Palmitoylethanolamide in Fibromyalgia: Results from Prospective and Retrospective Observational Studies

Fibromyalgia syndrome (FM) is a very prevalent rheumatic disease. Widely underestimated and rarely diagnosed, it strikes between 2 and 4% of the general population [1], with a clear predominance in females. In Italy, disease prevalence is 4.1% in the general population (6.9% in women and 0.3% in men) [1]. FM shows a bimodal pattern of incidence: a first peak between 25 and 35 years and a second between 45 and 55 years [2]. This syndrome is characterized by widespread chronic pain, tenderness in muscles and deep tissues, and fatigue accompanied by other non-specific symptoms, including sleep disturbances. In particular, the widespread pain of FM is a disabling condition and can become quite marked when evoked by digital pressure at tender points (TPs). Research suggests that pain in FM syndrome is associated with a generalized alteration in the central somatosensory system [3, 4]. Central sensitization is likely sustained by neuroinflammatory processes triggered by microglia activation [5]. These data suggest that the cross-talk between nervous and immune systems plays a fundamental role in the onset and progression of chronic pain in patients with FM [6].

Diagnosis is still carried out according to criteria developed in 1990 by the American College of Rheumatology (ACR-90 criteria): a history of widespread musculoskeletal pain lasting at least 3 months and the presence of at least 11 of 18 predefined TPs [7]. Nevertheless, the criteria of the ACR for FM of 2010 are increasingly applied [8], consisting of 2 scales: the Widespread Pain Index (WPI) and the Symptom Severity (SS) scale. Numerous other symptoms accompany the clinical course and daily life of patients with FM: asthenia and decreased muscle strength [9], headache, irritable bowel syndrome, paresthesias, cramps and fasciculations, cognitive disorders, anxiety-depressive syndrome, blurred vision, and unusual thermal, tactile, auditory, visual and/or olfactory sensations [10, 11]. Although trigger conditions such as strong psycho-physical stress [12, 13] or febrile illness (often of viral origin) have been suggested, the pathogenesis of FM remains largely unknown. Several hypotheses have been advanced, which have led to the definition of FM as a neuroimmune-endocrine disorder, whereby the molecular mechanisms of neurotransmitter dysfunction are associated with more obvious neurological deficits [10, 14‐20].

The etiopathogenic and clinical complexity of FM requires a multidisciplinary approach based on multimodal therapeutic strategies that include also non-pharmacological interventions [10, 14]. In particular: reduce peripheral nociceptive input (muscle relaxants, anti-inflammatory agents, physical therapy); reduce or prevent central sensitization; treat co-morbid conditions that contribute to maintaining a high pain threshold [17]. At present, treatment of FM favors the use of centrally acting anti-epileptics and antidepressants, since drugs acting peripherally (e.g., corticosteroids, non-steroidal anti-inflammatory drugs) would be less effective [21]. Anti-epileptics such as gabapentin and pregabalin (PGB) have been used in FM with especially encouraging results: 30% reduction in pain intensity in about half of patients and 50% in about one-third [22]. Further, PGB was effective in persistent pain refractory to common analgesics and sleep disorders [23]. Antidepressants, by improving the quality–quantity of sleep, can decrease some associated symptoms such as fatigue and gastrointestinal disorders, thereby contributing to the optimization of analgesia in patients with FM [24]. Among antidepressants, inhibitors of serotonin/norepinephrine reuptake (e.g., duloxetine [DLX]) were more efficacious than serotonin reuptake inhibitors [25, 26]. Optimal results were achieved by integrating treatments to take advantage of potential drug synergism while assuring a better safety profile, owing to the use of each drug at its lowest effective dose [27].

An important advance in the field of analgesic treatment for many chronic painful conditions is represented by N-(2-hydroxyethyl) esadecanamide (palmitoylethanolamide or PEA) [28], a member of the naturally occurring family of fatty acid amides. While initially recognized for its anti-inflammatory activity, PEA is today viewed as a key element of the body’s endogenous mechanism to maintain/restore homeostatic balance in the face of different types of damage, including activation of the inflammatory response and nociceptive pathways. There is increasing evidence that PEA acts as mediator of resolution of inflammatory processes, thus counteracting the progression of chronic inflammation: it is synthesized/metabolized by microglia and mast cells; it down-modulates mast cell and microglia activation; and tissue levels of PEA are alterated in brain areas involved in nociception following neuropathic pain induction, as well as conditions associated with injury to nervous tissue (stroke, spinal cord injury) [29, 30]. The mechanism of PEA action has been defined by the acronym ALIA (Autacoid Local Injury Antagonism) [31]. PEA is effective in the treatment of chronic pain caused by different etiopathogeneses [32] suggesting activation of non-neuronal cells (mast cells and glia) as a common factor in the various pathological conditions [33‐35]. Based on its effectiveness, lack of drug interactions and absence of adverse effects [30], PEA represents a promising and innovative therapeutic strategy, especially if placed within a multimodal pharmacotherapy.

The above findings encouraged us to evaluate PEA effects in patients with FM. Our investigation was devised so as to include two separate studies: a retrospective observational study and a prospective uncontrolled study. The first was intended to assess efficacy and safety of DLX + PGB association in controlling patient pain, while the second was to determine whether micronized PEA (PEA-m^®; Epitech Group, Italy) and ultramicronized PEA (PEA-um^®; Epitech Group, Italy) would provide additional clinical benefit over and above to the results obtained with DLX + PGB. As compared to naïve PEA (particle size profile ranging between 100 and 700 µm), micronized and ultramicronized PEA differs in their particles size profile (2–10 µm and 0.8–6 µm at most, respectively). Micronization and ultramicronization processes yield a different crystalline structure with higher energy content and smaller particle size which result in better diffusion and distribution of these molecules compared to the naïve form, and thus superior biological efficacy [30, 36]. The study aim was to investigate, whether PEA-m and PEA-um would provide additional clinical benefit in controlling pain in patients with FM, in multimodal therapy.

The complete study was conducted on a total of 80 patients with FM, divided into two separate arms, as described below. Patients were recruited within the Medical Clinic at the University of Perugia General Hospital “Santa Maria” of Terni. All patients provided informed written consent to participate. This study was carried out in accordance with the Helsinki Declaration of 1964, as revised in 2013, and Good Clinical Practice and was approved by The Local Ethical Committee of Umbria.

One of the most noteworthy clinical features of FM is widespread pain that, at particular points called TPs, can reach very high levels when provoked by pressure [1]. Centrally acting anti-epileptics and antidepressants have proven beneficial in reducing pain intensity in patients with FM, although their effects leave much to be desired. Inflammation is a key feature of chronic and neuropathic pain [33]. A major advance in our understanding of the pathogenic mechanisms underlying FM, as well as other chronic pain syndromes with important therapeutic consequences, is knowledge about the physiological role played by the body’s ‘built in’ mechanisms for resolution of inflammation [34]. We are coming to appreciate the importance of PEA as an ‘on demand’ molecule produced to restore homeostatic balance against stress and tissue injury [34]. Initially studied for its anti-inflammatory activity, PEA is now considered to be at the center of these endogenous mechanisms of protection. This fatty acid amide down-modulates mast cell degranulation and the consequent release of pro-inflammatory mediators, as well as the pro-algogenic actions of other immune-related non-neuronal cells such as microglia—effects likely to account for its pain-relieving qualities. Indeed, several studies have demonstrated the pain-relieving efficacy of PEA irrespective of etiology, suggesting a common cellular denominator in its mode of action [31, 32]. PEA anti-inflammatory and pain-relieving properties have been amply demonstrated in a number of animal models [30, 37, 38]. In humans, PEA is highly efficacious in the treatment of chronic pain associated with different diseases [32, 39‐42] and has no deleterious side effects at pharmacologically effective doses.

The main limitation of this exploratory study is the open-label design without a randomization and blinding. Therefore, it is not possible to ascertain the extent to which improvements with combination therapy may have been due to patient or investigator expectations. Moreover, it should be considered that, when this study was conducted, there were no available data on the combination of PEA + PGB on FM outcomes. Therefore, this was designed as an exploratory study to evaluate the potential effects of a multimodal pharmacotherapy in FM. The study results offer some clinical information regarding the potential benefits of adding PEA to DLX + PGB in patients with FM, indicating the need for further research into combinations with different drug classes. Again, further studies would need to be conducted to evaluate the benefits of combining these treatments in the general FM population.

Our research suggests the efficacy and safety of PEA in the treatment of pain associated with FM. Its introduction in the therapeutic regimen of DLX + PGB provided a significant improvement in pain symptoms, with a further reduction in the number of TPs and significant reduction in pain, compared to combined DLX + PGB only. It is interesting to note that the results achieved in 3 months with PEA-um and PEA-m added to therapeutic regimen are significantly better than those after 6 months of DLX + PGB only, and that this improvement appeared to depend on PEA. Given its effectiveness, lack of drug–drug interactions, and absence of adverse events, PEA-um and PEA-m may be a promising therapeutic strategy for the treatment of FM and other disorders with chronic pain, especially if utilized in the context of a multimodal pharmacotherapy.

The results from this open-label, non-randomized, non-blinding clinical study suggest that adding PEA to initial PGB + DLX therapy improved the outcome of FM. For some patients requiring more than one FM medication, the addition of PEA may be a favorable treatment option. Again, further studies would need to be conducted to evaluate the benefits of combining these treatments in the general FM population.