Tagged: Tom Isaac

Exenatide: An editorial

editorial

In my previous post, we briefly reviewed the results of the phase II double-blind, randomised clinical trial of Exenatide in Parkinson’s disease. The study indicates a statistically significant effect on motor symptom scores after being treated with the drug.

Over the last few days, there have been many discussions about the results, what they mean for the Parkinson’s community, and where things go from here, which have led to further questions.

In this post I would like to address several matters that have arisen which I did not discuss in the previous post, but that I believe are important.


bydureon

I found out about the Exenatide announcement – via whispers online – on the afternoon of the release. And it was in a mad rush when I got home that night that I wrote up the post explaining what Exenatide is. I published the post the following evening however because I could not access the research report from home (seriously guys, biggest finding in a long time and it’s not OPEN ACCESS?!?!?) and I had to wait until I got to work the next day to actually view the publication.

I was not really happy with the rushed effort though and decided to follow up that post. In addition, there has been A LOT of discussion about the results over the weekend and I thought it might be good to bring aspects of those different discussion together here. The individual topics are listed below, in no particular order of importance:

1. Size of the effect

There are two considerations here.

Firstly, there have been many comments about the actual size of the effect in the results of the study itself. When people have taken a deeper look at the findings, they have come back with questions regarding those findings.

And second, there have also been some comments about the size of the effect that this result has already had on the Parkinson’s community, which has been considerable (and possibly disproportionate to the actual result).

The size of the effect in the results

The results of the study suggested that Exenatide had a positive effect on the motor-related symptoms of Parkinson’s over the course of the 60 week trial. This is what the published report says, it is also what all of the media headlines have said, and it sounds really great right?

The main point folks keep raising, however, is that the actual size of the positive effect is limited to just the motor features of Parkinson’s disease. If one ignores the Unified Parkinson’s Disease Rating Scale (UPDRS) motor scores and focuses on the secondary measures, there isn’t much to talk about. In fact, there were no statistically significant differences in any of the secondary outcome measures. These included:

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Are Dyskinesias days NAM-bered?

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Addex Therapeutics and the Michael J Fox Foundation are preparing to initiate a new clinical trial testing a new drug called Dipraglurant on levodopa-induced dyskinesia (Source).

Dipraglurant is a mGluR5 negative allosteric modulator (don’t panic, it’s not as complicated as it sounds).

In today’s post, we’ll explain what all of that means and look at the science behind this new treatment.


Dysco

An example of a person with dyskinesia. Source: JAMA Neurology

For anyone familiar with Parkinson’s disease, they will know that long term use of the treatment L-dopa can lead to two possible outcomes:

  1. The treatment loses it’s impact, requiring ever higher doses to be administered
  2. The appearance of dykinesias

Now, not everyone taking L-dopa will be affected by both of these outcomes, but people with young, onset Parkinson’s disease do seem to be at risk of developing L-dopa induced dykinesias.

What are Dyskinesias?

Dyskinesias (from Greek: dys – abnormal; and kinēsis – motion, movement) are simply a category of movement disorders that are characterised by involuntary muscle movements. And they are certainly not specific to Parkinson’s disease.

As we have suggested above, they are associated in Parkinson’s disease with long-term use of L-dopa.

Below is a video of two legends: the late Tom Isaacs (who co-founded the Cure Parkinson’s Trust) and David Sangster (he founded www.1in20Parkinsons.org.uk). They were both diagnosed with Parkinson’s disease in their late 20’s. Tom, having lived with Parkinson’s for 20 years at the time of this video provides a good example of what dyskinesias look like:

As you can see, dyskinesias are a debilitating issue for anyone who suffers them.

How do dyskinesias develop in Parkinson’s disease?

Before being diagnosed and beginning a course of L-dopa, the locomotion parts of the brain in a person with Parkinson’s disease gradually becomes more and more inhibited. This increasing inhibition results in the slowness and difficulty in initiating movement that characterises this condition. A person with Parkinson’s may want to move, but they can’t.

They are akinetic (from Greek: a-, not, without; and kinēsis – motion).

972px-Paralysis_agitans_(1907,_after_St._Leger)

Drawing of an akinetic individual with Parkinson’s disease, by Sir William Richard Gowers
Source: Wikipedia

L-dopa tablets provide the brain with the precursor to the chemical dopamine. Dopamine producing cells are lost in Parkinson’s disease, so replacing the missing dopamine is one way to treat the motor features of the condition. Simply giving people pills of dopamine is a non-starter: dopamine is unstable, breaks down too quickly, and (strangely) has a very hard time getting into the brain. L-dopa, on the other hand, is very robust and has no problem getting into the brain.

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Sinemet is L-dopa. Source: Drugs

Once inside the brain, L-dopa is quickly converted into dopamine. It is changed into dopamine by an enzyme called DOPA decarboxylase, and this change rapidly increases the levels of dopamine in the brain, allowing the locomotion parts of the brain to function more normally.

4INJ4aV

The chemical conversion of L-dopa to dopamine. Source: Nootrobox

In understanding this process, it is important to appreciate that when an L-dopa tablet is consumed and L-dopa enters the brain, there is a rapid increase in the levels of dopamine. A ‘spike’ in the supply of dopamine, if you will, and this will last for the next few hours, before the dopamine is used up.

As the effects of the L-dopa tablet wear off, another tablet will be required. This use of multiple L-dopa pills across the day gives rise to a wave-like shape to the dopamine levels in the brain over the course of the day (see the figure below). The first pill in the morning will quickly lift the levels of dopamine enough that the individual will no longer feel akinetic. This will allow them to be able to function with normal controlled movement for several hours before the L-dopa begins to wear off. As the L-dopa wears off, the dopamine levels in the brain drop back towards levels that will leave the person feeling akinetic and at this point another L-dopa tablet is required.

Dysk1

After several years of L-dopa use, many people with Parkinson’s disease will experience a weaker response to each tablet. They will also find that they have more time during which they will be unable to move (exhibiting akinesia). This is simply the result of the progression of Parkinson’s disease – L-dopa treats the motor features of the disease but only hides/masks the fact that the disease is still progressing.

To combat this shorter response time, the dose of L-dopa is increased. This will result in increasing levels of dopamine in the brain (as illustrated by the higher wave form over time in the image below). It will take more L-dopa medication induced dopamine to lift the individual out of the akinetic state.

Dyskinesias3

This increasing of L-dopa dosage, however, is often associated with the gradual development of abnormal involuntary movements that appear when the levels of L-dopa induced dopamine are the highest.

These are the dyskinesias.

Are there different types of dyskinesias?

Yes there are.

Dyskinesias have been broken down into many different subtypes, but the two main types of dyskinesia are:

Chorea – these are involuntary, irregular, purposeless, and unsustained movements. To an observer, Chorea will look like a very disorganised/uncoordinated attempt at dancing (hence the name, from the Greek word ‘χορεία’ which means ‘dance’). While the overall activity of the body can appear continuous, the individual movements are brief, infrequent and isolated. Chorea can cause problems with maintaining a sustained muscle contraction,  which may result in affected people dropping things or even falling over.

Dystonia – these are sustained muscle contractions. They often occur at rest and can be either focal or generalized. Focal dystonias are involuntary contractions in a single body part, for example the upper facial area. Generalized dystonia, as the name suggests, are contraction affecting multiple body regions at the same time, typically the trunk, one or both legs, and another body part. The intensity of muscular movements in sufferers can fluctuate, and symptoms usually worsen during periods of fatigue or stress.

We have previously discussed the current treatment options for dyskinesias (click here to see that post).

Ok, so what clinical trials are Addex Therapeutics and the Michael J Fox Foundation preparing and why?

They are preparing to take a drug called Dipraglurant through phase III testing for L-dopa inducing dyskinesias in Parkinson’s disease. Dipraglurant is a mGluR5 negative allosteric modulator.

And yes, I know what you are going to ask next: what does any of that mean?

Ok, so mGluR5 (or Metabotropic glutamate receptor 5) is a G protein-coupled receptor. This is a structure that sits in the skin of a cell (the cell membrane), with one part exposed to the outside world – waiting for a chemical to bind to it – while another part is inside the cell, ready to act when the outside part is activated. The outside part of the structure is called the receptor.

Metabotropic receptors are a type of receptor that is indirectly linked with channels in cell membrane. These channels open and close, allowing specific elements to enter the cell. When a chemical (or agonist) binds to the receptor and it becomes activated, the part of the structure inside the cell will send a signal to the channel via a messenger (called a G-protein).

The chemical that binds to mGluR5 is the neurotransmitter glutamate.

U4.cp2.1_nature01307-f1.2

Metabotropic glutamate receptor 5 activation. Source: Nature

But what about the “negative allosteric modulator” part of ‘mGluR5 negative allosteric modulator’

Good question.

This is the key part of this new approach. Allosteric modulators are a new class of orally available small molecule therapeutic agents. Traditionally, most marketed drugs bind directly to the same part of receptors that the body’s own natural occurring proteins attach to. But this means that those drugs are competing with those endogenous proteins, and this can limit the potential effect of the drug.

Allosteric modulators get around this problem by binding to a different parts of the receptor. And instead of simply turning on or off the receptor, allosteric modulators can either turn up the volume of the signal being sent by the receptor or decrease the signals. This means that when the body’s naturally occurring protein binds in the receptor, allosteric modulators can either amplify the effect or reduce it depending on which type of allosteric modulators is being administered.

allosteric_modulation_mechanism

How Allosteric modulators work. Source: Addrex Thereapeutics

There are two different types of allosteric modulators: positive and negative. And as the label suggests, positive allosteric modulators (or PAMs) increase the signal from the receptor while negative allosteric modulators (or NAMs) reduce the signal.

So Dipraglurant turns down the volume of the signal from the mGluR5 receptor?

Exactly.

By turning down the volume of the glutamate receptor mGluR5, researchers believe that we can reduce the severity of dyskinesias.

But hang on a second. Why are we looking at glutamate in dyskinesias? Isn’t dopamine the chemical of interest in Parkinson’s disease?

So almost 10 years ago, some researchers noticed something interesting in the brains of Parkinsonian monkeys that had developed dyskinesias:

Monkey2
Title: mGluR5 metabotropic glutamate receptors and dyskinesias in MPTP monkeys.
Authors: Samadi P, Grégoire L, Morissette M, Calon F, Hadj Tahar A, Dridi M, Belanger N, Meltzer LT, Bédard PJ, Di Paolo T.
Journal: Neurobiol Aging. 2008 Jul;29(7):1040-51.
PMID: 17353071

The researchers conducting this study induced Parkinson’s disease in monkeys using a neurotoxin called MPTP, and they then treated the monkeys with L-dopa until they began to develop dyskinesias. At this point when they looked in the brains of these monkeys, the researchers noticed a significant increase in the levels of mGluR5, which was associated with the dyskinesias. This finding led the researchers to speculate that reducing mGluR5 levels might reduce dyskinesias.

And it did!

Subsequent preclinical research indicated that targeting mGluR5 might be useful in treating dyskinesias, especially with negative allosteric modulators:

Monkey
Title: The mGluR5 negative allosteric modulator dipraglurant reduces dyskinesia in the MPTP macaque model
Authors: Bezard E, Pioli EY, Li Q, Girard F, Mutel V, Keywood C, Tison F, Rascol O, Poli SM.
Journal: Mov Disord. 2014 Jul;29(8):1074-9.
PMID: 24865335

In this study, the researchers tested the efficacy of dipraglurant in Parkinsonian primates  that had developed L-dopa induced dyskinesias. They tested three different doses of the drug (3, 10, and 30 mg/kg).

Dipraglurant significantly reduced dyskinesias in the monkeys, with best effect being reached using the 30 mg/kg dose. Importantly, the dipraglurant treatment had no impact on the efficacy of L-dopa which was still being used to treat the monkeys Parkinson’s features.

This research lead to a clinical trials in man, and last year Addex Therapeutics published the results of their phase IIa clinical trial of Dipraglurant (also called ADX-48621):

NAM

Title: A Phase 2A Trial of the Novel mGluR5-Negative Allosteric Modulator Dipraglurant for Levodopa-Induced Dyskinesia in Parkinson’s Disease.
Authors: Tison F, Keywood C, Wakefield M, Durif F, Corvol JC, Eggert K, Lew M, Isaacson S, Bezard E, Poli SM, Goetz CG, Trenkwalder C, Rascol O.
Journal: Mov Disord. 2016 Sep;31(9):1373-80.
PMID: 27214664

The Phase IIa double-blind, placebo-controlled, randomised trial was a dose escalation study, conducted in 76 patients with Parkinson’s disease L-dopa-induced dyskinesia – 52 subjects were given dipraglurant and 24 received a placebo treatment. The dose escalation assessment of dipraglurant started at 50 mg once daily to 100 mg 3 times daily. The study was conducted over 4 weeks.

The investigators found that dipraglurant significantly reduced the dyskinesias on both day 1 of the study and on day 14, and this treatment did not result in any worsening of the Parkinsonian features. And remember that this was a double blind study, so both the investigators and the participants had no idea which treatment was being given to each subject. Thus little bias can influence the outcome, indicating that dipraglurant really is having a beneficial effect on dyskinesias.

The company suggested that dipraglurant’s efficacy in reducing L-dopa-induced dyskinesia warrants further investigations in a larger number of patients. And this is what the company is now doing with the help of the Michael J. Fox Foundation (MJFF). In addition, dipraglurant’s potential benefits on dystonia are also going to be investigated with support from the Dystonia Medical Research Foundation (DMRF).

And the really encouraging aspect of this research is that Addex Therapeutics are not the only research group achieving significant beneficial results for dykinesias using this treatment approach (click here to read about other NAM-based clinical studies for dyskinesias).

Fingers crossed for more positive results here.

What happens next?

L-dopa induced dyskinesias can be one of the most debilitating aspects of living with Parkinson’s disease, particularly for the early-onset forms of the condition. A great deal of research is being conducted in order to alleviate these complications, and we are now starting to see positive clinical results starting to flow from that research.

These results are using new type of therapeutic drug that are designed to increase or decrease the level of a signal occurring in a cell without interfering with the normal functioning of the chemicals controlling the activation of that signal.

This is really impressive biology.


The banner for today’s post was sourced from Steam

Disco-needs-ya – the science of dyskinesias

This is Tom Isaacs. He is the charismatic founder of the Cure Parkinson’s trust.

tom isaacs

Tom Isaacs. Source: GrannyButtons

He’s a dude.

The man walked the entire coastline of the UK to raise money/awareness for Parkinson’s disease! Trust me, he’s a dude.

The title of today’s post is a salute to Tom’s efforts to offer a humourous label to what is a very serious and debilitating aspect of Parkinson’s disease.

In this post, we will discuss the science of dyskinesias


For the last 50 years, Levodopa (L-dopa) has been the “gold standard” treatment for Parkinson’s disease. By replacing the lost dopamine, L-dopa allows for the locomotion parts of the brain to become less inhibited and for people with Parkinson’s disease to feel more in control of their movements.

This miraculous treatment, however, comes at a terrible cost.

After long-term use of the drug, abnormal and involuntary movements can begin to appear. These movements are called dyskinesias.

Dykinesias

An example of a person with dyskinesia. Source: JAMA Neurology

What are Dyskinesias?

Dyskinesias (from Greek: dys/dus – difficulty, abnormal; and kinēsis – motion, movement) are simply a category of movement disorders that are characterized by involuntary muscle movements. They are certainly not specific to just Parkinson’s disease.

In Parkinson’s disease, they are associated with long-term use of L-dopa.

An example of dyskinesia can be seen in this video of Tom Isaacs and David Sangster discussing life with Parkinson’s disease (Tom was diagnosed at age 26 years of age and has lived with Parkinson’s for 20 years – he has dyskinesias. David was diagnosed in 2011 at age 29; since diagnosis he foundered www.1in20Parkinsons.org.uk. He’s also a dude!).

How do dyskinesias develop in Parkinson’s disease?

Before beginning a course of L-dopa, the locomotion parts of the brain in people with Parkinson’s disease is pretty inhibited. This results in the slowness and difficulty in initiating movement. They want to move, but they can’t. They are akinetic.

L-dopa tablets provide the brain with the precursor to the chemical dopamine. Dopamine producing cells are lost in Parkinson’s disease, so replacing the missing dopamine is one way to treat the motor features of the condition. Simply giving people pills of dopamine is a non-starter: dopamine is unstable, breaks down too quickly, and (strangely) has a very hard time getting into the brain. L-dopa, on the other hand, is very robust and has no problem getting into the brain.

Once inside the brain, L-dopa is quickly converted – via an enzymatic reaction – into dopamine allowing the locomotion parts of the brain to function close to normal. In understanding this process, it is important to appreciate that when a tablet is taken and L-dopa  enters the brain, there is a sudden rush of dopamine. A spike in it’s supply, and for the next few hours this gradually wears off as the dopamine is used up. This tablet approach to L-dopa treatment gives a wave like shape to the L-dopa levels in the brain over the course of the day (see the figure below).

After prolonged use of L-dopa (7-10 years on average), the majority of people with Parkinson’s disease will experience a shorter response to each dose of L-dopa. They will also find that they have more time during which they will be unable to move (exhibiting akinesia). This is simply the result of the disease progression – L-dopa treats the motor features of the disease but hides the fact that the disease is still progressing.

This shortening of response is often associated with subtle abnormal involuntary movements that appear when the levels of l-DOPA are highest (usually soon after taking a tablet). It is as if there is too much dopamine for the system to handle.

Gradually, the response time (during which normal movement is possible) will grow shorter and to combat this the dose of L-dopa is increased. But with increased levels of L-dopa, there is an increase in the involuntary movements, or dyskinesias.

Dyskinesia

This figure illustrates the course of Parkinson’s disease for some people on L-dopa. The waving line indicates the level of L-dopa in the blood (as a result of taking L-dopa medication). The white space is the area where normal movement is possible, while the grey area illustrates periods of akinesia (inability to move). Without L-dopa, people with Parkinson’s disease would be stuck in this area, and as the L-dopa pill wears off (during the downward part of the waving line) they fall back into the akinesia area, thus requiring another pill. As the disease progresses, the akinetic (grey) area increases, requiring higher levels of L-dopa to be administered in order to escape it. The tan coloured area in the top right corner demonstrates the introduction of dyskinesias.

Are there different types of dyskinesias?

Yes there are. Dyskinesias have been broken down into many different subtypes, but the two main types of dyskinesia are:

Chorea – these are involuntary, irregular, purposeless, and unsustained movements. To an observer, Chorea will look like a very disorganised/uncoordinated attempt at dancing (hence the name, from the Greek word ‘χορεία’ which means ‘dance’). While the overall activity of the body can appear continuous, the individual movements are brief, infrequent and isolated. Chorea can cause problems with maintaining a sustained muscle contraction,  which may result in affected people dropping things or even falling over.

Dystonia – these are sustained muscle contractions. They often occur at rest and can be either focal or generalized. Focal dystonias are involuntary contractions in a single body part, for example the upper facial area. Generalized dystonia, as the name suggests, are contraction affecting multiple body regions at the same time, typically the trunk, one or both legs, and another body part. The intensity of muscular movements in sufferers can fluctuate, and symptoms usually worsen during periods of fatigue or stress.

When were Dyskinesias first discovered?

Ironically but unsurprisingly, L-dopa induced dyskinesias were first reported by the same scientists who first reported the drug’s amazing effects in Parkinson’s disease:

Dyskinesia_title

Title: Modification of Parkinsonism – chronic treatment with L-dopa.
Authors: Cotzias GC, Papavasiliou PS, Gellene R.
Journal: New England Journal of Medicine. 1969 Feb 13;280(7):337-45.
PMID: 4178641

George Cotzias was one of the first physicians to give L-dopa to people with Parkinson’s disease.

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Dr George Cotzias. Source: NewScientist

Cotzias and colleagues administered L-dopa to 28 people with Parkinson’s disease (17 males and 11 females) and observed modest to moderate response in 8 of them, a marked response in 10, and dramatic responses in the other 10 people. During their two year observation period, they also reported seeing involuntary movements (dyskinesias) in half of the subjects in the study (14/28). They ranged from rare and fleeting (eg. grimacing or gnawing and wave-like motions of the head) to severe (eg. full body/limb movements). They noted that the dyskinesias were most severe in the people with the longest duration of the disease.

It should be noted that the speed with which some of the patients (that Cotzias was treating) developed their dyskinesias – less than 2 years – was a reflection on the late stage of the condition at which the treatment was begun. When the administration of L-dopa is started at an earlier stage, the window of effective treatment is generally longer (5-10 years, depending on individual cases).

So what causes the dyskinesias?

Oh boy.

This question is the source of much debate.

Volumes of text have been bashed out and sides have been taken. We are going to have to tread very carefully here for fear of upsetting folks is the world of Parkinson’s research.

There is some agreement, however, that the factors associated with the development of L-dopa-induced dyskinesias include:

  • the duration of the disease
  • the severity of the disease
  • the dose of L-dopa (cue the debating)
  • young age onset

There are also some genetic forms of Parkinson’s disease that can have an impact on the chances of developing dyskinesias.

Duration/severity of the disease – Experimental studies in animal models of Parkinson’s disease indicate that, if L-dopa is given to the animals, involuntary movements will only develop when the loss of dopamine in the brain exceeds 80–85% of normal. Clinical observations, however, indicate that the severe loss of dopamine in the brain is not sufficient for patients to develop dyskinesias.

This has lead to theories regarding intact part of the brain, suggesting that there are changes in the neurons that the dopamine is acting on. And indeed postmortem analysis of brains from people with & without dyskinesias suggests that there are differences in the neurons that dopamine act on (Click here and here for more on this).

The dose of L-dopa – in a large clinical study, the researchers found that an average daily L-dopa dose of 338 mg was not associated with dyskinesias, while an average daily dose of 387 mg was (Click here and here to read more on this).

Young age onset – Given the length of time that people with early-onset Parkinson’s disease will be on L-dopa, there is a strong association between early-onset and dyskinesias.


EDITORIAL NOTE: We are now about to discuss what can be done to alleviate dyskinesias. Before doing so, we here at the Science of Parkinson’s disease would just like to repeat our standard warning that the contents provided on this website is of an informative nature, and no actions should be taken based on what you have read without first consulting your doctor. Please seek medical advice before changing or experimenting with your treatment regime.


And what can be done to alleviate dyskinesias?

There are several methods of reducing dyskinesias:

Reducing L-dopa dose

Obviously, one can lower the dose of L-dopa. This almost always results in a reduction of dyskinesias. BUT, this almost always results in a worsening of Parkinson’s disease motor features, so it can’t really be considered a solution.

Dopamine receptor agonists

Rather than giving the brain L-dopa or dopamine, chemicals that behave exactly like dopamine can be administered. Dopamine receptor agonists are drugs that act on the receptors of dopamine that are present on the cells that dopamine acts on. These drugs have a longer half‐life than levodopa, meaning that they hang around in the brain for longer (eg. they are not broken down or used up as quickly as L-dopa).

In a large double‐blind study that compared the safety and efficacy of a dopamine receptor agonist – ‘Ropinirole’ – with that of levodopa over a period of five years, researchers found that the incidence of dyskinesia (regardless of levodopa supplementation) was 20% in the ropinirole group and 45% in the levodopa-only group (Click here for more on that study, and click here for a similar study with the dopamine agonist pramipexole).

One cautionary note – Dopamine agonists have been associated with the development of compulsive and impulsive behaviours (Click here for more on this).

Drugs acting on NMDA receptors

N-methyl-D-aspartate receptors (NMDA receptors) are receptors of the chemical glutamate. They are widely found in the brain, but during dyskinesias they appear to become more abundant. As a result, researchers have used drugs that block NMDA receptors (called NMDA receptor antagonists) as potential treatment for dyskinesias. And they appear to help in many cases.

In a double‐blind, placebo‐controlled study of 18 people with Parkinson’s disease, researchers found that the NMDA receptor antagonist ‘Amantidine’ reduced the duration of L-dopa-induced dyskinesias by 60% (Click here for more on this).

Drugs acting on serotonergic systems

Recently there has been a lot of attention focused on the role in dyskinesias of another chemical in the brain: serotonin. There is significant loss of serotonergic cells and fibres in the brain of people with Parkinson’s disease, though not to the same scale as dopamine.

A recent clinical study investigating the use of drugs that prolong the serotonin floating around in the brain (called selective serotonin reuptake inhibitors or SSRIs), found that they did not protect people with Parkinson’s disease from dyskinesias, but may delay their onset (Click here for more on this). There are also clinical trials investigating the use of serotonin receptor agonists in Parkinson’s disease with dyskinesias, based on positive results from preclinical studies (Click here for more on this).

More recently researchers have been investigating the role of serotonin cells in the production of dopamine from L-dopa. Serotonin cells are known to absorb L-dopa and to convert it into dopamine, but they do not have any means of storing it and they release it in an uncontrolled fashion. Recent studies in rodent models of L-dopa-induced dyskinesias have reported reductions in dyskinetic behaviour as a result of lesioning the serotonin cells or blocking specific serotonin receptors. The clinical relevance of these finding is yet to be tested, however.

Neurosurgery

The use of ‘pacemaker’ surgeries (such as deep brain stimulation targeting regions such as the globus pallidum or subthalamic nucleus) have been shown to be effective in treating advanced Parkinson’s disease. The resulting motor improvements are also associated with a reduction in dyskinesias.

A blinded pilot study comparing the safety and efficacy of deep brain stimulation in people with advanced Parkinson’s disease reported a 60-90% reduction in dyskinesias, depending on the region of the brain that was targeted (Click here for more on this).

Surgical lesions targeting the thalamus, globus pallidum or subthalamic nucleus have also been used in the treatment of advanced Parkinson’s disease, with reductions in dyskinesias also being observed. It is effective in both young as well as elderly subjects, with benefit persisting for up to 5 years. These surgical lesion procedures, however, are irreversible.

Recent advances in our understanding

We always like to bring you new research here at the Science of Parkinson’s disease and recently there have been some interesting results published. For example, this one:

Roussakis_title

Title: Serotonin-to-dopamine transporter ratios in Parkinson disease: Relevance for dyskinesias.
Authors: Roussakis AA, Politis M, Towey D, Piccini P.
Journal: Neurology. 2016 Published Feb 26.
PMID: 26920358

The researchers in this study conducted brain imaging on people with Parkinson’s disease who did have dyskinesias (17 people) and did not have dyskinesias (11 people). Specifically they were looking to see the difference in the density of dopamine and serotonin fibres in particular areas of the brain affected by dyskinesias. They found that people with Parkinson’s disease AND dyskinesias had a higher ratio of serotonin fibres to dopamine fibres than people with Parkinson’s disease but no dyskinesias. This result adds further support to the role that serotonin cells are playing in the development of L-dopa-induced dyskinesias.


 

Phew, long post.

If you have got this far and you are still reading – thanks! We hope it was informative.

In (shorter) future posts, we will be assessing new research dealing the mechanisms of and novel ways to treat dyskinesias. This post was meant to be an introduction that we will refer back to from time to time.

Stay tuned!