Tag Archives: cognitive impairment

Bladder and bowel, Intimate issues

Intimate issues: bladder dysfunction

Bladder dysfunction in people with MS is a sign of early damage, particularly to the spinal cord, and an early indication of a poor prognosis. Why do people with MS who develop bladder dysfunction do worse than those with no bladder symptoms? Here, I explain why I take bladder problems seriously and their implications for MS management.

Key points

  • Urinary hesitancy, urgency, frequency and incontinence, including at night, are bladder problems that affect many people with MS and cause significant frustration and anxiety.
  • A range of drug-based treatments, behavioural techniques and specialist physical interventions can help people with MS to manage bladder dysfunction and achieve adequate control.
  • However, the bladder pathways will probably continue to be affected in the long term due to the development of new lesions or the expansion of old lesions.
  • Frequent and severe urinary tract infections (UTIs) increase the likelihood that MS will progress.
  • I recommend regular dipstick testing at home, as part of your MS self-management, to increase the chances of early detection and treatment of a UTI.
  • Lifestyle approaches, such as avoiding smoking and reducing alcohol and caffeine consumption, should help to reduce bladder symptoms. Pelvic floor exercises are also important.
  • Dehydration is not a good way to control your bladder symptoms. Chronic dehydration can have a significant impact on your overall health and well-being and can exacerbate many of your MS symptoms.

Causes and significance of bladder dysfunction

Bladder dysfunction is the most common symptomatic problem I encounter in an MS clinic, affecting more than 50% of people with MS. It is one of the signs of early damage, particularly spinal cord damage, and an early indication of a poor prognosis. It therefore has important implications for treatment: if you have early bladder symptoms, you may want to take a more effective therapy early on rather than starting on a less effective DMT and waiting to see how you respond. It is best to maximise your chances of responding to treatment by opting for a highly efficacious therapy first-line. I call this ‘flipping the pyramid’.

Infections, both viral and bacterial, are a known trigger of relapse in MS. Frequent and severe urinary tract infections (UTIs) increase the likelihood that your MS will progress. This is why it is important to improve the management of bladder problems in people with MS to prevent or reduce UTIs. You can read more about managing  UTIs here.

Why do people with MS who develop bladder dysfunction do worse than those with no bladder symptoms? The bladder is a complicated organ with several neurological components that need to be coordinated. The descending nerve fibres that travel from the brain to the lower segments of the spinal cord are very long and have the greatest chance of being damaged by MS lesions in their path down to the bladder centre in the sacral area of the lower spinal cord. Therefore, any progressive or worsening MS damage is likely to manifest with bladder dysfunction early on.

The detrusor (or balloon) muscles and the sphincter (or valve) need to coordinate their action to enable normal bladder function. When the bladder is filling, the detrusor muscle relaxes to allow the bladder to expand and the sphincter contracts to keep the urine in the bladder. The opposite occurs when you pass urine; the sphincter opens and the detrusor contracts to empty the bladder.

Common MS-related bladder problems

Hesitancy

Urinary hesitancy occurs when the function of the detrusor and sphincter muscles is not coordinated: you try to pass urine, but the bladder sphincter won’t open. Hesitancy may be intermittent; if you try again later, the bladder will open, allowing you to pass urine. Conversely, the sphincter may close as you pass urine, which breaks up the urine stream or prevents complete bladder emptying; this can cause dribbling. The medical term for incoordination of the bladder muscles is dyssynergia or, more correctly, detrusor-sphincter-dyssynergia (DSD). People with MS find urinary hesitancy and its unpredictability very frustrating.

The drug treatment for DSD includes alpha-blockers (prazosin, indoramin, tamsulosin, alfuzosin, doxazosin and terazosin). Other strategies include small bladder stimulators or vibrators that are placed over the pubic area and work by blocking signals that inhibit the sphincters. The vibrators work in some people with MS and may help relax the sphincter.

Trying to relax when passing urine can help to improve hesitancy. The sound of running water, for example from a tap, may trigger the relaxation of the sphincter. Simulating this in public toilets may not be possible. Some people with MS find pressing on the lower abdomen helps. If all else fails, intermittent self-catheterisation (ISC) may be the only option to manage urinary hesitancy (see below).

Frequency and urgency

In MS the commonest bladder problem is spasticity, or irritability, of the detrusor muscle. The detrusor can’t relax, which prevents the bladder from filling to its maximum capacity. Frequent spasms of the detrusor muscle tell the brain that the bladder is full and you need to pass urine. This causes frequency, i.e. the need to use the toilet many times during the day and night. Frequency often accompanies the symptom of urgency, the need to get to the toilet as quickly as possible to prevent incontinence. 

When urgency is a problem, distraction techniques such as breathing exercises and mental tricks (e.g. counting) may be helpful. If urinary frequency is your main problem, you might try to retrain your bladder by holding on for as long as you can each time before passing urine. The aim is to train the detrusor muscle to expand more to hold on for longer when you need the toilet. These behavioural techniques rarely work for long; MS is a relapsing and/or progressive disease, and the bladder pathways will likely continue to be affected due to the development of new lesions or the expansion of old lesions.

Incontinence

Incontinence occurs when you lose the ability to suppress or ignore the signals from the detrusor muscle with the result that the sphincter relaxes or opens as part of a spinal cord reflex. We typically treat this problem with anticholinergic drugs, e.g. oxybutynin, solifenacin or tolterodine. The older generation anticholinergics such as oxybutynin cross the blood ̶ brain barrier and enter the brain, where they can exacerbate cognitive problems in people with MS. The commonest side effect of anticholinergics is dryness of the mouth; they can also worsen constipation. People with MS must be warned about the risk that anticholinergics will relax the bladder too much and precipitate urinary retention; the solution to urinary retention is ISC. 

The good news is that we now have a relatively new muscle relaxant, mirabegron (Betmiga), which activates the β3 adrenergic receptor in the detrusor muscle. I am increasingly using mirabegron to avoid the side effects (particularly cognitive issues) associated with anticholinergics. The main side effect of mirabegron is that it tends to increase your blood pressure.

Nocturia

Nocturia means you need to get up frequently at night to pass urine. If nocturia is your main bladder problem, using agents to concentrate the urine at night might help. A hormone called DDAVP works on the kidneys to reduce urine production; it is available as a nasal spray or tablets (Desmotabs or Desmospray). DDAVP should only be taken once a day, to avoid continuous water retention by the kidneys; this presents as swelling of the feet and reduces the salt or sodium levels in your blood, which can be dangerous. You therefore need to have your sodium levels checked about 4 ̶ 6 weeks after starting DDAVP therapy. 

Second-line treatments for bladder problems

If you fail to respond to anticholinergics, mirabegron and/or behavioural techniques, you need a bladder scan to see if you have a raised residual volume (the amount of urine left after you have emptied your bladder). If the residual volume is greater than 80 ̶ 100mL you may need to consider intermittent self-catheterisation (ISC). Some continence advisors act at the 80 mL threshold, and others at the 100 mL threshold, when recommending ISC.

Intermittent self-catheterisation

ISC serves two purposes. It increases your functional residual bladder volume, allowing more storage space for urine, which reduces frequency and urgency. This can help if you need to travel some distance or to join in a social activity without having to pass urine. It also helps to reduce nocturia, which in turn improves sleep and possibly MS-related daytime fatigue.

ISC also removes urine from the bladder. The residual urine acts as a culture medium for bacteria; by clearing your bladder you can prevent bladder infections. Conversely, if you don’t do the ISC technique correctly you can introduce bacteria into the bladder that then cause infections.

Botox

Botox injection into the detrusor muscle is increasingly used as a treatment for bladder dysfunction, in conjunction with ISC. Botox paralyses the muscle, turning it into a flaccid bag for urine storage. The surgical techniques that were previously used to remove the nerve supply to the bladder (which had the same effect as Botox) are now rarely used.

Percutaneous tibial nerve stimulation 

Percutaneous (or posterior) tibial nerve stimulation is a form of neuromodulation that can help with impaired bladder function and may improve urinary urgency, urinary frequency and urge incontinence. It is offered as a treatment in specialist neuro-urology units.

Permanent catheterisation

If all else fails, some people with MS may need to be permanently catheterised. This can be done via the urethra or the lower abdominal wall; the latter is called a suprapubic catheter. Being permanently catheterised sounds drastic, but this significantly improves the quality of life in some people with MS. Allowing bladder dysfunction to control your life can result in social isolation and constant anxiety about being incontinent in public. With the above-mentioned strategies, adequate bladder control should be the norm in MS.

In my experience, the biggest hurdle to achieving adequate bladder control is when people with MS assume their bladder symptoms are part of the disease and resign themselves to living with them. Such patients may start using continence pads as if this is normal or inevitable for someone living with MS. This is not normal; incontinence can lead to skin rashes and pressure sores. Please don’t accept this as the norm or something you must live with. If you have problems, tell your MS nurse or neurologist; they can help you.

Anatomy of the human urinary bladder; reproduced from Wikipedia, created by U.S. National Cancer Institute’s Surveillance, Epidemiology and End Results (SEER) Program.

Lifestyle factors that impact your bladder

Smoking, alcohol and caffeine

Nicotine irritates the bladder. If you are a smoker, then stopping smoking may significantly improve your bladder symptoms. Similarly, reducing alcohol and caffeine consumption may help; these agents are diuretics and cause the kidneys to make more urine.

Pelvic floor exercises

One of the treatments recommended to all patients with bladder problems is pelvic floor exercises. These are also important for managing bowel and/or sexual problems. For detailed guidance on incorporating these into your daily life, please see pelvic floor training post.

Avoiding dehydration

Try to anticipate times when urinary frequency and urgency will be most inconvenient; reducing the amount you drink beforehand may help. For example, don’t drink too much for 2 ̶ 3 hours before you go out. After you have finished passing urine, go back to the toilet again after a few minutes to try to pass some more urine. This is called the double micturition technique, which aims to ensure the bladder is emptied completely. However, do not reduce your total fluid intake to less than 1.5 litres each day.

Dehydration is not a good way to control your bladder symptoms. The issue of people with MS dehydrating themselves to manage their bladder problems was highlighted as early as the 1960s by Professor Bryan Matthews, a neurologist in Oxford, in his textbook on MS.

When researching the topic in the 1990s, it became clear to me that people with MS with severe disability were most likely to have bladder dysfunction and were chronically dehydrating themselves to manage urinary frequency, urgency and nocturia. Studies showed that a high urinary concentration of creatinine, a waste product that the kidneys filter out of the blood through the urine, correlated with increased disability levels. Urine containing myelin basic protein-like material (MBPLM), an indicator of myelin damage in MS, was also shown to correlate with disability. It is dehydration that causes higher levels of MBPLM and creatinine in the urine, indicating that dehydration is associated with disability.1 

A more recent paper from researchers in the Southampton group described the same findings, that urinary tract symptoms are very common in people with progressive MS and are associated with inadequate hydration.2

Despite highlighting the issue of chronic dehydration in MS over the years, it remains a persistent problem. My message is clear: don’t use dehydration to manage your bladder symptoms. Chronic dehydration can have a significant impact on your overall health and well-being and can exacerbate many of your MS symptoms. Some potential effects of chronic dehydration are listed in the box below.

  1. Physical performance: Dehydration can decrease physical endurance, cause muscle cramps and exacerbate or cause fatigue. This can affect overall physical performance and make everyday tasks more challenging.
  2. Cognitive function: Dehydration has been linked to cognitive impairment, including issues with concentration, alertness and short-term memory. Prolonged dehydration may even contribute to long-term cognitive decline.
  3. Mood and mental health: Studies have shown that dehydration can affect mood and contribute to increased feelings of anxiety and irritability. In severe cases, it can even lead to symptoms resembling depression.
  4. Kidney function: Chronic dehydration can put a strain on the kidneys, potentially leading to the formation of kidney stones and urinary tract infections. It can impair the kidneys’ ability to effectively filter waste from the blood. It also makes you more susceptible to the side effects of non-steroidal anti-inflammatory medications.
  5. Digestive problems: Dehydration can lead to constipation and other digestive issues. It may also contribute to an increased risk of developing peptic ulcers and acid reflux.
  6. Skin health: Inadequate hydration can lead to dry, flaky skin and exacerbate conditions such as eczema and psoriasis. Proper hydration is essential for maintaining overall skin health and elasticity.
  7. Heat-related illnesses: Dehydration reduces your body’s ability to regulate temperature, increasing the risk of heat exhaustion and heat stroke, particularly in hot and humid conditions. Please remember that people with MS, particularly those with more advanced MS, may already have a problem with thermoregulation.

In conclusion

I advise using a holistic approach to managing urinary symptoms, in addition to medication or other aids where recommended. Please review the questions below to check whether you are optimising your self-management.

  • Have you deconditioned your bladder because you are not training yourself to resist emptying it whenever you get the urge to pass urine? The bladder is a muscle that needs to be trained.
  • Have you tried peripherally acting anticholinergics or mirabegron?
  • Have you had a post-micturition bladder scan to see if you are emptying your bladder?
  • Do you need to use intermittent self-catheterisation to increase your functional bladder volume?
  • Do you have a chronic low-grade urinary tract infection? Are you performing regular urine dipstick testing (see post on UTIs and dipstick testing)?
  • Do you have bladder stones?
  • Have you tried DDAVP (Desmotabs or Desmospray) to help concentrate your urine without dehydrating yourself?
  • Are you avoiding bladder irritants or stimulants such as caffeine and nicotine?
  • Are you doing your pelvic floor exercises? If you are a post-menopausal woman, have you tried HRT (hormone replacement therapy)? Pelvic floor tone and bladder function often improve on HRT. 

References

  1. Giovannoni G, et al. Urinary myelin basic protein-like material as a correlate of the progression of multiple sclerosis. Ann Neurol 1996;40:128 ̶ 9.
  2. Kaninia S, et al. Dehydration associates with lower urinary tract symptoms in progressive multiple sclerosis. Eur J Neurol 2024;31: e16175.
Fatigue and insomnia, Sleep disorders

Understanding and managing insomnia in MS

Insomnia is the most common sleep disorder I encounter in my MS practice. It often goes untreated because people with MS accept it as part of living with the disease or because healthcare professionals (HCPs) prioritise other MS-related problems.

Key points

  • Insomnia is more common in people with MS than in the general population and is associated with poor mental health and other medical problems.
  • Factors that contribute to insomnia include anxiety, frequent visits to the bathroom, pain, leg spasms, restless legs, inability to roll over in bed, menopausal symptoms (hot flushes and night sweats) and poor sleep hygiene; they need to be managed appropriately.
  • Several online tools and questionnaires exist that can help you assess the nature and severity of insomnia.
  • Sleep aids (drugs) available over the counter or on prescription may be helpful.
  • Cognitive and digital approaches to insomnia management also have a role but are not widely available or suitable for everyone.
  • Complementary and alternative therapies are a valuable aid to self-management of insomnia.

Sleep, glorious sleep!

Sleep is the most essential performance-enhancing agent we know. You know what it is like if you wake in the morning and have had a good night’s sleep; you feel energised, your mood is good and you are ready to face the day. In contrast, when you wake from a night of tossing and turning, or not being able to turn, legs jerking, getting up several times to go to the toilet, maybe with a hangover from too much alcohol the night before, then you are irritable, your mood is low and it is challenging to get through the day. 

Most studies on sleep in MS show that over 70% of people with MS have a sleep disorder. In an MS-Selfie survey on sleep, a minority (33%) of 173 respondents described their sleep as good, very good or excellent, with 49% formally diagnosed with one or more sleep disorder and over 80% not having undergone formal sleep studies. Insomnia is the most common sleep disorder I encounter in my MS practice. Insomnia is defined as difficulty initiating or maintaining sleep, which can be a symptom or a disorder. If a disorder, insomnia is associated with a feeling of distress about poor sleep, and it disrupts social or occupational functioning.

Causes and impact of insomnia

In the general population, ~10% of adults have insomnia disorder and another 15 ̶ 20% report occasional insomnia, i.e. the symptom. In comparison, 40 ̶ 50% of people with MS have insomnia. Insomnia is more common in women than in men and is associated with poor mental health and other medical problems. Common MS-associated symptoms linked to insomnia (and resulting in fatigue) include pain, lack of bladder control, spasticity, restless legs, periodic limb movements and discomfort from being unable to turn in bed; other factors that contribute to insomnia – not just in people with MS but also more widely –  include alcohol and stimulant misuse, menopausal symptoms, poor sleep hygiene (daytime napping), deconditioning (lack of exercise), anxiety and depression. All these problems can interfere with sleep initiation, maintenance or perception in people with MS.

Insomnia can be episodic (with symptoms lasting 1 ̶ 3 months) or situational (of short duration, in response to a specific event of circumstance) and tends to follow a persistent course. Episodic insomnia refers to insomnia for a defined period, for example lasting several months linked to anxiety. In comparison, situational insomnia refers to insomnia triggered by a specific stimulus or event, such as sleeping away from home or after alcohol consumption. Chronic insomnia can cause depression and is associated in the general population with the development of hypertension and dementia. Insomnia assessment, diagnosis and management require a careful history to document its course, concomitant comorbidities and potential contributing factors. 

Several studies show that approximately 40% of people with MS have obstructive sleep apnoea and that it is not necessarily associated with obesity and a large neck. Sleep apnoea in MS may be due to brain stem pathology from MS affecting pharyngeal (throat) muscle function. If you know or think you are a snorer and you have periods when you stop breathing, you can download one of the many smartphone sleep apps that can assess this.

Approaches to managing insomnia

Any MS-related symptoms that can affect sleep need to be managed appropriately. How can you treat insomnia if your sleep is interrupted by anxiety-related rumination, nocturia, pain, leg spasms, restless legs, inability to roll over in bed, menopausal symptoms of hot flushes and night sweats and poor sleep hygiene

Recording your sleep patterns

A 24-hour history of sleep ̶ wake behaviours can help to identify additional behavioural and environmental factors for intervention. Patient-reported outcome measures (PROMS) and sleep diaries provide valuable information about the nature and severity of insomnia. They can help screen for other sleep disorders and monitor treatment progress.

A sleep diary should collect information on your sleep cycle (bedtime, arising time, napping) and estimates of your sleep ̶ wake characteristics, i.e. sleep latency (how long it takes to fall asleep), number and duration of awakenings, and an estimated overall sleep time. Useful PROMS include the Insomnia Severity Index, the Pittsburgh Sleep Quality Index, the STOP-BANG Sleep Apnea Questionnaire (for evaluating the risk of sleep apnoea) and the Restless Legs Syndrome Rating Scale

Sleep hygiene

I suggest you start with a simple self-help guide to improve your sleep hygiene.

  1. Ensure you spend an appropriate amount of time asleep, at least 6 hours in bed. Some people need more than this to feel refreshed. 
  2. Limit daytime naps to 30 minutes. Please note that napping does not make up for inadequate nighttime sleep. 
  3. Avoid stimulants such as caffeine, modafinil and nicotine close to bedtime. 
  4. Only drink alcohol in moderation. Alcohol is known to help you fall asleep faster, but too much disrupts sleep.
  5. Exercise helps improve sleep quality. As little as 10 minutes of aerobic exercise daily can enhance the quality of sleep. 
  6. Don’t eat before going to bed. Heavy foods and fizzy drinks can trigger indigestion or heartburn/reflux that disrupts sleep.
  7. Ensure you get adequate exposure to natural light; exposure to sunlight during the day and darkness at night help to maintain a regular sleep ̶ wake cycle. 
  8. Establish a regular relaxing bedtime routine, which helps the body recognise it is bedtime. This could include taking a shower or bath or reading. However, avoid reading or watching emotionally upsetting content before attempting to sleep.
  9. Make sure that your sleep environment is pleasant. Your mattress and pillows should be comfortable. The bedroom should be cool for optimal sleep (16 ̶ 20°C). The bright light from lamps, smartphones and television screens can make it difficult to fall asleep, so turn those lights off or adjust them when possible. Use the blue filter mode on your smartphone and other devices to reduce the inhibition of melatonin from light. Consider using blackout curtains, eyeshades, earplugs, white noise machines and other devices to make the bedroom more relaxing.
  10. If you have pain, nocturia, restless legs, sleep apnoea or other causes of discomfort, get these adequately managed via your HCP.

If these self-help measures fail, other current treatment options include prescription-only and over-the-counter (OTC) medications, cognitive behavioural therapy for insomnia (CBTI) and complementary and alternative therapies. 

Over-the-counter sleep aids

Over-the-counter sedatives tend to be first-generation antihistamines with potent centrally acting anticholinergic effects that impair cognitive function and long-term brain health. I recommend you avoid them (see newsletter entitled ‘Your anticholinergic burden’). 

Some people with MS self-medicate with OTC melatonin, cannabidiol (CBD) or tetrahydrocannabinol (THC) preparations. Melatonin has a U-shaped dose ̶ response curve for some individuals; therefore, lower doses may be better than higher doses. In general, I cannot recommend the use of CBD or THC for insomnia. CBD is a drug and is associated with liver toxicity; it may also interact with your other medications. However, if you do decide to buy CBD and/or THC, please use a reputable supplier and pharmaceutical-grade products. Medicinal cannabis cannot be prescribed on the NHS but can be obtained via private clinics. Many patients purchase it online; as a doctor, I cannot recommend buying it this way. 

Prescription-only sleep aids

If you raise the issue of insomnia with your HCP, they may reach for the prescription pad. Before accepting a sedative, please be aware of its limitations and ensure you have optimised all the above guidance. Sedatives are only a short-term solution; they work well for about 4 ̶ 5 days before you develop tachyphylaxis and need higher doses. Tachyphylaxis refers to the rapidly diminishing response to successive doses of a drug, rendering it less and less effective. Once you develop tachyphylaxis and stop taking sedatives, you may experience rebound insomnia. Benzodiazepines (e.g. diazepam) are addictive and doctors generally avoid prescribing them for insomnia. However, they still have a role when insomnia is part of acute anxiety. The sedatives most often used are the so-called Z-drugs (zolpidem, zopiclone, zaleplon and eszopiclone). Zopiclone and eszopiclone have a longer half-life than the other two drugs (5 ̶ 6 hours). In comparison, zolpidem and zaleplon act for a much shorter period (1 ̶ 3 hours). 

The older, tricyclic antidepressants, such as amitriptyline, are commonly used as sedatives. I have largely stopped prescribing them unless there is another reason for using a tricyclic, e.g. to help with pain management (please read my newsletter ‘Amitriptyline: the neurologist‘s dirty little secret’. I mostly use duloxetine in my clinical practice for pain management. It is not as sedating as tricyclic antidepressants, but some patients find it helps with sleep. Duloxetine is a serotonin ̶ noradrenaline reuptake inhibitor and has fewer anticholinergic side effects than tricyclics.

Antispasticity agents such as baclofen and gabapentinoids (gabapentin and pregabalin) also help sleep, but they should only be used for insomnia if you have spasticity or, in the case of the gabapentinoids, spasticity and/or pain that needs to be managed.  

Psychiatrists and some neurologists use sedating antipsychotics to help with insomnia. Sadly, as a neurologist, I have seen too many severe adverse events resulting from the liberal use of antipsychotics as sedatives. There needs to be a good reason for prescribing an antipsychotic, and insomnia in isolation is not one of them; however, there is a role for them in patients with cognitive issues or significant psychiatric problems. The older generation antipsychotics (e.g. haloperidol) have now been replaced by safer drugs such as quetiapine and olanzapine.

A new class of sedatives is now available in some countries; these are the dual orexin receptor antagonists suvorexant, lemborexant and daridorexant. Daridorexant is NICE approved for use by the NHS; it is recommended for treating insomnia in adults with symptoms lasting for 3 nights or more per week for at least 3 months and whose daytime functioning is considerably affected, but only if CBTI has been tried and not worked, or if CBTI is not available or is unsuitable.

Cognitive approaches to managing insomnia

Cognitive Behavioural Therapy for Insomnia (CBTI)

Only some patients receive CBTI, owing to a lack of adequately trained therapists. CBTI aims to change the behaviour and psychological factors that contribute to insomnia (e.g. anxieties and unhelpful beliefs about sleep). At the core of CBTI are behavioural and sleep-scheduling strategies (sleep restriction and stimulus control instructions), relaxation methods, psychological and/or cognitive interventions to change unhelpful beliefs or excessive worrying about insomnia, and sleep hygiene education. 

CBTI is focused on sleep and oriented toward problem-solving. A psychologist typically guides the process over roughly six consultations. Several variants in the methods for implementing CBTI include shorter formats, group therapy, using other providers such as counsellors and specialist nurses, and the use of telehealth digital platforms, including smartphone applications. 

Brief behavioural treatment for insomnia

This abbreviated version of CBTI emphasises behavioural components and is typically implemented in fewer sessions. It involves education about sleep regulation, factors that promote or interfere with sleep, and a tailored behavioural prescription based on stimulus control and sleep restriction therapy.

eCBTI

Digital CBTI (eCBTI) is becoming increasingly popular. The Sleepio application, which is recommended and covered by the NHS, has a positive effect on several sleep outcomes and is said to be as effective as medication. NICE recommends Sleepio as a cost-saving option for treating insomnia and insomnia symptoms in primary care for people who would otherwise be offered sleep hygiene or sleeping pills. A medical assessment should be done before referral to Sleepio for people who may be at higher risk of other sleep disorder conditions, such as during pregnancy or in people with comorbidities.

Complementary and alternative therapies

Sleep restriction

Limit the time you spend in bed to match your sleep time as closely as possible. After the initial restriction, the sleep window can be gradually adjusted upward or downward on a weekly basis as a function of sleep efficiency (time asleep÷time spent in bed×100) until an appropriate sleep duration is established.

Stimulus control

You need to follow a set of instructions designed to reinforce the association between bedtime and bedroom stimuli with sleep and to re-establish a consistent sleep ̶ wake schedule.

  • Go to bed only when you feel sleepy.
  • Get out of bed when you are unable to sleep.
  • Use the bed and bedroom for sleep and sex only; do not use your bed for reading, watching television, etc.
  • Try and get up at the same time every morning.
  • Avoid napping.

Relaxation training

Try using different procedures such as progressive muscle relaxation and imagery training to reduce arousal, muscle tension and intrusive thoughts that interfere with sleep. Relaxation procedures need to be practised daily over a few weeks. 

Cognitive therapy

This is a psychological approach to revising many common misconceptions about sleep and reframing unhelpful beliefs about insomnia and its daytime consequences. This method also reduces excessive worrying about sleep difficulties and their daytime consequences. Additional cognitive strategies include paradoxical intention (willingly trying to stay awake rather than trying to fall asleep) to alleviate the performance anxiety triggered by attempting to force sleep.

Sleep hygiene education

These general guidelines include advice about a healthy diet, exercise, substance use, and optimising environmental factors such as light level, noise and excessive temperature that may promote or interfere with sleep (see above). 

Acceptance and commitment therapy (ACT)

ACT is a form of psychotherapy that aims to educate people to stay focused on the present moment and accept life experiences, thoughts, and feelings (even negative ones) without trying to change them. ACT uses different methods and processes (e.g. acceptance, defusion, mindfulness, and committed action) to increase psychological flexibility.

Mindfulness

This meditation method involves observing one’s thoughts and feelings and letting go of the need to change or ruminate. Originally designed to reduce stress and anxiety, mindfulness has been adapted for the management of insomnia and can be included as one component of ACT.

Conclusion

Poor sleep, be it due to a comorbid sleep disorder, MS-related symptoms or poor sleep hygiene, is a very common problem in people with MS. It contributes to daytime fatigue and hypersomnolence and impacts physical and cognitive function. As a result, poor sleep reduces quality of life and can exacerbate other MS-related problems such as poor cognition, anxiety and depression. It is essential that poor sleep is documented, investigated appropriately and treated accordingly to improve the functioning and quality of life of people with MS.

Fatigue and insomnia, Sleep disorders

Fatigue in MS – a disabling symptom

Fatigue in MS is common, but it is often not investigated or managed properly. This post highlights the complexity of MS-related fatigue and explains why and how to manage it holistically. 

Key points

  • The different mechanisms underlying MS-related fatigue are explained.
  • The MS disease process, the burden of living with MS, and other factors such as drug side effects, comorbidities and lifestyle choices may all contribute to fatigue in MS.
  • Practical guidance is provided on managing many aspects of MS-related fatigue, using a holistic and systematic approach.
  • Not all fatigue is MS-related; it is important to ascertain if your fatigue could be due to another disease process.

Fatigue is one of the most disabling of all the symptoms of MS. It is the symptom that over 50% of people with MS would most like to be rid of. MS-related fatigue has several underlying mechanisms.

Fatigue caused by MS disease processes

Inflammation in the brain

Inflammatory mediators or cytokines associated with MS – in particular, interleukin-1 (IL-1) and TNF-alpha – trigger ‘sickness behaviour’. This is the response to inflammation that forces us to rest and sleep so that our body can recover. Sickness behaviour is also the body’s response to a viral infection such as flu; in fact, many people with MS describe their fatigue as being like the fatigue they experience with flu. 

Sickness behaviour from an evolutionary perspective is well conserved and occurs in most animals. This type of fatigue needs to be managed by switching off ongoing inflammation in the brain. Many people with MS who take a highly effective DMT report feeling much better and free from fatigue and/or brain fog. This is why recent-onset fatigue that cannot be explained by other factors (see below) may indicate MS disease activity. At present, fatigue on its own does not constitute a relapse.

Many patients with MS who have had COVID-19 tell me that MS-related cog-fog and fatigue feel like the cog-fog and fatigue of COVID-19 and long-COVID. As many as one in four people with long-COVID experience cog-fog, which includes problems in attention, language fluency, processing speed, executive function, and memory: these are the same problems that affect people with MS. 

Cog-fog related to MS and to COVID-19 could be linked to the same inflammatory mechanisms. This syndrome of systemic inflammation causing profound fatigue and cog-fog is not new. Some people with MS who have a systemic infection take weeks or months to return to normal; some patients with more advanced MS never return to their original baseline. This is why, as part of the holistic management of MS, we need to treat and prevent systemic infections as best we can.

The overlap between COVID-19 and MS-related cog-fog raises the question whether both are due to viral infections. There is some evidence of recent Epstein-Barr virus (EBV) reactivation in patients with long-COVID,1 suggesting that the EBV rather than the SARS-CoV-2 may be causing long-COVID symptoms. This is important because chronic EBV infection has been associated with chronic fatigue syndrome. It has also been suggested that chemo-brain is due to similar mechanisms, i.e. chemotherapy triggers CNS inflammation, which causes cog-fog.

Neural plasticity

When parts of the brain are damaged by MS, other areas are co-opted to help take over, or supplement, the function of the damaged area. In other words, people with MS use more brain power than people without MS to complete the same task. This usually manifests as mental fatigue and is why people with MS have difficulty concentrating for prolonged periods and multitasking. At present we have no specific treatment for this type of fatigue, but some patients find amantadine or modafinil helpful. There is also some emerging evidence that fampridine may help with cognitive fatigue. However, preventing damage in the first place should prevent this type of fatigue.

Exercise-related conduction block

Damage to axons that conduct electrical impulses is the reason why people with MS notice their legs getting weaker or another neurological symptom getting worse with exercise. We think this is due to demyelinated or remyelinated axons failing to conduct electrical impulses when they become exhausted. Exercise-induced fatigue is probably the same as temperature-related fatigue; a rise in body temperature also causes vulnerable axons to block and stop conducting. To deal with this type of fatigue we need therapies to promote remyelination and to increase conduction. These types of fatigue are treated by rest, cooling and possibly drugs such as fampridine that improve conduction. At the heart of this type of fatigue is localised energy failure.

Fatigue from living with MS symptoms

Temperature sensitivity

Many people with MS are temperature sensitive. Typically, high temperatures worsen fatigue, but low temperatures also affect some patients. Many people with MS manipulate their behaviour to avoid hot or cold environments. Some find it helpful to use cooling suits, but these are costly and are not covered by NHS funding. Cold or ice baths, swimming and air conditioning can all help with temperature-related fatigue.

Case example

One of my patients had a walk-in butcher’s fridge installed in her house, and she spends 30 minutes there 4 ̶ 5 times a day to manage her fatigue. She is a wheelchair user, and she sits in her wheelchair in the fridge.

Menstrual and menopausal fatigue

Menstrual (or catamenial) fatigue is a form of temperature-related fatigue that occurs in women during the second half of the menstrual cycle when their body temperature increases. It responds to paracetamol and to non-steroidal anti-inflammatory drugs such as ibuprofen and naproxen. Fatigue is a common symptom of menopause too; some women with MS who are menopausal and have fatigue find hormone replacement therapy helpful. 

Whether or not men go through a ‘menopause’ is a moot point. Testosterone levels do drop with age, however, and some male patients find that testosterone replacement therapy helps their MS-related fatigue. In the UK, the indications for testosterone replacement therapy are very well defined and do not include MS-related fatigue, so most people with MS who want to try this therapy need to pay for a private prescription.

Bladder problems

Intermittent waking due to bladder problems may result in fatigue from disrupted sleep. Bladder problems may also contribute to insomnia, with the affected individual needing to visit the bathroom frequently and unable to relax into sleep. For detailed guidance on managing bladder problems, particularly at night, please see the bladder and bowel section of the website, particularly the article on nocturia.  

Insomnia due to pain and discomfort

Other disease-related factors that contribute to fatigue include insomnia from pain, discomfort of being unable to turn in bed and restless legs syndrome (RLS). RLS is common in people with MS, affects sleep quality and is associated with poor cognition. For detailed guidance on managing these MS symptoms, please see the post entitled Sleep disrupted by pain and discomfort.  

A case scenario

“A 28-year-old woman with early relapsing ̶ remitting MS, on glatiramer acetate, and little overt neurological impairment suffers from severe fatigue, which is worse during the latter half of her menstrual cycle. She has recently split up with her long-term partner because of the impact her symptoms have had on her relationship. She has also had to stop working as a bank clerk because of her fatigue.”

Prof G’s response
This patient needs to be examined and will need an MRI and a lumbar puncture to measure her spinal fluid neurofilament levels. If she has evident inflammatory disease activity, her DMT will need to be switched. She needs a full medical assessment, which includes a screen for comorbidities.

The patient complains of cognitive fatigue and, despite not having much physical disability, she was found to have a high brain MS lesion load and noticeable brain volume loss. A formal neuropsychological assessment to establish if she has cognitive impairment would allow her to be referred to a cognitive rehabilitation programme; this can target specific areas to help her cope with her cognitive deficits.

To combat fatigue during her menstrual cycle, this patient did well on naproxen, which is longer acting than ibuprofen and paracetamol. Naproxen only needs to be taken during the second half of her cycle. She was screened for poor sleep hygiene, and she volunteered intermittent early morning waking due to bladder problems and anxiety. Both would need to be addressed as part of her fatigue management programme.

It was clear that the patient had both depression and anxiety, which were related to the impact of MS on her occupational and social functioning. This must be managed with cognitive behavioural therapy (CBT), mindfulness and an exercise programme. If this approach is not helpful, then I would suggest the judicious use of an antidepressant and, failing this, a referral to a psychiatrist and/or psychologist.

Fatigue resulting from other factors

Comorbidities and other diseases

Comorbidities and other diseases related to MS can cause fatigue and should be screened for. These include infections (see above). In people with more advanced MS, the urinary tract is most often affected, but other sites of infection include the sinuses, teeth, lungs, skin (intertrigo and pressure sores) and bowels.

Fatigue is common with thyroid disease; an underactive thyroid gland (hypothyroidism) and an overactive gland (hyperthyroidism, or thyrotoxicosis) cause fatigue. Diabetes, other endocrine (hormonal) problems, anaemia and heart, kidney, liver or lung diseases all cause fatigue.

Side effects of drugs

Fatigue is a common side effect of many medications, particularly drugs that cause sedation and some DMTs. Flu-like side effects from interferon-beta, for example, may make fatigue worse. Anticholinergics and antispasticity drugs are sedating, blunt cognition and may worsen MS-related fatigue. If you have fatigue, therefore, it is important to review your medications. MS is associated with polypharmacy, but some of the medications that cause or exacerbate fatigue can be reduced in dose, stopped or potentially replaced with alternatives that don’t exacerbate fatigue.

Lack of sleep and/or sleep disorders

Poor sleep means you feel tired in the morning. Most people with MS have poor sleep hygiene and almost half have an actual sleep disorder. A clue to this is how you feel in the morning and whether you have excessive daytime sleepiness. If you wake up in the morning and don’t feel refreshed and/or you fall asleep frequently during the day, you need a formal sleep assessment. You can complete the Epworth Sleepiness Scale online to see if you have a problem.

Depression and anxiety

Fatigue is a common symptom of depression and anxiety. Of the many online screening tools for depression and anxiety, the best one to use if you have MS is probably the Hospital Anxiety and Depression Scale (HADS)

Obesity

Being overweight requires additional energy to perform physical tasks, and obesity itself causes fatigue. Recently an association has been found between obesity and depression. Obesity also predisposes you to sleep disorders; obese people with MS are more likely to have obstructive sleep apnoea. For all these reasons you should engage with lifestyle and wellness programmes to manage obesity and fatigue. 

Deconditioning

Deconditioning is simply the term we use for being unfit. If you are unfit, performing a demanding physical task makes you tired. Deconditioning is treated with exercise, which paradoxically can reduce fatigue. Patients may claim that exercising makes their fatigue worse. Yes, that does happen, but if you persevere and get fitter your fatigue often improves. The important thing is to start a graded exercise programme and build up slowly. Exercise does some incredible things to the brain, many of which explain why it is effective at treating not only fatigue but also depression and anxiety. Exercise is a form of ‘disease-modifying therapy’ and hence everyone with MS should be participating in an exercise programme. 

Poor nutrition and ‘food coma’

Some people with MS are anorexic and eat very poorly; as a result, they have little energy. Although this is quite rare, I have had a few such patients over the years. Similarly, overnutrition may have the same effect. Some of the hormones your gut produces cause you to feel tired and want to sleep; this is the so-called siesta effect (also referred to as food coma or postprandial hypersomnolence). Reducing the size of your meals and changing your eating behaviour may improve this. Postprandial hypersomnolence has two components.

  1. A state of perceived low energy related to activation of the parasympathetic nervous system (which is part of the autonomic nervous system) in response to expansion of the stomach and duodenum from a meal. In general, the parasympathetic nervous system slows everything down. 
  2. A specific state of sleepiness triggered by the hormone cholecystokinin that helps digest food and regulate appetite. It is released in response to eating and to changes in the firing and activation of specific brain regions. The coupling, or interaction, of digestion and the brain is referred to as ‘neurohormonal modulation of sleep’ and it underlies the reflexes responsible for postprandial hypersomnolence. There is therefore a well-studied biological reason why we feel sleepy after eating a meal. 

Managing food coma – practical tips

The first patient who alerted me to the problem of food coma in MS was so affected by postprandial hypersomnolence that she now eats only one meal a day, late in the evening. She can then ‘crash’ and go to sleep about an hour after eating. She needs to be functional during the day but cannot do her professional work if she eats anything substantial during working hours because of her overwhelming desire to sleep. She has tried caffeine, modafinil and amantadine to counteract postprandial hypersomnolence, but all these substances had only a small effect.

Other patients reporting postprandial hypersomnolence derive some benefit from the judicious use of stimulants. You can start by self-medicating with caffeine, but this may have the drawback of worsening your bladder function. Please note, however, that it is not advisable to take stimulants later than about 3 pm or 4 pm because they have a long half-life and can cause insomnia.

Some patients find carbohydrate-rich foods particularly potent at inducing ‘food coma’. Indeed, glucose-induced insulin secretion is one of the drivers of this behavioural response. This may be why people who fast or eat very low-carbohydrate or ketogenic diets describe heightened alertness and an ability to concentrate for long periods. Another option is to reduce your meal size: instead of large meals, try eating multiple small snacks during the day.

Exercise has helped some patients deal with postprandial hypersomnolence. I am not sure exactly how exercise works – possibly by lowering glucose and insulin levels and improving insulin sensitivity. The latter will reduce hyperinsulinaemia, which not only causes postprandial hypersomnolence but is an important driver and component of metabolic syndrome and obesity.

Postprandial hypersomnolence will be worse if you already suffer from a sleep disorder and excessive daytime sleepiness. Most people with MS have a sleep disorder, so there is little point in focusing on postprandial hypersomnolence and ignoring the elephant in the room.

Using your energy effectively

One strategy to manage MS-related fatigue is to imagine your energy levels as a battery, i.e. you have only so much energy in the day. People with MS have smaller batteries than people without MS and therefore need to plan their day and activities to maximise their use of energy. For example, if you do something tiring in the morning, you should rest in the afternoon to conserve energy for evening activities. Similarly, if you find some activities very tiring, such as taking a hot shower or bath, plan to do this in the evening before bed.

Conclusion

It is apparent from this discussion that fatigue in MS is more complex than we realise. So be careful, or at least wary, if your neurologist simply wants to reach for the prescription pad to get you out of the consultation room. Any MS-related symptoms that can affect sleep need to be managed accordingly. Like other MS-related problems, a holistic and systematic approach is needed to manage and treat MS-related fatigue correctly. Not all fatigue is MS-related. This is why it is important to take a step backwards and ask yourself if your fatigue could be due to another disease process.

Reference

  1. Gold JE et al. Investigation of long COVID prevalence and its relationship to Epstein-Barr virus reactivation. Pathogens 2021;10:763.
Detail, DMTsDetail, Treatment strategy

What are the attributes of the specific DMTs?

Multiple sclerosis (MS) treatment has evolved rapidly, with 11 classes of disease-modifying therapy (DMT) now available in the UK. I will summarise them briefly and explain how they fit within a treatment paradigm for effective and safe use.

Maintenance therapies versus immune reconstitution: what’s the difference?

There is a divide between the two main treatment philosophies: maintenance ̶ escalation versus immune reconstitution therapies (IRTs).

An IRT is given as a short course – a one-off treatment in the case of autologous haematopoietic stem cell transplantation (AHSCT) or intermittently for alemtuzumab, cladribine or mitoxantrone. IRTs are not given continuously, and additional courses are given only if inflammatory activity recurs. IRTs can induce long-term remission and, in some cases, potentially a cure.

Maintenance therapies, by comparison, are given continuously without an interruption in dosing (‘continuous’ administration may be daily, one or more times weekly, monthly or even once every few months). Although maintenance therapies can induce long-term remission, they cannot, by definition, result in a cure. The recurrence or continuation of inflammatory activity indicates a suboptimal response to treatment and typically requires a treatment switch. Ideally, this switch should be an escalation to a more effective class of DMT.

An article in our list of key questions, entitled How do I want my MS to be treated?, provides a more detailed comparison of maintenance and IRT therapies, including frequency of administration, efficacy, risks, use in pregnancy, vaccine response and potential for a cure.

The DMTs currently licensed in the UK (in August 2024) are listed in the table under the relevant category.

table format updated 180625 SS

Disease-modifying therapies for MS licensed in the UK. *Please note, Bonspri is available in other markets but not the UK.

How effective are the different DMTs?

The measures used to assess the effectiveness of a DMT include its ability to reduce or prevent relapses, focal inflammatory activity (that is, new or enlarging lesions) on magnetic resonance imaging (MRI), and disability progression. Additional factors that can help to assess the relative efficacy of DMTs include the proportion of clinical trial subjects who experience improvement in disability and the impact of the treatment on brain volume loss.

The MS-Selfie InfoCards are an easy-to-use resource to help people with MS compare the key features of each DMT. They contain bite-sized information designed to aid treatment choices and an overview of the key aspects of each DMT.

Efficacy of the licensed DMTs for MS can be visualised as pyramid, with the moderately effective treatments at the bottom and the more effective approaches at the top. What determines the most appropriate DMT efficacy level for an individual depends on several factors, such as baseline prognostic profile, family planning requirements, local or national treatment guidelines, socioeconomic factors, consideration of any co-existing illnesses, cognitive impairment, risk aversion and lifestyle issues.

Pyramid format updated 180625 SS

UK licensed DMTs for MS, in ascending order of efficacy.
HSCT/AHSCT, haematopoietic stem cell transplantation/autologous haematopoietic stem cell transplantation.

What is the goal of treatment? Introducing NEIDA as a target

In the past, we used no evident disease activity (NEDA) as a treatment target. ‘Disease activity’ included progression or disease worsening independent of relapse activity (termed smouldering MS). Although some of the more effective DMTs may modify this stage of the disease, many neurologists feel uncomfortable switching or stopping a DMT based simply on smouldering MS disease activity. 

Relapses and ongoing focal MRI activity are associated with a worse short-term to intermediate-term prognosis. These observations have led to the increasing adoption of ‘no evident inflammatory disease activity’ (NEIDA) as a new treatment target. For more information about treatment targets, please see the article in our key questions, Do I understand the concepts of treat-2-target and NEDA?

Many healthcare professionals (HCPs) remain sceptical of using NEIDA as a treatment target, fearing that this could lead to more people with MS being on ‘riskier’ high-efficacy therapies. However, achieving long-term remission, or NEIDA, is a well-established treatment target in other autoimmune diseases such as rheumatoid arthritis and inflammatory bowel disease. People with MS treated-to-target of NEIDA from the outset do better than those whose treatment is escalated following breakthrough disease (at a clinical or subclinical/MRI level)1. I would, therefore, strongly encourage people with MS and their HCPs to adopt NEIDA as an initial treatment target.

Flipping the pyramid

The effectiveness, or relative effectiveness, of individual DMTs becomes less critical in the context of a treatment target of NEIDA. Choosing a DMT with a lower efficacy rate simply means that a greater proportion of treated people with MS will need to be switched to higher efficacy therapies over time to achieve NEIDA. We refer to the latter of these three approaches – starting with high-efficacy treatment – as flipping the pyramid. In recent trials of alemtuzumab, ocrelizumab, ofatumumab and ublituximab, people with MS randomised to 2 years of lower efficacy DMTs (interferon-beta-1a or teriflunomide) had poorer outcomes than those receiving highly active therapy from the outset. Real-world data from registries also support this; groups of people with MS with delayed access to high-efficacy DMTs did worse than those who received high-efficacy treatments early.1,2

Horizontal versus vertical switching

If we consider the conventional step care paradigm, people with MS who switch horizontally from interferon-beta to glatiramer acetate, or vice-versa (i.e. from one moderate efficacy DMT to another moderate efficacy DMT) do less well than those who switch vertically to fingolimod, a highly effective DMT. Similarly, people with MS escalating to natalizumab, a very high-efficacy DMT, do better than those being escalated to the less effective, but still high-efficacy, DMT fingolimod. 

Continuous and intermittent immunosuppression

Another useful way of classifying DMTs is whether they are immunosuppressive, that is, they reduce the activation, or effectiveness, of the immune system. Drug regulators stipulate that a drug may be classified as immunosuppressive if it (1) causes significant lymphopaenia (low lymphocyte count) or leukopenia (low white blood cell count), (2) is associated with opportunistic infections, (3) reduces the antibody and immune response to vaccines and (4) increases the risk of secondary malignancies.

The duration and intensity of immunosuppression further determine the risks. For example, short-term or intermittent immunosuppression associated with IRTs front-loads the risks, which are substantially lower once the immune system has reconstituted itself. In comparison, long-term continuous or persistent immunosuppression, which occurs with some of the maintenance DMTs, accumulates problems over time, particularly opportunistic infections and secondary malignancies. You can read more detail on this topic in the key question How immunosuppressed am I? The following table summarises the main attributes of intermittent and persistent immunosuppression.

How immunosuppressed are you table updated format 180625 SS

The main characteristics of continuous (persistent) and short-term (intermittent) immunosuppression. Modified from Giovannoni, Curr Opin Neurol.2
AHSCT, autologous haematopoietic stem cell transplantation; PML, progressive multifocal leukoencephalopathy.

Adverse effects, monitoring and risk reduction

The complications associated with immunosuppression vary from DMT to DMT. Each individual drug summary in the DMTs section of MS-Selfie contains detailed information about the main adverse events, key monitoring requirements, use (or contraindication) during pregnancy and breastfeeding, and response to vaccines. The MS-Selfie InfoCards provide bite-sized summaries of several practical aspects, including side effects, to enable easy comparison of any treatments you are considering; some of this information is collated below for easy reference.

Short-term versus long-term adverse effects

Each drug has been given scores from 1 to 10 based on published analyses of its short-term and long-term side effects. Short-term refers to side effects that emerge when a treatment is started and decrease in severity or disappear within days or weeks. A well-known example of short-term side effects on starting interferon-beta is flu-like symptoms that typically abate within 4 ̶ 8 weeks.

A long-term side effect persists for months or doesn’t disappear on continuing the DMT. Examples include intermittent but persistent flushing after taking dimethyl fumarate, or low B lymphocyte counts with anti-CD20 therapies that may lead to low antibody or immunoglobulin levels (hypogammaglobulinaemia).

A low score denotes few or rare side effects; a high score denotes many or frequent side effects. The score does not correlate to a percentage. More information can be found in each drug summary and the manufacturer’s Summary of Product Characteristics.

Scores for short-term and long-term side effects assigned to the individual DMTs summarised in the MS-Selfie InfoCards, based on a published network meta-analysis.3
Alem, alemtuzumab; GA, glatiramer acetate; HSCT, haematopoietic stem cell transplantation; IFN-beta; interferon-beta; Nat, natalizumab.

Monitoring and risk reduction

Numerous tests are carried out at the start of treatment, and ongoing monitoring is required for many factors, to reduce the risk from adverse events. The key question, How can I reduce my chances of adverse events on specific DMTs?, explains what needs to be done at the start of DMT administration (baseline) and during subsequent monitoring. The specifics vary from DMT to DMT; please refer to the individual summaries for details such as baseline tests, follow-up, infection prevention, cancer risk, pregnancy, breastfeeding and vaccination. It is important to remember that all licensed MS DMTs have had a thorough risk ̶ benefit assessment, and their benefits are considered to outweigh the potential risks.

Administration and other practical considerations

Routes and frequency of administration

The MS-Selfie InfoCards contain a symbol for each DMT, showing how it is administered. Some DMTs are available in more than one formulation (e.g. tablets and injection). The frequency of administration varies greatly from DMT to DMT; please consult the relevant summary in the DMTs section and discuss your preferences and priorities with your MS HCP.

The route of administration for each drug in the MS-Selfie InfoCards is clearly identified by the relevant symbol. (If a DMT is available in more than one formulation, there is a separate card for each delivery route.)

Number of clinic visits

It may be important for you to consider the frequency of clinic visits. This will depend on factors such as the delivery route of your DMT, the monitoring requirements of the drug regulators and the risk of specific side effects. The table below summarises the assessments from the MS-Selfie InfoCards. This is another factor to consider in discussions with your MS HCPs about the most appropriate DMT for you.

Conclusions

People with MS must understand the objectives of MS treatments and the different treatment strategies currently available to achieve these objectives. Although the MS therapeutic landscape is complex and hence may seem overwhelming, framing the choices using a relatively simple construct should help each individual to make informed decisions about managing their MS. MS-Selfie aims to guide you in the process of deciding on the most appropriate therapeutic strategy and specific DMT for treating your disease.

References

  1. Rotstein D, et al. Association of No Evidence of Disease Activity with no long-term disability progression in multiple sclerosis: a systematic review and meta-analysis. Neurology 2022;99:e209̶ ̶ 20.
  2. Giovannoni G. Disease-modifying treatments for early and advanced multiple sclerosis: a new treatment paradigm. Curr Opin Neurol 2018;31:233 ̶ 43.
  3. Samjoo IA, et al. Efficacy classification of modern therapies in multiple sclerosis. J Comp Eff Res 2021;10:495–507.
Brain health and holistic management of MS, Treatment strategy

What are the consequences of not treating MS?

Are there valid reasons not to treat MS with a disease-modifying therapy? What are the consequences of not treating MS? Is watchful waiting justified?

Key points

  • Untreated MS will, given time, result in physical disability, impaired quality of life and ‘hidden’ problems such as cognitive impairment, anxiety and depression.
  • Brain atrophy, or shrinkage, occurs at a faster rate in people with MS than in healthy individuals.
  • Optic neuritis, inflammation or destruction of nerve fibres in the brain and spinal cord, and extensive damage to the cerebral cortex (grey matter) are some consequences of MS lesion development.
  • Quality of life impacts may include reduced mobility, relationship difficulties, increased likelihood of unemployment and memory impairment.
  • Without treatment, the life expectancy of people with MS is reduced by about 6 ̶ 8 years.
  • There are, however, several valid reasons why some people with MS prefer not to receive disease-modifying treatments.

Risks from no disease-modifying treatment

Many patients ask me what will happen to their MS if they don’t take a disease-modifying treatment (DMT) and how effective DMTs are at preventing negative outcomes. Here I try and address questions you need to ask yourself before starting a DMT.

If you are an individual with MS, predicting your disease course is difficult. However, many studies monitoring groups of people with MS show patterns in relation to the progression of the disease and its outcome, with various data sets being consistent.

Given sufficient time, most people with MS who are not treated will become disabled. Most people focus on physical disability, but MS causes many hidden problems, such as cognitive impairment, anxiety and depression.

How untreated MS can progress – headline results

The slides below summarise some of the outcomes of untreated MS; these include brain changes (atrophy), further MS lesion development, reduced health-related quality of life, long-term impact on physical and mental health and shorter life expectancy. (To enlarge an individual slide, click on the arrow at the top right.)

Brain changes
MS lesion development
Quality of life impact
Long-term outlook

DMTs have changed the landscape

It is important to note that these outcomes are from the pre-DMT era and don’t apply to populations of people with MS treated with DMTs. New real-life data indicate that DMTs, particularly high-efficacy DMTs, are preventing many of these problems. By not being on a DMT, if you have active MS, you are at risk of acquiring damage from focal inflammatory lesions. Early in the disease course, you may not be aware of this damage because of the remarkable capacity of the nervous system to compensate for damage (neurological reserve). However, once the compensatory mechanisms have been exhausted, further damage results in overt disability. It is important to regard DMTs as preventive treatments, i.e. their aim is to delay, and hopefully prevent, future disability.

Possible reasons for not receiving a DMT

Many people with MS will not be on a DMT, for a variety of reasons. The list below is probably not extensive; if you know of other reasons why someone who qualifies is not taking a DMT, please let me know.

Inactive MS

Someone with inactive MS will not be eligible for a DMT. There is no standard definition of active MS. To me, active MS is recent evidence of focal inflammatory disease activity, defined as:

  • clinical relapse(s) in the last 2 years
  • OR magnetic resonance imaging (MRI) activity in the last 12 ̶ 36 months (new or enlarging T2 lesions or T1 Gd-enhancing lesions)
  • OR a raised cerebrospinal fluid (CSF) neurofilament light chain level in the last 12 months.

Worsening disability in MS without focal inflammatory disease activity is not active disease. It can be due to damage caused by past inflammation, smouldering MS or the effects of premature ageing; anti-inflammatory DMTs can’t address this problem. We need different types of DMTs to address these mechanisms – for example, neuroprotective and/or remyelination therapies and anti-ageing therapies.

Watchful waiting

In many situations, some neurologists think someone with MS will end up having benign disease, so they are not prepared to start treatment until the patient develops some overt disability. I abhor this practice and it is one of the reasons I spend so much of my time disseminating knowledge and getting involved with health politics. Watchful waiting, in terms of treating MS, is not supported by data. The earlier and more effectively you treat MS, the better the outcome. The only situation I could condone watchful waiting in someone with active MS is when the diagnosis of MS is in question. Sometimes in neurology, time is the best diagnostician. If the person has MS, it will declare itself with further disease activity, and this would be the trigger to start a DMT.

Family planning

Trying to fall pregnant, pregnancy or breastfeeding are common reasons to interrupt or stop DMTs. Please note that most neurologists now have options to treat MS during pregnancy and while breastfeeding, so this is becoming a less common reason for not taking a DMT.

Risk aversion

Some people with MS are not prepared to take the potential risks associated with DMTs.

Personal reasons

Some people with MS don’t believe in having their MS treated, preferring to try alternative medicines and turn down traditional DMTs. If you are one of these people, I would recommend you continue to interact with your MS team and have regular monitoring of your MS (clinical, MRI, patient-related outcome measures [PROMS] and possibly CSF analyses). Then, if these alternative strategies don’t work, you will keep open the option of treatment with a ‘traditional DMT‘. Most alternative treatment strategies for MS are compatible with DMTs and hence should be viewed as complementary. Understanding the difference between complementary and alternative treatments is important. Complementary treatment strategies are part of the holistic management of MS.

Financial constraints

In some parts of the world, MS treatment is not covered by a national health service or medical insurance scheme and some people with MS simply can’t afford DMTs. Even in rich countries, people with MS who are disenfranchised don’t have access to treatment; these may include illegal immigrants, refugees and asylum seekers waiting for their applications to be processed.

Progressive or more advanced MS

In most countries, neurologists don’t initiate treatment in patients with more advanced MS. This approach is based on a lack of evidence of the effectiveness of DMTs in this population. However, we are increasingly offering ocrelizumab (for active primary progressive MS), siponimod (for active secondary progressive MS) or off-label therapies on a compassionate basis to people with more advanced MS. In addition, there is also the potential to participate in clinical trials of new treatments for more advanced MS.

Ageism

Some healthcare systems and some neurologists are reluctant to start DMTs in people with MS who are over a certain age. This is based on a lack of evidence of the effectiveness of DMTs in this population, and it is why we need to do clinical trials in older people with MS.

Comorbidities

Many people have other medical problems for which the treatment takes priority over the treatment of MS. For example, a patient of mine was diagnosed with stage four bowel cancer. After her surgery, she started an intensive period of chemotherapy during which we stopped her DMT.

References

  1. Fisher E, et al. Gray matter atrophy in multiple sclerosis: a longitudinal study. Ann Neurol 2008;64:255–65.
  2. Barkhof F, et al. Imaging outcomes for neuroprotection and repair in multiple sclerosis trials. Nat Rev Neurol 2009;5:256–66.
  3. Simon JH. Brain atrophy in multiple sclerosis: what we know and would like to know. Mult Scler 2006;12:679–87.
  4. Ziemssen T, et al. Optimizing treatment success in multiple sclerosis. J Neurol 2016;263:1053–65.
  5. Hickman SJ, et al. Detection of optic nerve atrophy following a single episode of unilateral optic neuritis by MRI using a fat-saturated short-echo fast FLAIR sequence. Neuroradiology 2001;43:123–8.
  6. Trapp BD, et al. Axonal transection in the lesions of multiple sclerosis. N Engl J Med 1998;338:278–85.
  7. Peterson JW, et al. Transected neurites, apoptotic neurons, and reduced inflammation in cortical multiple sclerosis lesions. Ann Neurol 2001;50:389–400.
  8. Orme M, et al. The effect of disease, functional status, and relapses on the utility of people with multiple sclerosis in the UK. Value Health 2007;10:54–60.
  9. Pfleger CC, et al. Social consequences of multiple sclerosis (1): early pension and temporary unemployment – a historical prospective cohort study. Mult Scler 2010;16:121–6.
  10. Kobelt G, et al. Costs and quality of life of patients with multiple sclerosis in Europe. J Neurol Neurosurg Psychiatry 2006;77:918–26.
  11. Feuillet L, et al. Early cognitive impairment in patients with clinically isolated syndrome suggestive of multiple sclerosis. Mult Scler 2007;13:124–7
  12. Confavreux C and Compston A. Chapter 4. The natural history of multiple sclerosis. In: McAlpine’s Multiple Sclerosis, Fourth Edition, 2006; 183 ̶ 272. Churchill Livingstone.
  13. Weinshenker BG et al. The natural history of multiple sclerosis: a geographically based study. I. Clinical course and disability. Brain 1989;112:133 ̶ 46.
  14. Torkildsen GN, et al. Survival and cause of death in multiple sclerosis: results from a 50-year follow-up in Western Norway. Mult Scler 2008;14:1191–8.
  15. Kingwell E, et al. Relative mortality and survival in multiple sclerosis: findings from British Columbia, Canada. J Neurol Neurosurg Psychiatry 2012;83:61–6.
  16. Sadovnick AD, et al. Cause of death in patients attending multiple sclerosis clinics. Neurology 1991;41:1193–6.
  17. Brenner P, et al. Multiple sclerosis and risk of attempted and completed suicide – a cohort study. Eur J Neurol 2016;23:1329–36

Brain health and holistic management of MS, Causes and prevention of MS

What prognostic group do I fall into?

Having some idea of how bad your MS is, or not, will allow you to discuss important issues with your neurologist so that you can make an informed decision about your MS treatment.

Key points

  • It is hard to predict the disease course of MS accurately for an individual.
  • Population data allow us to define three broad prognostic MS categories: good, indeterminate or poor.
  • Given sufficient time, most people with MS will do badly without treatment.
  • Factors linked to poor prognosis in untreated people with MS are listed.
  • The wide use of disease-modifying therapies is changing the natural history of MS for the better.
  • Adopting a healthy lifestyle, in parallel with appropriate treatment, can help to improve outcomes.  

Predicting MS outcomes: an imperfect science

We can’t predict the prognosis of an individual person with MS very accurately. So don’t let your neurologist mislead you if he or she says you are likely to have benign MS. ‘Benign MS’ is a relative term and can only be used retrospectively once you have had MS for many years or decades. In the era before disease-modifying treatments (DMTs), most people with MS would eventually become disabled, which is why I prefer not to use the term benign MS to predict outcomes. I now use it as a treatment aim, because we want all people with MS to have benign disease.

Three broad prognostic categories

Applying population data to place an individual into a broad prognostic group is often helpful. It allows you to frame your disease in terms of potential outcomes and may help you balance the risks of some treatments against the potential impact of MS later in your life. Predicting outcomes in MS is comparable to an actuary working in the insurance industry; we try to give you an average prognosis with a wide range of possibilities or errors. For this reason, I try to keep it simple and classify people with MS into three prognostic categories: poor, indeterminate, or good. Poor in this context means that if you leave MS to its own devices and let it run its natural course, the average person in this category will do badly.

Most people with a predicted poor prognosis will do badly without treatment for their MS.

Given sufficient time, most people with MS will deteriorate without treatment. This is why I actively promote treatment based on the scientific rationale that preventing damage now will protect your brain reserve and cognitive reserve and improve your long-term outcome. This is the philosophy behind the MS Brain Health initiative and the report Brain health: time matters in multiple sclerosis,1 which everyone with MS should take time to read. 

Factors linked to poor prognosis

Below is a list of factors that have been linked to poor prognosis in people who have not received a DMT. If you have fewer than five of these factors, you are likely to have a good outcome. In comparison, people with ten or more of these factors fall into the poor prognostic group. Most people with MS fall into the intermediate (indeterminate) prognostic group, with 5–10 of these factors. Some of these baseline factors are modifiable,2,3 so you can make the effort to help improve your own prognosis

Please note that the factors listed here only apply to people with MS who are untreated.  It is clear that DMTs are changing the outcome of MS.

  1. Older age of onset (greater than 40 years).
  2. Male sex.
  3. Multifocal onset – more than one site in the nervous system involved with the initial attack.
  4. Efferent or effector system is affected early – that is, the motor (power), cerebellar (balance and coordination) or bladder and bowel functions.  
  5. Partial or no recovery from initial relapses – do you have residual deficits from your initial attacks?
  6. A high relapse rate in the first 2 years – that is, more than two relapses. 
  7. Early disability – an Expanded Disability Status Scale (EDSS) score > 3.0 within 5 years of symptom onset indicates a poor prognosis. You can calculate your EDSS using an online calculator (web-EDSS calculator).
  8. Abnormal magnetic resonance imaging (MRI) scan with large lesion load – more than nine T2 lesions (white blobs) on the baseline MRI.
  9. Active or enhancing lesions on your baseline (initial) MRIenhancing lesions imply that the lesions are new and actively inflamed.
  10. Posterior fossa lesions on the MRI – these refer to lesions in the back of the brain that involve the brainstem and cerebellum.
  11. Lesions in the spinal cord on MRI.
  12. Obvious early brain atrophy on MRI – brain atrophy refers to premature shrinkage of the brain over and above what you would expect for your age. This information is unlikely to be available to you because neuroradiologists often do not measure or comment on it. 
  13. Retinal thinning on optic coherence tomography (OCT) – people with MS who have lost a lot of retinal nerve fibres do worse than people with a normal retina. Yes, the eye is truly a window into what is happening in the brain of someone with MS. 
  14. Abnormal cerebrospinal fluid – positive immunoglobulin (Ig) bands (known as oligoclonal bands, OCBs) in the spinal fluid.
  15. Raised neurofilament levels in your spinal fluid – this test may not be part of routine care at your neurology centre. Neurofilaments are proteins that are released from damaged nerve fibres, and high neurofilament levels indicate greater damage and poorer outcome than low levels.
  16. Low vitamin D levels – this is controversial, but several studies have shown that people with MS with low vitamin D levels do worse than those with higher levels. These observations do not necessarily imply that by taking vitamin D you will do better. Low vitamin D levels may be related to reverse causation, in that the MS-associated inflammation uses up vitamin D; more inflammation indicates worse MS and is therefore linked with greater depletion of vitamin D levels.
  17. Smoking – smokers with MS do worse than non-smokers. This is modifiable and it is one of many reasons why you should try and give up smoking. 
  18. Comorbidities – people with MS who are obese, have diabetes, prediabetes, hypertension or raised cholesterol do worse than people with MS without these comorbidities.4
  19. Cognitive impairment – people with MS with poor cognitive function do worse than people with MS with good cognition. You can’t really assess your own cognition at present; you need to have it tested by a neuropsychologist.

‘It won’t happen to me’

Humans have interesting psychology in that they tend to consider themselves to be the exception to the rule. Gamblers don’t enter a casino to lose; they always believe they will win. A person with lung cancer who starts chemotherapy believes they will be one of the 10% who is cured. When someone is diagnosed with MS, they believe they will be one of the 30% with benign disease. (The current view among MS neurologists is that 30% of untreated people with MS will have benign disease.) 

This definition of ‘benign MS’ is based on having no or little disability at 15 years since onset, i.e., an EDSS score of 3.0 or less (no visible disability). However, when you interrogate people with so-called benign MS you find that more than 50% of them have hidden symptoms of depression, anxiety or cognitive impairment. Can we really justify this definition of benign MS? What is more, when you follow people with benign MS past 15 years, only 15% remain benign at 25 years and 5% at 30 years. If you get to 40 years of follow-up, half of these with benign MS will become disabled over the next 10 years.

Moving towards a more favourable outcome

Many will state that these figures are now out of date and there are newer and better figures, which show MS is a more benign disease. You are right, and there are several very good reasons for this. In population-based studies, the proportion of subjects with benign MS is greater than in hospital- or clinic-based studies; for example, in the Olmsted Mayo Clinic MS population, about 45% have benign disease at 15 years. The reason for this is that people with MS with benign disease often drop out of hospital follow-up, but still show up in population-based studies. 

The earlier diagnosis of MS, that is, identification of those who would not have been diagnosed in the past, is changing the definition of MS. For example, most people with a clinically isolated syndrome (CIS) are now being diagnosed as having MS. The wide use of DMTs is beginning to change the natural history of MS for the better; making sure that people with MS adopt a healthy lifestyle is another strategy that can be done in parallel. 

With currently available high-efficacy DMTs and the prospect of effective combination treatments in the future, the proportion of people with MS who experience normal ageing is set to increase. The blue areas illustrate the likely number of people with MS in each prognostic category.
With currently available high-efficacy DMTs and the prospect of effective combination treatments in the future, the proportion of people with MS who experience normal ageing is set to increase. The blue areas illustrate the likely number of people with MS in each prognostic category.
With currently available high-efficacy DMTs and the prospect of effective combination treatments in the future, the proportion of people with MS who experience normal ageing is set to increase. The blue areas illustrate the likely number of people with MS in each prognostic category.
With currently available high-efficacy DMTs and the prospect of effective combination treatments in the future, the proportion of people with MS who experience normal ageing is set to increase. The blue areas illustrate the likely number of people with MS in each prognostic category.

With currently available high-efficacy DMTs and the prospect of effective combination treatments in the future, the proportion of people with MS who experience normal ageing is set to increase. The blue areas illustrate the likely proportion of people with MS in each prognostic category.

The above figures illustrate what we aim to do with currently available high-efficacy DMTs (compared with older, lower efficacy treatments). We are simply trying to move you to the right, into a more favourable prognostic group. In other words, we want to make sure your MS is benign and that you reach old age with as healthy a brain as possible. Your brain reserve and cognitive reserve protect you from developing age-related cognitive impairment and dementia. MS reduces both of these reserves, which is why it is so important to protect them. With the prospect of effective combination treatments in the future, the proportion of people with MS who experience normal ageing is set to increase.

References

  1. Giovannoni G, et al. Brain health: time matters in multiple sclerosis. 2015, Oxford Health Policy Forum CIC.
  2. Miller DH, et al. Clinically isolated syndromes. Lancet Neurol 2012: 11:157–69.
  3. Weld-Blundell IV, et al. Lifestyle and complementary therapies in multiple sclerosis guidelines: Systematic review. Acta Neurol Scand 2022;145:379–92.
  4. Kappus N, et al. Cardiovascular risk factors are associated with increased lesion burden and brain atrophy in multiple sclerosis. J Neurol Neurosurg Psychiatry 2016;87:181–7.