Did Internet-purchased diet pills cause serotonin syndrome?

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Did Internet-purchased diet pills cause serotonin syndrome?

Ms. G, age 28, presents to a tertiary care hospital with altered mental status. Six weeks ago she started taking phentermine, 37.5 mg/d, to lose weight. Her body mass index is 24 kg/m2 (normal range), and she obtained the stimulant agent via the Internet. Her family reports Ms. G was very busy in the past week, staying up until 2 AM cleaning. They say she also was irritable with her 5-year-old son.

Two days ago, Ms. G complained of fatigue and nausea without emesis. She went to bed early and did not awaken the next morning. Her sister found her in bed, minimally responsive to verbal stimuli, and brought her to the hospital.

Patients have used phentermine as a weight-reducing agent since the FDA approved this amphetamine-like compound in 1960.1 Phentermine’s mechanism of action is thought to involve dopaminergic, noradrenergic, and serotonergic effects.2 Stimulation of norepinephrine (NE) release is its most potent effect, followed by NE reuptake inhibition, stimulation of dopamine (DA) release, DA reuptake inhibition, stimulation of serotonin (5-HT) release, and 5-HT reuptake inhibition (weak).3

Because phentermine could in theory cause serotonin syndrome,4 its use is contraindicated with monoamine oxidase inhibitors (MAOIs) and not recommended with selective serotonin reuptake inhibitors (SSRIs).5 One case report describes an interaction between fluoxetine and phentermine that appears consistent with serotonin syndrome.6 We are aware of no case reports of serotonin syndrome caused by phentermine alone.

This article reports the case of Ms. G, who presented with probable serotonin syndrome associated with phentermine use and subsequently developed a rapid-onset, superimposed neuroleptic malignant syndrome (NMS). We hypothesize that phentermine use may increase NMS risk through adverse drug events and discuss potential pathophysiologic mechanisms and treatment implications.

Serotonin syndrome vs NMS

Serotonin syndrome is an infrequent and potentially life-threatening adverse drug reaction that presumably results from excess serotonin activity (Box 1).7-10 NMS also is an infrequent and potentially life-threatening neurologic emergency (Box 2).11-18 Similarities between disorders of increased serotonergic activity and disorders of low dopaminergic activity (Table 1) suggest both may result from an imbalance between the serotonergic and dopaminergic systems, which have reciprocal relationships in the CNS.19

Differentiating between serotonin syndrome and NMS is further complicated when both antipsychotics and serotonergic agents may be implicated.20 Clinical trials are not feasible because NMS and serotonin syndrome rarely occur.

Box 1

Serotonin syndrome: Excessive serotonin activity

Sternbach7 first summarized serotonin syndrome’s clinical presentation in a review of 38 cases. The most frequent clinical features include changes in mental status, restlessness, myoclonus, hyperreflexia, diaphoresis, shivering, and tremor (Table 1).

The clinical syndrome varies in scope and intensity. Animal models suggest the pathophysiologic mechanism involves brainstem and spinal cord inundation with serotonin, acting on 5-HT1A and 5-HT2A receptors. Recent evidence supports a greater role for 5-HT2A receptors.8

Primary treatment calls for discontinuing the suspected serotonergic agent and instituting supportive measures. Case reports also suggest using serotonin receptor antagonists—such as cyproheptadine, methysergide, chlorpromazine, or propranolol—to clinically manage serotonin syndrome, although empiric support is limited.9

The syndrome often improves within 24 hours of primary treatment, although confusion sometimes last for days and death has been reported.10

Box 2

NMS: Disorder of low dopaminergic activity

NMS—characterized by fever, extrapyramidal rigidity, and disturbances of autonomic function and consciousness—was first described with the use of haloperidol.11 Risk factors include catatonia, disorganized presentation, and dehydration.12 NMS is thought to result from deficient compensatory mechanisms following blockade of dopaminergic regulation of muscle tone and autonomic function.13

Although possibly idiosyncratic, the reaction has been associated with:

  • intramuscular, higher total dose, or abruptly increasing doses of antipsychotics14
  • withdrawal of dopaminergic agents, such as those used to treat Parkinson’s disease.15

Akin to serotonin syndrome, managing NMS focuses on removing the offending agent(s) and providing supportive care. Severe cases require intensive monitoring, aggressive IV hydration, and respiratory support. Dopaminergics such as bromocriptine16 and skeletal muscle relaxants such as dantrolene17 also have been used to manage NMS.

Unlike serotonin syndrome, NMS often resolves slowly (typically >1 week). NMS’ mortality rate of 11% to 38% appears to be declining in recent years, perhaps because it is being recognized more rapidly.18

Table 1

Signs and symptoms of NMS vs serotonin syndrome

 NMSSerotonin syndrome
OnsetInsidious, days to weeksAcute (minutes to hours)
ResolutionSlow, often >1 weekImprovement or resolution often within 24 hours
AutonomicFever, tachycardia, diaphoresis, elevated or labile blood pressure, sialorrhea, tachypnea, incontinenceDiaphoresis, shivering, fever, tachycardia, hypertension, mydriasis
GastrointestinalDysphagia, elevated transaminasesDiarrhea, nausea, vomiting, elevated ammonia and transaminases
NeuromuscularRigidity, bradykinesia, dysarthria, dyskinesias, coarse tremor, ataxia, opisthotonos, oculogyric crisis, rhabdomyolysisClonus, myoclonus, hyperreflexia, ataxia, incoordination, rigidity, tremor
PsychiatricAltered mental status, stupor, somnolence, mutismAltered mental status, agitation, hypomania, hyperactivity, restlessness, somnolence (less common)
OtherLeukocytosis, elevated creatine kinase (significant), elevated serum creatinine, proteinuria, renal failure, disseminated intravascular coagulationLeukocytosis (rarely >20K cells/mm3), elevated creatine kinase (less common), disseminated intravascular coagulation, metabolic acidosis
NMS: neuroleptic malignant syndrome
Note: Classically reported symptoms are italicized
 

 

CASE CONTINUED: Fever follows haloperidol

Initial workup. Ms. G has no significant medical or psychiatric history. She has no history of seizures, head trauma, changes in mental status, recent travel, tick bites, or mosquito bites. Family history is relevant only for a maternal aunt with a history of 1 seizure. Ms. G is employed and lives with her husband and son. She is not taking other medications, herbal supplements, or vitamins and does not use tobacco, alcohol, caffeine, or illicit drugs.

On admission, she is somnolent and arousable only to painful stimuli. Temperature is 36.7°C, blood pressure 89/58 mm Hg, heart rate 73 bpm, and respirations 21/minute. She does not talk but is cooperative to physical examination, which is otherwise unremarkable.

Neurologic exam also is unremarkable, with no evidence of meningeal irritation, abnormal reflexes, or muscle tone. Serum ammonia (51 µmol/L; normal range 7 to 42 µmol/L) is slightly elevated. Liver function tests, electrolytes, blood urea nitrogen, creatinine, complete blood counts, urinalysis, urine culture, and blood cultures are unremarkable. Ethanol, salicylate, and acetaminophen levels are negative. Evaluation reveals a positive urine drug screen only for amphetamines, attributed to use of phentermine. Chest radiography and head CT are unremarkable.

Electroencephalography (EEG) 17 hours after admission reveals left anterior temporal spikes suggestive of seizure activity lasting 50 seconds. The patient is described as stuporous but arousable during EEG, and diffuse delta slow waves are superimposed on an alpha rhythm with intermittent diffuse delta bursts. Brain MRI is unremarkable.

Despite no clinical evidence of seizure, Ms. G is transferred to the cardiac telemetry ward to monitor for potential side effects from IV phenytoin loading, at which time (24 hours after admission) she is found to have intermittent sinus tachycardia ≤140 bpm.

Antipsychotic therapy. Thirty hours after admission—after phenytoin loading and normalized EEG—Ms. G shows periodic episodes of sudden startling, with repetitive leg shaking. Continuous ankle clonus is present bilaterally. She complains of severe paresthesias in her legs and is unable to urinate on her own.

Because of her altered mental status and prominent lower extremity neurologic signs, MRI of the spine and lumbar puncture are ordered to rule out epidural abscess, meningitis, and/or encephalitis. Results are normal. Because her agitation interfered with these examinations, she was given IV haloperidol, a total 12 mg this day.

NMS signs emerge. Forty-eight hours after admission, Ms. G becomes febrile (38.3°C) and shows tachycardia, with heart rate consistently >130 bpm. Her vital signs did not normalize before the fever developed. She remains somnolent and continues to have spastic lower leg and ankle clonus. She shows no seizure activity on video EEG monitoring during later episodes of repetitive leg shaking, approximately 60 hours after admission.

Ms. G receives empiric vancomycin, ceftriaxone, ampicillin, and acyclovir for possible infectious encephalitis, and lumbar puncture is done emergently. Further laboratory tests reveal creatine kinase (CK) elevation (17,282 U/L, from 270 on admission), leukocytosis (white blood cell count 16.1K/mm3, from 7.2K on admission), and elevated transaminases (AST 199 U/L, up from 21 on admission; ALT 84 U/L, up from 19 on admission).

She is transferred to the ICU with a preliminary diagnosis of NMS. Again, continuous EEG monitoring does not show seizure activity. CSF specimen is negative for infection (negative cultures, negative herpes simplex virus PCR, protein 31 mg/dl, glucose 75 mg/dl). She is started on dantrolene, bromocriptine, and levodopa but shows no initial improvement.

Intubation. On hospital day 8, the patient is intubated to protect her airway and placed in a pentobarbital coma for 2 days, with no improvement. On hospital day 9, cyproheptadine, 24 mg/d, is added for possible serotonin syndrome, and continued for 9 days.

On day 11, the addition of IV diazepam, 10 mg per hour, is followed by gradual improvement in rigidity. Ms. G remains on continuous EEG, with no evidence of seizure activity before diazepam was added or after it is tapered off by day 23.

Discharge. Ms. G is extubated on hospital day 18. On day 23 she can follow commands but is not fully oriented, and levodopa, phenytoin, bromocriptine, and dantrolene are tapered off. She is discharged to a rehabilitation facility, where she again requires phenytoin for a witnessed seizure, attributed to anticonvulsant withdrawal.

On follow-up phone interviews 4 and 18 months after hospitalization, Ms. G says she remains seizure-free without taking anticonvulsants. She reports a subjective, interval improvement in cognitive function, which has since returned to baseline.

 

 

Evidence for serotonin syndrome

This case involves a young woman with a several-week history of phentermine use for weight reduction who presented with confusion, sedation, mutism, and nausea. She was initially found to have an abnormal EEG, for which she was loaded with the anticonvulsant phenytoin. However, she continued to exhibit altered mental status, myoclonus, and hyperreflexia along with autonomic dysregulation—such as urinary retention and tachycardia—despite a negative EEG on continuous monitoring.

On retrospective review, we believe she likely was experiencing serotonin toxicity from phentermine. She later developed NMS within several hours of receiving the antipsychotic haloperidol.

Seizure has been reported with Fen-Phen (fenfluramine and phentermine),21 but not to date with phentermine monotherapy. On the other hand, seizure—often generalized, tonic-clonic in nature—has been reported with serotonin syndrome.22 Partial seizures might explain Ms. G’s initial confusion. However, neuromuscular abnormalities persisted after a normalized EEG, further supporting the diagnosis of serotonin syndrome.

Even though phentermine is thought to have a relatively weak serotonergic effect,3 it has been shown to markedly increase serotonin efflux in the rat hypothalamus (to a greater degree than the SSRI fluoxetine).23 Although Ms. G did not report having consumed foods or supplements that could have interfered with phentermine’s metabolism, such use could have contributed to or prolonged a serotonin syndrome.20 Phentermine misuse also cannot be ruled out.

Excess phentermine or concomitant use of other serotonergic agents may have precipitated serotonin syndrome. Ms. G’s hyperactivity a few days before she complained of fatigue and somnolence may represent:

  • a sign of phentermine intoxication or overuse
  • a harbinger of serotonin syndrome, because these symptoms were followed by overt serotonin syndrome signs such as confusion, disorientation, myoclonus, and autonomic dysfunction.
Features such as slow progression to the full-blown signs and unclear medication history may obscure the clinical picture at presentation in this and similar cases.24

Evidence for NMS

Ms. G received haloperidol because her agitation obstructed urgent evaluation. After several doses, she rapidly developed signs and symptoms highly consistent with NMS. Onset was rapid compared with the typically described, more insidious NMS evolution of 24 to 72 hours, however.25 Rapid NMS onset may have been precipitated in 2 ways:

  • dopaminergic (phentermine) withdrawal combined with dopamine antagonist challenge (haloperidol)25,26
  • background serotonin syndrome caused by amphetamine (phentermine) predisposing the patient to develop NMS.27
For the first possibility, 1 case report has described a narcolepsy patient developing NMS after discontinuing dextroamphetamine, which he had been taking for 16 years.28 NMS also has been observed during withdrawal of dopaminergic medications used in Parkinson’s disease.29 For the second possibility, Kline et al30 reported a similar case of a 45-year-old woman with probable serotonin syndrome who developed NMS after a single neuroleptic dose.

Although phentermine-induced sympathetic hyperactivity also could have predisposed Ms. G to NMS,31 we think this is unlikely because phentermine was discontinued 3 to 4 days before she developed NMS. Nonetheless, sympathetic hyperactivity secondary to phentermine or serotonin syndrome may increase the risk of developing NMS.

Treatment strategy

Because serotonin syndrome and NMS share many clinical findings, differentiating between the 2 syndromes may be difficult, especially when the patient’s medication history does not implicate a specific agent. A detailed history and physical may help distinguish the syndromes. Clonus may be particularly specific and is important in the diagnosis of serotonin syndrome.32 If you are unable to differentiate between serotonin syndrome and NMS in a patient with this acute neurotoxic abnormal behavior syndrome,33 consider a common treatment strategy (Table 2).19,25

In Ms. G’s case, she probably should not have received bromocriptine for NMS,20 given the potential role of serotonin syndrome in precipitating her symptoms.

Case reports support our hypotheses of an increased predilection for NMS with dopaminergic withdrawal or serotonin syndrome. Growing evidence supports the use of chlorpromazine for serotonin syndrome,34 but consider its use contraindicated in patients with NMS.

Table 2

Serotonin syndrome or NMS?
When in doubt, follow 4 management principles

Avoid serotonin agonists and dopamine antagonists when a patient presents with features of serotonin syndrome or neuroleptic malignant syndrome (NMS) and the diagnosis is unclear20
Provide supportive care with monitoring, cooling blankets as needed, and hydration
Avoid using antipsychotics for agitation, when possible; benzodiazepines may be preferable, although their use in NMS is controversial25
Avoid using bromocriptine, given its contraindication in serotonin syndrome, but consider cyproheptadine for the serotonin syndrome component and dantrolene for skeletal muscle rigidity20
 

 

Related resources

  • Carbone JR. The neuroleptic malignant and serotonin syndromes. Emerg Med Clin North Am 2000;18:317-25.
  • Gillman PK. The serotonin syndrome and its treatment. J Psychopharmacol 1999;13:100-9.
  • Neuroleptic Malignant Syndrome Information Service (NMSIS). www.nmsis.org. NMS hotline for medical professionals (toll-free 888-667-8367) handles calls on NMS, serotonin syndrome, heat stroke, malignant catatonia, and other drug-induced heat-related disorders.

Promising New Investigator Kyoung Bin Im, MD

This paper was among those entered in the 2007 Promising New Investigators competition sponsored by the Neuroleptic Malignant Syndrome Information Service (NMSIS). The theme of this year’s competition was “New insights on psychotropic drug safety and side effects.”

Current Psychiatry is honored to publish this peer-reviewed, evidence-based article on a clinically important topic for practicing psychiatrists.

Drug brand names

  • Acyclovir • Zovirax
  • Ampicillin • various
  • Bromocriptine • Parlodel
  • Ceftriaxone • Rocephin
  • Chlorpromazine • Thorazine
  • Cyproheptadine • Periactin
  • Dantrolene • Dantrium
  • Diazepam • Valium
  • Dextroamphetamine • Dexedrine
  • Fluoxetine • Prozac
  • Haloperidol • Haldol
  • Levodopa • various
  • Methysergide • Sansert
  • Pentobarbital • Nembutal
  • Phentermine • various
  • Phenytoin • Dilantin
  • Propranolol • Inderal
  • Vancomycin • various
Disclosure

The authors report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

References

1. Mosby’s Drug Consult, 16th ed. St. Louis, MO: Mosby; 2006.

2. McEvoy G. AHFS drug information. Bethesda, MD: American Society of Health-System Pharmacists; 2006.

3. Rothman RB, Baumann MH, Dersch CM, et al. Amphetamine-type central nervous system stimulants release norepinephrine more potently than they release dopamine and serotonin. Synapse 2001;39:32-41.

4. Ener RA, Meglathery SB, Van Decker WA, Gallagher RM. Serotonin syndrome and other serotonergic disorders. Pain Med 2003;4:63-74.

5. Phentermine hydrochloride. Physicians’ Desk Reference, 53rd ed. Montvale, NJ: Medical Economics; 1999:3055-6.

6. Bostwick JM, Brown TM. A toxic reaction from combining fluoxetine and phentermine. J Clin Psychopharmacol 1996;16:189-90.

7. Sternbach H. The serotonin syndrome. Am J Psychiatry 1991;148(6):705-13.

8. Nisijima K, Yoshino T, Yui K, Katoh S. Potent serotonin (5-HT)(2A) receptor antagonists completely prevent the development of hyperthermia in an animal model of the 5-HT syndrome. Brain Res 2001;890:23-31.

9. Mason PJ, Morris VA, Balcezak TJ. Serotonin syndrome. Presentation of 2 cases and review of the literature. Medicine (Baltimore) 2000;79:201-9.

10. Boyer EW, Shannon M. The serotonin syndrome. N Engl J Med 2005;352:1112-20.

11. Delay J, Pichot P, Lemperiere T, et al. [A non-phenothiazine and non-reserpine major neuroleptic, haloperidol, in the treatment of psychoses.] Ann Med Psychol (Paris). 1960;118:145-52.

12. Berardi D, Dell’Atti M, Amore M, et al. Clinical risk factors for neuroleptic malignant syndrome. Hum Psychopharmacol 2002;17:99-102.

13. Pearlman CA. Neuroleptic malignant syndrome: a review of the literature. J Clin Psychopharmacol 1986;6:257-73.

14. Viejo LF, Morales V, Punal P, et al. Risk factors in neuroleptic malignant syndrome. A case-control study. Acta Psychiatr Scand 2003;107:45-9.

15. Ikebe S, Harada T, Hashimoto T, et al. Prevention and treatment of malignant syndrome in Parkinson’s disease: a consensus statement of the Malignant Syndrome Research Group. Parkinsonism Relat Disord 2003;9(suppl 1):S47-9.

16. Mueller PS, Vester JW, Fermaglich J. Neuroleptic malignant syndrome. Successful treatment with bromocriptine. JAMA 1983;249:386-8.

17. Coons DJ, Hillman FJ, Marshall RW. Treatment of neuroleptic malignant syndrome with dantrolene sodium: a case report. Am J Psychiatry 1982;139:944-5.

18. Spivak B, Maline DI, Kozyrev VN, et al. Frequency of neuroleptic malignant syndrome in a large psychiatric hospital in Moscow. Eur Psychiatry 2000;15:330-3.

19. Gerber PE, Lynd LD. Selective serotonin-reuptake inhibitor-induced movement disorders. Ann Pharmacother 1998;32:692-8.

20. Kaufman KR, Levitt MJ, Schiltz JF, Sunderram J. Neuroleptic malignant syndrome and serotonin syndrome in the critical care setting: case analysis. Ann Clin Psychiatry 2006;18:201-4.

21. Spencer DC, Hwang J, Morrell MJ. Fenfluramine-phentermine (Fen-Phen) and seizures: evidence for an association. Epilepsy Behav 2000;1(6):448-52.

22. Mills KC. Serotonin syndrome. A clinical update. Crit Care Clin 1997;13(4):763-83.

23. Tao R, Fray A, Aspley S, et al. Effects on serotonin in rat hypothalamus of D-fenfluramine, aminorex, phentermine and fluoxetine. Eur J Pharmacol 2002;445(1-2):69-81.

24. Gillman PK. Serotonin syndrome: history and risk. Fundam Clin Pharmacol 1998;12:482-91.

25. Bhanushali MJ, Tuite PJ. The evaluation and management of patients with neuroleptic malignant syndrome. Neurol Clin 2004;22:389-411.

26. Ebadi M, Pfeiffer RF, Murrin LC. Pathogenesis and treatment of neuroleptic malignant syndrome. Gen Pharmacol 1990;21:367-86.

27. Green AR, Cross AJ, Goodwin GM. Review of the pharmacology and clinical pharmacology of 3,4-methylenedioxymethamphetamine (MDMA or “Ecstasy”). Psychopharmacology (Berl) 1995;119:247-60.

28. Chayasirisobhon S, Cullis P, Veeramasuneni RR. Occurrence of neuroleptic malignant syndrome in a narcoleptic patient. Hosp Community Psychiatry 1983;34:548-50.

29. Serrano-Dueñas M. Neuroleptic malignant syndrome-like, or—dopaminergic malignant syndrome—due to levodopa therapy withdrawal. Clinical features in 11 patients. Parkinsonism Relat Disord 2003;9:175-8.

30. Kline SS, Mauro LS, Scala-Barnett DM, Zick D. Serotonin syndrome versus neuroleptic malignant syndrome as a cause of death. Clin Pharm 1989;8(7):510-14.

31. Gurrera RJ. Sympathoadrenal hyperactivity and the etiology of neuroleptic malignant syndrome. Am J Psychiatry 1999;156:169-80.

32. Dunkley EJ, Isbister GK, Sibbritt D, et al. The Hunter Serotonin Toxicity Criteria: simple and accurate diagnostic decision rules for serotonin toxicity. QJM 2003;96:635-42.

33. Fink M. Toxic serotonin syndrome or neuroleptic malignant syndrome? Pharmacopsychiatry 1996;29:159-61.

34. Gillman PK. Serotonin syndrome treated with chlorpromazine. J Clin Psychopharmacol 1997;17:128-9.

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Kyoung Bin Im, MD
Chief resident, internal medicine and psychiatry combined residency program, departments of internal medicine and psychiatry, Roy J. and Lucille A. Carver College of Medicine, University of Iowa, Iowa City

Jess G. Fiedorowicz, MD
Associate in psychiatry, department of psychiatry, Roy J. and Lucille A. Carver College of Medicine, University of Iowa, Iowa City

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Kyoung Bin Im; Jess G. Fiedorowicz; serotonin syndrome; neuroleptic malignant syndrome; phentermine; NMS; serotonin receptor antagonists; fever; extrapyramidal rigidity; altered mental status; serotonin toxicity; fenfluramine; Fen-Phen
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Jess G. Fiedorowicz, MD
Associate in psychiatry, department of psychiatry, Roy J. and Lucille A. Carver College of Medicine, University of Iowa, Iowa City

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Chief resident, internal medicine and psychiatry combined residency program, departments of internal medicine and psychiatry, Roy J. and Lucille A. Carver College of Medicine, University of Iowa, Iowa City

Jess G. Fiedorowicz, MD
Associate in psychiatry, department of psychiatry, Roy J. and Lucille A. Carver College of Medicine, University of Iowa, Iowa City

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Ms. G, age 28, presents to a tertiary care hospital with altered mental status. Six weeks ago she started taking phentermine, 37.5 mg/d, to lose weight. Her body mass index is 24 kg/m2 (normal range), and she obtained the stimulant agent via the Internet. Her family reports Ms. G was very busy in the past week, staying up until 2 AM cleaning. They say she also was irritable with her 5-year-old son.

Two days ago, Ms. G complained of fatigue and nausea without emesis. She went to bed early and did not awaken the next morning. Her sister found her in bed, minimally responsive to verbal stimuli, and brought her to the hospital.

Patients have used phentermine as a weight-reducing agent since the FDA approved this amphetamine-like compound in 1960.1 Phentermine’s mechanism of action is thought to involve dopaminergic, noradrenergic, and serotonergic effects.2 Stimulation of norepinephrine (NE) release is its most potent effect, followed by NE reuptake inhibition, stimulation of dopamine (DA) release, DA reuptake inhibition, stimulation of serotonin (5-HT) release, and 5-HT reuptake inhibition (weak).3

Because phentermine could in theory cause serotonin syndrome,4 its use is contraindicated with monoamine oxidase inhibitors (MAOIs) and not recommended with selective serotonin reuptake inhibitors (SSRIs).5 One case report describes an interaction between fluoxetine and phentermine that appears consistent with serotonin syndrome.6 We are aware of no case reports of serotonin syndrome caused by phentermine alone.

This article reports the case of Ms. G, who presented with probable serotonin syndrome associated with phentermine use and subsequently developed a rapid-onset, superimposed neuroleptic malignant syndrome (NMS). We hypothesize that phentermine use may increase NMS risk through adverse drug events and discuss potential pathophysiologic mechanisms and treatment implications.

Serotonin syndrome vs NMS

Serotonin syndrome is an infrequent and potentially life-threatening adverse drug reaction that presumably results from excess serotonin activity (Box 1).7-10 NMS also is an infrequent and potentially life-threatening neurologic emergency (Box 2).11-18 Similarities between disorders of increased serotonergic activity and disorders of low dopaminergic activity (Table 1) suggest both may result from an imbalance between the serotonergic and dopaminergic systems, which have reciprocal relationships in the CNS.19

Differentiating between serotonin syndrome and NMS is further complicated when both antipsychotics and serotonergic agents may be implicated.20 Clinical trials are not feasible because NMS and serotonin syndrome rarely occur.

Box 1

Serotonin syndrome: Excessive serotonin activity

Sternbach7 first summarized serotonin syndrome’s clinical presentation in a review of 38 cases. The most frequent clinical features include changes in mental status, restlessness, myoclonus, hyperreflexia, diaphoresis, shivering, and tremor (Table 1).

The clinical syndrome varies in scope and intensity. Animal models suggest the pathophysiologic mechanism involves brainstem and spinal cord inundation with serotonin, acting on 5-HT1A and 5-HT2A receptors. Recent evidence supports a greater role for 5-HT2A receptors.8

Primary treatment calls for discontinuing the suspected serotonergic agent and instituting supportive measures. Case reports also suggest using serotonin receptor antagonists—such as cyproheptadine, methysergide, chlorpromazine, or propranolol—to clinically manage serotonin syndrome, although empiric support is limited.9

The syndrome often improves within 24 hours of primary treatment, although confusion sometimes last for days and death has been reported.10

Box 2

NMS: Disorder of low dopaminergic activity

NMS—characterized by fever, extrapyramidal rigidity, and disturbances of autonomic function and consciousness—was first described with the use of haloperidol.11 Risk factors include catatonia, disorganized presentation, and dehydration.12 NMS is thought to result from deficient compensatory mechanisms following blockade of dopaminergic regulation of muscle tone and autonomic function.13

Although possibly idiosyncratic, the reaction has been associated with:

  • intramuscular, higher total dose, or abruptly increasing doses of antipsychotics14
  • withdrawal of dopaminergic agents, such as those used to treat Parkinson’s disease.15

Akin to serotonin syndrome, managing NMS focuses on removing the offending agent(s) and providing supportive care. Severe cases require intensive monitoring, aggressive IV hydration, and respiratory support. Dopaminergics such as bromocriptine16 and skeletal muscle relaxants such as dantrolene17 also have been used to manage NMS.

Unlike serotonin syndrome, NMS often resolves slowly (typically >1 week). NMS’ mortality rate of 11% to 38% appears to be declining in recent years, perhaps because it is being recognized more rapidly.18

Table 1

Signs and symptoms of NMS vs serotonin syndrome

 NMSSerotonin syndrome
OnsetInsidious, days to weeksAcute (minutes to hours)
ResolutionSlow, often >1 weekImprovement or resolution often within 24 hours
AutonomicFever, tachycardia, diaphoresis, elevated or labile blood pressure, sialorrhea, tachypnea, incontinenceDiaphoresis, shivering, fever, tachycardia, hypertension, mydriasis
GastrointestinalDysphagia, elevated transaminasesDiarrhea, nausea, vomiting, elevated ammonia and transaminases
NeuromuscularRigidity, bradykinesia, dysarthria, dyskinesias, coarse tremor, ataxia, opisthotonos, oculogyric crisis, rhabdomyolysisClonus, myoclonus, hyperreflexia, ataxia, incoordination, rigidity, tremor
PsychiatricAltered mental status, stupor, somnolence, mutismAltered mental status, agitation, hypomania, hyperactivity, restlessness, somnolence (less common)
OtherLeukocytosis, elevated creatine kinase (significant), elevated serum creatinine, proteinuria, renal failure, disseminated intravascular coagulationLeukocytosis (rarely >20K cells/mm3), elevated creatine kinase (less common), disseminated intravascular coagulation, metabolic acidosis
NMS: neuroleptic malignant syndrome
Note: Classically reported symptoms are italicized
 

 

CASE CONTINUED: Fever follows haloperidol

Initial workup. Ms. G has no significant medical or psychiatric history. She has no history of seizures, head trauma, changes in mental status, recent travel, tick bites, or mosquito bites. Family history is relevant only for a maternal aunt with a history of 1 seizure. Ms. G is employed and lives with her husband and son. She is not taking other medications, herbal supplements, or vitamins and does not use tobacco, alcohol, caffeine, or illicit drugs.

On admission, she is somnolent and arousable only to painful stimuli. Temperature is 36.7°C, blood pressure 89/58 mm Hg, heart rate 73 bpm, and respirations 21/minute. She does not talk but is cooperative to physical examination, which is otherwise unremarkable.

Neurologic exam also is unremarkable, with no evidence of meningeal irritation, abnormal reflexes, or muscle tone. Serum ammonia (51 µmol/L; normal range 7 to 42 µmol/L) is slightly elevated. Liver function tests, electrolytes, blood urea nitrogen, creatinine, complete blood counts, urinalysis, urine culture, and blood cultures are unremarkable. Ethanol, salicylate, and acetaminophen levels are negative. Evaluation reveals a positive urine drug screen only for amphetamines, attributed to use of phentermine. Chest radiography and head CT are unremarkable.

Electroencephalography (EEG) 17 hours after admission reveals left anterior temporal spikes suggestive of seizure activity lasting 50 seconds. The patient is described as stuporous but arousable during EEG, and diffuse delta slow waves are superimposed on an alpha rhythm with intermittent diffuse delta bursts. Brain MRI is unremarkable.

Despite no clinical evidence of seizure, Ms. G is transferred to the cardiac telemetry ward to monitor for potential side effects from IV phenytoin loading, at which time (24 hours after admission) she is found to have intermittent sinus tachycardia ≤140 bpm.

Antipsychotic therapy. Thirty hours after admission—after phenytoin loading and normalized EEG—Ms. G shows periodic episodes of sudden startling, with repetitive leg shaking. Continuous ankle clonus is present bilaterally. She complains of severe paresthesias in her legs and is unable to urinate on her own.

Because of her altered mental status and prominent lower extremity neurologic signs, MRI of the spine and lumbar puncture are ordered to rule out epidural abscess, meningitis, and/or encephalitis. Results are normal. Because her agitation interfered with these examinations, she was given IV haloperidol, a total 12 mg this day.

NMS signs emerge. Forty-eight hours after admission, Ms. G becomes febrile (38.3°C) and shows tachycardia, with heart rate consistently >130 bpm. Her vital signs did not normalize before the fever developed. She remains somnolent and continues to have spastic lower leg and ankle clonus. She shows no seizure activity on video EEG monitoring during later episodes of repetitive leg shaking, approximately 60 hours after admission.

Ms. G receives empiric vancomycin, ceftriaxone, ampicillin, and acyclovir for possible infectious encephalitis, and lumbar puncture is done emergently. Further laboratory tests reveal creatine kinase (CK) elevation (17,282 U/L, from 270 on admission), leukocytosis (white blood cell count 16.1K/mm3, from 7.2K on admission), and elevated transaminases (AST 199 U/L, up from 21 on admission; ALT 84 U/L, up from 19 on admission).

She is transferred to the ICU with a preliminary diagnosis of NMS. Again, continuous EEG monitoring does not show seizure activity. CSF specimen is negative for infection (negative cultures, negative herpes simplex virus PCR, protein 31 mg/dl, glucose 75 mg/dl). She is started on dantrolene, bromocriptine, and levodopa but shows no initial improvement.

Intubation. On hospital day 8, the patient is intubated to protect her airway and placed in a pentobarbital coma for 2 days, with no improvement. On hospital day 9, cyproheptadine, 24 mg/d, is added for possible serotonin syndrome, and continued for 9 days.

On day 11, the addition of IV diazepam, 10 mg per hour, is followed by gradual improvement in rigidity. Ms. G remains on continuous EEG, with no evidence of seizure activity before diazepam was added or after it is tapered off by day 23.

Discharge. Ms. G is extubated on hospital day 18. On day 23 she can follow commands but is not fully oriented, and levodopa, phenytoin, bromocriptine, and dantrolene are tapered off. She is discharged to a rehabilitation facility, where she again requires phenytoin for a witnessed seizure, attributed to anticonvulsant withdrawal.

On follow-up phone interviews 4 and 18 months after hospitalization, Ms. G says she remains seizure-free without taking anticonvulsants. She reports a subjective, interval improvement in cognitive function, which has since returned to baseline.

 

 

Evidence for serotonin syndrome

This case involves a young woman with a several-week history of phentermine use for weight reduction who presented with confusion, sedation, mutism, and nausea. She was initially found to have an abnormal EEG, for which she was loaded with the anticonvulsant phenytoin. However, she continued to exhibit altered mental status, myoclonus, and hyperreflexia along with autonomic dysregulation—such as urinary retention and tachycardia—despite a negative EEG on continuous monitoring.

On retrospective review, we believe she likely was experiencing serotonin toxicity from phentermine. She later developed NMS within several hours of receiving the antipsychotic haloperidol.

Seizure has been reported with Fen-Phen (fenfluramine and phentermine),21 but not to date with phentermine monotherapy. On the other hand, seizure—often generalized, tonic-clonic in nature—has been reported with serotonin syndrome.22 Partial seizures might explain Ms. G’s initial confusion. However, neuromuscular abnormalities persisted after a normalized EEG, further supporting the diagnosis of serotonin syndrome.

Even though phentermine is thought to have a relatively weak serotonergic effect,3 it has been shown to markedly increase serotonin efflux in the rat hypothalamus (to a greater degree than the SSRI fluoxetine).23 Although Ms. G did not report having consumed foods or supplements that could have interfered with phentermine’s metabolism, such use could have contributed to or prolonged a serotonin syndrome.20 Phentermine misuse also cannot be ruled out.

Excess phentermine or concomitant use of other serotonergic agents may have precipitated serotonin syndrome. Ms. G’s hyperactivity a few days before she complained of fatigue and somnolence may represent:

  • a sign of phentermine intoxication or overuse
  • a harbinger of serotonin syndrome, because these symptoms were followed by overt serotonin syndrome signs such as confusion, disorientation, myoclonus, and autonomic dysfunction.
Features such as slow progression to the full-blown signs and unclear medication history may obscure the clinical picture at presentation in this and similar cases.24

Evidence for NMS

Ms. G received haloperidol because her agitation obstructed urgent evaluation. After several doses, she rapidly developed signs and symptoms highly consistent with NMS. Onset was rapid compared with the typically described, more insidious NMS evolution of 24 to 72 hours, however.25 Rapid NMS onset may have been precipitated in 2 ways:

  • dopaminergic (phentermine) withdrawal combined with dopamine antagonist challenge (haloperidol)25,26
  • background serotonin syndrome caused by amphetamine (phentermine) predisposing the patient to develop NMS.27
For the first possibility, 1 case report has described a narcolepsy patient developing NMS after discontinuing dextroamphetamine, which he had been taking for 16 years.28 NMS also has been observed during withdrawal of dopaminergic medications used in Parkinson’s disease.29 For the second possibility, Kline et al30 reported a similar case of a 45-year-old woman with probable serotonin syndrome who developed NMS after a single neuroleptic dose.

Although phentermine-induced sympathetic hyperactivity also could have predisposed Ms. G to NMS,31 we think this is unlikely because phentermine was discontinued 3 to 4 days before she developed NMS. Nonetheless, sympathetic hyperactivity secondary to phentermine or serotonin syndrome may increase the risk of developing NMS.

Treatment strategy

Because serotonin syndrome and NMS share many clinical findings, differentiating between the 2 syndromes may be difficult, especially when the patient’s medication history does not implicate a specific agent. A detailed history and physical may help distinguish the syndromes. Clonus may be particularly specific and is important in the diagnosis of serotonin syndrome.32 If you are unable to differentiate between serotonin syndrome and NMS in a patient with this acute neurotoxic abnormal behavior syndrome,33 consider a common treatment strategy (Table 2).19,25

In Ms. G’s case, she probably should not have received bromocriptine for NMS,20 given the potential role of serotonin syndrome in precipitating her symptoms.

Case reports support our hypotheses of an increased predilection for NMS with dopaminergic withdrawal or serotonin syndrome. Growing evidence supports the use of chlorpromazine for serotonin syndrome,34 but consider its use contraindicated in patients with NMS.

Table 2

Serotonin syndrome or NMS?
When in doubt, follow 4 management principles

Avoid serotonin agonists and dopamine antagonists when a patient presents with features of serotonin syndrome or neuroleptic malignant syndrome (NMS) and the diagnosis is unclear20
Provide supportive care with monitoring, cooling blankets as needed, and hydration
Avoid using antipsychotics for agitation, when possible; benzodiazepines may be preferable, although their use in NMS is controversial25
Avoid using bromocriptine, given its contraindication in serotonin syndrome, but consider cyproheptadine for the serotonin syndrome component and dantrolene for skeletal muscle rigidity20
 

 

Related resources

  • Carbone JR. The neuroleptic malignant and serotonin syndromes. Emerg Med Clin North Am 2000;18:317-25.
  • Gillman PK. The serotonin syndrome and its treatment. J Psychopharmacol 1999;13:100-9.
  • Neuroleptic Malignant Syndrome Information Service (NMSIS). www.nmsis.org. NMS hotline for medical professionals (toll-free 888-667-8367) handles calls on NMS, serotonin syndrome, heat stroke, malignant catatonia, and other drug-induced heat-related disorders.

Promising New Investigator Kyoung Bin Im, MD

This paper was among those entered in the 2007 Promising New Investigators competition sponsored by the Neuroleptic Malignant Syndrome Information Service (NMSIS). The theme of this year’s competition was “New insights on psychotropic drug safety and side effects.”

Current Psychiatry is honored to publish this peer-reviewed, evidence-based article on a clinically important topic for practicing psychiatrists.

Drug brand names

  • Acyclovir • Zovirax
  • Ampicillin • various
  • Bromocriptine • Parlodel
  • Ceftriaxone • Rocephin
  • Chlorpromazine • Thorazine
  • Cyproheptadine • Periactin
  • Dantrolene • Dantrium
  • Diazepam • Valium
  • Dextroamphetamine • Dexedrine
  • Fluoxetine • Prozac
  • Haloperidol • Haldol
  • Levodopa • various
  • Methysergide • Sansert
  • Pentobarbital • Nembutal
  • Phentermine • various
  • Phenytoin • Dilantin
  • Propranolol • Inderal
  • Vancomycin • various
Disclosure

The authors report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

Ms. G, age 28, presents to a tertiary care hospital with altered mental status. Six weeks ago she started taking phentermine, 37.5 mg/d, to lose weight. Her body mass index is 24 kg/m2 (normal range), and she obtained the stimulant agent via the Internet. Her family reports Ms. G was very busy in the past week, staying up until 2 AM cleaning. They say she also was irritable with her 5-year-old son.

Two days ago, Ms. G complained of fatigue and nausea without emesis. She went to bed early and did not awaken the next morning. Her sister found her in bed, minimally responsive to verbal stimuli, and brought her to the hospital.

Patients have used phentermine as a weight-reducing agent since the FDA approved this amphetamine-like compound in 1960.1 Phentermine’s mechanism of action is thought to involve dopaminergic, noradrenergic, and serotonergic effects.2 Stimulation of norepinephrine (NE) release is its most potent effect, followed by NE reuptake inhibition, stimulation of dopamine (DA) release, DA reuptake inhibition, stimulation of serotonin (5-HT) release, and 5-HT reuptake inhibition (weak).3

Because phentermine could in theory cause serotonin syndrome,4 its use is contraindicated with monoamine oxidase inhibitors (MAOIs) and not recommended with selective serotonin reuptake inhibitors (SSRIs).5 One case report describes an interaction between fluoxetine and phentermine that appears consistent with serotonin syndrome.6 We are aware of no case reports of serotonin syndrome caused by phentermine alone.

This article reports the case of Ms. G, who presented with probable serotonin syndrome associated with phentermine use and subsequently developed a rapid-onset, superimposed neuroleptic malignant syndrome (NMS). We hypothesize that phentermine use may increase NMS risk through adverse drug events and discuss potential pathophysiologic mechanisms and treatment implications.

Serotonin syndrome vs NMS

Serotonin syndrome is an infrequent and potentially life-threatening adverse drug reaction that presumably results from excess serotonin activity (Box 1).7-10 NMS also is an infrequent and potentially life-threatening neurologic emergency (Box 2).11-18 Similarities between disorders of increased serotonergic activity and disorders of low dopaminergic activity (Table 1) suggest both may result from an imbalance between the serotonergic and dopaminergic systems, which have reciprocal relationships in the CNS.19

Differentiating between serotonin syndrome and NMS is further complicated when both antipsychotics and serotonergic agents may be implicated.20 Clinical trials are not feasible because NMS and serotonin syndrome rarely occur.

Box 1

Serotonin syndrome: Excessive serotonin activity

Sternbach7 first summarized serotonin syndrome’s clinical presentation in a review of 38 cases. The most frequent clinical features include changes in mental status, restlessness, myoclonus, hyperreflexia, diaphoresis, shivering, and tremor (Table 1).

The clinical syndrome varies in scope and intensity. Animal models suggest the pathophysiologic mechanism involves brainstem and spinal cord inundation with serotonin, acting on 5-HT1A and 5-HT2A receptors. Recent evidence supports a greater role for 5-HT2A receptors.8

Primary treatment calls for discontinuing the suspected serotonergic agent and instituting supportive measures. Case reports also suggest using serotonin receptor antagonists—such as cyproheptadine, methysergide, chlorpromazine, or propranolol—to clinically manage serotonin syndrome, although empiric support is limited.9

The syndrome often improves within 24 hours of primary treatment, although confusion sometimes last for days and death has been reported.10

Box 2

NMS: Disorder of low dopaminergic activity

NMS—characterized by fever, extrapyramidal rigidity, and disturbances of autonomic function and consciousness—was first described with the use of haloperidol.11 Risk factors include catatonia, disorganized presentation, and dehydration.12 NMS is thought to result from deficient compensatory mechanisms following blockade of dopaminergic regulation of muscle tone and autonomic function.13

Although possibly idiosyncratic, the reaction has been associated with:

  • intramuscular, higher total dose, or abruptly increasing doses of antipsychotics14
  • withdrawal of dopaminergic agents, such as those used to treat Parkinson’s disease.15

Akin to serotonin syndrome, managing NMS focuses on removing the offending agent(s) and providing supportive care. Severe cases require intensive monitoring, aggressive IV hydration, and respiratory support. Dopaminergics such as bromocriptine16 and skeletal muscle relaxants such as dantrolene17 also have been used to manage NMS.

Unlike serotonin syndrome, NMS often resolves slowly (typically >1 week). NMS’ mortality rate of 11% to 38% appears to be declining in recent years, perhaps because it is being recognized more rapidly.18

Table 1

Signs and symptoms of NMS vs serotonin syndrome

 NMSSerotonin syndrome
OnsetInsidious, days to weeksAcute (minutes to hours)
ResolutionSlow, often >1 weekImprovement or resolution often within 24 hours
AutonomicFever, tachycardia, diaphoresis, elevated or labile blood pressure, sialorrhea, tachypnea, incontinenceDiaphoresis, shivering, fever, tachycardia, hypertension, mydriasis
GastrointestinalDysphagia, elevated transaminasesDiarrhea, nausea, vomiting, elevated ammonia and transaminases
NeuromuscularRigidity, bradykinesia, dysarthria, dyskinesias, coarse tremor, ataxia, opisthotonos, oculogyric crisis, rhabdomyolysisClonus, myoclonus, hyperreflexia, ataxia, incoordination, rigidity, tremor
PsychiatricAltered mental status, stupor, somnolence, mutismAltered mental status, agitation, hypomania, hyperactivity, restlessness, somnolence (less common)
OtherLeukocytosis, elevated creatine kinase (significant), elevated serum creatinine, proteinuria, renal failure, disseminated intravascular coagulationLeukocytosis (rarely >20K cells/mm3), elevated creatine kinase (less common), disseminated intravascular coagulation, metabolic acidosis
NMS: neuroleptic malignant syndrome
Note: Classically reported symptoms are italicized
 

 

CASE CONTINUED: Fever follows haloperidol

Initial workup. Ms. G has no significant medical or psychiatric history. She has no history of seizures, head trauma, changes in mental status, recent travel, tick bites, or mosquito bites. Family history is relevant only for a maternal aunt with a history of 1 seizure. Ms. G is employed and lives with her husband and son. She is not taking other medications, herbal supplements, or vitamins and does not use tobacco, alcohol, caffeine, or illicit drugs.

On admission, she is somnolent and arousable only to painful stimuli. Temperature is 36.7°C, blood pressure 89/58 mm Hg, heart rate 73 bpm, and respirations 21/minute. She does not talk but is cooperative to physical examination, which is otherwise unremarkable.

Neurologic exam also is unremarkable, with no evidence of meningeal irritation, abnormal reflexes, or muscle tone. Serum ammonia (51 µmol/L; normal range 7 to 42 µmol/L) is slightly elevated. Liver function tests, electrolytes, blood urea nitrogen, creatinine, complete blood counts, urinalysis, urine culture, and blood cultures are unremarkable. Ethanol, salicylate, and acetaminophen levels are negative. Evaluation reveals a positive urine drug screen only for amphetamines, attributed to use of phentermine. Chest radiography and head CT are unremarkable.

Electroencephalography (EEG) 17 hours after admission reveals left anterior temporal spikes suggestive of seizure activity lasting 50 seconds. The patient is described as stuporous but arousable during EEG, and diffuse delta slow waves are superimposed on an alpha rhythm with intermittent diffuse delta bursts. Brain MRI is unremarkable.

Despite no clinical evidence of seizure, Ms. G is transferred to the cardiac telemetry ward to monitor for potential side effects from IV phenytoin loading, at which time (24 hours after admission) she is found to have intermittent sinus tachycardia ≤140 bpm.

Antipsychotic therapy. Thirty hours after admission—after phenytoin loading and normalized EEG—Ms. G shows periodic episodes of sudden startling, with repetitive leg shaking. Continuous ankle clonus is present bilaterally. She complains of severe paresthesias in her legs and is unable to urinate on her own.

Because of her altered mental status and prominent lower extremity neurologic signs, MRI of the spine and lumbar puncture are ordered to rule out epidural abscess, meningitis, and/or encephalitis. Results are normal. Because her agitation interfered with these examinations, she was given IV haloperidol, a total 12 mg this day.

NMS signs emerge. Forty-eight hours after admission, Ms. G becomes febrile (38.3°C) and shows tachycardia, with heart rate consistently >130 bpm. Her vital signs did not normalize before the fever developed. She remains somnolent and continues to have spastic lower leg and ankle clonus. She shows no seizure activity on video EEG monitoring during later episodes of repetitive leg shaking, approximately 60 hours after admission.

Ms. G receives empiric vancomycin, ceftriaxone, ampicillin, and acyclovir for possible infectious encephalitis, and lumbar puncture is done emergently. Further laboratory tests reveal creatine kinase (CK) elevation (17,282 U/L, from 270 on admission), leukocytosis (white blood cell count 16.1K/mm3, from 7.2K on admission), and elevated transaminases (AST 199 U/L, up from 21 on admission; ALT 84 U/L, up from 19 on admission).

She is transferred to the ICU with a preliminary diagnosis of NMS. Again, continuous EEG monitoring does not show seizure activity. CSF specimen is negative for infection (negative cultures, negative herpes simplex virus PCR, protein 31 mg/dl, glucose 75 mg/dl). She is started on dantrolene, bromocriptine, and levodopa but shows no initial improvement.

Intubation. On hospital day 8, the patient is intubated to protect her airway and placed in a pentobarbital coma for 2 days, with no improvement. On hospital day 9, cyproheptadine, 24 mg/d, is added for possible serotonin syndrome, and continued for 9 days.

On day 11, the addition of IV diazepam, 10 mg per hour, is followed by gradual improvement in rigidity. Ms. G remains on continuous EEG, with no evidence of seizure activity before diazepam was added or after it is tapered off by day 23.

Discharge. Ms. G is extubated on hospital day 18. On day 23 she can follow commands but is not fully oriented, and levodopa, phenytoin, bromocriptine, and dantrolene are tapered off. She is discharged to a rehabilitation facility, where she again requires phenytoin for a witnessed seizure, attributed to anticonvulsant withdrawal.

On follow-up phone interviews 4 and 18 months after hospitalization, Ms. G says she remains seizure-free without taking anticonvulsants. She reports a subjective, interval improvement in cognitive function, which has since returned to baseline.

 

 

Evidence for serotonin syndrome

This case involves a young woman with a several-week history of phentermine use for weight reduction who presented with confusion, sedation, mutism, and nausea. She was initially found to have an abnormal EEG, for which she was loaded with the anticonvulsant phenytoin. However, she continued to exhibit altered mental status, myoclonus, and hyperreflexia along with autonomic dysregulation—such as urinary retention and tachycardia—despite a negative EEG on continuous monitoring.

On retrospective review, we believe she likely was experiencing serotonin toxicity from phentermine. She later developed NMS within several hours of receiving the antipsychotic haloperidol.

Seizure has been reported with Fen-Phen (fenfluramine and phentermine),21 but not to date with phentermine monotherapy. On the other hand, seizure—often generalized, tonic-clonic in nature—has been reported with serotonin syndrome.22 Partial seizures might explain Ms. G’s initial confusion. However, neuromuscular abnormalities persisted after a normalized EEG, further supporting the diagnosis of serotonin syndrome.

Even though phentermine is thought to have a relatively weak serotonergic effect,3 it has been shown to markedly increase serotonin efflux in the rat hypothalamus (to a greater degree than the SSRI fluoxetine).23 Although Ms. G did not report having consumed foods or supplements that could have interfered with phentermine’s metabolism, such use could have contributed to or prolonged a serotonin syndrome.20 Phentermine misuse also cannot be ruled out.

Excess phentermine or concomitant use of other serotonergic agents may have precipitated serotonin syndrome. Ms. G’s hyperactivity a few days before she complained of fatigue and somnolence may represent:

  • a sign of phentermine intoxication or overuse
  • a harbinger of serotonin syndrome, because these symptoms were followed by overt serotonin syndrome signs such as confusion, disorientation, myoclonus, and autonomic dysfunction.
Features such as slow progression to the full-blown signs and unclear medication history may obscure the clinical picture at presentation in this and similar cases.24

Evidence for NMS

Ms. G received haloperidol because her agitation obstructed urgent evaluation. After several doses, she rapidly developed signs and symptoms highly consistent with NMS. Onset was rapid compared with the typically described, more insidious NMS evolution of 24 to 72 hours, however.25 Rapid NMS onset may have been precipitated in 2 ways:

  • dopaminergic (phentermine) withdrawal combined with dopamine antagonist challenge (haloperidol)25,26
  • background serotonin syndrome caused by amphetamine (phentermine) predisposing the patient to develop NMS.27
For the first possibility, 1 case report has described a narcolepsy patient developing NMS after discontinuing dextroamphetamine, which he had been taking for 16 years.28 NMS also has been observed during withdrawal of dopaminergic medications used in Parkinson’s disease.29 For the second possibility, Kline et al30 reported a similar case of a 45-year-old woman with probable serotonin syndrome who developed NMS after a single neuroleptic dose.

Although phentermine-induced sympathetic hyperactivity also could have predisposed Ms. G to NMS,31 we think this is unlikely because phentermine was discontinued 3 to 4 days before she developed NMS. Nonetheless, sympathetic hyperactivity secondary to phentermine or serotonin syndrome may increase the risk of developing NMS.

Treatment strategy

Because serotonin syndrome and NMS share many clinical findings, differentiating between the 2 syndromes may be difficult, especially when the patient’s medication history does not implicate a specific agent. A detailed history and physical may help distinguish the syndromes. Clonus may be particularly specific and is important in the diagnosis of serotonin syndrome.32 If you are unable to differentiate between serotonin syndrome and NMS in a patient with this acute neurotoxic abnormal behavior syndrome,33 consider a common treatment strategy (Table 2).19,25

In Ms. G’s case, she probably should not have received bromocriptine for NMS,20 given the potential role of serotonin syndrome in precipitating her symptoms.

Case reports support our hypotheses of an increased predilection for NMS with dopaminergic withdrawal or serotonin syndrome. Growing evidence supports the use of chlorpromazine for serotonin syndrome,34 but consider its use contraindicated in patients with NMS.

Table 2

Serotonin syndrome or NMS?
When in doubt, follow 4 management principles

Avoid serotonin agonists and dopamine antagonists when a patient presents with features of serotonin syndrome or neuroleptic malignant syndrome (NMS) and the diagnosis is unclear20
Provide supportive care with monitoring, cooling blankets as needed, and hydration
Avoid using antipsychotics for agitation, when possible; benzodiazepines may be preferable, although their use in NMS is controversial25
Avoid using bromocriptine, given its contraindication in serotonin syndrome, but consider cyproheptadine for the serotonin syndrome component and dantrolene for skeletal muscle rigidity20
 

 

Related resources

  • Carbone JR. The neuroleptic malignant and serotonin syndromes. Emerg Med Clin North Am 2000;18:317-25.
  • Gillman PK. The serotonin syndrome and its treatment. J Psychopharmacol 1999;13:100-9.
  • Neuroleptic Malignant Syndrome Information Service (NMSIS). www.nmsis.org. NMS hotline for medical professionals (toll-free 888-667-8367) handles calls on NMS, serotonin syndrome, heat stroke, malignant catatonia, and other drug-induced heat-related disorders.

Promising New Investigator Kyoung Bin Im, MD

This paper was among those entered in the 2007 Promising New Investigators competition sponsored by the Neuroleptic Malignant Syndrome Information Service (NMSIS). The theme of this year’s competition was “New insights on psychotropic drug safety and side effects.”

Current Psychiatry is honored to publish this peer-reviewed, evidence-based article on a clinically important topic for practicing psychiatrists.

Drug brand names

  • Acyclovir • Zovirax
  • Ampicillin • various
  • Bromocriptine • Parlodel
  • Ceftriaxone • Rocephin
  • Chlorpromazine • Thorazine
  • Cyproheptadine • Periactin
  • Dantrolene • Dantrium
  • Diazepam • Valium
  • Dextroamphetamine • Dexedrine
  • Fluoxetine • Prozac
  • Haloperidol • Haldol
  • Levodopa • various
  • Methysergide • Sansert
  • Pentobarbital • Nembutal
  • Phentermine • various
  • Phenytoin • Dilantin
  • Propranolol • Inderal
  • Vancomycin • various
Disclosure

The authors report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

References

1. Mosby’s Drug Consult, 16th ed. St. Louis, MO: Mosby; 2006.

2. McEvoy G. AHFS drug information. Bethesda, MD: American Society of Health-System Pharmacists; 2006.

3. Rothman RB, Baumann MH, Dersch CM, et al. Amphetamine-type central nervous system stimulants release norepinephrine more potently than they release dopamine and serotonin. Synapse 2001;39:32-41.

4. Ener RA, Meglathery SB, Van Decker WA, Gallagher RM. Serotonin syndrome and other serotonergic disorders. Pain Med 2003;4:63-74.

5. Phentermine hydrochloride. Physicians’ Desk Reference, 53rd ed. Montvale, NJ: Medical Economics; 1999:3055-6.

6. Bostwick JM, Brown TM. A toxic reaction from combining fluoxetine and phentermine. J Clin Psychopharmacol 1996;16:189-90.

7. Sternbach H. The serotonin syndrome. Am J Psychiatry 1991;148(6):705-13.

8. Nisijima K, Yoshino T, Yui K, Katoh S. Potent serotonin (5-HT)(2A) receptor antagonists completely prevent the development of hyperthermia in an animal model of the 5-HT syndrome. Brain Res 2001;890:23-31.

9. Mason PJ, Morris VA, Balcezak TJ. Serotonin syndrome. Presentation of 2 cases and review of the literature. Medicine (Baltimore) 2000;79:201-9.

10. Boyer EW, Shannon M. The serotonin syndrome. N Engl J Med 2005;352:1112-20.

11. Delay J, Pichot P, Lemperiere T, et al. [A non-phenothiazine and non-reserpine major neuroleptic, haloperidol, in the treatment of psychoses.] Ann Med Psychol (Paris). 1960;118:145-52.

12. Berardi D, Dell’Atti M, Amore M, et al. Clinical risk factors for neuroleptic malignant syndrome. Hum Psychopharmacol 2002;17:99-102.

13. Pearlman CA. Neuroleptic malignant syndrome: a review of the literature. J Clin Psychopharmacol 1986;6:257-73.

14. Viejo LF, Morales V, Punal P, et al. Risk factors in neuroleptic malignant syndrome. A case-control study. Acta Psychiatr Scand 2003;107:45-9.

15. Ikebe S, Harada T, Hashimoto T, et al. Prevention and treatment of malignant syndrome in Parkinson’s disease: a consensus statement of the Malignant Syndrome Research Group. Parkinsonism Relat Disord 2003;9(suppl 1):S47-9.

16. Mueller PS, Vester JW, Fermaglich J. Neuroleptic malignant syndrome. Successful treatment with bromocriptine. JAMA 1983;249:386-8.

17. Coons DJ, Hillman FJ, Marshall RW. Treatment of neuroleptic malignant syndrome with dantrolene sodium: a case report. Am J Psychiatry 1982;139:944-5.

18. Spivak B, Maline DI, Kozyrev VN, et al. Frequency of neuroleptic malignant syndrome in a large psychiatric hospital in Moscow. Eur Psychiatry 2000;15:330-3.

19. Gerber PE, Lynd LD. Selective serotonin-reuptake inhibitor-induced movement disorders. Ann Pharmacother 1998;32:692-8.

20. Kaufman KR, Levitt MJ, Schiltz JF, Sunderram J. Neuroleptic malignant syndrome and serotonin syndrome in the critical care setting: case analysis. Ann Clin Psychiatry 2006;18:201-4.

21. Spencer DC, Hwang J, Morrell MJ. Fenfluramine-phentermine (Fen-Phen) and seizures: evidence for an association. Epilepsy Behav 2000;1(6):448-52.

22. Mills KC. Serotonin syndrome. A clinical update. Crit Care Clin 1997;13(4):763-83.

23. Tao R, Fray A, Aspley S, et al. Effects on serotonin in rat hypothalamus of D-fenfluramine, aminorex, phentermine and fluoxetine. Eur J Pharmacol 2002;445(1-2):69-81.

24. Gillman PK. Serotonin syndrome: history and risk. Fundam Clin Pharmacol 1998;12:482-91.

25. Bhanushali MJ, Tuite PJ. The evaluation and management of patients with neuroleptic malignant syndrome. Neurol Clin 2004;22:389-411.

26. Ebadi M, Pfeiffer RF, Murrin LC. Pathogenesis and treatment of neuroleptic malignant syndrome. Gen Pharmacol 1990;21:367-86.

27. Green AR, Cross AJ, Goodwin GM. Review of the pharmacology and clinical pharmacology of 3,4-methylenedioxymethamphetamine (MDMA or “Ecstasy”). Psychopharmacology (Berl) 1995;119:247-60.

28. Chayasirisobhon S, Cullis P, Veeramasuneni RR. Occurrence of neuroleptic malignant syndrome in a narcoleptic patient. Hosp Community Psychiatry 1983;34:548-50.

29. Serrano-Dueñas M. Neuroleptic malignant syndrome-like, or—dopaminergic malignant syndrome—due to levodopa therapy withdrawal. Clinical features in 11 patients. Parkinsonism Relat Disord 2003;9:175-8.

30. Kline SS, Mauro LS, Scala-Barnett DM, Zick D. Serotonin syndrome versus neuroleptic malignant syndrome as a cause of death. Clin Pharm 1989;8(7):510-14.

31. Gurrera RJ. Sympathoadrenal hyperactivity and the etiology of neuroleptic malignant syndrome. Am J Psychiatry 1999;156:169-80.

32. Dunkley EJ, Isbister GK, Sibbritt D, et al. The Hunter Serotonin Toxicity Criteria: simple and accurate diagnostic decision rules for serotonin toxicity. QJM 2003;96:635-42.

33. Fink M. Toxic serotonin syndrome or neuroleptic malignant syndrome? Pharmacopsychiatry 1996;29:159-61.

34. Gillman PK. Serotonin syndrome treated with chlorpromazine. J Clin Psychopharmacol 1997;17:128-9.

References

1. Mosby’s Drug Consult, 16th ed. St. Louis, MO: Mosby; 2006.

2. McEvoy G. AHFS drug information. Bethesda, MD: American Society of Health-System Pharmacists; 2006.

3. Rothman RB, Baumann MH, Dersch CM, et al. Amphetamine-type central nervous system stimulants release norepinephrine more potently than they release dopamine and serotonin. Synapse 2001;39:32-41.

4. Ener RA, Meglathery SB, Van Decker WA, Gallagher RM. Serotonin syndrome and other serotonergic disorders. Pain Med 2003;4:63-74.

5. Phentermine hydrochloride. Physicians’ Desk Reference, 53rd ed. Montvale, NJ: Medical Economics; 1999:3055-6.

6. Bostwick JM, Brown TM. A toxic reaction from combining fluoxetine and phentermine. J Clin Psychopharmacol 1996;16:189-90.

7. Sternbach H. The serotonin syndrome. Am J Psychiatry 1991;148(6):705-13.

8. Nisijima K, Yoshino T, Yui K, Katoh S. Potent serotonin (5-HT)(2A) receptor antagonists completely prevent the development of hyperthermia in an animal model of the 5-HT syndrome. Brain Res 2001;890:23-31.

9. Mason PJ, Morris VA, Balcezak TJ. Serotonin syndrome. Presentation of 2 cases and review of the literature. Medicine (Baltimore) 2000;79:201-9.

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Current Psychiatry - 07(07)
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Current Psychiatry - 07(07)
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67-78
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67-78
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Did Internet-purchased diet pills cause serotonin syndrome?
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Did Internet-purchased diet pills cause serotonin syndrome?
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Kyoung Bin Im; Jess G. Fiedorowicz; serotonin syndrome; neuroleptic malignant syndrome; phentermine; NMS; serotonin receptor antagonists; fever; extrapyramidal rigidity; altered mental status; serotonin toxicity; fenfluramine; Fen-Phen
Legacy Keywords
Kyoung Bin Im; Jess G. Fiedorowicz; serotonin syndrome; neuroleptic malignant syndrome; phentermine; NMS; serotonin receptor antagonists; fever; extrapyramidal rigidity; altered mental status; serotonin toxicity; fenfluramine; Fen-Phen
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