1,250 electroconvulsive treatments without evidence of brain injury

What Is Brain Damage and Does Electroconvulsive Therapy Cause It?

ABSTRACT

Surveys show public misperceptions and confusion about brain damage and electroconvulsive therapy (ECT). Fictional movies have misrepresented ECT to suggest brain damage and to ridicule mental illness and psychiatric patients. "Brain damage" has become a colloquial expression without consistent meaning. In contrast, brain injury is the medical term for destruction of brain cells, such as from kinetic impact (concussion), hypoxia, or infection. Studies of both high-resolution magnetic resonance imaging (MRI) and enzyme assays find that causes of brain injury are accompanied by observable structural changes on MRI and elevated blood and cerebrospinal fluid levels of brain enzymes that leak from injured brain cells. Concussion is also followed by intracerebral bleeding, progressive brain atrophy, diffuse axonal injury, cranial nerve injury, and 2-4 fold increased risk for dementia. In contrast, there is no evidence that ECT produces any of these. Studies of ECT patients find no brain edema, structural change persisting 6 months, or elevated levels of leaked brain enzymes. Statistical comparisons between brain injury and ECT effects indicate no similarity ( P < 0.00000001). Moreover, the kinetic, thermal, and electrical effects of ECT are far below levels that could possibly cause harm. This robust evidence shows that there is no basis to claim that ECT causes brain injury.

The case against secondary epileptogenesis

Secondary epileptogenesis is a theory that hypothesizes that uncontrolled seizures in people with epilepsy lead to the development of new sites of seizure onset. This process has often been cited when people experience a new seizure type after a period of poor seizure control. The theory proposes that repeated seizures induce changes in regions of the brain that are regularly recruited into the seizure. These hypothetical changes can then lead to a new, independent seizure onset zone. The concept is based on a number of clinical observations which secondary epileptogenesis could explain. However there are alternative explanations from the clinic as well as from the laboratory that call the process into question. In this review some of the observations that have been used to support the theory will be reviewed, and the many counterarguments will be presented. At this time there is little evidence to support secondary epileptogenesis and much to refute it.

Electroconvulsive therapy is associated with increased immunoreactivity of neuroplasticity markers in the hippocampus of depressed patients

Electroconvulsive therapy (ECT) is an effective therapy for depression, but its cellular effects on the human brain remain elusive. In rodents, electroconvulsive shocks increase proliferation and the expression of plasticity markers in the hippocampal dentate gyrus (DG), suggesting increased neurogenesis. Furthermore, MRI studies in depressed patients have demonstrated increases in DG volume after ECT, that were notably paralleled by a decrease in depressive mood scores. Whether ECT also triggers cellular plasticity, inflammation or possibly injury in the human hippocampus, was unknown. We here performed a first explorative, anatomical study on the human post-mortem hippocampus of a unique, well-documented cohort of bipolar or unipolar depressed patients, who had received ECT in the 5 years prior to their death. They were compared to age-matched patients with a depressive disorder who had not received ECT and to matched healthy controls. Upon histopathological examination, no indications were observed for major hippocampal cell loss, overt cytoarchitectural changes or classic neuropathology in these 3 groups, nor were obvious differences present in inflammatory markers for astrocytes or microglia. Whereas the numbers of proliferating cells expressing Ki-67 was not different, we found a significantly higher percentage of cells positive for Doublecortin, a marker commonly used for young neurons and cellular plasticity, in the subgranular zone and CA4 / hilus of the hippocampus of ECT patients. Also, the percentage of positive Stathmin 1 cells was significantly higher in the subgranular zone of ECT patients, indicating neuroplasticity. These first post-mortem observations suggest that ECT has no damaging effects but may rather have induced neuroplasticity in the DG of depressed patients.

The Neurobiological Effects of Electroconvulsive Therapy Studied Through Magnetic Resonance: What Have We Learned, and Where Do We Go?

Electroconvulsive therapy (ECT) is an established treatment choice for severe, treatment-resistant depression, yet its mechanisms of action remain elusive. Magnetic resonance imaging (MRI) of the human brain before and after treatment has been crucial to aid our comprehension of the ECT neurobiological effects. However, to date, a majority of MRI studies have been underpowered and have used heterogeneous patient samples as well as different methodological approaches, altogether causing mixed results and poor clinical translation. Hence, an association between MRI markers and therapeutic response remains to be established. Recently, the availability of large datasets through a global collaboration has provided the statistical power needed to characterize whole-brain structural and functional brain changes after ECT. In addition, MRI technological developments allow new aspects of brain function and structure to be investigated. Finally, more recent studies have also investigated immediate and long-term effects of ECT, which may aid in the separation of the therapeutically relevant effects from epiphenomena. The goal of this review is to outline MRI studies (T1, diffusion-weighted imaging, proton magnetic resonance spectroscopy) of ECT in depression to advance our understanding of the ECT neurobiological effects. Based on the reviewed literature, we suggest a model whereby the neurobiological effects can be understood within a framework of disruption, neuroplasticity, and rewiring of neural circuits. An improved characterization of the neurobiological effects of ECT may increase our understanding of ECT's therapeutic effects, ultimately leading to improved patient care.

One century of healing currents into the brain from the scalp: From electroconvulsive therapy to repetitive transcranial magnetic stimulation for neuropsychiatric disorders

Electroconvulsive therapy (ECT) was applied for the first time in humans in 1938: after 80 years, it remains conceptually similar today except for modifications of the original protocol aimed to reduce adverse effects (as persistent memory deficits) without losing clinical efficacy. We illustrate the stages of development as well as ups and downs of ECT use in the last eighty years, and the impact that it still maintains for treatment of certain psychiatric conditions. Targeted, individualized and safe noninvasive neuromodulatory interventions are now possible for many neuropsychiatric disorders thanks to repetitive transcranial magnetic stimulation (rTMS) that injects currents in the brain through electromagnetic induction, powerful enough to depolarize cortical neurons and related networks. Although ECT and rTMS differ in basic concepts, mechanisms, tolerability, side effects and acceptability, and beyond their conceptual remoteness (ECT) or proximity (rTMS) to "precision medicine" approaches, the two brain stimulation techniques may be considered as complementary rather than competing in the current treatment of certain neuropsychiatric disorders.

Collateral Child and Parent Effects of Function‑Based Behavioral Interventions for Sleep Problems in Children and Adolescents with Autism

This study follows McLay et al., Journal of Autism and Developmental Disorders, (2020) to investigate whether the function-based behavioral sleep interventions received by 41 children and adolescents with autism spectrum disorder (ASD) produced collateral improvements in ASD severity, internalizing and externalizing symptoms and parent relationship quality, ratings of depression, anxiety and stress, and personal sleep quality. Concomitant with reduced sleep problem severity, improvements were found in children's internalizing and externalizing behavior and ASD symptom severity. Small improvements were also found in maternal sleep quality and parental stress. There was little change in parental relationship quality post-treatment, possibly reflecting high baseline scores. Overall, collateral benefits were generally small but positive, consistent with the limited extant research, and underscore the importance of investigating collateral effects across a range of variables.

The Effects of Maintenance Electroconvulsive Therapy on Hospitalization Rates

ABSTRACT

This study aimed to study the effect of maintenance electroconvulsive therapy (mECT) on hospitalization rates in patients who had been readmitted after acute courses of electroconvulsive therapy (ECT), and determine the most frequently used treatment schedules in mECT. Patients who had undergone mECT treatment for the last 5 years were retrospectively reviewed. Seventy patients were included in the study. The control group of 70 patients was selected from patients who received only acute ECT. Of the patients in the mECT group, 55.8% (39) were female, and 41.4% (29) were diagnosed with major depressive disorder. The mean number of patients hospitalized who received mECT after acute ECT was 0.55 ± 0.87, whereas it was 1.13 ± 1.31 in patients who received only pharmacotherapy after ECT in a covariant analysis adjusted for age and diagnosis. The most commonly used initial treatment protocol of mECT was weekly × 4, biweekly × 2, and monthly × 6. mECT is more effective in reducing hospitalization after acute ECT treatments than using psychotropic drugs alone for maintenance therapy.

Genetic landscape of autism spectrum disorder in Vietnamese children

Autism spectrum disorder (ASD) is a complex disorder with an unclear aetiology and an estimated global prevalence of 1%. However, studies of ASD in the Vietnamese population are limited. Here, we first conducted whole exome sequencing (WES) of 100 children with ASD and their unaffected parents. Our stringent analysis pipeline was able to detect 18 unique variants (8 de novo and 10 ×-linked, all validated), including 12 newly discovered variants. Interestingly, a notable number of X-linked variants were detected (56%), and all of them were found in affected males but not in affected females. We uncovered 17 genes from our ASD cohort in which CHD8, DYRK1A, GRIN2B, SCN2A, OFD1 and MDB5 have been previously identified as ASD risk genes, suggesting the universal aetiology of ASD for these genes. In addition, we identified six genes that have not been previously reported in any autism database: CHM, ENPP1, IGF1, LAS1L, SYP and TBX22. Gene ontology and phenotype-genotype analysis suggested that variants in IGF1, SYP and LAS1L could plausibly confer risk for ASD. Taken together, this study adds to the genetic heterogeneity of ASD and is the first report elucidating the genetic landscape of ASD in Vietnamese children.

Electroconvulsive Treatment for Catatonia in Autism Spectrum Disorders

Catatonia has been increasingly recognized in people with autism spectrum disorders (ASD). Assessment, diagnosis, and treatments are reviewed and illustrated with 2 new case vignettes. The use of electroconvulsive treatment (ECT) is recommended in patients who fail to respond to medical treatments, including a trial of lorazepam or another benzodiazepine. The importance of maintenance ECT is discussed. There is an urgent need for prospective studies of catatonia in ASD and for controlled treatment trials.

Treatment of catatonia in autism spectrum disorders

OBJECTIVE

To review the treatment courses of 22 autistic patients diagnosed with catatonia over a 12-year period, including treatment with benzodiazepines and electroconvulsive therapy.

METHOD

Retrospective review of inpatient and outpatient records of 22 autistic youth presenting to a neurobehavioral service who were treated for catatonia.

RESULTS

Six girls and 16 boys ranging from ages 8 to 26 years old presenting for neurobehavioral assessment were found to meet criteria for catatonia according to the DSM5 and were treated for such. All but one patient was initially unsuccessfully treated with benzodiazepines in dosages ranging from 1 to 27 mg daily, and all patients underwent electroconvulsive therapy. Mean age of ECT start was 15.6 years old, and the total number of ECT received ranged from 16 to 688, with 13 patients still receiving maintenance ECT at the end of the study period. ECT conferred prominent patient benefit in terms of catatonic symptom reduction, including alleviation of incapacitating, treatment-resistant self-injury.

CONCLUSION

Myriad symptoms of catatonia were seen in this sample of 22 autistic youth. Implementation of anti-catatonic paradigms, particularly electroconvulsive therapy, conferred vast patient benefit.

Potential Mechanisms Underlying the Therapeutic Effects of Electroconvulsive Therapy

In spite of the extensive application of electroconvulsive therapy (ECT), how it works remains unclear. So far, researchers have made great efforts in figuring out the mechanisms underlying the effect of ECT treatment via determining the levels of neurotransmitters and cytokines and using genetic and epigenetic tools, as well as structural and functional neuroimaging. To help address this question and provide implications for future research, relevant clinical trials and animal experiments are reviewed.

Treatment of Severe Self-Injurious Behavior in Autism Spectrum Disorder by Neuromodulation

An increasing number of case reports and series document the safe and effective use of electroconvulsive therapy (ECT) in children, adolescents, and young adults with autism spectrum disorder who engage in severe, intractable, repetitive self-injurious behavior (SIB) without environmental or operant function. Although the treatment is very effective for such patients, they typically remain highly dependent on frequent maintenance ECT (M-ECT) to maintain suppression of the SIB achieved during the acute course. Some patients receive M-ECT as frequently as once every 5 days. Such a regimen is quite burdensome for the patient and the patient's family, and the long-term effects of such regimens, starting as early as childhood, are unknown. In this review, we explore the expanding literature supporting the use of ECT for suppressing severe SIB associated with autism spectrum disorder. We also focus on the possible development of alternate nonconvulsive focal forms of brain stimulation, which might replace frequent M-ECT or reduce how frequently a patient needs to receive it. Although there are scarce clinical data currently available supporting these latter treatments, future studies are clearly indicated.

Electroconvulsive therapy: a life course approach for recurrent depressive disorder

We describe the case of an 89-year-old woman (deceased) with a 60-year history of recurrent depressive disorder treated with electroconvulsive therapy (ECT). It is estimated that she received up to 400 ECTs over her life course as her symptoms would not respond to oral medication. Despite extensive exposure to ECT, there was only minimal cognitive impairment and an excellent safety record, even in later life, as she became increasingly frail from multiple comorbidities. Over the years, there has been a drive to reduce the frequency of ECT administration. However, this case illustrates how in some patients ECT may be vital for acute episodes of severe depression as well as for maintenance therapy. This case report adds to observational evidence that maintenance ECT may be an underused treatment for recurrent depression and also recommends that greater emphasis be given to incorporating carers' views when planning individualised treatment approaches.

Searching for the mechanism(s) of ECT's therapeutic effect

The exact therapeutic mechanism of action of electroconvulsive therapy (ECT) remains unresolved. Numerous psychological theories from decades ago have been proven untrue. In the ensuing years, ECT has been proven to have numerous reproducible effects on brain chemistry, regional brain activity, electroencephalographic sleep stages, and neurogenesis. Clinically, ECT has been shown to have antidepressant, antipsychotic, antimanic, antiparkinsonian, and anticonvulsive effects. It is possible that different biological effects of ECT are responsible for different clinical effects or that several biological effects in concert work together to produce a given clinical effect. This paper comments on the array of possible mechanisms and points toward the future of mechanistic research in ECT.

Stability of intellectual functioning during maintenance electroconvulsive therapy

We describe the stability of neuropsychologic testing in a 16-year-old boy with cerebellar dysgenesis who received 61 acute and maintenance electroconvulsive therapy treatments for malignant catatonia. Measures of nonverbal intelligence and visual memory before treatment onset and after 61 electroconvulsive therapy treatments indicated no evidence of decline in intellectual functioning and acute or delayed memory. This case offers further support for the safety and efficacy of maintenance electroconvulsive therapy in both pediatric and developmentally disabled populations.

Maintenance electroconvulsive therapy in autistic catatonia: a case series review

The usage of electroconvulsive therapy for the acute resolution of catatonia in autistic children and adults is a novel area that has received increased attention over the past few years. Reported length of the acute ECT course varies among these patients, and there is no current literature on maintenance ECT in autism. The maintenance ECT courses of three patients with autism who developed catatonia are presented. Clinical, research, legal, and administrative implications for ECT treatment in this special population are discussed.

Unaltered neuronal and glial counts in animal models of magnetic seizure therapy and electroconvulsive therapy

Anatomical evidence of brain damage from electroconvulsive therapy (ECT) is lacking; but there are no modern stereological studies in primates documenting its safety. Magnetic seizure therapy (MST) is under development as a less invasive form of convulsive therapy, and there is only one prior report on its anatomical effects. We discerned no histological lesions in the brains of higher mammals subjected to electroconvulsive shock (ECS) or MST, under conditions that model closely those used in humans. We sought to extend these findings by determining whether these interventions affected the number of neurons or glia in the frontal cortex or hippocampus. Twenty-four animals received 6 weeks of ECS, MST, or anesthesia alone, 4 days per week. After perfusion fixation, numbers of neurons and glia in frontal cortex and hippocampus were determined by unbiased stereological methods. We found no effect of either intervention on volumes or total number or numerical density of neurons or glia in hippocampus, frontal cortex, or subregions of these structures. Induction of seizures in a rigorous model of human ECT and MST therapy does not cause a change in the number of neurons or glia in potentially vulnerable regions of brain. This study, while limited to young, healthy, adult subjects, provides further evidence that ECT and MST, when appropriately applied, do not cause structural damage to the brain.

Electroconvulsive therapy, brain-derived neurotrophic factor, and possible neurorestorative benefit of the clinical application of electroconvulsive therapy

Treatment-resistant depression (TRD) is a growing problem in psychiatry. A recent meta-analysis has estimated TRD to be as high as 40%. Just over a decade ago, TRD was estimated to be as low as 10% to 15%. The causes of TRD are not fully understood. Finding ways to bring patients to remission faster may be part of the solution, but increasing our understanding of how depression works and how the brain responds to treatment may shed some light on this growing problem. Patients with TRD have been shown to have decreased volumes in gray matter structures, particularly in the hippocampus. Hippocampal volumes are correlated with decreased expression of neurotrophic factors (most notably, brain-derived neurotrophic factor [BDNF]), and decreased expression of BDNF correlates with the presence of depression. Increased expression of BDNF has a strong association with increased volumes in the hippocampus. Electroconvulsive therapy (ECT), a safe and effective treatment of severe depression, has been shown to be effective in TRD. Patients who undergo ECT have also had measurable increases in BDNF, indicating that ECT may be modulating intracellular processes in the patients with depression. Taken together, ECT may have a positive effect on restoring gray matter volume in patients with depression and especially TRD.

Effects of maintenance electroshock on the oxidative damage parameters in the rat brain

Although several advances have occurred over the past 20 years concerning refining the use and administration of electroconvulsive therapy to minimize side effects of this treatment, little progress has been made in understanding the mechanisms underlying its therapeutic or adverse effects. This work was performed in order to determine the level of oxidative damage at different times after the maintenance electroconvulsive shock (ECS). Male Wistar rats (250-300 g) received a protocol mimicking therapeutic of maintenance or simulated ECS (Sham) and were subsequently sacrificed immediately after, 48 h and 7 days after the last maintenance electroconvulsive shock. We measured oxidative damage parameters (thiobarbituric acid reactive species for lipid peroxidation and protein carbonyls for protein damage, respectively) in hippocampus, cortex, cerebellum and striatum. We demonstrated no alteration in the lipid peroxidation and protein damage in the four structures studied immediately after, 48 h and 7 days after a last maintenance electroconvulsive shock. Our findings, for the first time, demonstrated that after ECS maintenance we did protocol minimal oxidative damage in the brain regions, predominating absence of damage on the findings.

The relevance of kindling for human epilepsy

Kindling is one of the most widely used models of seizures and epilepsy, and it has been used in its more than three decade history to provide many key insights into seizures and epilepsy. It remains a mainstay of epilepsy related research, but the question remains how the results from kindling experiments further our understanding of the underlying neurobiology of human epilepsy. In this article we compare the basic features of kindling and human epilepsy, especially human limbic or temporal lobe epilepsy. In this review we focus on a limited number of topics that may show areas in which kindling has been often cited as a tool for better understanding of human epilepsy. These areas include the underlying circuits, the importance of seizure spontaneity, the associated neuropathology, the contribution of genetics, seizure susceptibility, and the underlying pathophysiology of epilepsy. In the course of this article we will show that there are many features that kindling can teach us by direct comparison or implication about human temporal epilepsy. We will also see that not all findings associated with kindling may be applicable to the human condition. Ultimately we wish to encourage critical thinking about kindling and the similarities that it shares and does not share with the human epilepsy so the results from studies using this model are applied rationally to further our insights the mechanisms of human epilepsy.

[Adverse cognitive effects and ECT]

Electroconvulsive therapy (ECT) is a rapidly acting and highly effective treatment for severe and life threatening conditions seen in affective and schizophrenic diseases. Notwithstanding its therapeutic benefits, ECT remains controversial because of seizure induction, cognitive side effects, memory dysfunction and effects on cerebral physiology. These factors have raised the concern that ECT produces structural and functional brain damages. This issue continues to have a major impact on the acceptance of ECT as a therapeutic modality, both within the medical community and in public opinion. A close look at incidence, type, severity, neurofunctional and -anatomical correlates, aetiology and therapeutic approaches of the adverse cognitive effects attributed to ECT may contribute to rational and objective handling of this topic. The final chapter deals with the issue of whether ECT causes brain damage.

Successful maintenance electroconvulsive therapy for more than seven years

We report on a patient with recurrent major depressive episodes with psychotic features who was successfully treated with maintenance electroconvulsive treatment (M-ECT) over a long period without the need for concurrent treatment with an antidepressant or mood stabilizer. She started ECT in 1996 and has received M-ECT for more than 7 years. To date (2005), she has received 244 treatments. After 5 admissions in nearly 4 years, involving 29 months in hospital, she has not needed any further psychiatric admission for 7 1/2 years since the start of the M-ECT. Her depression has been in complete remission for nearly 6 years, with the exception of one mild-to-moderate nonpsychotic depressive episode lasting for 2 months. The patient exhibited slight cognitive deficits but had no subjective complaints before ECT, and her cognitive deficits did not worsen after the initial ECT. Thus M-ECT does not appear to cause cognitive deterioration. M-ECT is being continued on the patient's request.

Continuation and maintenance ECT in treatment-resistant bipolar disorder

Continuation and maintenance electroconvulsive therapy (c/mECT) is a treatment alternative for the long-term management of mood and psychotic disorders, especially in chronic, recurring, medication-resistant illnesses and in patients who are medication-intolerant, are non-compliant, and have a high risk of suicide with medications. A MEDLINE search was performed with maintenance electroconvulsive therapy (ECT), continuation ECT, and prophylactic ECT as keywords. The relevant literature was obtained and reviewed. Despite methodologic flaws, the overwhelming majority of the studies report the effectiveness of c/mECT in bipolar mood disorder. We also reviewed the charts of 13 patients with mood disorder receiving maintenance ECT in the ECT service of a Veterans Administration medical center. Despite good results, c/mECT is underused in the treatment of bipolar mood disorder. More research with better study design is needed to define the predictors of response to c/mECT and to develop c/mECT treatment protocols for treatment-resistant bipolar patients.

Postictal psychosis: resolution after electroconvulsive therapy

The association between epilepsy and psychosis has generated considerable debate since the 19th century. Recently, diagnostic criteria for a distinct type of epileptic psychosis, postictal psychosis, have emerged. We present the case of a 23-year-old woman who was admitted to the hospital with a catatonic-like psychosis after a cluster of partial complex seizures. She received a diagnosis of postictal psychosis, and fully recovered after electroconvulsive therapy. This article once again emphasizes the association between psychosis and epilepsy, a matter of great theoretical interest, as it provides a chance for developing an organic model for psychosis.

The anticonvulsant effect of electrical fields

The use of electrical fields to treat epilepsy is undergoing increased scrutiny as an alternative to medications and resective surgery. Much recent attention has been focused on ionic channels and seizure control; however, nonsynaptic mechanisms may be crucial for seizure onset, raising the possibility of using electrical field application to abort seizures. Furthermore, the inhibitory effects may outlast the immediate treatment and possibly be a prophylactic intervention. This paper reviews the use of brain stimulation for treatment of epilepsy, but also cites instances where the antithetical results occur. The greatest detail focuses on disrupting the onset or shortening the seizure. The paper does not extensively review deep brain or vagal nerve stimulation.

No evident neuronal damage after electroconvulsive therapy

Electroconvulsive therapy (ECT) is regarded as one of the most effective treatments for major depressive disorder but has also been associated with cognitive deficits possibly reflecting brain damage. The aim of this study was therefore to evaluate whether ECT induces cerebral damage as reflected by different biochemical measures. The concentrations in the cerebrospinal fluid (CSF) of three established markers of neuronal/glial degeneration, tau protein (tau), neurofilament (NFL) and S-100 beta protein, were determined in nine patients who fulfilled DSM-IV criteria for major depression. CSF samples were collected before and after a course of six ECT sessions. The CSF/serum (S) albumin ratio reflecting potential blood-brain barrier (BBB) dysfunction was also determined at these time points. The treatment was clinically successful with a significant decline of depressive symptoms in all patients as assessed by the Montgomery-Asberg Rating Scale for Depression. Several patients had signs of BBB dysfunction and/or neuronal damage before the start of treatment. Levels of CSF-tau, CSF-NFL and CSF-S-100 beta levels were not significantly changed by ECT. Also the CSF/S albumin ratio was found to be unchanged after the course of ECT. In conclusion, no biochemical evidence of neuronal/glial damage or BBB dysfunction could be demonstrated following a therapeutic course of ECT.

Serum neuron-specific enolase levels do not increase after electroconvulsive therapy

BACKGROUND

Cognitive disorders occurring after electroconvulsive therapy (ECT) are regarded as an expression of brain damage, despite computed tomography (CT) and magnetic resonance imaging (MRI) showing no signs of structural brain damage. Serum neuron-specific enolase (NSE) is a sensitive marker of neuronal damage (i.e., after stroke or cardiac arrest). The objective of this study was to investigate whether ECT leads to a rise in the serum NSE level as an expression of neuronal damage.

METHODS

We investigated seven patients (four women, three men; mean age 6212 years) with major depressive disorder, who were treated with ECT for the first time. ECT was administered every 2 days, three times a week under standard conditions (anaesthesia: thiopental, succinylcholine, 100% oxygen, unilateral ECT, seizure duration more than 20 s). Blood samples were drawn at the following times. For the first ECT: 15 and 1 min before ECT, and 1, 5, 10, 15, 20, 25, 30, 45, 60, 75, 90, 105, 120 min, and 8, 12, 24 h after ECT. For all subsequent ECT: 1 min before and 4 h after every ECT. Serum NSE was measured by means of enzyme immunoassay (Cobas Core NSE, EIA, Hoffmann-La Roche).

RESULTS

On average, each patient underwent ECT 10 times (range 5-20). In the first ECT there was no difference in serum NSE levels before and at all times following ECT. A comparison of serum NSE levels before and after each subsequent bout of ECT revealed no differences. Moreover, comparing the baseline serum NSE levels (before the first ECT) with the values after final ECT showed no differences either.

CONCLUSION

ECT did not increase serum NSE values, indicating that electroconvulsive therapy does not cause neuronal damage.

A review of continuation and maintenance electroconvulsive therapy

BACKGROUND

Many patients with major psychiatric disorders who are severely ill, medication-resistant, or medication-intolerant respond more reliably and quickly to a course of electroconvulsive therapy (ECT). The management of such patients after successful treatment with ECT is of significant importance given the high rate of relapse and recurrence of these disorders. The unmet clinical need to maintain the mental health of these seriously ill patients at an optimal level has revived the interest in ECT as an alternative prophylactic treatment.

METHOD

We review the historical background of ECT and the literature that supports its use as a prophylactic treatment in various disorders and special populations. A clinical summary outlining its efficacy, acceptability, risks, cost-effectiveness, and medicolegal aspects is followed by a guide for prescribing ECT for prophylactic reasons.

RESULTS

Continuation and maintenance ECT (C/MECT) has been found to be efficacious, safe, well tolerated, and cost-effective. Its greatest impact has been in reducing relapse, recurrence, and rehospitalization, particularly in the management of recurrent mood disorders in the elderly. The elderly are usually refractory or intolerant to pharmacotherapy but have a good response to ECT during the index episode. Parkinson's disease (PD), schizophrenia, and obsessive-compulsive disorder (OCD), as well as affective disorders coexisting with dementia, neurological disorder, or mental retardation, have also been reported to respond to C/MECT. The outcome depends greatly on rate of compliance. Cognitive risk of C/MECT need to be further studied because the literature to date consists mostly of case reports and anecdotal evidence. Controlled studies with well-defined outcome measurements are needed.

CONCLUSIONS

When planning a rational approach to the care of patients with major psychiatric disorders, clinicians should carefully consider ECT along with other alternatives.

Failed and short seizures associated with prior electroconvulsive therapy

Electroconvulsive therapy (ECT) has not been associated with many long-lasting effects that are associated with the treatments itself. The impact of having prior ECT to determine if the increased seizure threshold that is noticed during the treatment course is long-lasting was studied. If so, more failed and short seizures should occur among those patients who have had prior electroconvulsive treatments. A review of the treatments of 114 males and 220 females indicated a strong association of prior ECT with failed as well as short seizures for men but not for women.

Continuation electroconvulsive therapy: preliminary guidelines and an illustrative case report

Despite renewed interest in ECT as a continuation treatment after an episode of depressive illness, few guidelines for its use are available. Meaningful research findings are few, although the potential benefits and risks of modern continuation ECT merit study. We suggest preliminary guidelines and provide an illustrative clinical example.

Electroconvulsive therapy and cerebral computed tomography. A prospective study

Cerebral computed tomography (CT) was performed before and after right-sided electroconvulsive therapy (ECT) in 40 patients aged 26-87 years with major affective disorders. Nine patients with a concomitant definite or possible non-acute organic brain disorder were included. Several patients had long seizure durations, maximum 6.5 min, caused by hyperventilation-induced hypocapnia. Twenty-nine patients received at least 16 treatments (maximum 46). No CT changes occurred following ECT. A questionable dilatation of the left temporal horn in a 69-year-old hypertensive man who recovered completely without side effects after 3 ECT sessions was probably unrelated to the ECT. Provided sufficient oxygenation, even relatively long ECT series and seizures lasting several minutes do not cause any brain damage visible on CT.

Sources of public prejudice against electro-convulsive therapy

Recent legislation in NSW betrays a prejudice against electro-convulsive therapy. Factors probably contributing to popular prejudice against ECT are discussed.

The role of electroconvulsive therapy in the treatment of depressive illness in old age

Electroconvulsive therapy is an important treatment in the depressive states of late life, and there is general agreement about the indications for its use in old age psychiatry. Indeed, old age may be associated with a better response to ECT than that in younger age groups. The additional risk involved through physical problems in the elderly is not great when compared with that of continuing depression and of the side-effects of alternative treatments. Temporary memory disorders and confusion may occur, but are minimised if unilateral electrode placement is used. Some patients treated with unilateral ECT do not respond, but will respond to bilateral treatment. Anxiety over unwanted treatment effects, which can lead to ineffective treatment of depressive illness, must be outweighed by knowledge of the dangers of leaving depression untreated in old age.

Cerebral and brain stem changes after ECT revealed by nuclear magnetic resonance imaging

Nuclear magnetic resonance images of the brain were obtained in fourteen patients with major depression during a course of ECT. The T1 relaxation time rose immediately after the fit, reaching a maximum 4-6 h later. The T1 values then returned to their original level; no long-term increase occurred over the course of treatment. These results are consistent with an extensive but temporary breakdown of the blood-brain barrier during ECT.

Mental deterioration in epilepsy

A variety of factors could potentially influence the occurrence of mental deterioration in epilepsy, including seizure type, age of seizure onset, seizure duration, and seizure severity. The available literature suggests that measures of severity are more predictive of progressive decreases in intellectual functioning. There is also evidence suggesting that seizure severity and cognitive deterioration might both be the result of underlying pathophysiologic abnormalities in some cases. In the majority of patients with epilepsy, however, with relatively less severe disease, there is little evidence for cognitive deterioration. Total seizure number also has an inverse correlation with level of psychosocial functioning in some studies, whereas others have found that patients with emotional difficulties have fewer seizures. In the case of emotional deterioration, the impact of interpersonal relationships and other environmental factors upon psychosocial outcome seems clear, and the evidence for specific pathophysiologic explanations for emotional deterioration, less convincing.