Catatonia: Clinical Aspects and Neurobiological Correlates
Epidemiology
The prevalence of catatonia is unknown. Catatonia is likely underdiagnosed by psychiatrists and other physicians. 1 It is common among psychiatric inpatients (7%–31% in six prevalence studies conducted after 1976 [total N=1,081]), and it occurs most often in patients with mood disorders (28%–31% of catatonic patients had mixed mania or mania in three studies conducted since 1977 [total N=280]). 2 Only 10%–15% of catatonic patients have an underlying diagnosis of schizophrenia as measured in five studies dating from 1932 to 1986. 2
Catatonia caused by a medical condition is believed to be common. There are no known prevalence studies regarding the frequency of catatonia on inpatient medical units. On psychiatric units, the frequency of catatonia due to a general medical condition was measured at 20%–25%, based on three prospective prevalence studies (pooled N=65) conducted after 1985. 3 – 6 Case reports have been published describing a wide array of medical conditions, ranging from multiple sclerosis to uremia and metabolic ketoacidosis.
Clinical Presentation and Characterization
Catatonia includes behavioral, motor, cognitive, affective, and sometimes autonomic disturbances. To organize and quantify these symptoms for research and diagnostic purposes, a number of rating scales have been developed. The Bush-Francis Catatonia Rating Scale (BFCRS) 4 is the most widely used in research studies and case reports. Signs included on this scale—excitement, immobility/stupor, mutism, staring, posturing/catalepsy, grimacing, stereotypy, mannerisms, verbigeration, rigidity, negativism, waxy flexibility, echolalia, echopraxia, and withdrawal—should raise a high suspicion for the presence of catatonia. Impulsivity, automatic obedience, mitgehen , gegenhalten, ambitendency, perseveration, combativeness, and autonomic abnormalities are signs which can be also found in catatonia and are included in the scale. Other scales, including the Bochum-German rating scale, the University of Frankfort scale, the Stony Brook scale, and the Catatonia Rating Scale (CRS), have been published and report good inter-rater reliability within each instrument and across instruments. 7 , 8 In 1994 the DSM-IV included catatonia due to a general medical condition and catatonia as a specifier in mood disorders; these criteria are also often used in research studies and clinical case reports. 9
No difference in the expression of catatonic symptoms in patients with underlying psychiatric or medical causes has been reported; the same rating scales have been used for clinical and research purposes in both populations.
In addition to behavioral disturbances, catatonia is also characterized by affective and cognitive changes. Patients with catatonia, though they often appear to have a flat affect, describe experiencing very intense emotional states. In an ongoing study (with an unreported design) Rosebush and Mazurek 10 found that the majority of patients felt very anxious and 15% thought they were either already dead or going to die. Northoff et al. 11 studied the subjective experience of 24 patients 3 weeks after their catatonia had resolved by using a self-questionnaire. He found that despite being aware of their very anxious emotional state, most patients were not aware of motor disturbances that had occurred during their previous episode of catatonia. This phenomenon has been called “motor anosognosia” or “postural anosognosia.”
Catatonia Subtypes and Differential Diagnosis
The expression of the catatonic syndrome has most often been divided into excited and withdrawn types, though patients often exhibit signs of both. The underlying cause does not appear to predict which type is expressed. Patients with classic withdrawn-type catatonia appear awake and watchful, but with minimal spontaneous speech and movement. Stupor, mutism, negativism, and posturing are common signs. Excited-type catatonia is characterized by excessive purposeless motor activity associated with disorganized speech, disorientation, aggression, and violence. 7
Catatonia with escalating fever and autonomic instability is known as “lethal” or “malignant” catatonia. Before 1960, the death rate was found to be 75%–100%, but since 1986 the death rate has dropped to 9% for reported cases, which has led to proposals to change the name from “lethal catatonia” to “malignant catatonia.” 12 , 13
Malignant catatonia resembles neuroleptic malignant syndrome (NMS) in many ways, but was described long before the introduction of neuroleptics. 14 Neuroleptic malignant syndrome is an idiosyncratic response to dopamine receptor antagonist medications. The incidence of NMS is estimated at 0.01%–0.02% of patients treated with neuroleptic medications. 15 Due to a number of case reports and a case-controlled study, catatonia, in particular catatonic excitement, has been thought to be a risk factor for NMS. 16 , 17
Some authors also consider toxic serotonin syndrome as a subtype of malignant catatonia. It has similar characteristics and course, but is precipitated by serotonergic medications and typically has gastrointestinal symptoms, hyperreflexia or clonus. 18 Unlike NMS or malignant catatonia, it is a toxic response that occurs in a dose-related fashion 19 whereas NMS is an idiosyncratic reaction which is not dose related. 20
Periodic catatonia is most often described as a rare heritable subtype of catatonic schizophrenia with a chronic degenerating course. 21 – 23 It has been characterized by specific genetic mutations and autosomal dominant inheritance. 24 , 25 Gjessing described the disorder and systematically studied metabolic disturbances in these patients. He suggested that the behavioral fluctuations of periodic catatonia were related to a cyclic nitrogen imbalance and could be treated with thyroid hormone extract, which seemed to control the symptoms but not cure the disorder. 26 Periodic catatonia has yet to reach nosological definition in the DSM-IV. 27
Neurobiology of Catatonic Symptoms
Lesions in many different brain regions (including the frontal lobes, basal ganglia, cerebellum-pons, parietal lobe, and corpus callosum 28 ) as well as frontal lobe degeneration and ruptured anterior artery aneurysms 7 have been reported to cause catatonic symptoms in case reports, but it is very rare for one focal lesion to do so. Reports of medical catatonias caused by a diffuse CNS etiology are far more common than those reporting catatonia due to a single CNS lesion, supporting the hypothesis that catatonia is caused by pathway dysregulation and not as a result of a focal insult. 29 No consistent postmortem changes have been found in patients with medical catatonia.
In recent years, some authors have attempted to create a coherent neurobiological explanation for the catatonic syndrome. Northoff 11 has been the most active researcher, conducting imaging, neuropsychological, and neurochemical testing. However, clinical experience has provided the basis for most hypotheses regarding catatonia and its neurology. Because current pharmacologic interventions modify γ-aminobutyric acid (GABA)-A, glutamate, and dopamine systems, it is thought that dysregulation of each of these neurotransmitter systems may be involved in catatonia.
GABA-A agonists have been found to be very effective in quickly alleviating catatonic symptoms in most patients. Northoff et al. 30 evaluated GABA-A binding in 10 akinetic catatonic patients in a case-controlled SPECT study. He found that the GABA-A radioligand binding was significantly lower in the right lateral orbitofrontal cortex of catatonia patients compared with both psychiatric patients and healthy comparison subjects and that cerebral perfusion was significantly decreased in the right parietal cortex of catatonia patients. 1 , 30 Lesions in the lateral orbitofrontal cortex have previously been found to cause imitation behaviors 31 which could be likened to echophenomena. The orbitofrontal cortex is also reciprocally connected with the amygdala which could account for the state of extreme fearfulness which catatonia patients often report. 13 Administration of a GABA-agonist has been postulated to correct dysregulation of GABA-ergic tone in the orbitofrontal cortex.
There is growing clinical evidence that NMDA-antagonists can treat catatonia, suggesting that glutamate hyperactivity might be related to catatonic symptoms. It has been postulated that NMDA hyperactivity causes dysregulation of GABA-A function and that NMDA antagonists can indirectly restore GABA-A function in the frontal lobes, though more slowly than GABA-A agonists. 32 Northoff 11 hypothesizes that either excess glutamate or hyperactivity of glutamate receptors causes dysfunction of the posterior parietal lobe. This could lead to symptoms such as posturing and impairment in spatial positioning that occur in patients with lesions of parietal cortex and in patients with catatonia. Carroll et al. 33 reported a case in which a patient with vascular dementia with no perfusion to the left posterior parietal area (as measured by SPECT) and catatonia refractory to multiple treatments finally responded to memantine, an NMDA antagonist. The authors proposed that memantine may have reduced excess glutamate at the NMDA receptor within a circuit that connects the parietal lobe, the subcortex and the frontal cortex, thus reregulating neurotransmitter function in these areas. 33
The role of dopamine in catatonia is very complex. Dopamine pathways play a central role in catatonia, malignant catatonia, and neuroleptic malignant syndrome in conjunction with other neurotransmitter systems; however, the exact role of dopamine has yet to be clarified. Atypical antipsychotic medications which block D 2 receptors (among other receptor actions) have been found to cause and treat catatonia as well as cause progression to neuroleptic malignant syndrome. The lateral and medial orbitofrontal cortical areas are each connected to the subcortex through a “thalamocortical loop” which connects the cortical area to the striatum, pallidum/substantia nigra, the thalamus and then back to the cortex. 34 These loops are heavily modulated by dopamine. 29 The dopaminergic circuit is in turn modulated by GABA and by serotonergic projections from the dorsal raphae. 7
Northoff 11 proposes that the initial neurochemical dysregulation in catatonia occurs in the cortex, with involvement of the GABA-A system and subsequent dopamine dysregulation in the thalamocortical loops and subcortex. He also postulates that the “top-down” dysfunction of dopamine could lead to catatonia and malignant catatonia, whereas NMS may originate as a dopamine dysregulation in the subcortex and subsequently cause catatonic symptoms (in some cases) via “bottom-up” dysregulation of the GABA-A function in the orbitofrontal cortex. 11 Mann 34 proposes that the medial orbitofrontal cortex thalamocortical loop to the lateral hypothalamus causes the autonomic symptoms of malignant catatonia/NMS.
Catatonia and Seizure Activity
Because of the effectiveness of benzodiazepines and ECT in catatonia, two treatments that usually raise seizure threshold, it has been proposed that catatonia may be caused by underlying seizure activity. 35 Though seizures are one of the most commonly reported causes of medical catatonia, there is no evidence that seizure activity underlies every case of catatonia. EEG changes have been found in catatonic schizophrenia patients, but it is not clear whether these changes were state indicators or trait indicators. 36 No study has ever consistently found seizure activity by EEG in catatonia, but subcortical seizures cannot be eliminated as a cause. 10
Making a Diagnosis and Finding an Underlying Cause
Catatonia is always caused by an underlying medical, neurological, or psychiatric illness. Identification of the symptoms of catatonia must be made while at the same time determining its cause.
Syndromes and symptoms to be differentiated from catatonia include coma, 37 akinetic mutism, abulia, hypoactive delirium, and locked-in syndrome. 38 An accurate diagnosis can change the treatment and prognosis dramatically. Alisky 39 reports the case of a 90-year-old man who was found unresponsive and was thought to be in a coma. Though the patient did not respond to any stimuli, he was found to be purposefully squeezing his eyes closed; he was diagnosed with catatonia after “waking up” with a dose of lorazepam.
To thoroughly identify and monitor signs and symptoms of catatonia, it can be helpful to use a standardized examination and rating scale for catatonia. History from family and friends will be particularly important as catatonic patients are often mute.
The broad array of medical causes that can underlie catatonia demands an extensive workup including a thorough history, physical and neurologic exam. Reports of severe psychiatric symptoms suggest a catatonic state of severe intensity. A drop in weight may suggest poor PO intake. Malingering may need to be investigated. HIV risk factors should be assessed. A very thorough medication and substance abuse history can provide valuable information. Suggested laboratory tests include CBC, BUN, and creatinine, serum glucose level, thyroid function tests, RPR, B12, folate, liver function tests, creatinine phosphokinase, therapeutic medication levels, HIV/AIDS test, serum iron, urine drug screen, urinalysis, EEG, brain MRI, lumbar puncture (if signs of encephalitis or meningitis). A workup for systemic lupus erythematosis may also be indicated. Finally, a “test dose” of lorazepam as described below may also help to make the diagnosis of catatonia.
Medical and toxic causes of catatonia must always be considered, even if a psychiatric cause is suspected, because there are often multiple causes of catatonia. 40 Over one hundred medical conditions have been reported to cause catatonia; most commonly these are processes that cause diffuse cerebral dysfunction such as encephalitis, seizures, metabolic disturbances, phencyclidine exposure, systemic lupus erthythematosus, corticosteroids, and disulfiram toxicity. 27 , 41 Focal disturbances such as CNS structural damage, infections, and focal seizures can also cause catatonia.
Immediately dangerous etiologies such as NMS, epilepsy, 33 encephalitis, mass lesion or cerebrovascular infarction 42 need to be ruled out quickly. Most authors recommend an EEG and brain imaging be performed in all patients with catatonic symptoms. 43 Seizures should be suspected especially if episodic bradycardia is present. 44
Many nonpsychiatric medications can cause neuropsychiatric symptoms and potentially lead to catatonia. In one case report, sibutramine was postulated to cause psychosis and subsequent catatonia via dopamine uptake inhibition and increased dopaminergic tone. Clarithromycin, azithromycin and amoxicillin have all been reported to cause psychotic symptoms at times leading to catatonic symptoms. Minocycline has been described as improving catatonic symptoms in two patients with schizophrenia, possibly via NMDA antagonism. 45
Medical problems that cause diffuse neuropsychiatric symptoms, such as systemic lupus erythematosus and HIV/AIDS, have been reported to cause catatonia in a number of case reports. Systemic lupus erythematosus causes neuropsychiatric disturbances in 50–70% of patients, even in cases without cerebritis. Ahuja et al. 46 support treating catatonia due to systemic lupus erythematosus with corticosteroids, immunosuppressive agents and plasma exchange, in addition to treating the catatonia with benzodiazepines and ECT. Neuropsychiatric disturbances due to the direct effect of HIV/AIDS, as well as CNS opportunistic infections, have also been reported to cause catatonia. Ferrando and Nims reported a case of HIV-associated mania that progressed to catatonia in a man with no focal neurologic lesions and a CD4 lymphocyte count of 33 cells/mm 3 . The mania and catatonia were effectively treated with benzodiazepines, ECT and highly active antiretroviral therapy. 47 Cancer can cause both focal CNS masses and leptomeningeal disease, as well as paraneoplastic encephalitis, all of which can lead to catatonia. Treatments can be aimed at eliminating focal lesions with radiation and chemotherapy, or treatment of the encephalitis while treating catatonic symptoms. 48 One case report describes vitamin B 12 deficiency as a possible cause of mental status changes and catatonia; treatment with vitamin B 12 supplementation alone was an effective treatment. 49
Interestingly, a number of case reports describe catatonia following liver transplantation. Liver transplant recipients have the most neuropsychiatric sequelae among transplant patients; the relationship to alcoholism, hepatitis C, and immunosuppressant medications remains unclear. Three case reports describe patients who received liver transplants (diagnosed with cirrhosis related to hepatitis C, alcohol abuse, and one for which the cause was not reported). All patients developed catatonic signs on postoperative day two or three and were successfully treated with benzodiazepines alone. There are no case reports describing catatonia in other types of organ transplantation.
Patients with NMS or malignant catatonia can have signs of catatonia as well as dysarthria, diaphoresis, sialorrhea, incontinence, myoclonus, tremors or tachypnea 50 along with autonomic instability, muscle rigidity, delirium, and leukocytosis. Laboratory abnormalities include a very high creatine phosphokinase, leukocytosis, thrombocytosis, and elevated LFTs. Low serum iron has been found in catatonia and NMS; one study found that NMS was more likely to occur in catatonic patients with low serum iron, but this has not been replicated. 51 – 53 It has been postulated that up to 10% of patients with catatonia treated with neuroleptics will develop NMS. 54
Treatment
While identification and treatment of underlying etiology are sought, treatment of catatonia begins with supportive care to reduce the risk of morbidity and mortality caused by immobility and poor nutrition. A number of case reports have described the risks of catatonic immobility: bed sores, flexion contractures, rhabdomyolysis, deep venous thrombi, and pulmonary emboli, urinary retention, infection, aspiration pneumonia, and death. 55 – 58 Treatment with subcutaneous heparin, urinary catheterization and a high level of nursing care can prevent these complications. Catatonic patients who refuse to eat or drink can become dehydrated and malnourished and require IV fluids. Nasogastric tube feeds and PEG tube placement may be required. Severe deconditioning along with malnutrition may require extensive physical rehabilitation.
Pharmacologic treatments and ECT are the primary treatment interventions for catatonia. Among these treatments, there has only been one prospective randomized placebo-controlled trial that was conducted with lorazepam in chronic catatonia patients with schizophrenia. In case reports, catatonic symptoms due to both psychiatric and medical causes seem to respond similarly to the standard treatments for catatonia; in both cases the underlying illness must also be addressed. 6
Benzodiazepines and ECT have been the first-line treatments for almost all types of catatonia. In 1995, Hawkins et al., 59 in a retrospective literature review including 178 psychiatric inpatients with catatonia, found that lorazepam was the most commonly used treatment, resolving symptoms in 70% of reported cases. ECT alone resulted in resolution of symptoms in 85%, whereas antipsychotics alone were effective in only 7.5% of cases. In malignant catatonia, the response to ECT was 89%, response to benzodiazepines was 40% and response to antipsychotics was 0% (0 of 2). 59
Benzodiazepines
Benzodiazepines are all GABA-A agonists. It has been hypothesized that GABA-A agonists correct deficient GABA-ergic function in the orbitofrontal cortex. 10 Lorazepam is the most commonly used benzodiazepine in the treatment of catatonia, but other benzodiazepines such as diazepam, 60 oxazepam, 61 and clonazepam 62 – 64 have also been reported to treat catatonia. An open prospective study found that of 18 psychiatric inpatients with catatonic signs, two patients showed an immediate response to intravenous lorazepam and 16 patients overall showed significant clinical improvement; nine patients of the responding patients later required ECT for complete remission. 65 Numerous authors have found that giving lorazepam 1–2 mg intravenously to a catatonic patient can dramatically reduce catatonic signs and symptoms within minutes; this can be helpful but not definitive in making a diagnosis of catatonia.
It has been noted that patients with catatonia due to a medical or affective illness may respond better to lorazepam than do patients with schizophrenia with catatonic features. A 12-week-long randomized double-blind, placebo-controlled cross-over study conducted in 18 patients diagnosed with schizophrenia and exhibiting chronic catatonic symptoms as measured by the Bush-Francis Catatonia Rating Scale found no statistical difference between groups treated with 6 mg/day of lorazepam and those not treated with lorazepam. 66
No consensus on the dosing schedule of lorazepam for catatonia has been established. Most authors suggest starting at 1–2 mg intravenous lorazepam every 4–12 hours and increasing this over the course of days with the goal of relieving catatonic signs and symptoms but not sedating the patient, which carries the risk of aspiration. The duration of treatment with benzodiazepines has not been firmly established, but a number of authors report that it is necessary to continue the benzodiazepines until the causative illness has been fully treated 67 , 68 ; otherwise the patient will be at high risk for relapse. One case report describes a patient with idiopathic recurrent catatonia who required chronic lorazepam treatment. 69
Zolpidem
Zolpidem, like the benzodiazepines, is a GABA-A agonist and has been reported in one case series to be effective in the treatment of catatonia. 70 Zolpidem has a quick onset (15 to 30 minutes) which makes it a useful diagnostic tool, but it lasts only 3–4 hours, requiring frequent administration. It was reported to be effective in one case where lorazepam failed. 71
Electroconvulsive Therapy
Available studies and case reports suggest a high success rate in treating all types of catatonia with ECT. 72 It has been found to be effective in catatonia refractory or partially refractory to lorazepam. 69 There are few studies regarding electrode placement, assessment of seizure threshold, and frequency of trials—these have yet to be standardized. Most reports of successful treatment of catatonia use bitemporal ECT, though there is one case report using biparietal ECT, which was used to augment stimulus intensity. 73 There has been a general consensus among specialists that temporal or frontal placement is the most effective. One case report described the rapid discontinuation of benzodiazepines in anticipation of ECT treatment which caused an exacerbation of catatonia. 74 Some physicians describe discontinuing benzodiazepine treatment just prior to ECT, whereas others recommend continuing benzodiazepines during and beyond the ECT treatments. 45 A synergistic effect between benzodiazepines and ECT has also been postulated. 75
ECT poses a risk in hypokinetic patients; ECT normally causes a transient rise in serum potassium levels, but when administered to a patient after a prolonged immobilization, significant hyperkalemia leading to life-threatening arrhythmias may occur. 76 In addition, there is a recommended waiting time of 3 months after a myocardial infarction 77 and concern for increased intracranial pressure with ECT in patients with CNS space-occupying masses. In these cases, a risk-benefit ratio needs to be assessed.
Repetitive Transcranial Magnetic Stimulation (rTMS)
A number of case reports have found that rTMS can be used successfully to treat catatonia, 78 , 79 and one showed success in a case in which lorazepam had failed. 80
NMDA Antagonists
N -methyl- D -aspartic acid antagonists may provide clinicians with another option when benzodiazepines and ECT fail or are not an option. Case reports have been published describing the success of NMDA antagonists amantadine and memantine in treating catatonia. 32 , 81 , 82 Amantadine can have anticholinergic side effects and can also increase dopaminergic tone. 83 One case report described successful use of amantadine 100 mg daily in a 38-year-old man with catatonia related to end stage renal failure and major depression, after ECT failed. 84 More recently, a review of glutamate antagonist therapy in the treatment of catatonia was published by Carroll et al. 85 They found 25 reported cases of catatonic patients who had received either amantadine (200–500 mg PO or IV) or memantine (5–20 mg oral) in addition to their original regimen for catatonia. All showed a strong positive response, with initial response time ranging from 1 to 7 days. The effect of NMDA antagonists is slower than that of benzodiazepines—effects can be seen within 24 hours with complete recovery occurring within 3 weeks. 86
Antiepileptics
Topiramate is a novel antiepileptic agent that is thought to increase GABA-ergic tone and augment GABA activity as well as indirectly reduce the activation of AMPA (non-NMDA glutamate receptor). 82 One case series found that topiramate was effective in four cases of catatonia refractory to benzodiazepines and divalproex, though two patients relapsed while still taking the medication. 87
One case report found valproate to be effective in 2 siblings with catatonic schizophrenia who do not respond to benzodiazepines, though their therapeutic effects took longer. 88 Its efficacy was postulated to be related to its GABA-ergic properties.
Atypical Antipsychotics
The role of atypical antipsychotics in the treatment of catatonia remains unclear; it is possible that atypicals directly treat catatonia. In addition to causing a D 2 receptor blockade, atypicals have weak GABA-agonism and 5HT 2 antagonism that could stimulate dopamine release in the prefrontal cortex and help alleviate catatonic symptoms. 89 Though many case reports describe the successful use of antipsychotics in catatonia (in patients with schizophrenia and psychotic symptoms in particular), a few case reports suggest that they can cause catatonia. 90 Moreover, all atypical antipsychotics have been found to cause NMS. Given that catatonia patients are believed to be at high risk for NMS, 91 some authors recommend against their use entirely. 92 In the literature, multiple case reports and retrospective studies 93 indicating the successful treatment of catatonia with atypical antipsychotics (olanzapine, risperidone, ziprasidone, aripiprizole, and clozapine) 89 , 94 – 96 have far outnumbered reports of atypical antipsychotics causing catatonia, though these studies were largely in patients with schizophrenia and only one focused on a patient with a medical illness. 97 , 98 In a recent review of the use of atypicals in the treatment of catatonia that included 10 case reports of successful treatment of catatonia with atypical antipsychotics, Van Den Eede et al. 99 advised using atypical antipsychotics in catatonic patients with caution, given the risk of NMS. They postulated that treatment with an antipsychotic might target the psychiatric illness that is driving the catatonia, rather than treating the catatonia itself. This would imply that using atypical antipsychotics in patients with catatonia due to a general medical condition would not be appropriate. It remains unclear as to whether atypical antipsychotics should be used in cases of catatonia due to a general medical condition.
CONCLUSION
Psychiatrists are in a position to diagnose and treat catatonia on both medical and psychiatric units, given the combination of medical and psychiatric problems that catatonic patients often present. Though catatonia is highly treatable and more common than thought, there have been very few research studies investigating the prevalence, pathophysiology, and treatment of the syndrome. Much more research is required to understand its biological underpinnings and the most effective treatments. Pooled case reports suggest that catatonic symptoms due to medical conditions can be treated similarly to those due to psychiatric conditions and that the catatonic symptoms and the underlying illness must be addressed in both types. Benzodiazepines and ECT continue to be mainstays of treatment, and evidence is mounting for the use of NMDA antagonists in catatonia refractory to lorazepam. The safety and usefulness of atypical antipsychotic medications in catatonia due to a general medical condition remain unclear, though there appears to be some evidence for their effectiveness in patients with catatonic schizophrenia.
An increased awareness of the diagnosis and treatment of catatonia among clinicians has the potential to significantly improve morbidity and mortality of catatonic patients. In addition, catatonia provides us with a unique window into how the mind works. Further research into its pathophysiology and clinical treatment will offer us an excellent chance at expanding our understanding of psychiatric illness and its causes.
1. Van der Heijden, Tuinier S, Arts NJ, et al: Catatonia: disappeared or under-diagnosed? Psychopathology 2005; 38:3–8Google Scholar
2. Taylor MA, Fink M: Catatonia in psychiatric classification: a home of its own. Am J Psychiatry 2003; 160:1233–1241Google Scholar
3. Barnes MP, Saunders M, Walls TJ, et al: The syndrome of Karl Ludwig Kahlbaum. J Neurol Neurosurg Psychiatry 1986; 49:991–996Google Scholar
4. Bush G, Fink M, Petrides G, et al: Catatonia I: rating scale and standardized examination. Acta Psychiatr Scand 1996; 93:129–136Google Scholar
5. Rosebush PI, Hildebrand AM, Furlong BG, et al: Catatonic syndrome in a general psychiatric inpatient population: frequency, clinical presentation, and response to lorazepam. J Clin Psychiatry 1990; 51:357–362Google Scholar
6. Carroll BT, Goforth HW: Medical catatonia, in Catatonia: From Psychopathology to Neurobiology. Edited by Caroff SN, Mann SC, Francis A, et al. Washington, DC, American Psychiatric Publishing, 2004, p 123Google Scholar
7. Fink M, Taylor MA: Catatonia is measurable and common, in Catatonia: A Clinician’s Guide to Diagnosis and Treatment. New York, Cambridge University Press, 2003, pp 129–130Google Scholar
8. Kruger S, Bagby RM, Hoffler J, et al: Factor analysis of the catatonia rating scale and catatonic symptom distribution across four diagnostic groups. Compr Psychiatry 2003; 44:472–482Google Scholar
9. American Psychiatric Association: Diagnostic and Statistical Manual of Mental Disorders, 4th ed. Washington, DC, American Psychiatric Association, pp 169–170, 382–383Google Scholar
10. Rosebush PI, Mazurek MF: Pharmacotherapy, in Catatonia: From Psychopathology to Neurobiology. Edited by Caroff SN, Mann SC, Francis A, et al. Washington, DC, American Psychiatric Publishing, 2004, p 145Google Scholar
11. Northoff G: What catatonia can tell us about “top-down modulation”: a neuropsychiatric hypothesis. Behavioral and Brain Sciences 2002; 25:555–604Google Scholar
12. Mann SC, Caroff SN, Bleier HR: Lethal catatonia. Am J Psychiatry 1986; 123:1374–1381Google Scholar
13. Moskowitz AK: “Scared stiff”: catatonia as an evolutionary fear-based response. Psychol Rev 2004; 111:984–1002Google Scholar
14. Philbrick KL, Rummans TA: Malignant catatonia. J Neuropsychiatry Clin Neurosci 1994; 6:1–13Google Scholar
15. Strawn JR, Keck PE Jr, Caroff SN: Neuroleptic malignant syndrome. Am J Psychiatry 2007; 164:870–876Google Scholar
16. Berardi D, Amore M, Keck PE Jr: Clinical and pharmacologic risk factors for neuroleptic malignant syndrome: a case-control study. Biol Psychiatry 1998; 44:748–754Google Scholar
17. Paparrigopoulos T, Tzavellas E, Ferentinos P, et al: Catatonia as a risk factor for the development of neuroleptic malignant syndrome: report of a case following treatment with clozapine. World J Biol Psychiatry 2009; 10:70–73Google Scholar
18. Looper KJ: Potential medical and surgical complications of serotonergic antidepressant medications. Psychosomatics 2007; 48:1–9Google Scholar
19. Boyer EW, Shannon M: The serotonin syndrome. N Engl J Med 2005; 352:1112–1123Google Scholar
20. Gillman, P: Understanding toxidromes: serotonin toxicity: a commentary on Montanes-Rada et al. J Clin Psychopharmacol 2005; 25:625–626Google Scholar
21. Stöber G, Saar K, Rüschendorf F, et al: Splitting schizophrenia: periodic catatonia–susceptibility locus on chromosome 15q15. Am J Hum Genet 2000; 67:1201–1207Google Scholar
22. Stöber G, Kohlmann B, Siekiera M, et al: Systematic mutation analysis of KIAA0767 and KIAA1646 in chromosome 22q-linked periodic catatonia. BMC Psychiatry 2005; 5:36Google Scholar
23. Pfuhlmann B, Stöber G: The different conceptions of catatonia: historical overview and critical discussion. Eur Arch Psychiatry Clin Neurosci 2001; 251:4–7Google Scholar
24. Beld JT, Philbrick K, Rummans T: Periodic catatonia, in Catatonia: From Psychopathology to Neurobiology. Edited by Caroff SN, Mann SC, Francis A, et al. Washington, DC, American Psychiatric Publishing, 2004, pp 93–102Google Scholar
25. Stöber G, Seelow W, Ruschendorf F: Periodic catatonia: confirmation to linkange to chromosome 15 and further evidence for genetic heterogeneity. Hum Genet 2002; 111:323–330Google Scholar
26. Fink M, Taylor MA: The many faces of catatonia, in Catatonia: A Clinician’s Guide to Diagnosis and Treatment. New York, Cambridge University Press, 2003, pp 59–60Google Scholar
27. Lee JW: Cycloid psychosis, catatonia, and periodic catatonia. Aust N Z J Psychiatry 38:975–976Google Scholar
28. Arora M, Praharaj SK: Butterfly glioma of corpus callosum presenting as catatonia. World J Biol Psychiatry 2007; 8:54–55Google Scholar
29. Carroll BT, Goforth HW: Medical catatonia, in Catatonia: From Psychopathology to Neurobiology. Edited by Caroff SN, Mann SC, Francis A, et al. Washington, DC, American Psychiatric Publishing, 2004, pp 123–125Google Scholar
30. Northoff G, Steinke R, Czcervenka C, et al: Decreased density of GABA-A receptors in the left sensorimotor cortex in akinetic catatonia: investigation of in vivo benzodiazepine receptor binding. J Neurol Neurosurg Psychiatry 1999; 67:445–450Google Scholar
31. Cummings JL: Frontal-subcortical circuits and human behavior. Arch Neurol 1993; 50:873–880Google Scholar
32. Carroll BT, Goforth HW, Thomas C, et al: Review of adjunctive glutamate antagonist therapy in the treatment of catatonic syndromes. J Neuropsychiatry Clin Neuroscience 2007; 19:406–412Google Scholar
33. Carroll BT, Thomas C, Jayanti K, et al: Treating persistent catatonia when benzodiazepines fail. Curr Psychiatry 2005; 4:56–64Google Scholar
34. Mann SC, Caroff SN, Fricchione GL, et al: Malignant catatonia, in Catatonia: From Psychopathology to Neurobiology. Edited by Caroff SN, Mann SC, Francis A, Fricchione GL. Washington, DC, American Psychiatric Publishing, 2004, pp 111–115Google Scholar
35. Louis ED, Pflaster NL: Catatonia mimicking nonconvulsive status epilepticus. Epilepsia 1995; 36:943–945Google Scholar
36. Sengoku A, Takagi S: Electroencephalographic findings in functional psychoses: state or trait indicators? Psychiatry Clin Neurosci 1998; 52:375–381Google Scholar
37. Freudenrich O, McEvoy JP, Goff DC, et al: Catatonic coma with profound bradycardia. Psychosomatics 2007; 48:74–78Google Scholar
38. Carroll BT, Kennedy JC, Goforth HW: Approach to the differential diagnosis of catatonia. Medscape Psychiatry & Mental Health eJournal 1996; 1Google Scholar
39. Alisky JM: Lorazepam-reversible catatonia in the elderly can mimic dementia, coma, and stroke. Age Ageing 2007; 36:229Google Scholar
40. Carroll BT, Kennedy JC, Goforth HW: Catatonic signs in medical and psychiatric catatonias. CNS Spect 2000; 5:66–69Google Scholar
41. Fricchione GL, Huffman JC, Stern TA, et al: Catatonia, neuroleptic malignant syndrome, and serotonin syndrome, in The Massachusetts General Hospital Handbook of General Hospital Psychiatry. Edited by Stern TA, Fricchione GL, Cassem NH, et al. Philadelphia, Elsevier, 2004, p 516Google Scholar
42. Barnes MP, Sanders M, Walls JJ, et al: The syndrome of Karl Ludwig Kahlbaum. J Neurol Neurosurg Psychiatry 1986; 49:991–996Google Scholar
43. Suzuki K, Miura N, Awata S, et al: Epileptic seizures superimposed on catatonic stupor. Epilepsia 2006; 47:793–798Google Scholar
44. Niraj A, Lloyd AJ: On catatonia, seizures, and bradycardia. Psychosomatics 2008; 49:86Google Scholar
45. Ahuja N, Carroll BT: Possible anti-catatonic effects of minocycline in patients with schizophrenia. Prog Neuropsychopharmacol Biol Psychiatry 2007; 31:968–969Google Scholar
46. Ahuja N, Carroll BT, Lloyd AJ: Catatonia associated with systemic lupus erythematosus. Psychiatry Clin Neurosci 2007; 60:450–451Google Scholar
47. Ferrando SJ, Nims C: HIV-associated mania treated with electroconvulsive therapy and highly-active antiretroviral therapy. Psychosomatics 2006; 47:170–173Google Scholar
48. Waller K, Borik A, Choi C: Breast cancer, bipolar disorder, catatonia, and life-preserving electroconvulsive therapy. Psychosomatics 2000; 41:442–445Google Scholar
49. Catalano G, Catalano M, Rosenberg EI, et al: Another neuropsychiatric presentation of vitamin B 12 deficiency? Psychosomatics 1998; 39:456–460 Google Scholar
50. Caroff SN, Mann SC, Campbell EC: Neuroleptic malignant syndrome. Adverse Drug React Bull 2001; 209:799–802Google Scholar
51. Carroll BT, Goforth HW: Serum iron in catatonia. Biol Psychiatry 1995; 38:776–777Google Scholar
52. Lee JW: Serum iron in catatonia and neuroleptic malignant syndrome. Biol Psychiatry 1998; 44:499–507Google Scholar
53. Peralta V, Cuesta MJ, Mata I, et al: Serum iron in catatonic and noncatatonic psychotic patients. Biol Psychiatry 1999; 45:788–790Google Scholar
54. Carroll BT: Catatonic stupor: diagnosis and treatment. Federal Practioner 2001; 18:48–54Google Scholar
55. Lachner C, Sandson NB: Medical complications of catatonia: a case of catatonia-induced deep venous thrombosis. Psychosomatics 2003; 44:512–514Google Scholar
56. McCall WV, Mann SC, Shelp FE, et al: Fatal pulmonary embolism in the catatonic syndrome: two case reports and a literature review. J Clin Psychiatry 1995; 56:21–25Google Scholar
57. Swartz C, Galang RL: Adverse outcome with delay in identification of catatonia in elderly patients. Am J Geriatr Psychiatry 2001; 9:78–80Google Scholar
58. Carroll BT: Catatonia on the consultation-liaison service. Psychosomatics 1992; 33:310–315Google Scholar
59. Hawkins JM, Archer KJ, Strakowski SM, et al: Somatic treatment of catatonia. Int J Psychiatry Med 1995; 25:345–369Google Scholar
60. Huang TL: Lorazepam and diazepam rapidly relieve catatonic signs in patients with schizophrenia. Psychiatry Clin Neurosci 2005; 59:52–55Google Scholar
61. Schmider J, Standhart H, Deuschle M, et al: A double-blind comparison of lorazepam and oxazepam in psychomotor retardation and mutism. Biol Psychiatry 1999; 46:437–741Google Scholar
62. Kumar R: Acute severe catatonia in a young woman with chronic schizophrenia responding to parenteral clonazepam. Aust N Z J Psychiatry 2001; 35:391Google Scholar
63. Lee JW, Schwartz DL, Hallmayer J: Catatonia in a psychiatric intensive care facility: incidence and response to benzodiazepines. Ann Clin Psychiatry 2000; 12:89–96Google Scholar
64. Benazzi F: Parenteral clonazepam for catatonia. Can J Psychiatry 1991; 36:312Google Scholar
65. Ungvari GS, Leung CM, Wong MK, et al: Benzodiazepines in the treatment of catatonic syndrome. Acta Psychiatr Scand 1994; 89:285–288Google Scholar
66. Ungvari GS, Chiu HFK, Chow LY, et al: Lorazepam for chronic catatonia: a randomized double-blind, placebo controlled cross-over study. Psychopharmacology 1999; 142:393–398Google Scholar
67. Clothier JL, Pazzaglia P, Freeman TW: Evaluation and treatment of catatonia. Am J Psychiatry 1989; 146:553–554Google Scholar
68. McEvoy JP: Relief from catatonic immobility can be maintained. J Clin Psychopharm 1986; 6:126–127Google Scholar
69. Manjunatha N, Saddichha S, Khess CR: Idiopathic recurrent catatonia needs maintenance lorazepam: case report and review. Aust N Z J Psychiatry 2007; 41:625–627Google Scholar
70. Thomas P, Rascle C, Mastain B, et al: Test for catatonia with zolpidem. Lancet 1997; 349:702Google Scholar
71. Thomas P, Cottencin O, Rascle C, et al: J catatonia in French psychiatry: implications of the zolpidem challenge test. Psychiatr Annals 2007; 37:45–54Google Scholar
72. Caroff SN, Ungvari GS, Bhati MT, et al: Catatonia and prediction of response to electroconvulsive therapy. Psychiatr Ann 2007; 37:57–64Google Scholar
73. Suzuki K, Shindo T, Katsura M, et al: Resolution of catatonia by successful seizure induction via electroconvulsive therapy with electrodes applied bilaterally to the parietotemporal region. J ECT 2007; 23:103–105Google Scholar
74. Malur C, Francis A: Emergence of catatonia during ECT. J ECT 2001; 17:201–204Google Scholar
75. Petrides G, Divadeenam KM, Bush G, et al: Synergism of lorazepam and electroconvulsive therapy in the treatment of catatonia. Biol Psychiatry 1997; 42:375–381Google Scholar
76. Hudcova J, Schumann R: Electroconvulsive therapy complicated by life-threatening hyperkalemia in a catatonic patient. Gen Hosp Psychiatry 2005; 28:440–442Google Scholar
77. Magid M, Lapid MI, Sampson SM, et al: Use of electroconvulsive therapy in a patient 10 days after myocardial infarction. J ECT 2005; 21:182–185Google Scholar
78. Vittorio DM, Bolino F: A novel treatment option of bipolar depression with psychotic and catatonic features. Gen Hosp Psychiatry 2006; 28:364–365Google Scholar
79. Grisaru N, Chudakov B, Yaroslavsky Y, et al: Catatonia treated with transcranial magnetic stimulation. Am J Psychiatry 1998; 155:1626Google Scholar
80. Saba G, Rocamora JF, Kalalou K, et al: Catatonia and transcranial magnetic stimulation. Am J Psychiatry 2002; 159:1794Google Scholar
81. Carpenter S, Hatchett AD, Fuller MA: Catatonic schizophrenia and the use of memantine. Ann Pharmacother 2006; 40:344–346Google Scholar
82. Munoz C, Yulan N, Achaval V, et al: Memantine in major depression with catatonic features. J Neuropsychiatry Clin Neurosci 2008; 20:119–120Google Scholar
83. Northoff G, Eckert J, Fritze J: Glutamatergic dysfunction in catatonia? Successful treatment of three akinetic catatonic patients with the NMDA antagonist amantadine. J Neurol Neurosurg Psychiatry 1997; 62:404–406Google Scholar
84. Gorforth H: Amantadine in catatonia due to major depressive disorder in a medically ill patient. J Neuropsychiatry Clin Neurosci 2007; 19:480Google Scholar
85. Carroll BT, Goforth HW, Thomas C, et al: Review of adjunctive glutamate antagonist therapy in the treatment of catatonic syndromes. J Neuropsychiatry Clin Neurosci 2007; 19:406–412Google Scholar
86. Carpenter SS, Hatchett AD, Fuller MA: Catatonic schizophrenia and the use of memantine. Ann Pharmacother 2006; 40:344–346Google Scholar
87. McDaniel WW, Spiegel DR, Sahota AK: Topiramate effect in catatonia: a case series. J Neuropsychiatry Clin Neurosci 2006; 18:234–237Google Scholar
88. Yoshida I, Monji A, Hashioka S, et al: Prophylactic effect of valproate in the treatment for siblings with catatonia: a case report. J Clin Psychopharmacology 2005; 5:504Google Scholar
89. Cassidy EM, O’Brien M, Osman MF, et al: Lethal catatonia responding to high-dose olanzapine therapy. J Psychopharmacology 2001; 15:302–304Google Scholar
90. Markham-Abedi C, McNeely C, DeLeon J: A case report with ziprasidone-induced catatonic symptoms. J Neuropsychiatry Clin Neurosci 2007; 19:476Google Scholar
91. Carroll BT, Lee JW: Catatonia is a risk factor for neuroleptic malignant syndrome. J Clin Psychiatry 2004; 65:1722–1723Google Scholar
92. Fink M, Taylor MA. Management of catatonia today, in Catatonia: A Clinicians Guide to Diagnosis and Treatment. New York, Cambridge University Press, 2003, p 150Google Scholar
93. Naber D, Holzbach R, Perro C, et al: Clinical management of clozapine patients in relation to efficacy and side effects. Br J Psychiatry 1992; 160:54–59Google Scholar
94. Hung YY, Yang PS, Huang TL: Clozapine in schizophrenia patients with recurrent catatonia: report of two cases. Psychiatry Clin Neurosci 2006; 60:256–258Google Scholar
95. Numata S, Kato O, Misawa H, et al: Treatment of catatonia with olanzapine. German Journal of Psychiatry 2002; 5:115–116Google Scholar
96. Valevski A, Loebl T, Karen T, et al: Response of catatonia to risperidone: two case reports. Clin Neuropharmacology 2001; 24:228–231Google Scholar
97. Bahro M, Kampf C, Strnad J: Catatonia under medication with risperidone in a 61-year-old patient. Acta Psychiatr Scand 1999; 99:223–224Google Scholar
98. Markham-Abedi C, McNeely C, DeLeon J: A case report with ziprasidone-induced catatonic symptoms. J Neuropsychiatry Clin Neurosci 2007; 19:476–477Google Scholar
99. Van Den Eede F, Van Hecke J, Van Dalfsen A, et al: The use of atypical antipsychotics in the treatment of catatonia. European Psychiatry 2005; 20:422–429Google Scholar
