the Cochrane analysis,44 the following were discerned: 1) pregabalin 150 mg/day was not different from placebo in efficacy; 2) greater response was noted with higher dosages up to 450 mg/day, with lower (better) number needed to treat values; 3) pregabalin 600 mg/day did not produce better results than 450 mg; and 4) the relative benefit for >30% or >50% pain reduction with pregabalin 450 mg/day was 1.5 as compared to 1.1 for placebo. Although only about a third of total patients were able to achieve the clinically meaningful benefit in terms of pain response, it does represent an important difference for those who achieve this.

Efficacy in treatment of sleep disturbance

It is intriguing that pregabalin enhances slow-wave sleep. A double-blind study involving 12 healthy volunteers compared the effects on sleep of pregabalin 450 mg/day to alprazolam and placebo.45 Pregabalin-treated patients had a higher proportion of delta wave sleep (stage 3 and stage 4) compared to both placebo and alprazolam (~36%, 18%, and 25% of total sleep time on night 3, for pregabalin, alprazolam, and placebo, respectively (P<0.001)); this effect was evident in all thirds of the night. This was in contrast to alprazolam which decreased slow-wave sleep in the second and final thirds of night and increased the proportion of stage 2 sleep. Pregabalin therapy was also associated with fewer awakenings of longer than 1-minute duration. Another randomized, placebo-controlled two-way crossover polysomnography study23 involving 119 patients with fibromyalgia with a history of disturbed sleep (subjective total sleep time <6 hours/night and subjective wake after sleep onset [WASO] >60 minutes for >3 nights/week) with objective polysomnographic abnormalities of WASO >45 minutes and total sleep time of 3–6.5 hours for 2 consecutive nights revealed a reduction of WASO by 19 minutes after 4 weeks of treatment (WASO for pregabalin 51.5 vs 70.7 minutes for placebo [P<0.0001]) and increase in total sleep time by >25 minutes (total sleep time 396 and 370 minutes for pregabalin and placebo, respectively [P<0.0001]). Hence, pregabalin may improve the quality as well as the quantity of sleep.

Benefits of pregabalin therapy on sleep are well translated in clinical trials. Clinically meaningful improvement in sleep quality corresponds to a change of 10 mm on sleep quality variable on Leeds Sleep Evaluation Questionnaire VAS,46 0.83 on sleep quality diary,47 and 7.9 units on medical outcome sleep study48 (Table 1). In an analysis of two randomized trials in fibromyalgia,47 patients taking pregabalin had statistically significant improvements in both sleep quality diary and medical outcome sleep study, the difference with placebo exceeding the thresholds for clinical meaningfulness (0.86–1.35 for sleep quality diary and 8.91–14.93 for medical outcome sleep study); these results were more consistent at doses 450 mg/day or higher (Table 1). Using a mediation analysis model, the study47 concluded that 43%–80% of improvement of sleep was due to medication itself and 20%–57% of the improvement was mediated via improvement in pain. Beneficial effects on sleep can be seen as early as day 1 and median time to sustained clinical improvement is 11 days.49 Durability of benefit was also evaluated by a post hoc analysis of FREEDOM trial, where median time to loss of therapeutic response was 41 days for placebo, whereas >50% of pregabalin-treated patients continued to maintain therapeutic response at week 26.50 Thus, meaningful benefit in sleep is lasting and there is little evidence of significant tolerance.

Efficacy in functioning and quality of life

The fibromyalgia impact questionnaire (FIQ) and SF-36 health survey are the most commonly used measures for functioning and HRQoL. Significant improvements in FIQ were noted with pregabalin at the doses of 450 and 600 mg/day compared to placebo in a randomized trial36 (baseline FIQ scores: 58.7, 61.1, 59.6, and 59.5 for placebo and pregabalin 300, 450, and 650 mg/day, respectively; FIQ scores at week 14: 51.99, 49.03, 46.75, and 46.65 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; mean change from baseline: −7.74 for placebo, −12.98 for pregabalin 450 mg/day [P=0.0041] and −13.08 for pregabalin 600 mg/day [P=0.0034]); the difference did not reach statistical significance in patients taking the dose of 300 mg/day (FIQ score at baseline: 61.1 and at week 13: 49.03; mean change: −10.70 vs −7.74 for placebo [P=0.1]). Another randomized trial38 showed significant improvement in FIQ with the pregabalin dose of 450 mg/day only (baseline FIQ score 62.58 and 60.59 for placebo and pregabalin 450 mg/day, respectively; FIQ scores at week 14: 54.14 for placebo 48.29 for pregabalin 450 mg/day; mean change: −6.74 for placebo and −12.79 for pregabalin 450 mg/day [P=0.0012]) but not with 300 and 600 mg/day (baseline FIQ scores: 60.69 and 60.4, respectively; FIQ scores at week 14: 52.97 and 52.7, respectively; mean change −8.11 and −8.38 [P=0.5 and 0.4, respectively]). A third randomized trial with a similar sample size,37 however, failed to show a statistically significant response in FIQ although there was an overall trend toward improvement (baseline FIQ scores: 64.3 for all groups; FIQ at week 13: 50.66, 48.18, 48.62, and 49.45 for placebo and pregabalin 300, 450, and 600 mg/day, respectively; mean change: −13.66, −16.15, −15.71, and −14.88 for placebo, pregabalin 300, 450, and 600 mg/day, respectively: all P-values >0.2). A study from Japan revealed the most remarkable improvement in the following domains of FIQ: waking up well rested, feeling good, fatigue, and pain.39 Considering a change of 8 points in FIQ to be a minimal clinically important difference,50 almost all the dosages of pregabalin seem to exceed this outcome while the effect of placebo was closely approaching36,38 and, indeed, exceeding in one study37 (Table 1). Although only a modest improvement from placebo, this difference does have a clinical meaningfulness as discussed.

SF-36 health survey results are diverse. Significant improvements in several domains of SF-36 are demonstrated but are not consistent across different studies. Improvement was noted on the following domains: social functioning,35,36 bodily pain,34 vitality,35,36,39 general health,35 physical functioning,39 and mental health36,39 with all studies showing improvement in SF-36 vitality scale. Considering a change of 5 units on SF-36 vitality scale equated with a minimally important clinical difference,50 all studies35,36,39 achieved this consistently (Table 1). The FREEDOM trial40 demonstrated the persistence of beneficial effects for up to 6 months in the majority of patients who initially responded to therapy. Hence, meaningful benefit in quality of life, at least on the vitality scale, may be achieved by pregabalin therapy. In addition, there are beneficial effects in ergonomics. In a meta-analysis of four randomized trials,51 patients who had VAS pain score <30 mm at the end of trial and >50% improvement of pain from baseline (double responders) had 67% reduction in work interference (both presenteeism and absenteeism), those with endpoint VAS pain score <30 mm only had 55% reduction, and those with >50% improvement only had 27% reduction (as compared to 12% with reduction in nonresponders; all P-values <0.001). Approximately 1.4 days of work per week was gained in double responders, 1.2 days/week in patients achieving VAS pain score of 30 mm or less, and 1 day/week in patients with >50% improvement in pain. As a result of this, improved productivity and perhaps a reduction of indirect costs of fibromyalgia could ensue.

Safety

Side effects of pregabalin treatment are common but do not interfere with functions of daily life. The rate of discontinuation is low. Treatment emergent adverse events are noted in ~80%–90% of patients in pregabalin-treated group and approximately 70%–75% in placebo group in randomized trials.35,36,39 Among the side effects attributed to pregabalin therapy, the most common are dizziness and somnolence with relative frequency of approximately 40%–50% and 30%–45%, respectively.3539 The median time to onset for each of these is 1–2 days.35,37 In patients, who continued pregabalin, the median duration of dizziness was 4–44 days (longer duration for those taking higher dose, ie, dose-related) and the median duration of somnolence was 18–88 days (not dose-related).35,37,43 Overall, 3%–9% of patients discontinue pregabalin due to dizziness and a further 3%–6% withdraw due to somnolence.3538 In long-term extension studies, the prevalence of dizziness and somnolence decreases by about half, where 17% continue to complain of dizziness and approximately 8% continue to complain of somnolence.52 This is thought to be related to the development of tolerance to these side effects.52

Weight gain and peripheral edema are less common than dizziness and somnolence but can lead to discontinuation of therapy. Approximately 14% of pregabalin-treated patients complain of weight gain at 3 months of therapy and the incidence of clinically significantly weight gain (>7% weight gain) is approximately 10%. The severity of weight gain is usually deemed as mild to moderate and approximately 2% of patients discontinue treatment.3638 However, the incidence of weight gain has been reported to be as high as 18%–26% in a year in some long term studies,39,52 which may further lead to discontinuation of therapy. Peripheral edema, on the other hand, is experienced by approximately 8%–11% of patients at 3 months of therapy.3538 Discontinuations due to peripheral edema is rare (<0.5%) and there is no incremental incidence at 1 year compared to 3 months.3538,41,52 No changes in cardiovascular and renal function were noted in patients with peripheral edema.35 A handful of case reports of worsening of preexisting heart failure5355 due to fluid retention are available in literature. This has led to a proposal of a systematic analysis for evaluation of the strength of association between heart failure and pregabalin therapy,56 the results of which are actively awaited. In the interim, the New York Heart Association has issued a warning about being careful when prescribing pregabalin in patients with New York Heart Association class 3 and 4 heart failure.57

Central adverse events associated with pregabalin therapy with incidence higher than 5% include blurring of vision, disturbance of attention, balance issues, vertigo, incoordination, thinking abnormally, confusion, euphoria, and impaired attention. These rarely lead to discontinuation of therapy and are also deemed mild to moderate in severity.3538 Noncentral adverse effects of incidence higher than placebo include dry mouth, increased appetite, and constipation, which are also usually mild.3538 Most of these adverse effects were noted with pregabalin when used as an anticonvulsant before its use in fibromyalgia. Reassuringly, no new patterns of adverse events were noted with its use in fibromyalgia patients.

The serious adverse events leading to discontinuation of pregabalin therapy are mostly related to dizziness and somnolence.3538 Other extremely rare events, with prevalence in the range of 0.1%, described in patients taking pregabalin which led to discontinuation of therapy, include myoclonus, chest pain, crush injury, motor vehicle accidents, abnormal liver function tests, and suicidal ideation.3639,52 Because of the rarity of these events with only one to two events per randomized trial, the causal association is difficult to establish. Moreover, corresponding investigators of the trials have concluded that almost all these events were unrelated to pregabalin therapy.

No significant differences were noted between placebo and pregabalin-treated patients in blood pressure, pulse rates, serum chemistry, liver function tests, electrocardiogram (EKG), or urinalysis.3538 A mild increase in creatinine kinase was noted in Japanese patients (2.8% with pregabalin vs 0.4% with placebo) but this did not lead to discontinuation of therapy.39 It has to be noted that all trials were conducted in patients with a Glomerular function rate (GFR) of more than 60 mL/minute/1.73 m2 except in one trial where the dose was halved in patients with a GFR of 30–60 mL/minute/1.73 m2;41 no significant increase in adverse events were noted in the latter. To date, the safety of pregabalin in fibromyalgia patients with a GFR less than 30 mL/minute/1.73 m2 has not been evaluated.

In summary, pregabalin-treated patients have moderate to high incidence of side effects; the side effects are usually mild and serious adverse events are extremely rare. The rate of discontinuation of therapy due to adverse event is not uncommon and is more likely with a higher dose with relative risk of 1.6 for 300 mg/day and 2.5 for 600 mg/day.44 Many patients develop tolerance to the side effects with continuation of therapy. There is no need for regular monitoring of blood chemistry or hematology and clinical monitoring can usually be accomplished in the primary care setting.

Accessibility: cost-effectiveness

Pharmacoeconomic studies reveal that pregabalin is cost-effective. A Marcov58 model for the assessment of cost-effectiveness of pregabalin in the USA noted that at 12 weeks, the total and indirect costs were lower in patients taking pregabalin 300 and 450 mg/day compared to placebo. The direct costs (outpatient visits and medications) were, however, slightly higher. In this instance, pregabalin 450 mg/day was cost saving overall, but pregabalin 300 mg/day was not. Nevertheless, at 1 year, both the dosages of pregabalin were cost saving; the total, direct and indirect, costs were all lower than that of placebo.58 Pregablin was also cost saving as compared to duloxetine, gabapentin, and milnacipran.58 A study from UK59 revealed similar findings where pregabalin was found to be cost-effective at a threshold of £30,000 (approximately US$48,000) per QALY gained (in general, an intervention is considered cost-effective at a threshold of US$50,000 or less per QALY gained60). In both studies,58,59 the incremental cost-effectiveness ratios with pregabalin therapy was highest in patients with severe fibromyalgia and with 450 mg/day dosage. Studies from Iran61 and Mexico62 revealed consistent effects on cost saving, with most benefit with pregabalin 450 and 600 mg/day.61 Comparative analyses of pregabalin and other drugs in fibromyalgia, especially duloxetine, have not always revealed consistent results with some studies pointing toward higher health care resource use with pregabalin, probably driven by more inpatient and outpatient visits and medication use, while others revealed nonsignificant difference between the two.63 Almost all cost-effectiveness analyses are dominated by amitriptyline because of its lower costs but the comparison between amitriptyline and pregabalin relies on older studies which may not meet current quality criteria59 and the degree of overall clinical improvement (reduction of VAS score by >50% and decrease in FIQ score by 30%) is lower with amityrptyline.62 It may thus be stated that pregabalin therapy results in better outcomes at a higher cost when compared to amitriptyline. To conclude, long-term pregabalin therapy is certainly cost-effective in fibromyalgia especially at doses 450 mg/day or higher and at least cost neutral, if not cost saving, with 300 mg/day dose and is comparable to other drugs used in fibromyalgia.

Conclusion

Fibromyalgia, a chronic disease with poorly understood pathophysiology, carries a substantial burden in patients as well as the society. Pregabalin therapy in patients with fibromyalgia is modestly effective in terms of response, but a good number of patients are able to achieve meaningful benefit in terms of pain control, improvement of sleep, functioning, and quality of life. Side effects from pregabalin therapy, although common, are usually mild, well tolerated in long-term, and can be monitored in primary care setting. Pregabalin is cost saving to the society, especially if used at dosages 450 mg/day or higher. Until the availability of better drugs in future, pregabalin is well suited to serve as one of the “anchor drugs” in fibromyalgia.

Disclosure

The authors report no conflicts of interest in this work.


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