Pharmacologic Treatment

Gerdelet-Mas et al. (2007)^{Reference Gerdelet-Mas7} published one of the first studies looking at controlling pain in PD by optimizing the dopaminergic treatment with levodopa. This study was based on previous findings that suggested that patients with PD had a lower subjective pain threshold than healthy subjects.^{Reference Massetani8} Despite a relatively small sample size, including 13 patients in the study arm (levodopa, “OFF” state – off levodopa for 12 hours, “ON” state – morning dose of levodopa plus an additional 100 mg), and 10 patients in the age-matched healthy control group (200 mg dose of levodopa), they found that in addition to having a lower pain threshold (measured by recording the RIII nociceptive flexion reflex threshold, 6.9 (1.2) mA in the “OFF” group compared to 8 (1.05) mA in the “ON” group) than age-matched controls, patients with PD that had been treated with levodopa had a significant increase in their objective pain thresholds. However, many patients optimized on levodopa treatment still experience a significant amount of pain, and therefore, the adjustment of dopaminergic treatment alone is not always sufficient in treating this prevalent symptom.^{Reference Schapira, Chaudhuri and Jenner9}

Dellapina et al. (2010)^{Reference Dellapina10} performed a follow-up study assessing the effect of the dopamine agonist apomorphine on pain thresholds in patients with PD. Previously, it had been shown that other monoamine systems might be involved in central pain modulation^{Reference Pertovaara11}, and given levodopa is also converted to other monoamines in the central nervous system, it was postulated that the effect seen on central pain thresholds may be related to monoamines other than dopamine. In this randomized-controlled crossover trial (n = 25), apomorphine (individualized dose based on motor improvement) given for 2 days prior to testing, compared to placebo, had no specific effect on pain threshold using the same RIII nociceptive flexion reflex (10.7 (3.6) mA in the study group and 9.4 (3.7) mA in the control group), and on pain-induced cerebral activity based on positron emission tomography scanning. There was no significant difference compared to baseline for either group, indicating that apomorphine was not non-inferior compared to placebo, but rather the treatment was ineffective. Given this study showed that a dopamine agonist is not efficacious in modulating pain thresholds, this could indicate that perhaps the increased pain threshold in PD patients is related to the conversion of levodopa to noradrenaline, or its effect as a “false transmitter” in serotonergic terminals.

Based on this theory that norepinephrine and serotonin may regulate central pain, Djaldetti et al. (2007)^{Reference Djaldetti12} performed an open-label study assessing the effect of duloxetine on central pain symptoms in patients with PD. They enrolled 23 consecutive PD patients complaining of any type of pain and treated with 60 mg of duloxetine for 6 weeks. Given the open-label nature of the study, there was no control group. There was a significant reduction in pain on an 11-point Likert visual analog scale after 6 weeks of treatment (7.6 (3.2) pre treatment compared to 4.2 (2.6) after treatment). The antidepressant activity of duloxetine may have played a role in these results. However, Beck Depression Inventory scores were not significantly different between the two groups at the end of the treatment period, and patients with significant depression were excluded from the study altogether. Three patients had to withdraw from the study, and three had to reduce the dose to 30 mg due to medication side effects including nausea and vomiting, vertigo, sleepiness, insomnia, diarrhea, and aggravations of tremor. Given the open-label nature of the study, the potential for placebo response is high and a randomized-controlled trial is required to measure clinically significant efficacy.

The first randomized controlled trial specifically designed to investigate the pharmacologic treatment of PD-related pain came from Trenkwalder et al. in 2015.^{Reference Trenkwalder13} This was a phase 2 study in which OXN PR, a combination of oxycodone and naloxone (thought to reduce gastrointestinal side effects of opioid medication), was used in patients with scores of at least 6 on an 11-point pain scale, in comparison to placebo. While safe, OXN PR did not have a significant effect on the primary endpoint of improved average 24-h pain score at 16 weeks on the same Likert scale. Per-protocol analysis, however, showed that adherence to protocol resulted in significantly improved pain scores compared to placebo (least-squares mean difference of −0.9 (0.8) on the likert scale). Possibly, the heterogeneity of PD pain types may have contributed to the negative trial, as OXN PR has been shown to improve severe musculoskeletal pain and severe nocturnal pain, but not necessarily central or neuropathic pain. The dropout rate was also high, and understandably so, as many patients are unlikely to tolerate severe PD-related pain for 16 weeks, which was an inclusion criterion. This study was released shortly following a Madeo et al. (2015)^{Reference Madeo14} study which assessed the efficacy and safety profile of OXN PR in the PD population. Despite negative results from the Trenkwalder et al. study, Madeo et al. did describe a significant reduction in global pain on a numeric rating scale, as well as pain intensity over 8 weeks in their small, prospective, open-label study (−2.31 (0.52) reduction on the numeric rating scale, from 0 to 10). Once again, the open-label nature of the Madeo study means that there may be a strong placebo effect on the results.

Following the OXN PR studies, Rascol et al. (2016)^{Reference Rascol15} performed a randomized-controlled pilot study looking at the efficacy of the transdermal rotigotine patch in treating chronic PD-related pain. Based on the RECOVER study which suggested that rotigotine may help improve PD-related pain compared to placebo, the Rascol trial was intended to be a large-scale study as assessed on an 11-point Likert scale after 4 weeks of treatment.^{Reference Trenkwalder16} A post-hoc analysis of the RECOVER study by Kassubek et al. (2014)^{Reference Kassubek17} indicated a statistically significant improvement in the Likert scale in PD patients with “any pain” (least square mean difference of −0.88) or “moderate-to-severe pain” (least square mean difference of −1.31), but not in those with “mild pain”. With these post-hoc results, it is important to keep in mind that because patients were not selected for the original study based on symptoms of pain, post-hoc selection using subjective pain scales may bias results. These patients were also categorized into arbitrary subgroups of “mild pain” and “moderate-to-severe pain” on the Likert scale.^{Reference Antonini18} That being said, the results showed promise and certainly warranted an investigation into the potential improvements in pain seen with the rotigotine transdermal patch.

Unfortunately, a subsequent trial investigating non-motor symptoms in PD did not demonstrate a statistically significant difference between rotigotine and placebo in the individual item of the Non-Motor Symptoms Scale that assessed pain.^{Reference Antonini18} Therefore, a smaller number of patients than initially planned were enrolled into the 2016 Rascol trial^{Reference Rascol15} – with 33 randomized to the placebo arm and 35 to the rotigotine arm. The goal of the study was to collect preliminary information on the potential efficacy of rotigotine on PD-associated chronic pain, and to assess the feasibility of conducting a larger trial. Given the small sample size, the study was heavily underpowered and although no statistically significant improvements were seen over the 12-week trial period, numerical improvements in the primary outcome, the severity of PD-associated pain experienced in the last 7 days of the trial, as assessed by an 11-point Likert pain scale, were seen (least square mean difference of −0.76, p = 0.172). Importantly, the percentage of patients who responded to treatment as assessed by a ≥2-point improvement on the Likert scale was numerically higher in the rotigotine group (60%) compared to the placebo group (47%). While a nearly 50% placebo response should be noted, a 2-point change on an 11-point Likert scale is generally considered to be a clinically important difference, and therefore with an adequately powered study, a statistically significant difference may be seen.

One of the more recent studies assessing pharmacologic treatment for PD-related pain was the Cattaneo et al. (2017)^{Reference Cattaneo19}post-hoc analysis of two studies assessing the efficacy and safety of safinamide, an orally active, selective, reversible monoamine oxidase-B inhibitor with both dopaminergic and glutamatergic properties, compared to placebo as an adjunct medication to stable doses of levodopa. These trials were conducted in patients with mid- to late-stage PD and motor fluctuations. At 24 weeks, safinamide (at a dose of 100 mg) significantly improved scores on the “bodily discomfort” domain of the PDQ-39 questionnaire, which addresses musculoskeletal and neuropathic pain (−5.28 (−3.79 to −6.78) numerical reduction in “bodily discomfort” domain score compared to −1.59 (−1.10 to −3.09) in the placebo group). In addition, significantly more patients were free of pain medications as compared with the placebo group, and there was a 34% reduction in the number of concomitant pain treatments. Again, given the original trials were not designed to investigate pain as a primary endpoint, only indirect measures could be used to evaluate pain. As such, these results should also be considered exploratory, and their clinical relevance must be confirmed in larger trials with pain as a primary endpoint.

Botulinum toxin is frequently used in PD patients to treat dystonia and rigidity, most commonly in patients with advanced disease.^{Reference Cardoso20} Based on results from a retrospective study and clinical experience with patients that received injections and had subjective improvements in pain,^{Reference Bruno21} Bruno et al. (2017)^{Reference Bruno22} performed a prospective randomized placebo-controlled crossover trial using botulinum toxin type A (BTXA) to treat limb pain in advanced PD. Fourteen patients were enrolled and twelve finished the trial. Half of the patients had dystonic pain and half musculoskeletal pain defined using the Ford’s clinical classification of pain.^{Reference Ford23} Pain was assessed using both a numeric rating scale and a visual analog scale. Overall, the study showed a mild, non-significant reduction in pain after 4 weeks (peak effect) compared to placebo (reduction in 1.75 points on the numeric rating scale compared to 1.16 in the placebo group), and subgroup analysis showed that those with dystonic pain had an even greater, yet still non-significant, reduction in pain (2.66 points reduction compared to 0.75 in the placebo group). There were no changes seen at the conclusion of the 12-week study. This subgroup analysis was insufficiently powered, and a clinically meaningful benefit from BTXA injections is usually seen after multiple treatments, rather than just after one injection as per this study’s protocol. Certainly, the results showed that BTXA is safe in patients with limb pain and further studies may focus on evaluating long-term effects of BTXA in patients with dystonic pain, as they seemed to show the most benefit.

Non-Pharmacologic Treatment

Deep brain stimulation (DBS) is a well-documented treatment for severely disabled PD patients with motor fluctuations, and interestingly, previous studies have shown clinical pain relief after bilateral DBS of the subthalamic nuclei (STN).^{Reference Kim24} However, it was unclear as to whether this improvement was based on a central or nociceptive mechanism. Marques et al. (2013)^{Reference Marques25} aimed to investigate the effect of DBS to the STN and levodopa administration on pain and pain tolerance thresholds. Three groups were included in the study: stimulation on with levodopa off, stimulation off without levodopa on, and stimulation off with levodopa off. They used Thermotest and Algometer devices to measure thresholds for thermal pain and mechanical pain, respectively. Following acute DBS surgery to the STN, there was a significant increase in both thermal and mechanical pain thresholds, and with acute stimulation, there was an increase in mechanical pain threshold.

Finally, Rintala et al. (2010)^{Reference Rintala26} explored the use of cranial electrotherapy stimulation (CES), a non-invasive technique which applies a small amount of current through the head via ear-clip electrodes, to treat pain in PD. A review of the use of CES in chronic pain concluded that CES has been found to be effective in reducing both headache and spinal pain, amongst others.^{Reference Kirsch and Smith27} Therefore, Rintala et al. performed a small feasibility randomized-controlled trial assessing the efficacy of CES in lower body pain only. They limited the study to patients with lower body pain to ensure a more homogenous sample, and because lower body pain typically contributes to limitations in mobility. Even in this small sample size with the application of CES for 40 minutes/d for 6 weeks, there was a significant pain reduction in the active treatment group compared to the sham group, based on a 10-point Likert scale. With only 13 participants reporting data, it is very difficult to generalize the results, but this study provides the basis for future trials investigating non-invasive, non-pharmacologic treatments for PD-related pain.