LEARNING OBJECTIVES

After reading this article you will be able to:

• • contextualise the ongoing burden of opiate dependence

• • better understand the needs of an ageing opioid dependent population

• • recognise treatment gaps for opioid dependent individuals.

Opioid related deaths are making global headlines of late. The USA is described as having an ‘opioid epidemic’ as opioid related drug deaths reach the highest recorded levels. America's heroin deaths increased five-fold between 2010 and 2017, equating to approximately 130 deaths daily and costing $2.5 trillion between 2015 and 2018 (Council of Economic Advisers 2019). Meanwhile in Australia, opioid related deaths have almost doubled over the past 10 years, from 3.8 per 100 000 in 2007 to 6.6 per 100 000 in 2016. The majority of these deaths (65%) were due to prescription opioids alone (Roxburgh Reference Roxburgh, Dobbins and Degenhardt2018).

In the UK, drug-related deaths are also at an all-time high. In 2018 England and Wales had the highest annual increase (16%) in drug-related deaths since records began, the majority of these deaths (51%) involving an opioid (Office for National Statistics 2019). These rates continue to be maintained, with drug-related deaths increasing by 0.8% from 2018–2019 (Public Health England Reference Public Health England2020a). Meanwhile, Scotland is reported to have had the highest number of drug-related deaths per million population of any country in the European Union (National Records of Scotland 2020).

Examining the statistics of drug trends in the UK indicates that opiate users currently make up the largest proportion of individuals accessing treatment in drug and alcohol services, 52% in 2019–2020 (Public Health England Reference Public Health England2020a). More than half of these individuals (58%) are over the age of 40 (Public Health England 2020b). Additionally, there has been a 34% increase in those using opioids over the age of 35 between 2010 and 2017, and 69% of those individuals started using heroin before 2001. This increase in individuals over the age of 35 in treatment is therefore not due to new users entering treatment but is consistent with an ageing opioid-dependent cohort (Public Health England 2019). Although this reflects the success of our treatment of opioid dependence, in that users are staying alive for longer, the deaths of middle-aged heroin users is one of the main drivers for the spike in drug-related deaths (Public Health England 2019). This dispels a commonly held belief that opioid related deaths usually occur from overdose in inexperienced users.

Not only do these statistics indicate that the average age of opiate dependent individuals is on the rise, but additionally that the rate of abstinence is decreasing. Latest data from England shows that those with opiate dependence had the lowest rate of ‘successful exits’ (i.e. leaving treatment opioid-free) in 2019–2020 at 24%, down from 28% in 2015 and from a peak of 37% in 2011–2012. For comparison, the highest rate of ‘successful exits’ was for alcohol, at 59% in 2018 (Public Health England Reference Public Health England2020a).

Taken together, this reflects the trend that has been seen in research and medical treatment for opiate dependence, namely that following the focus on opioid substitution in the 1980s and 1990s, there has been limited scientific or clinical attention paid to either opiate detoxification (detox) or relapse prevention, with consequently limited innovations in recent decades.

In this article, we briefly describe the neurobiology of the opioid system and clinical management of opiate dependence. We then go on to discuss the decline in opiate detoxes, and the aspects of service provision and treatment we feel could be improved. Finally, we provide an update of current research being undertaken in this field.

A note on terminology: although often used interchangeably, the terms opiate and opioid have different meanings which are detailed in Box 1 below.

The opioid system: an overview

The opioid system in the brain is the main target for both endogenous and exogenous opioids (e.g. heroin, morphine). ‘Good’ effects from other substances of misuse, such as alcohol and amphetamines, have been shown to be associated with increases in endogenous opioids in the brain (Colasanti Reference Colasanti, Searle and Long2012; Mitchell Reference Mitchell, O'Neil and Janabi2012). There are three main types of opioid receptor – mu (μ), kappa (κ) and delta (δ) – which are responsible for the range of effects of both exogenous and endogenous opioids (Table 1).

TABLE 1 Opioid receptor effects

The mu-opioid receptor (MOR) is found in various brain regions involved in the reward circuitry, including the ventral tegmental area and ventral striatum. It is thought that effects elicited by this receptor are responsible for the misuse potential and reinforcing properties of opioids. The nucleus accumbens within the ventral striatum receives input from dopaminergic cell bodies in the ventral tegmental area via the mesolimbic pathway, while inhibitory gamma-aminobutyric acid (GABA) neurons project from the nucleus accumbens to the ventral palladium via the striatopallidial pathway (Nutt Reference Nutt and Nestor2013). Opioids produce their effects in the ventral striatum directly by binding to MOR in the ventral striatum or indirectly by binding to MOR on inhibitory GABA neurons, both of which increase dopaminergic neuronal firing.

The MOR is also found in abundance in brain regions that are implicated in emotion processing, motivation and impulsivity, which are cognitive processes shown to be dysregulated in those vulnerable to addiction and once addicted. Positron emission tomography (PET) studies have shown that individuals who report higher trait impulsivity scores have significantly higher MOR numbers in regions such as the amygdala, orbitofrontal cortex and other areas involved in motivated behaviour (Love Reference Love, Stohler and Zubieta2009).

To maintain brain function and homeostasis in the presence of increasing circulating opioids, individuals will develop marked tolerance, namely reduced sensitivity and physical dependence, with repeated and prolonged opioid use. Such neurobiological adaptation is an expected response and seen with other drugs, such as benzodiazepines and alcohol. Thus, an individual can be dependent on a drug but not necessarily ‘addicted’, which is a complex behaviour including difficulty in controlling use and continuing despite harm. The latest changes to the DSM's diagnostic criteria for substance dependence (DSM-5; American Psychiatric Association 2013) reflect this (Box 2). Tolerance in opioid addiction commonly manifests itself as users requiring greater doses to produce the desired pleasant euphoric effects. Although this occurs rapidly, leading to reinforcement and increase of dosage and frequency of drug taking, tolerance for other effects of opioids, such as nausea and respiratory depression, can develop at different rates. For pupillary constriction, tolerance appears limited, thus making it clinically useful for assessing intoxication/withdrawal in addicts. Additionally, not all opioid agonists have the same mechanism and therefore cross-tolerance may be incomplete. This may help to explain why heroin use on top of opioid substitution therapy (e.g. methadone) can still result in fatal respiratory depression (Williams Reference Williams, Christie and Manzoni2001).

Development of physical dependence from regular, chronic use of opioids (including opioid analgesics) will also manifest itself as a withdrawal syndrome in the absence of opioids. Of particular relevance to treatment of opioid withdrawal is the ‘noradrenergic storm’. At the MOR, opioids acutely decrease levels of cyclic adenosine monophosphate (cAMP), and with chronic use this is compensated for by up-regulation of the cAMP pathway so that that pathway returns to a normal level of function in the presence of a circulating opioid. When a circulating opioid is then removed, cAMP levels increase to far above normal levels. Functionally this occurs in the main noradrenaline-containing nucleus in the brain, the locus ceruleus, resulting in an increase in circulating noradrenaline (Nestler Reference Nestler2004). This accounts for some of the symptoms and signs observed in opioid withdrawal (Box 3). Understanding this underlying neurobiology has helped to inform appropriate pharmacological treatments for opioid withdrawal, such as the use of alpha-2 adrenergic agonists in acute withdrawal, which will be discussed in more detail below.

There is evidence to suggest that chronic substance misuse has enduring effects on the endogenous opioid system that may contribute to the relapsing and remitting nature of substance dependence. PET studies using [¹¹C]-diprenorphine to label MOR, KOR and DOR receptors in opioid dependent individuals during early abstinence showed higher [¹¹C]-diprenorphine binding in multiple brain regions compared with controls. This higher binding reflects an increase in opioid receptor availability due to either increased numbers of receptors or reduced circulating endogenous opioids. There was, however, no correlation between craving or withdrawal symptoms and opioid receptor availability (Williams Reference Williams, Daglish and Lingford-Hughes2007). Using the MOR-specific radiotracer [¹¹C]-carfentanil, higher MOR availability in the paralimbic brain regions following abrupt cessation of buprenorphine treatment has been shown in opioid dependent individuals; however, the relationship with craving and withdrawal was not examined (Zubieta Reference Zubieta, Greenwald and Lombardi2000). Whether opioid receptor numbers and activity return to baseline levels following prolonged periods of abstinence from opioids remains unclear.

In keeping with findings of increased MOR binding in opioid dependence, PET studies have found that recently abstinent cocaine users also have higher MOR binding with [¹¹C]-carfentanil in the frontal, anterior cingulate and lateral temporal cortex, which was positively correlated with craving and predictive of relapse (Gorelick Reference Gorelick, Kim and Bencherif2005, Reference Gorelick, Kim and Bencherif2008). Similar findings have been reported for recently abstinent alcohol dependent individuals (Weerts Reference Weerts, Wand and Kuwabara2011). Higher MOR availability has also been positively associated with craving for alcohol in this group (Heinz Reference Heinz, Reimold and Wrase2005). To investigate whether endogenous opioid levels were blunted in addiction our group used [¹¹C]-carfentanil to assess changes in levels following an oral d-amphetamine challenge. We showed that both pathological gamblers and abstinent alcoholics have blunted d-amphetamine-induced endogenous opioid release in various brain regions, including the nucleus accumbens, putamen and frontal lobe (Mick Reference Mick, Myers and Ramos2016; Turton Reference Turton, Myers and Mick2020). Together this suggests that dysregulation of the endogenous opioid system is a feature of various substance and behavioural addictions.

Treatment of opiate dependence

Treatment for opiate dependence initially involves a phase of assessment and stabilisation using opioid substitution therapy (OST) and engagement with services. Following this, ongoing treatment can be broadly categorised as either harm reduction or abstinence oriented. Early access to medication is a key factor in engagement, but developing a strong therapeutic alliance is thought to be more important for long-term recovery (Moos Reference Moos2007).

Where have all the detoxes gone?

As described above, OST in combination with psychosocial interventions remains the mainstay of treatment for opiate dependence. Undoubtedly this ‘harm minimisation approach’ using OST with psychosocial support has been highly effective in improving health and social functioning in opiate addiction (Lingford-Hughes Reference Lingford-Hughes, Welch and Peters2012; Schuckit Reference Schuckit2016; Sordo Reference Sordo, Barrio and Bravo2017). The improvements in infection rates and survival from HIV and hepatitis in particular have been transformative, and overall mortality remains significantly reduced for individuals who are receiving OST compared with those are not in treatment. In a meta-analysis by Sordo et al (Reference Sordo, Barrio and Bravo2017), the out-to-in all-cause mortality rate ratio per 1000 person-years in and out of treatment was found to be 3.20 and 2.20 for methadone and buprenorphine respectively. However, in such studies, those who are not ‘in treatment’ are likely to have dropped out of treatment and to be still using rather than to have left treatment when they are abstinent and in recovery. Understandably then, improving accessibility to OST is a key approach in many parts of the world. However, a typical day in any addiction service will have opiate dependent individuals presenting for treatment and asking to ‘get off all drugs’. It is striking that individuals do not present saying ‘please prescribe me methadone for years’, but that is what often happens.

In England, 94% of opiate dependent individuals engage with services for at least 12 weeks, the highest proportion of all the addictions, which likely reflects the successful provision of OST. This is in direct contrast to opiate dependence having the lowest rate of ‘successful exits’ (i.e. leaving treatment opioid-free), as described above (other reasons for exiting treatment include dropping out, leaving the area, death and transferring to custody). Currently it appears that most detoxifications in England occur in the community. For 2019–2020, 8059 individuals receiving treatment for opiate dependence left either ‘free of dependence’ (840) or with no drug/alcohol use (7219), which would imply that these individuals either had a community detox or slow OST taper. There were only 1427 in-patient detoxifications reported. Given that 140 599 individuals were recorded as receiving treatment for opiate dependence over that period, this suggests that only 5.73% overcame their dependence (Public Health England 2020b).

Contrast this with alcohol dependence, where providing a detox and relapse prevention pathway is generally seen as ‘core business’ for any addiction service. Individuals who are severely alcohol dependent generally require medically assisted withdrawal (i.e. detox) to prevent serious complications. This should be followed by a relapse prevention programme, which might include both pharmacological and psychosocial interventions. In a recent study of alcohol dependent individuals who were followed up 180 days after structured detoxification and rehabilitation, 69.6% had remained abstinent (Ledda Reference Ledda, Battagliese and Attilia2019). The benefits of stopping drinking excessive amounts of alcohol are very clear (Nutt Reference Nutt and Rehm2014), and the absence of an equivalent of OST for alcohol also helps alcohol dependent individuals to concentrate on detox and relapse prevention. This focus has resulted in the development and availability of a range of pharmacological options to support detox and relapse prevention in alcohol dependence (i.e. acamprosate, disulfiram, naltrexone and baclofen). The effectiveness of these adjuncts remains modest, reflecting adherence problems commonly seen with these patients and the complex nature of addiction biology (reviewed in Lingford-Hughes Reference Lingford-Hughes, Welch and Peters2012).

Attention is now focusing on preventing and treating alcohol-related ‘brain damage’ as well as modulating cognitive processes underpinning addictive processes, such as reward, impulsivity and emotion processing. Similar approaches are being pursued for other addictions but rarely is such innovative activity applied to treating opioid addiction.

Current challenges for detoxification and relapse prevention

A range of social, environmental and biological factors are likely to be contributing to the low number of detoxes observed for opiate dependence. Owing to the complexity of the subject we have chosen to focus on three main issues that we believe are underpinning this decline: the culture of long-term OST prescribing, the ‘outcomes’ on the basis of which services are granted funding, and the lack of medications to support detox and relapse prevention. It is worth noting that several other factors are likely contributing to this, particularly in the UK, which has seen significant cuts in government funding to services as well as reduced in-patient services.

Current and future directions

Although psychosocial approaches are the mainstay of treating addiction, we have seen how adjunctive medication can play a vital role in preventing complications, reducing illicit drug use, supporting abstinence or protecting the individual (e.g. an opioid antagonist such as naloxone in opioid overdose). Understanding the underlying neurobiology of addiction is therefore vital to inform developments, particularly of adjunctive medication, to improve outcomes. In particular, there is evidence to show that drug addiction is associated with dysregulation in several neural networks involved in reward, stress and inhibitory control. Pharmacological treatments that might modulate any dysregulation of these systems have been investigated to improve outcomes in alcohol and cocaine addiction but only recently has this approach been applied to opiate addiction.

The National Institute on Drug Abuse recently published its top ten ‘medication development priorities in response to the opioid crisis’: orexin, kappa opioid, nociceptin opioid peptide, GABA-B, muscarinic M5, glutamate (AMPA and mGluR2/3), ghrelin, dopamine D₃ and cannabinoid (Rasmussen Reference Rasmussen, White and Acri2019). This is a welcome development and focuses on ‘the development of novel therapeutics to treat opioid overdose and OUD [opioid use disorder] in the near term’ (emphasis as in original). Thus, medications exist for these targets but are licensed for another indication, so ‘repurposing’ such medications is already underway. It is often fortunate that once a neurobiological target has been identified, a medication with appropriate pharmacological profile is already available to speed up translation, again highlighting the importance of understanding underlying neurobiology.

Final note from the authors

At the time of writing, we are in the midst of the COVID-19 pandemic and witnessing first-hand the effects this is having on patients and service delivery. As services are being restructured to minimise patient contact and therefore reduce the spread of the coronavirus, in the UK opioid detoxes were initially suspended. Community detoxes are now slowly being reintroduced, but services are seeing increased waiting times for in-patient detoxes. There is an emphasis on starting or switching patients from methadone to buprenorphine where possible, with minimal visits to clinic during titration to minimise clinical contact further. However, many patients are still preferring treatment with methadone. OST is being delivered largely ‘unsupervised’, to help people to stay at home, particularly those who are clinically vulnerable, and not to overwhelm pharmacy capacity. Access to the supervised OST we have become so reliant on is becoming increasingly difficult. As we start to recover from this pandemic, there will be an inevitable backlog of issues that will need to be addressed for this population and the need for better detoxes and relapse prevention will be even more pressing.