Guidelines for the Management of Bipolar Disorder.

turner

The first German-language guidelines for the management of bipolar disorder were published in 2012, and now, an abbreviated English translation is available online for free [link].

The German Society for Bipolar Disorder (DGBS) and the German Association for Psychiatry & Psychotherapy (DGPPN) set up a project group, a steering group and 6 working groups made up of psychiatrists, psychotherapists, patients and their families. Devoid of any industry funding, their intention was to providedecision-making support for patients, their families, and therapists“. Following an extensive literature review, and ten consensus conferences they concluded:

“Bipolar disorder should be diagnosed as early as possible. The most extensive evidence is available for pharmacological monotherapy; there is little evidence for combination therapy, which is nonetheless commonly given. The appropriate treatment may include long-term maintenance treatment, if indicated. The treatment of mania should begin with one of the recommended mood stabilizers or antipsychotic drugs; the number needed to treat (NNT) is 3 to 13 for three weeks of treatment with lithium or atypical antipsychotic drugs. The treatment of bipolar depression should begin with quetiapine (NNT = 5 to 7 for eight weeks of treatment), unless the patient is already under mood-stabilizing treatment that can be optimized. Further options in the treatment of bipolar depression are the recommended mood stabilizers, atypical antipsychotic drugs, and antidepressants. For maintenance treatment, lithium should be used preferentially (NNT = 14 for 12 months of treatment and 3 for 24 months of treatment), although other mood stabilizers or atypical antipsychotic drugs can be given as well. Psychotherapy (in addition to any pharmacological treatment) is recommended with the main goals of long-term stabilization, prevention of new episodes, and management of suicidality. In view of the current mental health care situation in Germany and the findings of studies from other countries, it is clear that there is a need for prompt access to need-based, complex and multimodal care structures. Patients and their families need to be adequately informed and should participate in psychiatric decision-making“.

The abridged guidelines (in English) are available here.

 

Natural antidepressants & new brain cells

New Brain Cells

In the last decade it has become clear that new cells can form in the adult brain. This happens in a region known as the hippocampal complex. The hippocampal complex is found deep inside either temple and is crucial for memory and emotion. The hippocampal complex inhibits the human stress response, but can itself be damaged by persistent stress, leading to a vicious cycle in which the stress response is amplified further and depression ensues.

hippocampus from nieuwenhuys et al

The hippocampal complex is found in the temporal lobe, and has a crucial role in regulating the stress response.

Experimental work suggests that neurogenesis (the birth of new neurons) in the hippocampal complex is vital for the action of conventional antidepressant drugs. Exercise and enriched environments also promote neurogenesis, whilst stress has the opposite effect.The current picture is that hippocampal health (including the birth of new neurons) is essential for protecting the organism against the effects of stress, so that if hippocampal functioning is compromised, anxiety and depression can emerge.

 

Natural Antidepressants

There has been recent interest in the antidepressant properties of a natural molecule called curcumin. This substance is found in the herb turmeric. As well as a foodstuff, turmeric has been used for centuries in traditional Indian medicine (Ayurveda). In pre-clinical studies, curcumin exhibited clear antidepressant effects.

curcumin

Research has focused on the mechanism of action of curcumin. Remarkably it appears that curcumin can also increase the birth of new neurons in the hippocampal complex. This is an intriguing finding which hints at the possibility of a new class of antidepressant drug.

A new paper from researchers at King's College London provides an excellent summary of work in this area. The full paper can be read here.

 

Glutamate & GABA for psychiatrists

Rapid Dissemination of Information
Glutamate and GABA are the archetypal ‘fast’ transmitters. If a neuron in the brain ‘wishes’ to communicate rapidly with another cell, the chances are that it will utilise glutamate or GABA. Of course, glutamate neurons exert an excitatory influence on the cells they contact, whereas GABA, at least on first glance, is inhibitory.

Fast transmitters bind to receptors on membrane-spanning ion channels. An ion-channel is in constant flux between various conformations: e.g. open, closed, desensitised. Binding of fast transmitter ‘causes’ the ion channel to snap open for brief periods, and ions rush down their concentration gradients causing an abrupt, short-lived, change in the local membrane potential of the post-synaptic cell (Figure 1). From start to finish the whole process is over within tens of milliseconds, and constitutes a discrete electrical signal (termed an excitatory or inhibitory post-synaptic potential; EPSP, IPSP).

nmda receptor

Figure 1. The NMDA Receptor mediates an EPSP.

Neurotransmission v neuromodulation
Fast transmission, as a concept, pre-supposes slow transmission. The classical slow transmitters are the monoamines, e.g. noradrenaline and dopamine. These substances are used as transmitters by neurons within specific brainstem nuclei, whose axons project to numerous subcortical structures and large areas of cortex. There are relatively few monoamine neurons (tens of thousands), but their projections show massive arborisation within the ‘higher centres’ and the limbic system. Anatomically, glutamate and GABA signalling is characterised by point-to-point communication between narrowly separated (and tethered) pre-synaptic and post-synaptic elements, whereas for monoamine systems, the release sites (boutons) and post-synaptic receptors are not necessarily in close proximity. In contrast to glutamate and GABA, which convey a fast, discrete, short-lived electrical signal, monoamines evoke slower-onset, diffuse, longer-duration biochemical changes in their target neurons. Monoamine systems are not optimised for the rapid dissemination of specific information, but instead for modulating those neurons that are.

Ensemble formation and Gestalts
Pyramidal neurons (the principal output neuron of the hippocampus and cortex) use glutamate as a transmitter to communicate rapidly with neurons in ‘lower centres’ such as the striatum, thalamus, pontine nuclei and the cord although most communication is with other pyramidal neurons. Pyramidal neurons organise themselves into ensembles. This process, in which pyramidal neurons fire in synchrony for brief periods of time is thought to be essential for object perception and for movement, speech and thinking.

Consider a pyramidal neuron ‘sitting’ at resting-membrane-potential (-70mV). It receives tens of thousands of excitatory (glutamate) inputs on its dendritic spines, (dynamic structures that are moulded by experience over a lifetime). A single excitatory input (by itself) has little overall impact on the pyramidal neuron. But when numerous EPSP’s from a multitude of inputs arrive ‘synchronously’, the depolarisation may be sufficient for the pyramidal neuron to fire an action potential (AP). In short, the pyramidal neuron is recruited (by the ensemble) into joining the ensemble.

It can be grasped that for AP firing to occur in a pyramidal neuron, there has to be a convergence of excitatory information from numerous sources. Excitatory inputs come from various thalamic nuclei and from stellate cells (in primary sensory cortices), although the overwhelming majority come from other pyramidal neurons. Regardless of the source, timing is key. In order to generate enough depolarisation to trigger an AP, inputs must arrive (and summate) within the same narrow time window (of the order of milliseconds).

Precise Timing and cortical dynamics
The output of a pyramidal neuron (AP spiking) is finely controlled. Precise timing is so fundamental for cortical processing that various auxiliary neurons appear to be tasked with a pacemaker role. These neurons utilise GABA as a transmitter. Classical neuroscience conceptualised GABA containing neurons as nothing more than inhibitory interneurons – this is no longer tenable. There are various populations of GABA containing neuron, which have been classified according to their morphology, their location in the cortex, which proteins they use to sequester calcium, and their electrophysiological properties. Some are even excitatory. For simplicity, we shall restrict ourselves to a simple classification based upon where the GABA neuron contacts the pyramidal neuron (Figure 2).

glutamate and gaba neurons

Figure 2. A pyramidal neuron receives inhibitory GABA-ergic input to its dendrites. GABA pacemakers synapse on the soma and axon initial segment.

 

Contacts formed with the dendrites of pyramidal neurons function as inhibitory interneurons in the classical sense (i.e. they oppose excitatory drive), whereas GABA neurons targeting the soma or the proximal axon (of the pyramidal neuron) function as pacemakers. We can consider how these GABA pacemaker neurons are optimised for their task. Firstly they have very fast dynamics, swifter for example than the pyramidal neurons that they make contact with. Secondly, they provide a very strong and reliable signal to the pyramidal neuron by engulfing the soma or the proximal axon with numerous terminals. A strong, brief, recurrent signal to the soma and proximal axon creates a series of time windows, which determine precisely when the pyramidal neuron fires. Thirdly, individual pacemaker neurons make contact with numerous local pyramidal neurons. And finally, groups of pacemaker neurons are connected by electrical synapses (gap junctions) so that they can function as an interconnected single entity, a syncytium. For completion, pyramidal neurons make strong, reliable synapses (excitatory) with pacemaker neurons.

It is readily apparent that the interconnectivity of pyramidal neurons and GABA interneurons favours the emergence of oscillations, with successive, precisely timed periods of integration followed by periods of AP discharge. Experiments have shown that the population of neurons in an active ensemble generate the rhythm, whilst the rhythm puts precise constraints upon when an individual neuron can fire.

Systems and levels
For slow, diffuse modulators such as noradrenaline, it makes sense to talk of a system. To recap, noradrenaline [NA] is synthesized by no more than tens of thousands of neurons, confined to discrete nuclei within the brainstem, and is ‘sprayed’ from en-passant boutons over large territories of CNS tissue, in a hormone-like manner. Crucially, the release patterns of noradrenaline [and other neuromodulators] can be clearly mapped onto distinct behavioural states, the most marked differences arising in the sleep-state [noradrenaline – ‘off’] versus the waking-state [noradrenaline – ‘on’]. Since the extracellular concentrations of noradrenaline [and other neuromodulators] can inform directly about higher brain/mind levels, the idea of a noradrenergic system has utility.

Glutamate and GABA are too ubiquitous as fast point-to-point transmitters for the term ‘system’ to be applicable in the same way. Particular patterns of behaviour cannot be mapped onto the release of GABA or glutamate at a specific locus. All we can say is that neurons in an ensemble use glutamate and GABA to communicate with each other. Whereas transient fluctuations in the extracellular concentrations of GABA/glutamate do not reveal anything about behaviour, the dynamics of neuronal ensembles correspond with distinct behavioural states. Again the sleep wake-cycle is illustrative. Oscillatory activity generated by the ensemble can be mapped unambiguously onto the sleep-state and the waking-state.

Learning & Memory
In the 1970s it became clear that excitatory connections onto pyramidal neurons could be made stronger, if they were subjected to particular patterns of input. This was the first experimental support for an idea that can be traced back to Ramon y Cajal – the idea that synapses are modifiable (plastic) and that such plasticity might serve as the physical basis of memory.

There are various forms of plasticity, but the most widely studied is NMDA-dependent long-term potentiation (LTP). In the early 1980’s, researchers based in Bristol showed that NMDA receptor antagonists could block the initiation of LTP [and subsequent behavioural experiments, (most famously, by Richard Morris in Edinburgh) showed that such drugs could inhibit new learning].

NMDA receptor channels are found at the heads of dendritic spines, adjacent to the glutamate terminal. AMPA receptor channels are found in the same locale. When activated, both receptor channels produce an excitatory-post-synaptic-potential (EPSP). In the case of the AMPA receptor, the EPSP is mediated by sodium ions flowing into the spine. For NMDA receptors, the EPSP is mediated by a combination of sodium and calcium ions. [It is the calcium signal that initiates LTP (Figure 3). Early-phase LTP is mediated by phosphorylation of AMPA receptors (increasing their conductance) and by insertion of new AMPA receptors into the post-synaptic membrane].

long term potentiation

Long Term Potentiation (LTP) is induced by NMDA receptor activation. The mechanism of early-phase LTP involves the enhancement of AMPA receptor conductances and insertion of new AMPA receptors into the post-synaptic membrane.

AMPA and NMDA receptor channels differ in one other key property. The NMDA channel is voltage-dependent. At membrane potentials less than -50mV, the NMDA channel remains closed, even if glutamate is bound to the receptor. For the NMDA channel to snap open, the membrane potential must be already depolarised to at least -30mV. So two conditions are necessary for NMDA conductance; binding of glutamate and membrane depolarisation. For this reason, the NMDA receptor is said to be a coincidence detector (or in engineering terms, an AND gate).

Sufficient post-synaptic depolarisation can occur from backward-propagating action potentials (APs) or from temporally or spatially summated excitatory input to a dendritic branch. Research in the last decade has revealed that the timing of pre-synaptic activity (glutamate release) and of post-synaptic activity (post-synaptic-depolarisation) is critical in determining whether synaptic strength will be altered. Pre and post synaptic ‘events’ must occur within approximately 20 milliseconds, otherwise synaptic strength remains unchanged. This form of plasticity, known as Spike-Timing-Dependent-Plasticity (SDTP), is likely to become increasingly relevant as we begin to conceptualise ‘micro-circuit’ abnormalities in major neurodevelopmental disorders. Two final points about SDTP will be made here. Plasticity is bidirectional (potentiation or depression) depending on the order of pre and post-synaptic events. And conventional modulators such as dopamine can impact upon the timing rules and alter the direction of the plasticity, (LTP or LTD).

Some Psychiatry: The K-Hole and beyond
Ketamine, a drug that has attracted the attention of psychiatrists in the past few decades, ‘blocks’ the NMDA channel. It has been used as a model psychosis, and latterly has been demonstrated to have acute anti-depressant properties. (It certainly impairs new learning, as would be expected).

Downstream of NMDA blockade, there is no clear consensus as to how ketamine produces a psychosis. Counter-intuitively (for a glutamate antagonist), ketamine increases the excitability (spiking) of pyramidal neurons. Ketamine also increases the power of gamma band (~40 Hz oscillations) and some have proposed that ‘kernels’ of ‘abnormal’ gamma underlie the psychotic-like effect.

But the behavioural pharmacology of ketamine is far from straightforward. Rating-scales used in schizophrenia research, are probably not ideal for capturing the nuances of the drug. Those who have taken a more phenomenological approach [in the sense of ‘bracketing-out’ existing assumptions, whilst focussing on clear descriptions] have identified a much richer and more complex behavioural psychopharmacology, which includes euphoria, near-death experiences, the cessation of time, the dissolution of the ego, and the experience of being immersed in fractal geometries or boundless oneness (Jansen K, Ketamine: Dreams & Realities 2000).

Close observation reveals the dose-dependent emergence of an oneroid (dream-like) state, and other catatonic features (ambitendency, posturing) but not a classic paranoid psychosis. Researchers have also tended to assume that ketamine can ‘cause’ negative symptoms, but reports of euphoria, terror and awe are inconsistent with this categorisation. Motor output (which includes speech of course) is certainly restricted following ketamine, but because the concurrent inner world is a kaleidoscope of strange, mystical and fantastic experiences with extremes of emotion, the overall picture is far removed from the negative syndrome.

Nevertheless, ketamine is frequently championed as the most convincing drug-model of schizophrenia because it can induce negative symptoms, on a rating scale. The irony perhaps is that the ketamine experience might actually be more schizophrenia-like than many of its proponents have suggested. Ketamine elicits phenomena, which are now very rarely encountered in psychiatric clinics, given the modern-day domination of the softer, paranoid form of the illness.

Update

Paul Janssen’s genius was in predicting that a drug which blocked the effects of amphetamine in animals, would be an effective treatment for those cases of schizophrenia that resembled an amphetamine psychosis (characterised by agitation, hallucinations and delusions)[link]. That drug was haloperidol, and that class of drug (D2 dopamine receptor antagonists) changed the landscape of psychiatry.

Janssen’s logic would also suggest that a drug which inhibited the effects of ketamine in animals, would be an effective treatment for those cases of schizophrenia which resemble ketamine-elicited psychopathology (characterised by bizarre, inaccessible dream-like states, and psychotic motor phenomena. i.e. cases where ECT becomes a sensible option). A pharmacological antagonist of ketamine (in animals) proved to be ineffective against human paranoid schizophrenia. Perhaps this could have been predicted, by closer attention to the phenomenology of ketamine. The question now is whether ‘The Lilly compound‘ has efficacy against non-paranoid schizophrenia?

Complementary Treatments for Depression

Exercise, meditation and nutritional supplements in depression: Helpful or not?

Since 1965 it has been clear from clinical trials that antidepressant medications are effective in major depression. However many patients are not keen to take tablets, expressing a wish for more 'natural' forms of treatment. Numerous alternative treatments have been advocated, but is there any evidence that any of these work? Here we briefly review the case for physical exercise, meditation (or mindfulness, as it is now known) and several nutritional supplements.

Alternative treatments as a group can often be criticised because they do not subject themselves to rigorous trials, as is the case with conventional treatments (pharmacological or psychological). This criticism is valid. Indeed it is only within the last 60 years that conventional medicine itself has demanded clear demonstrations of efficacy before a treatment can be licensed for a particular illness. The randomised, double-blind control trial (RCT) is the gold standard by which efficacy is judged. Until recently, very few alternative treatments were subjected to the strict demands of the RCT. But this is changing.

Is physical exercise beneficial in depression?

There is now good evidence that a programme of physical exercise is an effective treatment for depression. Researchers in Brazil conducted a metanalysis in which the results from 10 separate trials were pooled to give an overall finding. (Metanalysis is a powerful method for deciding whether a treatment works. All available trials are scrutinised, and those with no control group or no randomised allocation to drug or placebo are usually excluded on the grounds of being poor quality studies).

The present meta-analysis concluded that physical exercise, mainly aerobic training, improves the response to depression treatment. However, the efficacy of exercise in the treatment of depression was influenced by age and severity of symptoms“.

The full paper can be read here.

Meditation (Mindfulness)

Mindfulness is a currently fashionable psychological approach for the treatment of depression, which has its roots in eastern meditation techniques. The various traditional schools of meditation differ in flavour, but all centre on the idea of mastering an unruly and restless mind. Mindfulness training involves short sessions in which the aim is to direct consciousness towards full immersion in the activity at hand, rather than on the mind's incessant chatter. But does it work?

meditation candle

A recent review from the US attempted to tackle this question. However the authors were unable to reach a definitive conclusion. At present there are not enough studies, of sufficient quality, to yield an answer. They point out that further (and more robust) trials are needed, but they regard mindfulness as a promising approach to depression. They remark:

Regardless of the various limitations present in the available literature, findings to date have consistently demonstrated that training focused on improving attention, awareness, acceptance, and compassion may facilitate more flexible and adaptive responses to stress.

The full paper can be read here.

Nutritional Supplements

Vitamin deficiencies (especially B-vitamins) can cause neuropsychiatric disorders, although this is very rarely seen now in developed countries. But the idea of supplementation is to provide additional quantities of a specific nutrient in an effort to obtain a therapeutic effect. Three nutrients in particular have attracted attention as possible treatments for depression: folic acid, S-adenosylmethionine (SAM-e) and omega-3 fatty acids. A recent Canadian paper has reviewed the evidence.

nutritional supplements

Omega-3 fatty acids (fish oils) have been shown to possess antidepressant properties in a metanalysis of 16 trials. SAM-e has also been shown to be effective in a metanalysis of 7 trials. The evidence in support of folic acid has been more limited. One of two trials was positive and further work is needed. The authors conclude:

Physicians should consider screening for and treating folate deficiency but the benefits of folate supplementation remain unclear. Limited evidence supports the use of omega-3 fatty acids and S-adenosylmethionine, but further research is required“.

The full paper can be read here

 

 

BD or not BD?


The Bipolar Spectrum: can brain scans resolve diagnostic uncertainty?

The concept of manic-depression was extended some years back to cover less extreme manifestations characterised by hypomania (Bipolar II), as well as the classical form, defined by mania (Bipolar I). But other forms (perhaps less dramatic, though still a cause of much suffering) also exist.

These ‘softer’ forms of bipolar illness appear to blur into unipolar depression and perhaps also with the category which has been termed, borderline personality disorder. Although there has been a trend to view psychiatric disorders as points on a spectrum, rather than as discrete, encapsulated diagnoses, many psychiatrists would hesitate to equate borderline personality disorder and bipolar illness. Ultimately the matter will be resolved when we fully grasp the underlying neurobiology of affective disorders.

A new paper from researchers based in Sydney provides an authoritative and balanced account of the current state of our knowledge. The authors elegantly summarise the functional MRI literature across the hypothesised spectrum. One feature appears to be common across the various disorders – limbic hyperactivity. Perhaps this is not so surprising as the limbic system is the ‘seat’ of emotion, and all the various disorders/forms are characterised by emotional upset.

But there also appear to be differences. For example, the orbitofrontal cortex (a higher centre, which ‘dampens’ and regulates emotion) appears to be underactive in bipolar I, but not in unipolar depression nor in borderline personality disorder.

Further work will be needed before clear-cut conclusions can be drawn. The authors conclude…”Eventually, as the respective signatures of personality-based emotional dysregulation and bipolar mood dysregulation become increasingly crisp, we may be able to use functional neural profile to assist in clarifying diagnosis or treatment options in clinically muddy presentations, although a great deal of work will need to be done before imaging will be sufficiently robust to be used in this manner.”

The full paper can be read here:

http://www.expert-reviews.com/doi/pdfplus/10.1586/ern.12.126