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Oral ketamine for the treatment of pain and treatment-resistant depression

Published online by Cambridge University Press:  02 January 2018

Robert A. Schoevers*
Affiliation:
University of Groningen, University Medical Center Groningen, Department of Psychiatry, Research School of Behavioural and Cognitive Neurosciences (BCN), Interdisciplinary Center for Psychopathology and Emotion Regulation (ICPE), Groningen
Tharcila V. Chaves
Affiliation:
University of Groningen, University Medical Center Groningen, Department of Psychiatry, Research School of Behavioural and Cognitive Neurosciences (BCN), Interdisciplinary Center for Psychopathology and Emotion Regulation (ICPE), Groningen
Sonya M. Balukova
Affiliation:
University of Groningen, University Medical Center Groningen, Department of Psychiatry, Research School of Behavioural and Cognitive Neurosciences (BCN), Interdisciplinary Center for Psychopathology and Emotion Regulation (ICPE), Groningen
Marije aan Het Rot
Affiliation:
Department of Psychology and Research School of Behavioral and Cognitive Neurosciences
Rudie Kortekaas
Affiliation:
Department of Psychiatry, Interdisciplinary Center for Psychopathology and Emotion Regulation, Department of Neuroscience, University Medical Center Groningen, University of Groningen, Groningen, The Netherlands
*
Robert A. Schoevers University Medical Center Groningen, Department of Psychiatry, Hanzeplein 1, P.O. Box 30001(CC-11), 9700 RB Groningen, The Netherlands. Email: [email protected]
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Abstract

Background

Recent studies with intravenous (i.v.) application of ketamine show remarkable but short-term success in patients with MDD. Studies in patients with chronic pain have used different ketamine applications for longer time periods. This experience may be relevant for psychiatric indications.

Aims

To review the literature about the dosing regimen, duration, effects and side-effects of oral, intravenous, intranasal and subcutaneous routes of administration of ketamine for treatment-resistant depression and pain.

Method

Searches in PubMed with the terms ‘oral ketamine’, ‘depression’, ‘chronic pain’, ‘neuropathic pain’, ‘intravenous ketamine’, ‘intranasal ketamine’ and ‘subcutaneous ketamine’ yielded 88 articles. We reviewed all papers for information about dosing regimen, number of individuals who received ketamine, number of ketamine days per study, results and side-effects, as well as study quality.

Results

Overall, the methodological strength of studies investigating the antidepressant effects of ketamine was considered low, regardless of the route of administration. The doses for depression were in the lower range compared with studies that investigated analgesic use. Studies on pain suggested that oral ketamine may be acceptable for treatment-resistant depression in terms of tolerability and side-effects.

Conclusions

Oral ketamine, given for longer time periods in the described doses, appears to be well tolerated, but few studies have systematically examined the longer-term negative consequences. The short- and longer-term depression outcomes as well as side-effects need to be studied with rigorous randomised controlled trials.

Type
Review Articles
Copyright
Copyright © Royal College of Psychiatrists, 2016 

The rapid antidepressant action of the glutamatergic N-methyl-d-aspartate (NMDA) receptor antagonist ketamine has kindled great interest and optimism among researchers, clinicians and patients. Reference Vollenweider and Kometer1,Reference Berman, Cappiello, Anand, Oren, Heninger and Charney2 Both open-label studies and small randomised controlled trials (RCTs) in treatment-resistant unipolar or bipolar depression have shown antidepressant effects occurring within hours of intravenous (i.v.) infusion with ketamine. This supports the idea that, besides the monoaminergic systems, the glutamatergic system may also be targeted for the treatment of major depressive disorder (MDD). Reference Hashimoto3 In patients with mood disorders, glutamate levels in the serum and cerebrospinal fluid are altered. Reference Murrough4 Ketamine increases the presynaptic release of glutamate, resulting in higher extracellular levels of glutamate by a combination of disinhibition of the neurotransmitter γ-aminobutyric acid (GABA) and blockage of the NMDA receptors at the phencyclidine binding site within the ion channel. Reference Moghaddam, Adams, Verma and Daly5 This increase in extracellular glutamate release favours coexpressed α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA), resulting in ‘an increased glutamatergic throughput of AMPA relative to NMDA’. Reference Moghaddam, Adams, Verma and Daly5 The glutamatergic system is also fundamental for neuroplasticity, which is linked to mood disorders. Reference Zarate, Machado-Vieira, Henter, Ibrahim, Diazgranados and Salvadore6 NMDA receptor activation is part of the induction process for long-term potentiation, an important form of synaptic plasticity. Synapse-associated proteins and the number of dendritic spines then increase, for example, in the prefrontal cortex, Reference Li, Lee, Liu, Banasr, Dwyer and Iwata7 thus reversing the structural and functional deficits resulting from long-term stress exposure. Reference Li, Liu, Dwyer, Banasr, Lee and Son8

In treatment-resistant unipolar or bipolar depression studies, ketamine has mostly been administered intravenously. Reference aan het Rot, Zarate, Charney and Mathew9 A rapid i.v. infusion of ketamine for treatment-resistant unipolar or bipolar depression, usually at a dose of 0.5 mg/kg, leads to an immediate bioavailability of 100%. To date, six double-blind, crossover RCTs have been published that compared a single dose of i.v. ketamine with placebo. (Five of them used an inactive placebo – saline Reference Berman, Cappiello, Anand, Oren, Heninger and Charney2,Reference Diazgranados, Ibrahim, Brutsche, Newberg, Kronstein and Khalife10Reference Sos, Klirova, Novak, Kohutova, Horacek and Palenicek13 – and one used an active placebo – midazolam. Reference Price, Iosifescu, Murrough, Chang, Al Jurdi and Iqbal14 ) Overall, these studies showed rapid initial effects (40 min after infusion) that increase to 1 day post-infusion, but overall the difference between ketamine and placebo (inactive or active) was no longer statistically significant at 7 days post-infusion. A recent open-label study that compared ketamine with active placebo (midazolam) had a similar effect size of 0.81 at 1 day post-infusion, but again the effect did not last. Reference Murrough, Iosifescu, Chang, Al Jurdi, Green and Perez15 The great challenge with ketamine as an antidepressant is to extend its duration of action.

To study the efficacy of repeated ketamine infusions, a non-blinded study provided six infusions over 2 weeks. After the last infusion, 8 of 9 patients (89%) were in remission. The average time to relapse after the last infusion was much longer than in single injection studies: 19 days (s.d. = 13) after the last infusion. Reference aan het Rot, Collins, Murrough, Perez, Reich and Charney16 Investigators reported no worsening of cognitive function during the follow-up period although this was not formally tested.

Other researchers Reference Ibrahim, Diazgranados, Franco-Chaves, Brutsche, Henter and Kronstein17,Reference Mathew, Murrough, aan het Rot, Collins, Reich and Charney18 have sought to maintain the effect of i.v. ketamine by adding oral riluzole, a glutamatergic modulator with antidepressant and synaptic plasticity-enhancing effects, but this was unsuccessful. Future research should then explore new strategies to optimise the antidepressant response, including dosing regimens and routes of administration. Reference aan het Rot, Zarate, Charney and Mathew9

To date, the field of psychiatry has paid little attention to the experience with oral and other non-intravenous administrations of ketamine for chronic pain. Ketamine is a well-known anaesthetic, with analgesic effects that may be used to treat chronic pain in a range of disorders. Reference Blonk, Koder, van den Bemt and Huygen19 In the field of pain management, there is ample experience with the oral as well as i.v. application of ketamine. Indications for oral ketamine include neuropathic pain of various origins, complex regional pain syndrome, cancer pain, orofacial pain and phantom limb pain. As in depression, the therapeutic effect is believed to be based on antagonism of the NMDA receptor. Reference Fisher, Coderre and Hagen20

This review describes the findings of these studies and combines the fields of pain management and depression, with special attention to safety, dosing regimen and treatment duration.

Method

We searched PubMed with the following terms: ‘oral ketamine’ AND ‘depression’; ‘oral ketamine’ AND ‘chronic pain’ OR ‘neuropathic pain’; ‘intravenous ketamine’ AND ‘depression’; ‘intravenous ketamine’ AND ‘chronic pain’ OR ‘neuropathic pain’; ‘intranasal ketamine’ AND ‘depression’; ‘intranasal ketamine’ AND ‘chronic pain’ OR ‘neuropathic pain’; and ‘subcutaneous ketamine’ AND ‘depression’ and ‘subcutaneous ketamine’ AND ‘chronic pain’ OR ‘neuropathic pain’ (final search date 27 October 2014). Our searches yielded 112 studies. We excluded literature reviews, studies with animals and studies with healthy individuals, thereby yielding 88 studies. We scanned all papers for information about study type and size, dosing regimen, number of individuals who received ketamine, number of ketamine days per study, results and side-effects. When these were described, we entered them into two tables (both available online). Table DS1 refers to the studies where ketamine was used to treat depression and Table DS2 refers to the studies where ketamine was used to treat pain. We designed two graphs with the information provided by those tables (Figs 1 and 2).

Fig. 1 Overview of daily dose of ketamine for treating depression and number of ketamine days. Fifty-two studies about ketamine used to treat depression were included. The x-axis represents the number of ketamine days, which is different from the study duration. (In some studies, only one or few doses were given during a long follow-up time.) The size of the bubbles represents the size of the sample (number of individuals who received ketamine). The numbers close to the bubbles refer to the study identification, which can be found in Table DS1.

Fig. 2 Overview of daily dose of ketamine for treating pain and number of ketamine days. Thirty-six studies about ketamine used for treating pain were included. The x-axis represents the number of ketamine days, which is different from the study duration. (In some studies, only one or few doses were given during a long follow-up time.) The size of the bubbles represents the size of the sample (number of individuals who received ketamine). The numbers close to the bubbles refer to the study identification, which can be found in Table DS2.

In total, for depression 4 studies were found using oral ketamine (n = 22), 43 studies used intravenous ketamine (n = 763), 2 studies used intranasal ketamine (n = 19), 1 study used sublingual ketamine (n = 26), and 2 case reports concerned intramuscular ketamine (n = 3). For pain, 12 studies used oral (n = 76), 21 studies intravenous (n = 553), 2 studies intranasal (n = 21) and 1 study intramuscular ketamine (n = 35). We found only one study on subcutaneous ketamine for pain that met the inclusion criteria, but it presented insufficient data (no dose and no number of ketamine days described), so we excluded it from the analysis. We found no subcutaneous ketamine for depression study. One sublingual ketamine for depression study and three intramuscular ketamine studies (one for pain and two for depression) were included in our analysis.

To compare dosing regimens across studies, we calculated the daily oral racemate equivalent dose, in mg/kg/day, by multiplying the i.v. dose by five to correct for the five times lower average oral bioavailability Reference Clements, Nimmo and Grant21,Reference Chong, Schug, Page-Sharp and Ilett22 and by multiplying the (S)-ketamine dose by two to correct for the double potency relative to racemate. For intranasal dosing regimens, we obtained the daily oral racemate equivalent dose by multiplying them by 2.25 to correct for the 2.25 times lower oral bioavailability. Reference Yanagihara, Ohtani, Kariya, Uchino, Hiraishi and Ashizawa23 In the case of intramuscular dosing regimens, we calculated the daily oral racemate equivalent dose by multiplying them by 4.65 to correct for the 4.65 times lower oral bioavailability. Reference Clements, Nimmo and Grant21 We multiplied the sublingual dose by 1.5 to obtain their daily oral racemate equivalent dose. Reference Yanagihara, Ohtani, Kariya, Uchino, Hiraishi and Ashizawa23

Results

Oral ketamine for depression

Five uncontrolled, open-label studies were found that investigated the antidepressant properties of oral (including sublingual) ketamine. Reference Paslakis, Gilles, Meyer-Lindenberg and Deuschle24Reference De Gioannis and De Leo28 A small study (n = 4) found depression relief in patients with treatment-resistant unipolar or bipolar depression who were given up to 1.25 mg/kg oral (S)-ketamine for 2 weeks. Reference Paslakis, Gilles, Meyer-Lindenberg and Deuschle24 In one study on palliative healthcare, Reference McNulty and Hahn25 the effects of ketamine on pain, anxiety and depression were assessed. This case report described a hospice patient who was treated daily with 40 mg oral ketamine, which relieved all three complaints. Another hospice-based study described two severely ill and depressed patients who showed significant improvements lasting 1 or 2 weeks after a single oral dose of 0.5 mg/kg ketamine. Reference Irwin and Iglewicz26 A more recent hospice-based study administered daily oral ketamine (0.5 mg/kg) over a 28-day period to patients in hospice care who had depressive symptoms. Eight out of 14 patients completed the trial and showed significant improvement in pain and depression with few side-effects. Reference Irwin, Iglewicz, Nelesen, Lo, Carr and Romero27 De Gioannis & De Leo treated two patients with chronic suicidal ideation (and at least two significant past suicide attempts) with a solution of ketamine ingested with a flavoured drink. The maximum dose used was 3 mg/kg of ketamine. Both patients achieved sustained remission from suicidal ideation. Reference De Gioannis and De Leo28

Lara et al reported on 10 mg sublingual ketamine, administered once, or every 2, 3 or 7 days for a total of up to 20 doses. They observed improved mood in 20 out of 26 patients with treatment-resistant unipolar or bipolar depression. The antidepressant effects outlasted the acute side-effects, which primarily concerned light-headedness, and which did not include euphoria or dissociation. Reference Lara, Bisol and Munari29

Clearly, these are only first indications of possible antidepressant effects of oral ketamine, as all of these studies were very small and uncontrolled, and the quality of the evidence was low.

Dosing regimen and treatment duration of ketamine in chronic pain

Figures 1 and 2 show that both for depression and pain most studies used the i.v. route of application. Expressed in daily oral racemate equivalent dose, the doses for depression are in the lower range compared with studies that investigated analgesic use. Also, the graphs show that ketamine as an antidepressant is generally given for shorter durations (1–32 days) than ketamine as an analgesic. Finally, it shows that on average i.v. ketamine is given for a shorter duration than oral ketamine. Studies with oral ketamine, where pain was the primary indication, administered ketamine once Reference Kaviani, Khademi, Ebtehaj and Mohammadi30 or for as long as 660 days, Reference Villanueva-Perez, Cerdá-Olmedo, Samper, Mínguez, Monsalve and Bayona31 with most studies in the range of 20–80 days.

The doses used in the pain studies we analysed differed from the 0.1 daily oral racemate equivalent dose via oral administration Reference Kaviani, Khademi, Ebtehaj and Mohammadi30 to 62.5 mg/kg/day intravenously. Reference Klepstad, Borchgrevink, Hval, Flaat and Kaasa32 It is not possible to establish a dose–response association, but the majority of the pain studies we analysed describe ketamine as effective in reducing pain, even with low oral doses. The exceptions are six studies that used i.v. ketamine, Reference Kapural, Kapural, Bensitel and Sessler33Reference Barreveld, Correll, Liu, Max, McGowan and Shovel38 which did not lead to any reduction in the pain scores. Although the study conducted by Kapural et al used a high dose (daily oral racemate equivalent dose of 21.5 mg/kg/day), it did not achieve an improvement in long-term pain scores in patients with high opioid requirements. Reference Kapural, Kapural, Bensitel and Sessler33

Some studies in patients with chronic pain (that could be progressive or related to terminal illness) showed that patients required higher doses over time. For instance, Villanueva-Perez et al administered 30 mg of oral ketamine every 8 hours to a patient with complex regional pain syndrome type 1, increasing this dose weekly by 5 mg until a maximum dose of 60 mg/6 h was reached. This patient kept this last dose for more than 2 years with significant improvement mainly in the first 17 months. Reference Villanueva-Perez, Cerdá-Olmedo, Samper, Mínguez, Monsalve and Bayona31 Vick & Lamer achieved significant improvement in pain, allodynia and hyperalgesia in one patient with central post-stroke pain at a dose of 50 mg oral ketamine three times per day. This treatment lasted 3 months. Reference Vick and Lamer39 This is in line with preclinical and clinical studies on anaesthesia and studies on ketamine misuse, that suggest that tolerance may develop. Reference Pouget, Wattiez, Rivaud-Péchoux and Gaymard40Reference Cumming45

Clearly, the dosage is directly related to the bioavailability of ketamine. With oral administration the bioavailability is generally low, because of extensive first-pass metabolism. Reference Clements, Nimmo and Grant21 Reported values of oral ketamine in adults are in the range of 17–24%. Reference Clements, Nimmo and Grant21Reference Yanagihara, Ohtani, Kariya, Uchino, Hiraishi and Ashizawa23,Reference Chong, Schug, Page-Sharp, Jenkins and Ilett46 A study by Brunette et al in children showed the highest bioavailability (45%), and used a nasogastric tube and a 10 mL water flush, Reference Brunette, Anderson, Thomas, Wiesner, Herd and Schulein47 but Yanagihara et al also used a water flush (100 mL) and found a bioavailability of only 20% in adults. Reference Yanagihara, Ohtani, Kariya, Uchino, Hiraishi and Ashizawa23 Other factors underlying the variability after oral dosing may include the formulation (tablet or solution, ketamine concentration), state of the stomach, dietary enzyme induction, and individual differences in cytochrome phenotype. It should be noted that interindividual pharmacokinetic variability is common to oral administration in general Reference Zimm, Collins, Riccardi, O'Neill, Narang and Chabner48Reference Di, Kadva, Johnston and Silman50 and has also been described for currently prescribed antidepressants. Reference Lund, Thayssen, Mengel, Pedersen, Kristensen and Gram51 Intranasal and sublingual ketamine administration have been reported to yield 45% and 30% bioavailability, respectively, Reference Yanagihara, Ohtani, Kariya, Uchino, Hiraishi and Ashizawa23 but interindividual variability has been described for these routes of ketamine administration as well. Reference Weber, Wulf, Gruber and Biallas52,Reference Rolan, Lim, Sunderland, Liu and Molnar53 Ketamine absorption after intramuscular injection has been described as more rapid, with a bioavailability of 93%. Reference Clements, Nimmo and Grant21

Safety and abuse potential

The most common side-effects of i.v. ketamine are psychotomimetic effects and dissociative symptoms, Reference Morgan, Muetzelfeldt and Curran54 which correlate with high initial plasma levels and may thus be less pronounced in oral administration. Reference Bowdle, Radant, Cowley, Kharasch, Strassman and Roy-Byrne55 Feeling ‘high’ after ketamine is also dependent on plasma levels. Reference Bowdle, Radant, Cowley, Kharasch, Strassman and Roy-Byrne55 Other known side-effects are confusion, dizziness, euphoria, elevated blood pressure and increased libido, although all of these usually dissipate within 2 h of i.v. infusion. Reference Liebrenz, Borgeat, Leisinger and Stohler56

Ketamine neurotoxicity has been described in preclinical studies, Reference Malinovsky, Cozian, Lepage, Mussini, Pinaud and Souron57 but this was suggested to be due to the presence of the preservative chlorobutanol rather than to the ketamine itself. Reference Malinovsky, Lepage, Cozian, Mussini, Pinaudt and Souron58 Without preservative, ketamine can induce neurotoxicity when injected in very high doses into the subarachnoid space. Reference Gomes, Garcia, Ribamar and Nascimento59 The study by Sun et al showed that i.v. ketamine given to adolescent cynomolgus monkeys at a dose of 1 mg/kg in saline for 6 months might also produce permanent and irreversible deficits in brain function through the neurotoxic effect caused by the activation of the apoptotic pathway in the prefrontal cortex. Reference Sun, Li, Li, Zhang, Liu and Jiang60 This appears to be in contrast with studies in humans where ketamine was given in similar or higher doses with few mentions of cognitive problems. Reference Diazgranados, Ibrahim, Brutsche, Newberg, Kronstein and Khalife10,Reference Zarate, Brutsche, Ibrahim, Franco-Chaves, Diazgranados and Cravchik11 It should be noted that currently available clinical studies with i.v. ketamine used only one or few applications. In the studies involving pain, patients were given ketamine more often but mostly did not have the ‘peak effect’ of i.v. application. Prolonged ketamine misuse has been associated with white matter changes, Reference Edward Roberts, Curran, Friston and Morgan61 memory changes, Reference Freeman, Morgan, Pepper, Howes, Stone and Curran62 neurocognitive impairment Reference Morgan, Muetzelfeldt and Curran54,Reference Morgan and Curran63 and reduced well-being. Reference Morgan, Muetzelfeldt and Curran54 Finally, inflammation and damage to the ureter and bladder are well documented in very heavy ketamine users who consume daily amounts of 1 g by inhalation and for prolonged periods of months or even years. Reference Shahani, Streutker, Dickson and Stewart64,Reference Tsai, Cha, Lin, Tsao, Tang and Chuang65 Notably, in these studies daily doses were substantially higher than those used in clinical studies. Calculated in daily oral racemate equivalent dose, these users had approximately 80 mg/kg/day, which is 2.2 times higher than the highest daily oral racemate equivalent dose found in a study where ketamine was used to treat depression. Reference Correll and Futter66

The majority of the pain and depression studies retrieved by our search did not report the side-effects of oral ketamine as a major burden in treatment maintenance. Side-effects commonly mentioned were: dizziness, hallucinations, nausea, vomiting, drowsiness, confusion, light-headedness, headache, somnolence and anxiety. An exception to this is the study by Kannan et al involving nine patients with neuropathic pain, which stated that the beneficial effects in the management of intractable neuropathic pain were limited in some patients by adverse events such as nausea, vomiting, loss of appetite, drowsiness, sedation and feeling of unreality. Reference Kannan, Saxena, Bhatnagar and Barry67 Haines & Gaines found that ketamine caused an analgesic response in only 14% of individuals and described that the adverse events (light-headedness, dizziness, tiredness, headache, nervous floating feeling and bad dreams) limited the use of ketamine in almost half of their patients. Reference Haines and Gaines68 Side-effects commonly mentioned in studies using oral ketamine were light-headedness or dizziness, nausea, vomiting, drowsiness, confusion, headache, somnolence, and having bad dreams. Hallucinations and paranoid feelings were reported in only one patient, Reference Villanueva-Perez, Cerdá-Olmedo, Samper, Mínguez, Monsalve and Bayona31 and memory impairment and dysuria were reported in one study on 12 patients. Reference Bredlau, McDermott, Adams, Dworkin, Venuto and Fisher69

Very-low-dose sublingual administration of 10 mg (approximately equivalent to 0.036 mg/kg i.v.) was not associated with euphoria, or psychotic and dissociative symptoms. Reference Lara, Bisol and Munari29 In some studies, increased blood pressure was recorded when a benzodiazepine was administered concomitantly. Reference Mercadante, Arcuri, Tirelli and Casuccio70,Reference Schwartzman, Alexander, Grothusen, Paylor, Reichenberger and Perreault71 The reported adverse events were usually limited to the ketamine treatment phase and did not persist after ketamine discontinuation (see online Tables DS1 and DS2 for more details on these side-effects).

Another concern with ketamine is its misuse potential, which has been demonstrated in both animals and humans. Reference Beardsley and Balster72,Reference Klein, Calderon and Hayes73 Ketamine has been used as a street drug since the 1960s, probably because of its rapid effects, its low cost and its specific psychotropic effects, such as hallucinatory and dissociative experiences (e.g. ‘melting into the surrounding’, ‘out-of-body experiences’) as well as ‘giggliness’. Reference Corazza, Assi and Schifano74,Reference Muetzelfeldt, Kamboj, Rees, Taylor, Morgan and Curran75 Multi-drug users who have used ketamine in large doses recreationally have also expressed concerns about its addictive properties. Reference Muetzelfeldt, Kamboj, Rees, Taylor, Morgan and Curran75 No studies compared different routes of ketamine administration directly, but the misuse potential is generally found to be higher with i.v. administration or inhalation that produces much more rapid and intensive effects compared to oral administration. Reference Argoff, Stanos and Wieman76 In line with this, the psychedelic effects of ketamine are directly related to plasma concentrations. Reference Bowdle, Radant, Cowley, Kharasch, Strassman and Roy-Byrne55 Importantly, in the pain studies mentioned earlier, addiction or misuse were not described as side-effects. Still, it is clear that these unwanted effects should be balanced against the possible beneficial properties of ketamine.

Discussion

Overall, the results suggest that oral ketamine in the described doses may be well tolerated. However, few studies have systematically studied its possible longer-term consequences. In comparison with studies of patients with pain, treatment duration in the currently available studies of depression is at the lower end of the spectrum. Further research is needed including basic science, acceptability and feasibility studies, ethical perspectives, and ultimately building to randomised trial designs. A number of issues need to be addressed. First, ketamine raises concerns, such as its potential for misuse, that warrant solid monitoring. Even though our review did not show such problems to be very important in studies on depression and pain, this may be much more of a problem if ketamine were to be used on a broader basis in clinical practice. We fully agree with the cautionary note of Schatzberg, Reference Schatzberg77 who has signalled growing use without good evidence underlying it. It is also in line with the recent Cochrane review by Caddy et al Reference Caddy, Amit, McCloud, Rendell, Furukawa and McShane78 that states that there is a need for studies examining the longer-term effects of repeated use of ketamine that also take into account oral and intramuscular routes. Both the short- and longer-term therapeutic effects as well as the possible side-effects of longer treatment duration of ketamine should be thoroughly assessed and reported before this could be applied on any scale in clinical practice. Reference Schatzberg77

Second, even though the side-effect profile of oral ketamine seems to be milder than that reported in i.v. studies and in severe drug misusers, the overall safety profile would warrant that ketamine should be provided within a hospital setting. After an initial in-patient phase, oral ketamine might, however, be prescribed to depressed patients outside of the hospital environment for maintenance purposes, depending on an assessment of risk for each individual patient. Furthermore, side-effects should systematically be monitored using an instrument such as the Systematic Assessment for Treatment Emergent Events. Reference Levine and Schooler79

Third, oral bioavailability of ketamine is rather low and variable, and studies should take into account blood levels and ketamine formulation. Fourth, as the antidepressant effects of ketamine may partially be related to its anaesthetic potential, especially in depressed patients with pain, a thorough assessment of both depressive symptoms and pain needs to be incorporated into upcoming trials.

Based on the above, we believe it is time to conduct rigorous RCTs that determine the benefits as well as possible unsolicited consequences of oral ketamine, given for weeks rather than days, for patients with treatment-resistant depression.

Acknowledgements

We thank Robert Berman and Lisa Roach of Yale University School of Medicine for help with data mining.

Footnotes

See editorial, pp. 101–103, this issue.

Declaration of interest

None.

References

1 Vollenweider, FX, Kometer, M. The neurobiology of psychedelic drugs: implications for the treatment of mood disorders. Nat Rev Neurosci 2010; 11: 642–51.Google Scholar
2 Berman, RM, Cappiello, A, Anand, A, Oren, DA, Heninger, GR, Charney, DS, et al. Antidepressant effects of ketamine in depressed patients. Biol Psychiatry 2000; 47: 351–4.CrossRefGoogle ScholarPubMed
3 Hashimoto, K. Emerging role of glutamate in the pathophysiology of major depressive disorder. Brain Res Rev 2009; 61: 105–23.Google Scholar
4 Murrough, JW. Ketamine as a novel antidepressant: from synapse to behavior. Clin Pharmacol Ther 2012; 91: 303–9.CrossRefGoogle ScholarPubMed
5 Moghaddam, B, Adams, B, Verma, A, Daly, D. Activation of glutamatergic neurotransmission by ketamine: a novel step in the pathway from NMDA receptor blockade to dopaminergic and cognitive disruptions associated with the prefrontal cortex. J Neurosci 1997; 17: 2921–7.Google Scholar
6 Zarate, C Jr, Machado-Vieira, R, Henter, I, Ibrahim, L, Diazgranados, N, Salvadore, G. Glutamatergic modulators: the future of treating mood disorders? Harv Rev Psychiatry 2010; 18: 293303.CrossRefGoogle ScholarPubMed
7 Li, N, Lee, B, Liu, RJ, Banasr, M, Dwyer, JM, Iwata, M, et al. mTOR-dependent synapse formation underlies the rapid antidepressant effects of NMDA antagonists. Science 2010; 329: 959–64.Google Scholar
8 Li, N, Liu, RJ, Dwyer, JM, Banasr, M, Lee, B, Son, H, et al. Glutamate N-methyl-d-aspartate receptor antagonists rapidly reverse behavioral and synaptic deficits caused by chronic stress exposure. Biol Psychiatry 2011; 69: 754–61.Google Scholar
9 aan het Rot, M, Zarate, CA Jr, Charney, DS, Mathew, SJ. Ketamine for depression: where do we go from here? Biol Psychiatry 2012; 72: 537–47.Google Scholar
10 Diazgranados, N, Ibrahim, L, Brutsche, NE, Newberg, A, Kronstein, P, Khalife, S, et al. A randomized add-on trial of an N-methyl-d-aspartate antagonist in treatment-resistant bipolar depression. Arch Gen Psychiatry 2010; 67: 793802.Google Scholar
11 Zarate, CA Jr, Brutsche, NE, Ibrahim, L, Franco-Chaves, J, Diazgranados, N, Cravchik, A, et al. Replication of ketamine's antidepressant efficacy in bipolar depression: a randomized controlled add-on trial. Biol Psychiatry 2012: 71: 939–46.Google Scholar
12 Zarate, CA Jr, Singh, JB, Carlson, PJ, Brutsche, NE, Ameli, R, Luckenbaugh, DA, et al. A randomized trial of an N-methyl-d-aspartate antagonist in treatment-resistant major depression. Arch Gen Psychiatry 2006; 63: 856–64.Google Scholar
13 Sos, P, Klirova, M, Novak, T, Kohutova, B, Horacek, J, Palenicek, T. Relationship of ketamine's antidepressant and psychotomimetic effects in unipolar depression. Neuro Endocrinol Lett 2013; 34: 287–93.Google ScholarPubMed
14 Price, RB, Iosifescu, DV, Murrough, JW, Chang, LC, Al Jurdi, RK, Iqbal, SZ, et al. Effects of ketamine on explicit and implicit suicidal cognition: a randomized controlled trial in treatment-resistant depression. Depress Anxiety 2014; 31: 335–43.Google Scholar
15 Murrough, JW, Iosifescu, DV, Chang, LC, Al Jurdi, RK, Green, CE, Perez, AM, et al. Antidepressant efficacy of ketamine in treatment-resistant major depression: a two-site randomized controlled trial. Am J Psychiatry 2013; 170: 1134–42.Google Scholar
16 aan het Rot, M, Collins, KA, Murrough, JW, Perez, AM, Reich, DL, Charney, DS, et al. Safety and efficacy of repeated-dose intravenous ketamine for treatment-resistant depression. Biol Psychiatry 2010; 67: 139–45.Google Scholar
17 Ibrahim, L, Diazgranados, N, Franco-Chaves, J, Brutsche, N, Henter, ID, Kronstein, P, et al. Course of improvement in depressive symptoms to a single intravenous infusion of ketamine vs add-on riluzole: results from a 4-week, double-blind, placebo-controlled study. Neuropsychopharmacology 2012; 37: 1526–33.Google Scholar
18 Mathew, SJ, Murrough, JW, aan het Rot, M, Collins, KA, Reich, DL, Charney, DS. Riluzole for relapse prevention following intravenous ketamine in treatment-resistant depression: a pilot randomized, placebo-controlled continuation trial. Int J Neuropsychopharmacol 2010; 13: 7182.Google Scholar
19 Blonk, MI, Koder, BG, van den Bemt, PM, Huygen, FJ. Use of oral ketamine in chronic pain management: a review. Eur J Pain 2010; 14: 466–72.CrossRefGoogle ScholarPubMed
20 Fisher, K, Coderre, TJ, Hagen, NA. Targeting the N-methyl-d-aspartate receptor for chronic pain management. Preclinical animal studies, recent clinical experience and future research directions. J Pain Symptom Manage 2000; 20: 358–73.Google Scholar
21 Clements, JA, Nimmo, WS, Grant, IS. Bioavailability, pharmacokinetics, and analgesic activity of ketamine in humans. J Pharm Sci 1982; 71: 539–42.Google Scholar
22 Chong, CC, Schug, SA, Page-Sharp, M, Ilett, KF. Bioavailability of ketamine after oral or sublingual administration. Pain Medicine 2006; 7: 469.CrossRefGoogle Scholar
23 Yanagihara, Y, Ohtani, M, Kariya, S, Uchino, K, Hiraishi, T, Ashizawa, N, et al. Plasma concentration profiles of ketamine and norketamine after administration of various ketamine preparations to healthy Japanese volunteers. Biopharm Drug Dispos 2003; 24: 3743.Google Scholar
24 Paslakis, G, Gilles, M, Meyer-Lindenberg, A, Deuschle, M. Oral administration of the NMDA receptor antagonist S-ketamine as add-on therapy of depression: a case series. Pharmacopsychiatry 2010; 43: 33–5.CrossRefGoogle ScholarPubMed
25 McNulty, JP, Hahn, K. Compounded oral ketamine. Int J Pharm Compd 2012; 16: 364–8.Google ScholarPubMed
26 Irwin, SA, Iglewicz, A. Oral ketamine for the rapid treatment of depression and anxiety in patients receiving hospice care. J Palliat Med 2010; 13: 903–8.CrossRefGoogle ScholarPubMed
27 Irwin, SA, Iglewicz, A, Nelesen, RA, Lo, JY, Carr, CH, Romero, SD, et al. Daily oral ketamine for the treatment of depression and anxiety in patients receiving hospice care: a 28-day open-label proof-of-concept trial. J Palliat Med 2013; 16: 958–65.Google Scholar
28 De Gioannis, A, De Leo, D. Oral ketamine augmentation for chronic suicidality in treatment-resistant depression. Aust NZ J Psychiatry 2014; 48: 686.CrossRefGoogle ScholarPubMed
29 Lara, DR, Bisol, LW, Munari, LR. Antidepressant, mood stabilizing and procognitive effects of very low dose sublingual ketamine in refractory unipolar and bipolar depression. Int J Neuropsychopharmacol 2013; 16: 2111–7.Google Scholar
30 Kaviani, N, Khademi, A, Ebtehaj, I, Mohammadi, Z. The effect of orally administered ketamine on requirement for anesthetics and postoperative pain in mandibular molar teeth with irreversible pulpitis. J Oral Sci 2011; 53: 461–5.Google Scholar
31 Villanueva-Perez, VL, Cerdá-Olmedo, G, Samper, JM, Mínguez, A, Monsalve, V, Bayona, MJ, et al. Oral ketamine for the treatment of type I complex regional pain syndrome. Pain Pract 2007; 7: 3943.Google Scholar
32 Klepstad, P, Borchgrevink, P, Hval, B, Flaat, S, Kaasa, S. Long-term treatment with ketamine in a 12-year-old girl with severe neuropathic pain caused by a cervical spinal tumor. J Pediatr Hematol Oncol 2001; 23: 616–9.Google Scholar
33 Kapural, L, Kapural, M, Bensitel, T, Sessler, DI. Opioid-sparing effect of intravenous outpatient ketamine infusions appears short-lived in chronic-pain patients with high opioid requirements. Pain Physician 2010; 13: 389–94.Google Scholar
34 Joseph, C, Gaillat, F, Duponq, R, Lieven, R, Baumstarck, K, Thomas, P, et al. Is there any benefit to adding intravenous ketamine to patient-controlled epidural analgesia after thoracic surgery? A randomized double-blind study. Eur J Cardiothorac Surg 2012; 42: e5865.Google Scholar
35 Hu, J, Liao, Q, Zhang, F, Tong, J, Ouyang, W. Chronic postthoracotomy pain and perioperative ketamine infusion. J Pain Palliat Care Pharmacother 2014; 28: 117–21.Google Scholar
36 Tena, B, Gomar, C, Rios, J. Perioperative epidural or intravenous ketamine does not improve the effectiveness of thoracic epidural analgesia for acute and chronic pain after thoracotomy. Clin J Pain 2014; 30: 490500.Google Scholar
37 Yazigi, A, Abou-Zeid, H, Srouji, T, Madi-Jebara, S, Haddad, F, Jabbour, K. The effect of low-dose intravenous ketamine on continuous intercostal analgesia following thoracotomy. Ann Card Anaesth 2012; 15: 32–8.Google Scholar
38 Barreveld, AM, Correll, DJ, Liu, X, Max, B, McGowan, JA, Shovel, L, et al. Ketamine decreases postoperative pain scores in patients taking opioids for chronic pain: results of a prospective, randomized, double-blind study. Pain Med 2013; 14: 925–34.Google Scholar
39 Vick, PG, Lamer, TJ. Treatment of central post-stroke pain with oral ketamine. Pain 2001; 92: 311–3.Google Scholar
40 Pouget, P, Wattiez, N, Rivaud-Péchoux, S, Gaymard, B. Rapid development of tolerance to sub-anaesthetic dose of ketamine: an oculomotor study in macaque monkeys. Psychopharmacology (Berl) 2010; 209: 313–8.Google Scholar
41 Rocha, BA, Ward, AS, Egilmez, Y, Lytle, DA, Emmett-Oglesby, MW. Tolerance to the discriminative stimulus and reinforcing effects of ketamine. Behav Pharmacol 1996; 7: 160–8.Google Scholar
42 Stevens, RW, Hain, WR. Tolerance to rectal ketamine in paediatric anaesthesia. Anaesthesia 1981; 36: 1089–93.Google Scholar
43 Byer, DE, Gould, AB Jr. Development of tolerance to ketamine in an infant undergoing repeated anesthesia. Anesthesiology 1981; 54: 255–6.Google Scholar
44 Livingston, A, Waterman, AE. The development of tolerance to ketamine in rats and the significance of hepatic metabolism. Br J Pharmacol 1978; 64: 63–9.CrossRefGoogle ScholarPubMed
45 Cumming, JF. The development of an acute tolerance to ketamine. Anesth Analg 1976; 55: 788–91.Google Scholar
46 Chong, C, Schug, SA, Page-Sharp, M, Jenkins, B, Ilett, KF. Development of a sublingual/oral formulation of ketamine for use in neuropathic pain: preliminary findings from a three-way randomized, crossover study. Clin Drug Investig 2009; 29: 317–24.Google Scholar
47 Brunette, KE, Anderson, BJ, Thomas, J, Wiesner, L, Herd, DW, Schulein, S. Exploring the pharmacokinetics of oral ketamine in children undergoing burns procedures. Paediatr Anaesth 2011; 21: 653–62.Google Scholar
48 Zimm, S, Collins, JM, Riccardi, R, O'Neill, D, Narang, PK, Chabner, B, et al. Variable bioavailability of oral mercaptopurine. Is maintenance chemotherapy in acute lymphoblastic leukemia being optimally delivered? N Engl J Med 1983; 308: 1005–9.Google Scholar
49 Harvey, VJ, Slevin, ML, Joel, SP, Smythe, MM, Johnston, A, Wrigley, PF. Variable bioavailability following repeated oral doses of etoposide. Eur J Cancer Clin Oncol 1985; 21: 1315–9.Google Scholar
50 Di, WL, Kadva, A, Johnston, A, Silman, R. Variable bioavailability of oral melatonin. N Engl J Med 1997; 336: 1028–9.Google Scholar
51 Lund, J, Thayssen, P, Mengel, H, Pedersen, OL, Kristensen, CB, Gram, LF. Paroxetine: pharmacokinetics and cardiovascular effects after oral and intravenous single doses in man. Acta Pharmacol Toxicol (Copenh) 1982; 51: 351–7.CrossRefGoogle ScholarPubMed
52 Weber, F, Wulf, H, Gruber, M, Biallas, R. S-ketamine and s-norketamine plasma concentrations after nasal and i.v. administration in anesthetized children. Paediatr Anaesth 2004; 14: 983–8.Google Scholar
53 Rolan, P, Lim, S, Sunderland, V, Liu, Y, Molnar, V. The absolute bioavailability of racemic ketamine from a novel sublingual formulation. Br J Clin Pharmacol 2014; 77: 1011–6.Google Scholar
54 Morgan, CJ, Muetzelfeldt, L, Curran, HV. Consequences of chronic ketamine self-administration upon neurocognitive function and psychological wellbeing: a 1-year longitudinal study. Addiction 2010; 105: 121–33.Google Scholar
55 Bowdle, TA, Radant, AD, Cowley, DS, Kharasch, ED, Strassman, RJ, Roy-Byrne, PP. Psychedelic effects of ketamine in healthy volunteers: relationship to steady-state plasma concentrations. Anesthesiology 1998; 88: 82–8.Google Scholar
56 Liebrenz, M, Borgeat, A, Leisinger, R, Stohler, R. Intravenous ketamine therapy in a patient with a treatment-resistant major depression. Swiss Med Wkly 2007; 137: 234–6.Google Scholar
57 Malinovsky, JM, Cozian, A, Lepage, JY, Mussini, JM, Pinaud, M, Souron, R. Ketamine and midazolam neurotoxicity in the rabbit. Anesthesiology 1991; 75: 91–7.Google Scholar
58 Malinovsky, JM, Lepage, JY, Cozian, A, Mussini, JM, Pinaudt, M, Souron, R. Is ketamine or its preservative responsible for neurotoxicity in the rabbit? Anesthesiology 1993; 78: 109–15.Google Scholar
59 Gomes, LM, Garcia, JB, Ribamar, JS Jr, Nascimento, AG. Neurotoxicity of subarachnoid preservative-free S(+)-ketamine in dogs. Pain Physician 2011; 14: 8390.Google ScholarPubMed
60 Sun, L, Li, Q, Li, Q, Zhang, Y, Liu, D, Jiang, H, et al. Chronic ketamine exposure induces permanent impairment of brain functions in adolescent cynomolgus monkeys. Addict Biol 2014; 19: 185–94.CrossRefGoogle ScholarPubMed
61 Edward Roberts, R, Curran, HV, Friston, KJ, Morgan, CJ. Abnormalities in white matter microstructure associated with chronic ketamine use. Neuropsychopharmacology 2014; 39: 329–38.Google Scholar
62 Freeman, TP, Morgan, CJ, Pepper, F, Howes, OD, Stone, JM, Curran, HV. Associative blocking to reward-predicting cues is attenuated in ketamine users but can be modulated by images associated with drug use. Psychopharmacology (Berl) 2013; 225: 4150.Google Scholar
63 Morgan, CJ, Curran, HV, Independent Scientific Committee on Drugs. Ketamine use: a review. Addiction 2012; 107: 2738.Google Scholar
64 Shahani, R, Streutker, C, Dickson, B, Stewart, RJ. Ketamine-associated ulcerative cystitis: a new clinical entity. Urology 2007; 69: 810–2.CrossRefGoogle ScholarPubMed
65 Tsai, TH, Cha, TL, Lin, CM, Tsao, CW, Tang, SH, Chuang, FP, et al. Ketamine-associated bladder dysfunction. Int J Urol 2009; 16: 826–9.Google Scholar
66 Correll, GE, Futter, GE. Two case studies of patients with major depressive disorder given low-dose (subanesthetic) ketamine infusions. Pain Med 2006; 7: 92–5.Google Scholar
67 Kannan, TR, Saxena, A, Bhatnagar, S, Barry, A. Oral ketamine as an adjuvant to oral morphine for neuropathic pain in cancer patients. J Pain Symptom Manage 2002; 23: 60–5.Google Scholar
68 Haines, DR, Gaines, SP. N of 1 randomised controlled trials of oral ketamine in patients with chronic pain. Pain 1999; 83: 283–7.Google Scholar
69 Bredlau, AL, McDermott, MP, Adams, HR, Dworkin, RH, Venuto, C, Fisher, SG, et al. Oral ketamine for children with chronic pain: a pilot phase I study. J Pediatr 2013; 163: 194200.CrossRefGoogle Scholar
70 Mercadante, S, Arcuri, E, Tirelli, W, Casuccio, A. Analgesic effect of intravenous ketamine in cancer patients on morphine therapy: a randomized, controlled, double-blind, crossover, double-dose study. J Pain Symptom Manage 2000; 20: 246–52.Google Scholar
71 Schwartzman, RJ, Alexander, GM, Grothusen, JR, Paylor, T, Reichenberger, E, Perreault, M. Outpatient intravenous ketamine for the treatment of complex regional pain syndrome: a double-blind placebo controlled study. Pain 2009; 147: 107–15.Google Scholar
72 Beardsley, PM, Balster, RL. Behavioral dependence upon phencyclidine and ketamine in the rat. J Pharmacol Exp Ther 1987; 242: 203–11.Google Scholar
73 Klein, M, Calderon, S, Hayes, B. Abuse liability assessment of neuroprotectants. Ann NY Acad Sci 1999; 890: 515–25.Google Scholar
74 Corazza, O, Assi, S, Schifano, F. From “Special K” to “Special M”: the evolution of the recreational use of ketamine and methoxetamine. CNS Neuroscience Ther 2013; 19: 454–60.Google Scholar
75 Muetzelfeldt, L, Kamboj, SK, Rees, H, Taylor, J, Morgan, CJ, Curran, HV. Journey through the K-hole: phenomenological aspects of ketamine use. Drug Alcohol Depend 2008; 95: 219–29.Google Scholar
76 Argoff, CE, Stanos, SP, Wieman, MS. Validity testing of patient objections to acceptance of tamper-resistant opioid formulations. J Pain Res 2013; 6: 367–73.Google Scholar
77 Schatzberg, AF. A word to the wise about ketamine. Am J Psychiatry 2014; 171: 262–4.Google Scholar
78 Caddy, C, Amit, BH, McCloud, TL, Rendell, JM, Furukawa, TA, McShane, R, et al. Ketamine and other glutamate receptor modulators for depression in adults. Cochrane Database Syst Rev 2015; 9: CD011612.Google Scholar
79 Levine, J, Schooler, NR. SAFTEE: a technique for the systematic assessment of side effects in clinical trials. Psychopharmacol Bull 1986; 22: 343–81.Google Scholar
Figure 0

Fig. 1 Overview of daily dose of ketamine for treating depression and number of ketamine days. Fifty-two studies about ketamine used to treat depression were included. The x-axis represents the number of ketamine days, which is different from the study duration. (In some studies, only one or few doses were given during a long follow-up time.) The size of the bubbles represents the size of the sample (number of individuals who received ketamine). The numbers close to the bubbles refer to the study identification, which can be found in Table DS1.

Figure 1

Fig. 2 Overview of daily dose of ketamine for treating pain and number of ketamine days. Thirty-six studies about ketamine used for treating pain were included. The x-axis represents the number of ketamine days, which is different from the study duration. (In some studies, only one or few doses were given during a long follow-up time.) The size of the bubbles represents the size of the sample (number of individuals who received ketamine). The numbers close to the bubbles refer to the study identification, which can be found in Table DS2.

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Table DS1 ketamine for depression studies

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