Disorder
Onset time
Muscular symptom
Other features
Postulated mechanism
Causative agents
Possible treatments
Medication-induced movement disorder
Medication-induced acute dystonia
Hours to a few days
Sustained, involuntary muscle contraction, torticollis, retrocollis, oculogyric crisis, blepharospasm
–
Imbalance of dopaminergic/cholinergic transmission
Neuroleptic dosage increase or decrease in dosage of medication to treat EPS
Anticholinergics, benzodiazepines
Medication-induced acute akathisia
Hours to days
Fidgety movements of the legs, rocking from foot to foot, pacing
Complaints of restlessness and unease
Mesocortical D2 antagonism
Dose reduction, propranolol, benzodiazepines, anticholinergics
Neuroleptic-induced parkinsonims
Weeks
Akinesia, bradykinesia, rigidity, shuffling gait, resting tremor
Masklike facies, postural instability
Postsynaptic striatal D2 antagonism
Dose reduction, anticholinergics, dopamine agonists
Tardive dyskinesia
3 months to years
Late onset involuntary athetoid or choreiform movements, buccolinguomasticatory movements
–
Excess dopaminergic activity
Neuroleptic use for at least a few months
Early recognition, stop offending antipsychotic, cholinergics
Toxin-induced hyperthermia
Neuroleptic malignant syndrome
2–10 days
Lead-pipe rigidity, bradyreflexia
Altered mental status, hyperthermia, autonomic instability, catatonia, mutism
D2 antagonism in striatum, hypothalamus and mesocortex
FGAs (chlorpromazine, haloperidol, fluphenazine), SGAs (clozapine, risperidone, olanzapine, quetiapine), antiemetics (prochlorperazine, promethazine, trimethobenzamide, thiethylperazine, metoclopramide), amoxapine
Early recognition, stop offending drug, cooling, fluid resuscitation, cardiopulmonary support, benzodiazepines, dantrolene, bromocriptine, amantadine, or other direct-acting dopamine agonist, ECT
Serotonin syndrome
Hours (<24)
Clonus, hyperreflexia, fasciculation, tremor
Anxiety, disorientation, psychomotor agitation, hyperalertness, hyperthermia, autonomic hyperactivity, gastrointestinal symptoms
Excessive stimulation of serotoninergic receptors in the peripheral and central nervous system
MAOIs, SSRIs, meperidine, dextromethorphan, TCAs, L-tryptophan, lithium, linezolid, valproate, ondansetron
Cyproheptadine, active cooling
Central anticholinergic syndrome
1 to 2 h
Myoclonus, choreoathetosis
Hypervigilance, agitation, hallucinations, delirium, coma, mydriasis, hyperthermia, tachycardia, hypertension, tachypnea, dry flushed skin, dry mucous membranes, decreased bowel sounds, urinary retention
Central cortical and subcortical muscarinic receptor antagonism
Antihistamines, TCAs, cyclobenzaprine, orphenadrine, antiparkinson agents, antispasmodics, phenothiazines, atropine, scopolamine
Physostigmine, supportive care
Malinant hyperthermia
Minutes to hours (<12 h)
Rigor mortis-like rigidity
Hypercarbia, tachycardia, tachypnea, mixed respiratory and metabolic acidemia, hyperthermia, rhabdomyolysis
AD gene disorder of ryanodine receptor Ca+ channel, uncontrolled release of Ca+ with elevation of intracytyoplasmic Ca + levels, continuous muscle activation, and ATP breakdown. SR Ca+ pump unable to re-sequester Ca+. ATP breakdown further aggravates heat production
Volatile anesthetic agents (halothane, isoflurane, sevoflurane, desflurane), depolarizing neuromuscular blocker (succinylcholine)
Dantrolene, active cooling
Drugs with anticholinergic activity, such as tricyclic antidepressants, antihistamines, phenothiazines, and antiparkinson agents can cause fever by disturbing central hypothalamic function and decreasing peripheral heat dissipation [29–32]. Marked hyperthermia and CAS can occur when these drugs are taken in combination. Anticholinergic medications are a common treatment for FGA extrapyramidal side effects; distinguishing between NMS and CAS by medication history can be difficult in these patients. Direct or indirect serotonin agonists lead to SS and diagnosis of NMS may be also be challenging in patients taking both serotonergic and neuroleptic agents [33]. On the other hand, exposure history is helpful in distinguishing between NMS and MH, a hypermetabolic crisis that occurs when a MH-susceptible individual is administered potent halogenated inhalational anesthetics or succinylcholine. When the history uncovers several possible offending drugs from multiple categories or in the absence of a reliable history, a detailed examination of clinical features can also be useful in differentiating among disorders [34] (Table 39.1).
The Clinical Tetrad of NMS: Clues to Diagnosis and Management Concerns
A review of 222 published cases revealed a common sequence of symptom development in 70.5 % of NMS patients, beginning with mental status changes, followed by muscle rigidity, then hyperthermia, and finally autonomic dysfunction [11]. Appearance of any of these four cardinal signs should prompt early initiation of supportive care with a low threshold for suspicion since NMS complications are severe and occur frequently. A recent analysis of the nationwide inpatient sample (NIS) database was performed, identifying rates of complications, mortality, and outcomes in 1346 patients with NMS from 2002 to 2011 [35]. In-hospital death occurred in 75 (5.6 %) patients and the most prevalent complication was rhabdomyolysis (30.1 %). Universal management of NMS includes immediate discontinuation of the offending drug, or reinstitution in the case of abrupt discontinuation of dopaminergic therapy, correction of dehydration and electrolyte imbalance, controlling the hyperthermia and rigidity, and preventing complications. The need for monitoring in an intensive care unit with expert and robust supportive care is undisputed.
Hyperthermia
Abrupt reduction in dopaminergic transmission in the hypothalamus alters the core temperature set point, leading to impaired thermoregulation in NMS [36]. Blockade of dopamine receptors in the corpus striatum causes muscular rigidity and secondary heat production. While fever is a defining symptom in NMS, many conditions in critically ill patients result in inflammation, tissue injury and a febrile reaction and it may be difficult to determine the etiology of a fever early in the clinical course. Leukocytosis, ranging from 10,000 to 40,000/μL, with or without a “left shift” is a consistent laboratory finding in NMS [37]. Obtaining appropriate cultures should not be avoided although approximately half of febrile patients in the intensive care unit (ICU) will have a non-infectious cause of fever, with most no greater than 38.9 °C (102 °F) [38]. A fever in excess of 38.9 °C (102 °F) is usually of an infectious etiology, though a transfusion reaction or a drug fever may also trigger temperatures exceeding 102 °F [39]. In patients with a temperature greater than 104 °F, however, NMS, SS, MH and SAH should always be considered. Hyperthermia should be aggressively treated with cooling blankets, ice packs and fans. The role of NSAIDs and acetaminophen in toxin-induced hyperthermia is not established but antipyretic agents can be helpful if an infection is a comorbid factor.
Altered Mental Status
A reduced or fluctuating level of consciousness typically precedes systemic signs in patients with NMS [11] but the onset of symptoms may be underappreciated given the psychiatric comorbidity of susceptible patients. Altered mental status is multifactorial and may reflect hypothalamic and spinal dopamine receptor antagonism, hyperthermia effects on the CNS, or direct effects of other drugs [40]. Individuals may appear alert but dazed and unresponsive. Catatonic signs and mutism can be prominent and patients may evolve into profound encephalopathy and eventual coma [41]. Malignant or lethal catatonia, a condition similar to NMS that some argue is on the same spectrum [42], can be distinguished by a several-week prodrome of psychosis, agitation, and catatonic excitement [43, 44]. Hyperactivity and agitation are common to SS and CAS, in contrast to the catatonic stupor more prevalent in NMS [12].
Muscular Rigidity
Interference with nigrostriatal dopamine pathways contributes to muscle rigidity and tremor in NMS, classically characterized by “lead pipe rigidity” or stable resistance through all ranges of motion when passively moving the extremities [1, 2, 45, 46]. The motor symptoms of malignant catatonia display more positive phenomena (dystonic posturing and stereotyped repetitive movements) than what is seen in NMS while the presence of myoclonus, ataxia, shivering and hyperreflexia is more indicative of serotonin syndrome [33, 47] (Table 39.1). Patients with anticholinergic syndrome have few muscular abnormalities because skeletal muscle contraction is effected by nicotinic rather than muscarinic transmission. The muscle rigidity seen in malignant hyperthermia, however, is quite similar to NMS and must be distinguished by the clinical setting. Tremor is often associated with NMS, and dystonia, trismus, chorea, opisthotonus, and other dyskinesias are present less commonly [5, 48]. Patients can also have prominent dysarthria, sialorrhea, and dysphagia and prophylactic intubation may be required. Acute respiratory failure was the strongest independent predictor of mortality (p < 0.001) in the NIS database analysis [35]. Creatine kinase concentration may be elevated before the onset of muscle rigidity and higher levels are consistent with a poor prognosis [48–50]. Muscle damage and necrosis from the metabolic inequality between energy consumption and production can progress quickly to rhabdomyolysis, with associated hyperkalemia, hyperphosphatemia, hyperuricemia, hypocalcemia and lactemia. Aggressive fluid resuscitation to maintain adequate urine output is imperative in preventing progression to acute myoglobinuric renal failure, compartment syndrome, cardiac dysrhythmias from electrolyte abnormalities, and disseminated intravascular coagulopathy [51, 52]. Sodium bicarbonate to alkalinize the urine and prevent breakdown of myoglobin into nephrotoxic metabolites is often used though it has not been shown to be superior to saline alone, and bicarbonate may worsen hypocalcemia [51].
Autonomic Dysfunction
Dysautonomia in NMS is likely due to hypothalamic dopamine type-2 (D2) receptor blockade. Removal of normal dopamine regulation of efferent sympathetic activity leads to autonomic activation while unregulated vasomotor and sudomotor activity causes labile blood pressure and heart rate [53]. Early clues of autonomic instability are urinary incontinence, pallor and profuse diaphoresis, with increased “insensible fluid losses.” Hypotension should be treated with generous isotonic crystalloid administration but vasopressors, antiarrhythmic agents or pacing may be required. Respiratory distress and tachypnea are common and result from hypermetabolism and subsequent metabolic acidosis. Chest wall restriction, autonomic dysfunction with loss of protective airway reflexes and aspiration pneumonia can lead to respiratory failure.
Evidence Contour
Treatment of NMS with pharmacological agents and electroconvulsive therapy (ECT) is controversial and large clinical trials investigating specific therapies are lacking. Recommendations for the use of single- or combination-therapy consisting of benzodiazepines, dantrolene, bromocriptine, amantadine and ECT are based upon case reports and anecdotal evidence and their benefit over good supportive care is debated [54, 55]. The lack of other proven treatments and high fatality rate of the disorder easily justifies their use in patients with severe NMS.
Benzodiazepines
Benzodiazepines are the most widely used pharmacologic adjuncts in management of NMS because of their rapid onset of action and usefulness in reversing catatonic symptoms and agitation. Benzodiazepines facilitate GABA-mediated chloride transport, producing neuronal hyperpolarization which attenuates the sympathetic hyperactivity characterized by NMS [40]. Several clinical reports suggest that lorazepam and other benzodiazepines may reduce recovery time and improve outcome [19, 56, 57] and a few cases found benzodiazepines to be effective when other medications failed [58]. A trial of lorazepam, starting with 1–2 mg parenterally, is a reasonable first-line intervention for acute NMS with difficulty in assessing mental status as the primary disadvantage.
Dantrolene
Because of its efficacy in reducing heat production, rigidity and oxygen consumption in anesthetic-induced malignant hyperthermia, dantrolene, a direct-acting skeletal muscle relaxant, has been used in the treatment of NMS. Dantrolene is believed to decrease skeletal muscle contraction by interfering with calcium ion release from the sarcoplasmic reticulum which uncouples the excitation-contraction process. In some meta-analyses, improvement of NMS occurred in approximately 80 % of patients treated with dantrolene monotherapy [59–61]. In contrast, a more recent meta-analysis of 271 published cases found that treatment of NMS with dantrolene as monotherapy was associated with a higher mortality, and complete time to remission was prolonged by combination therapy including dantrolene [54]. Dantrolene can be administered intravenously starting with an initial bolus dose of 1–2.5 mg/kg followed by 1 mg/kg every 6 h up to a maximum dose of 10 mg/kg/day [6, 60–63]. Effects are usually reported within minutes of administration. Due to a risk of hepatoxicity, dantrolene is typically discontinued once symptoms begin to resolve although some recommend continuing for 10 days followed by a slow taper with doses of oral dantrolene that range from 50 to 200 mg/d to minimize relapse [63].