5 exciting developments in the management of Wilson’s disease

In all fairness, neurologists only very rarely come across patients with Wilson’s disease. This disorder of excessive copper deposition in tissues is however not vanishingly rare. And because it is one of the few curable neurological disorders, it is drummed into the brain of every neurologist to consider Wilson’s disease in any person, at any age, with any movement disorder. Dystonia is probably the most characteristic movement disorder in Wilson’s disease, and one of its classical signs is rhisus sardonicus, a fixed vacuous smile (which, by the way, may also be seen in tetanus). Other movement disorders of Wilson’s disease include parkinsonism, wing-beating tremor, ataxia, myoclonus, chorea, athetosis, stereotypies, tics, and restless legs syndrome. It is therefore not surprising that the disorder is named after one of neurology’s greats, Samuel Alexander Kinnier Wilson.

By Carl Vandyk – Carl Vandyk, Public Domain, https://commons.wikimedia.org/w/index.php?curid=11384670

The other name for Wilson’s disease is hepatolenticular degeneration. ‘Lenticular’ in this context refers to the favoured brain targets of Wilson’s disease, the lentiform nuclei. These are the putamen and globus pallidus, which, along with the caudate nucleus, make up the basal ganglia. The basal ganglia are very important in the coordination of movement, and are also dysfunctional in disorders such as Huntington’s disease and Parkinson’s disease.

By Niubrad at the English Wikipedia, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=19495297

Wilson’s disease is however more than a brain disorder because it is, quintessentially, multi-systemic. The monicker hepatolenticular, for example, hints at the prominent and varied involvement of the liver in Wilson’s disease. Liver dysfunction here ranges from mild elevation of liver enzymes, to frank hepatic failure requiring liver transplantation. The eye is another important organ targeted by Wilson’s disease, and the neurologist is ever searching for the tell-tale but elusive Kayser-Fleischer ring. This is a brownish tinge seen around the iris caused by copper deposition, and named after the German ophthalmologists Bernhard Kayser and Bruno Fleischer. Another distinctive eye sign in Wilson’s disease is the sunflower cataract. The long reach of Wilson’s disease however extends to almost every organ system.

By Herbert L. Fred, MD, Hendrik A. van Dijk – http://cnx.org/content/m15007/latest/, CC BY 3.0, https://commons.wikimedia.org/w/index.php?curid=2746925

Wilson’s disease is all about the ‘C’ words. The first ‘C’, Copper, is of course the essential element recognised as Cu, with atomic number 29, and snugly occupying group 4 in the periodic table. An autosomal recessive genetic mutation in ATP7B, the copper transporter gene, means some people are unable to move copper around the body. It therefore accumulates, and is eventually deposited, in almost every organ. Oh, and it also overflows in high amounts in urine.

Copper crystals. James St John on Flickr. https://www.flickr.com/photos/jsjgeology/17127538489

The other ‘C’ word is Ceruloplasmin, the blood protein that binds up the dangerous free-floating copper in the blood. The blood level of ceruloplasmin is low in Wilson’s disease because it is overwhelmed by the massive amounts of copper. The classical laboratory features of Wilson’s disease are therefore raised blood copper, low blood ceruloplasmin, and elevated 24 hour urinary copper excretion. The diagnosis of Wilson’s disease may also involve a liver biopsy to confirm copper accumulation, but this is rarely required. Long-term treatment depends on one of several therapeutic options for chelating or binding copper. Surveillance requires a tight monitoring regime to monitor the metabolic profile of the disease, and the complications its treatment.

By own work – adapted from http://www.pdb.org/pdb/files/1kcw.pdb using PyMOL, Public Domain, https://commons.wikimedia.org/w/index.php?curid=4982229

Is it however not all and dusted for Wilson’s disease. Not at all. There are advances being made to simplify the diagnosis and monitoring of this devastating disease, and below are 5 exciting developments in the management of Wilson’s disease.

Exchangeable copper

I learnt of this from a paper published in the European Journal of Neurology titled Exchangeable copper: a reflection of the neurological severity in Wilson’s disease. The authors, Aurelia Poujois and colleagues, investigated this new technique of measuring exchangeable copper (CuEXC) as an aid to the diagnosis of Wilson’s disease, and as an indicator of the severity of extra-hepatic damage. They studied 48 newly diagnosed subjects and found that CuEXC is a reliable test for making the diagnosis, and a cut-off value of >2.08 μmol/l is a marker of severe organ damage. Other papers have confirmed the value of exchangeable copper, even if they call it relative exchangeable copper.

By Alchemist-hp (pse-mendelejew.de) – Own work, CC BY-SA 3.0 de, https://commons.wikimedia.org/w/index.php?curid=6958463

X-ray fluorescence

Slávka Kaščáková and colleagues, in their paper published in the journal Pathology, touted X-ray fluorescence as a rapid way to quantify copper in tissues, thereby facilitating the diagnosis of Wilson’s disease. The rather technical paper, titled Rapid and reliable diagnosis of Wilson disease using X-ray fluorescence, describes the technique as ‘high‐resolution mapping of tissue sections’ which enables the measurement of ‘the intensity and the distribution of copper, iron and zinc while preserving the morphology’. This technique can, we have to accept, reliably distinguish Wilson’s disease from other diseases such as haemochromatosis and alcoholic cirrhosis. Not a bad deal, but the squeamish neurologist must realise it requires a liver biopsy!

X-ray Fluorescence Analyzer. IAEA Imagebank on Flickr. https://www.flickr.com/photos/iaea_imagebank/30483472557

Quantitative transcranial ultrasound

The typical method of ‘seeing’ the brain abnormalities of Wilson’s disease is by magnetic resonance imaging (MRI). Ultrasound is however much cheaper and easier, and would be a preferable option if it can be shown to be sensitive and specific. And this is what Gotthard Tribl and colleagues demonstrated in their paper published in the Journal of Neurological Sciences titled Quantitative transcranial sonography in Wilson’s disease and healthy controls: cut-off values and functional correlates. They reported that in Wilson’s disease, the lenticular nuclei (we are familiar with this now) and substantia nigra (literally a black substance in the midbrain) are hyperechogenic compared to normal control subjects. They also came up with reliable cut-off for normality. To make things better, the thalami and midbrain are also hyperechogenic. And to add the cherry on top, the third ventricle is enlarged. More than expected from a rather simple technology.

CC BY-SA 3.0, https://en.wikipedia.org/w/index.php?curid=19500021

Optical coherence tomography (OCT)

Hardly a day goes by that one doesn’t read a report on the applicability of optical coherence tomography (OCT) in one neurological disorder or the other. And Wilson’s disease is clearly not going to be the exception. OCT simply assesses the thickness or density of the retinal nerve fiber layer (RNFL), and this is reduced in many neurodegenerative diseases. In their paper titled Optical coherence tomography as a marker of neurodegeneration in patients with Wilson’s diseaseEwa Langwińska-Wośko and colleagues studied 58 subjects with Wilson’s disease. They reported that OCT can reliably measure the severity of Wilson’s disease, and it may reliably monitor disease progression. Another simple and non-invasive tool with big potential. 

Optical coherence tomography of my retina. Brewbooks on Flickr. https://www.flickr.com/photos/brewbooks/8463332137

Bis-choline tetrathiomolybdate

The treatment of Wilson’s disease centres on chelation or binding of copper. And the three major players here are  Penicillamine, Trientine, and Zinc, each with its own unique advantages and serious complications. They are however all rather cumbersome and inconvenient to administer and monitor. Into this unsatisfactory situation enters a study which promises to ease the burden for neurologist and patient. The trial is titled Bis-choline tetrathiomolybdate in patients with Wilson’s disease: an open-label, multicentre, phase 2 study, and it is published in the journal Lancet Gastroenterology and Hepatology. The authors, Karl Heinz Weiss and colleagues, investigated bis-choline tetrathiomolybdate (nicknamed WTX101), which they described as ‘an oral first-in-class copper-protein-binding molecule’. It binds up copper that is either stuck in the liver or swimming freely in blood. 70% of the 28 subjects they treated met the criteria for treatment success, and they were not unduly bothered by any nasty side effects. To add to this favourable profile, WTX101 has the convenience of a once daily dosing regime.

By I, Jonathan Zander, CC BY-SA 3.0, Link

 

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It is reassuring that so much as happening at the cutting edge of Wilson’s disease, and neurologists can’t wait to see when these will form part of their armamentarium.

The 13 most dreadful neurological disorders…and the groups standing up to them

Neurology embodies some of the most dreadful diseases known to man. Every neurological disorder is disheartening, each characterised by unique frustrations for patients and their families. It is difficult to quantify the distress and misery these afflictions impose on their victims, and even harder to appreciate the despair and anguish they evoke in those who care for them.

Brain Art. Ars Electronica on Flikr. https://www.flickr.com/photos/arselectronica/7773544158

It is clearly hard to compare the impact of different neurological diseases. Some neurological disorders however stand out because of the consternation their names evoke, and the terror that follows in their wake. These diseases come with unimaginable physical and psychological burdens, and crushing demands on human and material resources. They impose either a debilitating morbidity, or a hasty mortality.

Neural pathways in the brain. NICHD on Flikr. https://www.flickr.com/photos/nichd/16672073333

The nervous system ailments in the list below pose exacting therapeutic challenges, resistant as they are to all attempts at treatment or cure. This list sets out to emphasise the urgency for neuroscience to find a remedy for each of them, but it does not intend to belittle the horror of the disorders omitted from it. The choice of the number 13 is, sadly, self-evident. Here then are the top 13 most dreadful neurological disorders…all with gold links to the associations helping to defeat them.

Working Brain. Gontzal García del Caño on Flikr. https://www.flickr.com/photos/euskalanato/2052487054

Ataxia

Ataxia, in lay terms, is incoordination. This typically manifests as an unsteady gait and clumsiness. Ataxia converts all activities of daily living into burdensome chores. Whilst many types of ataxia are preventable or reversible, primary ataxias are progressive and carry a dismal outlook. In this category are Spinocerebellar ataxia (SCA)Friedreich’s ataxia, and Ataxia telangiectasia. You may read more about ataxia in these previous blog posts:

The 43 spinocerebellar ataxias: the complete checklists

Old drugs, new roles?

Will Riluzole really be good for cerebellar ataxia?

Brain tumours

Brain cancers hardly need any description. They are either primary, arising from the brain cells, or metastatic, spreading to the brain from other organs. Some primary brain cancers, such as meningiomas and pituitary tumours, are, relatively, treatable. Many others are unfortunately ominously malignant. The most dreadful in this category is surely the spine-chilling glioblastoma multiforme. You may check out these previous blog posts for more on these tumuors: 

Calming the rage of brain tumours: hope for a dreaded cancer

Maggots, viruses and lasers: some innovations for brain tumours 

Are steroids detrimental to survival in brain tumours?

Peripheral neuropathy

Peripheral neuropathy is ubiquitous in the neurology clinic. Neuropathy may result from reversible situations such as overindulgence in alcohol, uncontrolled diabetes, or Vitamin B12 deficiency. Neuropathy is often just a minor inconvenience when it manifests with sensory symptoms such as tingling and numbness. It may however be debilitating when it presents as limb paralysis, or complicated by major skeletal deformities. At the severe end of the spectrum of neuropathy are the hereditary forms such as Charcot Marie Tooth disease (CMT) and Familial amyloid polyneuropathy. Read more in these blog posts:

The 52 variants of CMT… and their practical checklists 

What’s looming at the frontline of peripheral neuropathy?

Will a pill really hold the cure for CMT?

Creutzfeldt Jakob disease (CJD)

CJD is the most iconic of the prion diseases. These disorders are as horrendous as they are enigmatic, defying categorisation as either infections or neurodegenerative diseases. More puzzling is their ability to be either hereditary and acquired. CJD exists in the classic or variant form, but both share a relentlessly rapid course, and a uniformly fatal end. You may read more in these previous blog posts titled:

Final day of ANA 2015- Prions center stage

What are the links between Prion diseases and Parkinsonian disorders?

Dementia

Dementia is the scourge of longevity. Its name strikes terror because it insidiously colonises the cells that make us who we are. The most prominent dementia is Alzheimer’s disease, but it has equally dreadful companions such as Frontotemporal dementia (FTD) and Dementia with Lewy bodies (DLB). Read more on dementia in these blog posts:

How bright is the future for Alzheimer’s disease?

Alzheimer’s disease: a few curious things 

Alzheimers disease and its promising links with diabetes

Dystonia

Dystonia marks its presence by distressing movements and painful postures. At its most benign, dystonia is only a twitch of the eyelid (blepharospasm) or a flicker of one side of the face (hemifacial spasm). At the extreme end, it produces continuous twisting and swirling motions, often defying all treatments. The causes of dystonia are legion, but the primary dystonias stand out by their hereditary transmission and marked severity. Read more on dystonia in these blog posts:

Why does dystonia fascinate and challenge neurology?

Making sense of the dystonias: the practical checklists

Huntington’s disease (HD)

Huntington’s disease is an iconic eponymous neurological disorder which is marked by the vicious triumvirate of chorea, dementia, and a positive family history. It is an awful condition, often driving its victims to suicide. It is a so-called trinucleotide repeat expansion disorder, implying that successive generations manifest the disease at an earlier age, and in more severe forms (genetic anticipation). You may read more on HD in the previous blog post titled:

What are the prospects of stamping out Huntington’s disease? 

Motor neurone disease (MND) 

Also known as Amyotrophic lateral sclerosis (ALS), MND is simply devastating. Recognising no anatomical boundaries, it ravages the central and peripheral nervous systems equally. MND creeps up on the neurones and causes early muscle twitching (fasciculations) and cramps. It then gradually devours the nerves resulting in muscle wasting, loss of speech, ineffectual breathing, and impaired swallowing. Our previous blog posts on MND are:

Is neurology research finally breaking the resolve of MND?

The emerging links between depression and MND

What is the relationship of MND and cancer?

Does diabetes protect from MND?

MND and funeral directors-really?

Multiple sclerosis (MS)

Multiple sclerosis is a very common disease, and gets more common the further away you get from the equator. It is the subject of intense research because of the devastation it foists on predominantly young people. Many drugs now ameliorate, and even seem to halt the progression of, relapsing remitting MS (RRMS). This is however not the case with primary progressive MS (PPMS) which, until the introduction of ocrelizumab, defied all treatments. There are many contenders vying for the cause of MS, but the reason nerves in the central nervous system inexplicably lose their myelin sheaths remains elusive. You may read more on MS in these blog posts:

The emerging progress from the world of MS

What are the remarkable drugs which have transformed the treatment of MS?

Is low vitamin D a cause of multiple sclerosis?

Muscular dystrophy 

Muscular dystrophy is an umbrella term that covers a diverse range of inherited muscle diseases. The most devastating, on account of its early onset and unrelenting progression, is Duchenne muscular dystrophy (DMD). Adult neurologists will be more familiar with late onset muscular dystrophies such as Myotonic dystrophy and Facioscapulohumeral muscular dystrophy (FSHD). Read more on muscular dystrophy in these previous blog posts:

How is neurology stamping out the anguish of Duchenne?

The A–Z of limb girdle muscular dystrophy (LGMD)

Rabies

Rabies, a rhabdovirus, is a zoonosis-it is transmitted to man by a wide range of animals such as dogs, bats, racoons, and skunks. It is the quintessential deadly neurological disease, popularised by the Steven King book and film, Cujo. Rabies manifests either as the encephalitic (furious) or the paralytic (dumb) forms. It wreaks havoc by causing irritability, hydrophobia (fear of water),  excessive sweating, altered consciousness, and inevitably death. Whilst there are vaccines to protect against rabies, a cure has eluded neuroscientists. This blog is yet to do justice to rabies but it is, at least, listed in the post titled What are the most iconic neurological disorders? But you could better by checking neurochecklists for details of the clinical features and management of rabies.

Spinal cord injury

Nothing is quite as heart-wrenching as the sudden loss of body function that results from spinal cord trauma. This often causes paralysis of both legs (paraplegia), or all four limbs (quadriplegia). This life-changing disorder is often accompanied by loss of control over bowel and bladder functions, and complications such as bed sores and painful spasms. You may read about the heroic efforts to treat spinal cord injury in the blog posts titled:

6 innovations in the treatment of spinal cord injury

Head transplant, anyone?

Tetanus

Tetanus is an eminently preventable disease, now almost wiped out in developed countries by simple immunisation. It however continues its pillage and plunder in the developing world. It strikes young and old alike, often invading the body through innocuous wounds. Tetanus is caused by tetanospasmin and tetanolysin, the deadly toxins of the bacterium Clostridium tetani. The disease is classified as generalised, localised, cephalic, or neonatal tetanus. It is characterised by painful spasms which manifest as lockjaw (trismus), facial contortions (risus sardonicus), trunkal rigidity (opisthotonus), and vocal cord spasms (laryngospasm). The disease is awfully distressing and, when advanced, untreatable. It is a stain on the world that this avoidable disorder continuous to threaten a large number of its inhabitants. Check neurochecklists for more on the pathology, clinical features, and management of tetanus.

 

Light brain. Mario D’Amore on Flikr. https://www.flickr.com/photos/kidpixo/3470448888

As for all lists, this will surely be subject to debate, or perhaps some healthy controversy. Please leave a comment.

What are the new diseases emerging in neurology?

Medical futurists predict that scientific advances will lead to more precise definition of diseases. This will inevitably result in the emergence of more diseases and fewer syndromes. This case is made very eloquently in the book, The Innovators Prescription. Many neurological disorders currently wallow at the intuitive end of medical practice, and their journey towards precision medicine is painfully too slow. Neurology therefore has a great potential for the emergence of new disorders.

https://pixabay.com/en/pie-chart-diagram-statistics-parts-149727/
https://pixabay.com/en/pie-chart-diagram-statistics-parts-149727/

In the ‘good old days’, many diseases were discovered by individual observers working alone, and the diseases were named after them. In this way, famous diseases were named after people such as James Parkinson, Alois Alzheimer, and George Huntington. For diseases discovered by two or three people, it didn’t take a great stretch of the imagination to come up with double-barrelled names such as Guillain-Barre syndrome (GBS) or Lambert-Eaton myasthenic syndrome (LEMS).

By uncredited - Images from the History of Medicine (NLM) [1], Public Domain, https://commons.wikimedia.org/w/index.php?curid=11648572
By uncredited – Images from the History of Medicine (NLM) [1], Public Domain, https://commons.wikimedia.org/w/index.php?curid=11648572
Today, however, new diseases emerge as a result of advances made by large collaborations, working across continents. These new diseases are named after the pathological appearance or metabolic pathways involved (as it will require an act of genius to create eponymous syndromes to cater for all the scientists and clinicians involved in these multi-centre trials). This is unfortunately why new disorders now have very complex names and acronyms. Take, for examples, chronic lymphocytic inflammation with pontine perivascular enhancement responsive to steroids (CLIPPERS) and chronic relapsing inflammatory optic neuropathy (CRION). It is a sign that we should expect new neurological diseases to be baptised with more descriptive, but tongue-twisting, names.

 

https://pixabay.com/en/letters-a-abc-alphabet-literacy-67046/
https://pixabay.com/en/letters-a-abc-alphabet-literacy-67046/

New disease categories emerge in different ways. One is the emergence of a new disorder from scratch, with no antecedents whatsoever. Such was the case with autoimmune encephalitis, a category which has come from relative obscurity to occupy the centre stage of eminently treatable diseases. I have posted on this previously as What’s evolving at the cutting edge of autoimmune neurology and What are the dreadful autoimmune disorders that plague neurology? Other disease categories form when different diseases merge into a completely new disease category, or when a previously minor diseases mature and stand on their own feet. These are the stuff of my top 8 emerging neurological disorders.

 

By Photo (c)2007 Derek Ramsey (Ram-Man) - Self-photographed, CC BY-SA 2.5, Link
By Photo (c)2007 Derek Ramsey (Ram-Man) – Self-photographed, CC BY-SA 2.5, Link

1. mTORopathy

This huge monster is ‘threatening’ to bring together, under one roof, diverse disorders such as tuberous sclerosis complex, epilepsy, autism, traumatic brain injury, brain tumours, and dementia. You may explore this further in my previous blog post titled mTORopathy: an emerging buzzword for neurology.

Merging bubbles. Charlie Reece on Flikr. https://www.flickr.com/photos/charliereece/777487250
Merging bubbles. Charlie Reece on Flikr. https://www.flickr.com/photos/charliereece/777487250

2. IgG4-related autoimmune diseases

This new group of neurological diseases is threatening to disrupt the easy distinction between several neurological disorders such as myasthenia gravis (MG), chronic inflammatory demyelinating polyradiculoneuropathy (CIDP), and Guillain Barre syndrome (GBS). It even includes the newly described IgLON 5 antibody disorder, something I blogged about as IgLON5: a new antibody disorder for neurologists. You may explore IgG4-related disorders in this paper titled The expanding field of IgG4-mediated neurological autoimmune disorders. 

By Aida Pitarch - Own work, CC BY-SA 4.0, Link
By Aida PitarchOwn work, CC BY-SA 4.0, Link

3. Anti-MOG antibody disorders

Now, neurologists have always known about MOG, mostly as a minor bit player, an extra, so to say. No more, it is now all grown up and matured. And the growth is fast and involves many inflammatory demyelinating disease of the CNS such as fulminant demyelinating encephalomyelitis and multiphasic disseminated encephalomyelitis. How far will it go?

http://thebluediamondgallery.com/a/autoimmune.html
http://thebluediamondgallery.com/a/autoimmune.html

4. Hepatitis E virus related neurological disorders

A field which is spurning new neurological disorders is neurological infections, and Hepatitis E virus (HEV) is in the forefront. We are now increasingly recognising diverse Hepatitis E related neurological disorders. HEV has now been linked to diseases such as Guillain Barre syndrome (GBS) and brachial neuritis. And the foremost researcher in this area is Harry Dalton, a hepatologist working from Cornwall, not far from me! And Harry will be presenting at the next WESAN conference in Exeter in November 2017.

By Transferred from en.wikipedia to Commons.This media comes from the Centers for Disease Control and Prevention's Public Health Image Library (PHIL), with identification number #5605.Note: Not all PHIL images are public domain; be sure to check copyright status and credit authors and content providers.English | Slovenščina | +/−, Public Domain, Link
By Transferred from en.wikipedia to Commons.This media comes from the Centers for Disease Control and Prevention‘s Public Health Image Library (PHIL), with identification number #5605.Note: Not all PHIL images are public domain; be sure to check copyright status and credit authors and content providers.English | Slovenščina | +/−, Public Domain, Link

5. Zika virus

Zika virus is another novel infection with prominent neurological manifestations. We are learning more about it every day, and you may check my previous blog post on this, titled 20 things we now know for certain about the Zika virus.

By Manuel Almagro Rivas - Own work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=47941048
By Manuel Almagro RivasOwn work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=47941048

6. Multisystem proteinopathy

Multisystem proteinopathy is a genetic disorder which affects muscles and bone, in addition to the nervous system. It is associated with Paget’s disease of the bone and inclusion body myositis, with implications for motor neurone disease (MND) and frontotemporal dementia (FTD). Quite a hydra-headed monster it seems, all quite complex, and perhaps one strictly for the experts.

Hydra. Andrew Jian on Flikr. https://www.flickr.com/photos/andrew_jian/475479747
Hydra. Andrew Jian on Flikr. https://www.flickr.com/photos/andrew_jian/475479747

7. GLUT-1 deficiency syndromes

GLUT-1 stands for glucose transporter type 1. Deficiency of GLUT-1 results in impaired transportation of glucose into the brainGLUT-1 deficiency syndrome presents with a variety of neurological features such as dystonia, epilepsy, ataxia, chorea, and a host of epilepsy types. It starts in infancy and is characterised by a low level of glucose and lactic acid in the cerebrospinal fluid. Expect to hear more on this in the near future.

Sugar Cubes. David pacey on Flikr. https://www.flickr.com/photos/63723146@N08/7164573186
Sugar Cubes. David pacey on Flikr. https://www.flickr.com/photos/63723146@N08/7164573186

8. Progressive Solitary Sclerosis

And this is my favourite paradigm shifter. Neurologists often see people with brain inflammatory lesions and struggle to decide if they fulfil the criteria for multiple sclerosis (MS). The current threshold for concern is when there have been two clinical events consistent with inflammation of the nervous system, or their MRI scan shows involvement of at least two different sites of the nervous system. Well, dot counting may soon be over, going by this paper in Neurology titled Progressive solitary sclerosis: gradual motor impairment from a single CNS demyelinating lesion. The authors identified 30 people with progressive clinical impairment arising from a single inflammatory nervous system lesion. The authors were convinced enough to recommend the inclusion of this new entity, progressive solitary sclerosis, in future classifications of inflammatory disorders of the central nervous system. Move over progressive MS, here comes progressive SS. Neurologists will surely have their job cut out for them.

Solitary tree at Sunset. epcp on Flikr. https://www.flickr.com/photos/epcprince/3418260382
Solitary tree at Sunset. epcp on Flikr. https://www.flickr.com/photos/epcprince/3418260382

Do you have any suggestions of emerging neurological disorders? Please leave a comment

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PS. These disorders are all covered in neurochecklists

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Metronidazole-two case lessons for neurologists

I came across two articles recently which highlighted neurological complications of metronidazole I was previously unaware of.

321-Metronidazole by Chris on Flikr. https://www.flickr.com/photos/chrisinplymouth/3947569729
321-Metronidazole by Chris on Flikr. https://www.flickr.com/photos/chrisinplymouth/3947569729

 

The first is a case report of metronidazole-induced encephalopathy in the journal Neurocritical Care. I admit I only read the abstract and the key word there is involvement of the dentate nuclei.

 

Metronidazole by Chris on Flikr. https://www.flickr.com/photos/chrisinplymouth/3949517597/
Metronidazole by Chris on Flikr. https://www.flickr.com/photos/chrisinplymouth/3949517597/

 

The second case report is of metronidazole-induced ataxia in the journal Movement Disorders.

 

These are rather uncommon side-effects and should not deter from prescribing metronidazole. But it is just worth looking more carefully at that medication list if your next patient  has unexplained encephalopathy or ataxia.

 

 

Old drugs, new roles?

Three recent articles caught my interest because they point to potential new roles for old drugs.

The first paper in the Lancet Neurology  suggests a role for Riluzole in hereditary cerebellar ataxia. With 50% of the treatment arm improving against 11% of the placebo arm, I hope this is not false hope for patients with Friedreich’s ataxia (FA) and spinocerebellar ataxia (SCA).

By Kamil9243 - Own work, CC BY 3.0, Link
By Kamil9243Own work, CC BY 3.0, Link

The second paper in Neurology reports that Statins reduce the risk of post-stroke seizures. You say hmmm, they say more studies needed.

By Solidach - With software of which I am the product manager, CC BY-SA 3.0, Link
By Solidach – With software of which I am the product manager, CC BY-SA 3.0, Link

The third paper in JNNP points to the benefit (or not) of Dantrolene for subarachnoid haemorrhage vasospasm. Feasible, tolearable and safe… but study not powered to detect efficacy!

By Jynto (talk) - Own workThis chemical image was created with Discovery Studio Visualizer., CC0, Link
By Jynto (talk) – Own workThis chemical image was created with Discovery Studio Visualizer., CC0, Link

Keep up with the expanding role of drugs in neurology with my recent blog posts:

 

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