Methoxyflurane Analgesia in Adult Patients in the Emergency Department: A Subgroup Analysis of a Randomized, Double-blind, Placebo-controlled Study (STOP!)

Despite advances in pain medication and widely accepted guidelines for the treatment of pain such as the World Health Organization’s analgesic ladder [1], inadequate assessment and management of acute pain remains common in both the pre-hospital and Emergency Department (ED) setting, with pain prevalence figures of up to 90% in the ED [2, 3] and many patients undertreated [4‐6]. Pain relief regimes work optimally when effective analgesics are supported by formal protocols/guidelines underpinned by staff and patient education [7]. The ‘ideal analgesic’ for acute pain should have rapid onset of action, act over an extended period of time, be well-tolerated and effective across a wide range of pain types in different populations.

Methoxyflurane belongs to the fluorinated hydrocarbon group of volatile anesthetics. It was first introduced as an inhalation anesthetic in the 1960s [8], but its use was generally discontinued by the late 1970s due to availability of newer anesthetic agents and reports of dose-related renal tubular damage at anesthetic doses [9‐11]. Among inhalational fluorinated anesthetics, methoxyflurane is unique in having well-documented analgesic properties at low doses [12]. It has been used extensively for over 30 years in Australia and New Zealand (administered via a handheld inhaler; Penthrox^®, Medical Developments International Limited, Scoresby, Australia) as a self-administered, rapid-acting analgesic agent for short-term pain relief in emergency medicine, minor surgical and dental procedures. The Penthrox inhaler is a green whistle-shaped single-use device that delivers methoxyflurane in analgesic doses, with a maximum recommended dose in 24 h of two 3 mL vials [13].

The historical concern regarding methoxyflurane has been nephrotoxicity, which was reported following significantly higher doses with deep methoxyflurane anesthesia [9]. Renal damage is most likely due to the metabolism of methoxyflurane in the liver and kidney and release of fluoride ions [14, 15]. Clinical experience suggests that a low but effective analgesic dose is not associated with the risk of renal adverse events [16]. Laboratory evidence also shows a large safety margin for analgesic use of methoxyflurane in the Penthrox inhaler [a dose of 6 mL/day and 15 mL/week results in exposure of 0.59 methoxyflurane minimum alveolar concentration (MAC)-hours, which is well below the reported level of risk of nephrotoxicity of 2.0 MAC-hours [14]]. Therefore, it has been concluded that the use of methoxyflurane in analgesic doses does not carry a risk of nephrotoxicity [17].

Studies of low-dose methoxyflurane as an analgesic agent show decreases in pain scores and indicate that methoxyflurane is an efficacious analgesic in the ED and pre-hospital settings [18‐20] and for procedural analgesia [21]. Due to the physiochemical characteristics of methoxyflurane, absorption is rapid, providing fast onset of analgesic action (usually within 6–10 inhalations) to treat acute pain rapidly [13, 17]. The portability of the Penthrox inhaler and self-administration by the patient mean that it has practical advantages over alternatives such as nitrous oxide. Penthrox is a noncontrolled drug making it easier to prescribe and requiring less patient monitoring than opioid analgesics; it does not interfere with other analgesic agents or anesthetic drugs, and therefore does not limit subsequent treatment choices, and its effects are quickly reversible. Its characteristics make it suitable as a bridging analgesic, should more powerful intravenous (IV) analgesia be required, or for patients in whom IV access is difficult or impractical, or patients with contraindications or intolerance to other pain medications including opioids. Penthrox may eliminate the need for opioid analgesia for dislocations or fractures, for example, since the pain relief from Penthrox with or without the addition of simple non-opioid analgesia, may be sufficient for reduction or splinting.

Despite a large volume of published literature supporting the efficacy and safety of methoxyflurane at analgesic concentrations [18], previous studies have been mostly observational and uncontrolled. Furthermore, little data have been generated within an ED setting, or outside Australia and New Zealand. This double-blind, randomized, placebo-controlled, UK-based study evaluated the short-term efficacy and safety of methoxyflurane at low analgesic doses for the treatment of acute pain in patients presenting to the ED with minor trauma. The study included both adult and adolescent patients aged ≥12 years and the results for the full study population have been reported previously [22]. Since Penthrox has recently been approved in Europe for the treatment of adult patients, a subgroup analysis was performed to evaluate the data in patients aged ≥18 years, and the data for this adult subgroup are the focus of this secondary paper.

The results of this study confirm that methoxyflurane is a highly effective analgesic for adult patients in the ED setting. There was a highly significant difference between the methoxyflurane and placebo groups (p < 0.0001) in the analysis of the VAS pain intensity score at all-time points tested, despite a considerable ‘placebo effect’. In a previous hypothesis-generating study, Todd et al. found that a difference of approximately 13 mm on a 100 mm VAS scale represented the minimum change in acute pain that was clinically significant in a cohort of trauma patients [28], which was supported by findings of Gallagher et al. [26]. This was appreciably exceeded in our adult population results, with a treatment difference of −17.4 mm (95% CI: −22.3, −12.5 mm) overall in favor of methoxyflurane. A reduction of approximately two points or 30% in the pain intensity NRS has also been postulated to represent a clinically important difference by Farrar and colleagues [29]. While the primary efficacy results of the current study are based on the VAS pain score and acute pain, rather than the 11-point NRS and chronic pain (as evaluated by Farrar), the overall adjusted change from baseline in VAS pain intensity of −29.0 mm in the methoxyflurane group (from a baseline mean of 66.2 mm) represents a reduction in pain of ~44%, also considerably exceeding this definition of clinical significance. This is important, as small differences in mean VAS score can be declared “statistically significant”, even though they may be of little clinical significance to the patient [30]. In comparison, the overall adjusted change from baseline in VAS pain intensity in the placebo group was −11.6 mm (from a baseline mean of 65.5 mm), representing an 18% reduction. Although the STOP! study was placebo-controlled, our results for methoxyflurane are similar to those observed for IV morphine and intranasal fentanyl in a study by Borland et al. with a similar design and endpoint in pediatric patients presenting to the ED with acute long-bone fractures [31]. This study showed mean changes from baseline in 100 mm VAS pain scores at 5, 10 and 20 min of −25, −26 and −32 mm for morphine and −13, −22 and −31 mm for fentanyl from a baseline of 67 and 68 mm, respectively, compared with our results for methoxyflurane of −21, −27 and −35 mm from a baseline of 66 mm.

The secondary efficacy results supported the findings of the primary efficacy analysis, with significantly fewer methoxyflurane-treated patients requiring rescue medication than placebo-treated patients (11.8% vs. 38.6%), and approximately three-quarters of patients, physicians and research nurses rating methoxyflurane treatment as ‘Excellent’, ‘Very Good’ or ‘Good’. The high patient and treating medical professional satisfaction with methoxyflurane analgesia observed in this study is consistent with results reported by Buntine et al. [20], who reported that 81.9% of paramedics and 72.3% of patients felt satisfied with methoxyflurane pre-hospital analgesia. As expected, the onset of pain relief with methoxyflurane was rapid (median 5 min) with 79.4% of patients experiencing pain relief within 1–10 inhalations. This is consistent with the rapid onset of pain relief reported by Johnston et al. in their study of pre-hospital analgesia for visceral pain, which found a mean reduction in visual/verbal analog scale pain score (0–10 scale) with methoxyflurane of 2.0 (95% CI: 1.7, 2.2) after 5 min and 2.5 (95% CI: 2.1–2.9) on arrival at hospital, compared with 1.6 (95% CI: 1.4, 1.8) and 3.2 (95% CI: 2.9, 3.5), respectively, for intranasal fentanyl [19]. The onset of pain relief with methoxyflurane is also similar to that reported by Tveita et al. for a 10 mg bolus dose of IV morphine [32]. Although methoxyflurane is currently only licensed for emergency relief of pain due to trauma in Europe, several studies in Australia and New Zealand have also demonstrated its effectiveness as a procedural analgesic [21, 33‐36].

The rate of treatment-related adverse events was higher with methoxyflurane (42.2%) than placebo (14.9%); this was mostly attributable to a higher incidence of dizziness/lightheadedness and headache in the methoxyflurane group, which are both adverse events already captured in the product label [13]. However, the majority of adverse events were mild and transient in nature, no patients discontinued use of methoxyflurane due to adverse events and patients rated their satisfaction with methoxyflurane treatment highly, (77.6% assessing treatment as ‘Excellent’, ‘Very Good’ or ‘Good’). It should also be taken into account that study treatment exposure was higher in the methoxyflurane group than the placebo group; patients in the placebo group requested rescue medication significantly earlier than patients in the methoxyflurane group, and 24.5% of patients in the methoxyflurane group compared with 14.9% in the placebo group used a second inhaler. While this is unlikely to have affected the key efficacy endpoints, which mainly considered the early effects of study treatment (in the first 20 min), it may have had an impact on safety results. We also observed no effects of methoxyflurane on vital signs, which are consistent with the findings from two retrospective, observational studies of methoxyflurane analgesia in the pre-hospital setting that looked at records of 1217 patients treated by the Australian Ambulance Service [19, 37].

In this study, although clinical laboratory sampling was limited, no evidence of nephro- or hepatotoxicity was observed. Similarly, in patients receiving methoxyflurane as procedural analgesia for bone marrow biopsy, blood analysis of urea and electrolytes was no different between those patients receiving methoxyflurane and those receiving placebo [35]. These observations are consistent with the findings of Dayan [17], who reviewed laboratory and clinical data relevant to nephrotoxicity and methoxyflurane and concluded that low-dose use of methoxyflurane for analgesia has a large safety margin (at least 2.7- to 8-fold based on methoxyflurane MAC-hours or serum fluoride level) and does not carry a risk of causing renal dysfunction or damage. Furthermore, over 5 million doses of Penthrox have been sold with no pharmacovigilance-related trends suggesting nephrotoxicity. In a much larger controlled observational study of patients receiving analgesia during ambulance transport, comparing 17,629 patients receiving methoxyflurane with 118,141 patients not receiving methoxyflurane, no link between methoxyflurane use for emergency analgesia and renal disease (or hepatic disease) was observed [16]. Whilst the literature and post-marketing surveillance in Australia suggest that nephrotoxicity and/or hepatotoxicity of methoxyflurane at analgesic doses is not a risk [16, 17], a study is underway in the UK to understand hepatotoxicity in the pre-hospital and ED settings.

A limitation of the study was the lack of an active comparator, as previously observed by Carley and Body [38]. An active comparator was not considered feasible in this study due to the unique mode of delivery and smell of methoxyflurane, as well as the difficulty in blinding possible inhaled comparators such as nitrous oxide. Due to methoxyflurane’s fast onset of action, if an oral comparator was used, it would have been evident which treatment the patient had been randomized to. Placebo use is considered warranted when the placebo effect is known to be very variable (e.g., pain) and when associated with minimization measures, e.g., rescue treatment [39]. Patients randomized to placebo had immediate access to rescue medication to mitigate the risk of under treatment, therefore the placebo group was considered to be ethically justified and was approved by the National Research Ethics Committee, and the decision to include placebo as the comparator was ratified by regulatory agencies. A double-blind, double-dummy study design would have been required for an active comparator, which would have had implications in terms of the time taken to dispense and administer study medication (when rapid analgesia is required in the ED), and also in terms of affecting the provision of rescue analgesia. Despite the lack of active control, the study provided meaningful and clinically relevant results indicating a beneficial clinical effect of methoxyflurane.

In conclusion, consistent with evidence from previous studies, the results of this study show that low-dose methoxyflurane administered via the Penthrox inhaler is an easy to use, well-tolerated, effective and rapid-acting analgesic in the ED setting. Considering its fast onset of action, ease of use and minimal impact on subsequent treatment choices, methoxyflurane may also lend itself as a bridging agent in the pre-hospital/ED setting until it is possible to administer more powerful analgesia if required, and also as a short-term procedural analgesic.