The deleterious effects of uncontrolled pain on patient quality of life are well known, consisting of increased incidence of cardiac, pulmonary, thromboembolic and infectious complications.1,2 Consequently, any issue that might interfere with optimal pain control is of special interest.

A 24-year old female patient, 60kg, 14-week pregnant housewife who sustained multiple gunshot wounds to the abdomen. She was seriously compromised on admission, with hypovolemic shock and 3000cc hemoperitoneum, injuries to the stomach, spleen, splenic flexure and descending colon, and multiple injuries to the proximal jejunum from the first portion posterior to Treitz angle, left kidney and left psoas muscle (through-and-through section).

Damage control surgery was performed consisting of left nephrectomy, splenorrhaphy of the lower pole of the spleen, partial gastrectomy, ligation of the splenic flexure, ligation of portion IV of the duodenum and proximal jejunum, multiple ligations in the mesocolon, cavity lavage, packing of the abdominal cavity and placement of a vacuum system.

Transfusion of multiple red blood cell, plasma, cryoprecipitate and platelet units was required for the management of coagulopathy. The patient was put on vasoactive support and mechanical ventilation.

She was taken to surgery later, with findings of intestinal necrosis in an 80cm portion of the jejunum, ligated openings of the duodenum, distal ileum and transverse and descending colon, requiring side-to-side ileo-duodenal anastomosis, and side-to-side anastomosis of the transverse and descending colon. The abdomen was left open with the vacuum system, and lavage and debridement were required repeatedly because of evidence of necrotizing fasciitis.

The course was torpid, with development of peritonitis secondary to the injuries and then sepsis, requiring prolonged stay in the ICU. The patient developed multiple leaks, abdominal obstruction, short gut and abdominal wall necrosis; she underwent multiple surgical interventions and developed severe abdominal pain that was difficult to control. Initial pain management was instituted by the intensive care team based on fixed-dose opioid escalation and rotation (morphine and hydromorphone), in accordance with a specific time schedule. However, despite this management, the patient continued to experience severe pain with a score always above seven on the pain scale.

An additional difficulty in this patient was a non-functional gastrointestinal tract that limited the use of oral adjuvants and analgesics, compounded by a phenomenon of pseudoaddiction with a negative effect on the rescue provided by nursing and the patient's trust in the healthcare team.

After a consult with the pain team was prompted by this situation, the decision was made to rotate the hourly morphine regimen with unlimited hydromorphone treatment using PCA plus a continuous infusion with 0.1mg/h, associated with paracetamol IV and transdermal fentanyl titrated up to 200mcg and 30mg/day of hydromorphone, with worsening of the symptoms and pain extending to the lumbar region.

No regional techniques were considered given the presence of infectious foci in close proximity of the puncture areas.

The use of methadone was not considered because of its availability only in oral form.

Given the poor response to the therapy, the diagnosis of opioid-induced hyperalgesia was considered. Therefore, opioid tapering was started in association with a continuous infusion of ketamine titrated up to a maximum dose of 0.3mg/kg/h, with slight improvement of the pain score6 but onset of hallucinations. This required discontinuation of this regimen with worsening of the pain score (intensity of 8–10).

It was then decided to initiate combined therapy with continuous infusion of ketamine 0.1mg/kg/h and dexmedetomidine titrated up to 0.5mcg/kg/h, with a dramatic improvement on the pain scale (score of 2–3) and minimum sedation, finally allowing opioid tapering and discontinuation.

Several challenges were faced during the management of this case, including the absence of a functional gastrointestinal tract, the presence of concomitant infection adjacent to the sites that could be used for regional analgesia, and phenomena such as pseudo-addiction, tolerance and hyperalgesia. These challenges were finally overcome by means of careful titration of intravenous medications and slow opioid tapering.

Opioid tolerance and hyperalgesia are related occurrences that may manifest in the context of acute or prolonged opioid treatment,3 and they require different management approaches and often pose a great challenge to pain specialists.4,5

Tolerance is defined as the need for increasing doses of opioids to obtain the same effect.6–9 In this condition, a gradual increase allows to maintain the effect,10 and at the origin there are many pharmacodynamic issues such as internalization of opioid receptors11,12 associated with cytoplasmic destruction and reduced re-expression.11,12 This pharmacodynamic effect may worsen as a result of pharmacokinetic tolerance resulting from interference with opioid absorption and distribution.6

As far as hyperalgesia is concerned, it is a purely pharmacodynamic effect associated with the modulation of the pain pathways towards a pro-nociceptive11–13 state provoked by the opioid itself. It begins, like tolerance, with internalization of the opioid receptor, which tends to be less available as a result of repeated interaction with its ligand.11,12 Moreover, this repeated interaction leads to an up-regulation of excitatory G proteins (it is worth noting that the opioid receptor is coupled to an inhibitor G protein), and this will elicit activation of protein kinases that, in turn, will mediate the influx of calcium into the cell, revert opioid-induced hyperpolarization, and favour the synthesis of NMDA receptor antagonist excitatory neurotransmitters, with the known pro-nociceptive effect.3,7,11–13

Additionally, upregulation of the non-opioid-dependent ascending pain pathways plays a very important role, sometimes overlooked, in the context of tolerance and hyperalgesia. These pathways are divisions of the spinothalamic and thalamocortical tracts that synapse in laminae VI to VIII where opioid receptor populations are minimal or non-existent, instead of synapsing at Rexed lamina II where there is a large concentration of those receptors. This mechanism helps explain, first, the absence of response to high opioid doses and, second, the efficacy of adjuvant analgesics, mainly GABA agonists, which may improve analgesia through modulation of over-excited independent opioid pathways.10

On the other hand, opioids such as morphine may induce, long term, the release of anti-opioid peptides such as dynorphin A,11,12 an NMDA receptor agonist, and exert direct opioid antagonist effects through their own metabolites such as morphine-3-glucoronide.11,12

The phenomena described above activate central pro-nociceptive systems, changing the natural pattern of On-and-Off cell activation in the periaqueductal grey matter and the medulla oblongata, favouring pro-nociceptive pathways.11,12

Clinically, this manifests as diffuse, less defined pain, which usually increases with opioid dose escalation.6,11–13

The therapeutic approach to a patient with increasing pain who has been treated with opioids requires the initial step of ruling out progression of the underlying disease and any pharmacological issues such as tolerance and hyperalgesia.6 It is important to improve on the scarce training of the healthcare staff in the area of pain that results in inadequate pain assessment and a phobia towards opioids. The latter, besides being the result of lack of knowledge, also originates in the fear of addiction and the concern over adverse effects, in particular respiratory depression. However, addiction rarely occurs in the hospital setting, and adverse effects are also rare with judicious dosing and titration of the opioid medication. Nevertheless, opiophobia is a common barrier to the provision of rescue doses and creates a vicious circle of uncontrolled pain with the resulting deleterious effects on quality of life, associated morbidity and pseudoaddiction,6 the latter being characterized by behavioural changes and active seeking of the drug at increasing doses. This creates suspicion by the healthcare staff and leads to lowering of the analgesic dose, creating the vicious circle of increased pain, less analgesia, and worsening of the behavioural changes (Fig. 1).

Fig. 1.

Algorithm for the management of opioid-induced tolerance and hyperalgesia.

(0,17MB).

Source: Authors.

From the pharmacological stand point, management of opioid-related hyperalgesia includes the use of acetaminophen and selective COX-2 antagonists plus NMDA antagonist opioids such as methadone.6,11,12 In this case, these were not used because of the patient's non-functional gastrointestinal tract which would have prevented reliable absorption of these medications, available only in oral form.

Finally, in cases of opioid-induced hyperalgesia, the use of ketamine is of great help because of its NMDA-receptor antagonist effect that also confers anti-hyperalgesic and opioid-sparing properties.11,12,14 The same is true of dexmedetomidine, an alpha-2 agonist with its action on locus ceruleus and spinal cord receptors and sedative, analgesic and anti-hyperalgesic effects. The limitations are excess sedation, bradycardia and hypotension.15 The latter two effects may be attenuated by ketamine, and the therapeutic success will also depend on finding the minimum effective dose through judicious titration.

Opioid tolerance and hyperalgesia are complex occurrences that involve several physiologic, pharmacodynamic and even pharmacokinetic mechanisms ranging from alterations in ligand–reception interactions, activation of pro-nociceptive systems, and upregulation of opioid-independent ascending nociceptive systems. Understanding these mechanisms must be the basis for an adequate therapeutic approach that is successful in relieving pain and suffering.

This case illustrates the complexity of pharmacokinetic and pharmacodynamic interactions in a patient with severe pain, non-functional gastrointestinal tract, exposed to high-dose opioids. It provides elements for making a differential diagnosis in this context, as well as guidelines for instituting an adequate pharmacological strategy.

The authors did not receive sponsorship to undertake this article.

The authors have no conflicts of interest to declare.